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The Cochrane Database of Systematic Reviews logoLink to The Cochrane Database of Systematic Reviews
. 2019 Nov 25;2019(11):CD011284. doi: 10.1002/14651858.CD011284.pub2

Individual recovery expectations and prognosis of outcomes in non‐specific low back pain: prognostic factor review

Jill A Hayden 1,, Maria N Wilson 2, Richard D Riley 3, Ross Iles 4, Tamar Pincus 5, Rachel Ogilvie 6
Editor: Cochrane Back and Neck Group
PMCID: PMC6877336  PMID: 31765487

Abstract

Background

Low back pain is costly and disabling. Prognostic factor evidence can help healthcare providers and patients understand likely prognosis, inform the development of prediction models to identify subgroups, and may inform new treatment strategies. Recent studies have suggested that people who have poor expectations for recovery experience more back pain disability, but study results have differed.

Objectives

To synthesise evidence on the association between recovery expectations and disability outcomes in adults with low back pain, and explore sources of heterogeneity.

Search methods

The search strategy included broad and focused electronic searches of MEDLINE, Embase, CINAHL, and PsycINFO to 12 March 2019, reference list searches of relevant reviews and included studies, and citation searches of relevant expectation measurement tools.

Selection criteria

We included low back pain prognosis studies from any setting assessing general, self‐efficacy, and treatment expectations (measured dichotomously and continuously on a 0 ‐ 10 scale), and their association with work participation, clinically important recovery, functional limitations, or pain intensity outcomes at short (3 months), medium (6 months), long (12 months), and very long (> 16 months) follow‐up.

Data collection and analysis

We extracted study characteristics and all reported estimates of unadjusted and adjusted associations between expectations and related outcomes. Two review authors independently assessed risks of bias using the Quality in Prognosis Studies (QUIPS) tool. We conducted narrative syntheses and meta‐analyses when appropriate unadjusted or adjusted estimates were available. Two review authors independently graded and reported the overall quality of evidence.

Main results

We screened 4635 unique citations to include 60 studies (30,530 participants). Thirty‐five studies were conducted in Europe, 21 in North America, and four in Australia. Study populations were mostly chronic (37%), from healthcare (62%) or occupational settings (26%). General expectation was the most common type of recovery expectation measured (70%); 16 studies measured more than one type of expectation.

Usable data for syntheses were available for 52 studies (87% of studies; 28,885 participants). We found moderate‐quality evidence that positive recovery expectations are strongly associated with better work participation (narrative synthesis: 21 studies; meta‐analysis: 12 studies, 4777 participants: odds ratio (OR) 2.43, 95% confidence interval (CI) 1.64 to 3.62), and low‐quality evidence for clinically important recovery outcomes (narrative synthesis: 12 studies; meta‐analysis: 5 studies, 1820 participants: OR 1.89, 95% CI 1.49 to 2.41), both at follow‐up times closest to 12 months, using adjusted data. The association of recovery expectations with other outcomes of interest, including functional limitations (narrative synthesis: 10 studies; meta‐analysis: 3 studies, 1435 participants: OR 1.40, 95% CI 0.85 to 2.31) and pain intensity (narrative synthesis: 9 studies; meta‐analysis: 3 studies, 1555 participants: OR 1.15, 95% CI 1.08 to 1.23) outcomes at follow‐up times closest to 12 months using adjusted data, is less certain, achieving very low‐ and low‐quality evidence, respectively. No studies reported statistically significant or clinically important negative associations between recovery expectations and any low back pain outcome.

Authors' conclusions

We found that individual recovery expectations are probably strongly associated with future work participation (moderate‐quality evidence) and may be associated with clinically important recovery outcomes (low‐quality evidence). The association of recovery expectations with other outcomes of interest is less certain. Our findings suggest that recovery expectations should be considered in future studies, to improve prognosis and management of low back pain.

Plain language summary

The impact of individual recovery expectations on pain, limitations in activities and return to work in low back pain

What is the aim of this review?

The aim of this Cochrane Review is to find out if positive recovery expectations of people with low back pain are related to their future pain, activities they are able to do and return to work. Are people who think they will recover from their low back pain more likely to get better?

Key messages

People with low back pain who have positive expectations of their own recovery are more likely to return to work and to recover from pain and increase the activities they are able to do.

What was studied in this review?

Low back pain is costly and causes a lot of disability. It is important to understand what characteristics of a person with low back pain are connected with how well they will recover (also known as their ‘prognosis’). People’s characteristics are often not changeable, including a characteristic like age. However, there is evidence that someone’s expectations of recovery may be changeable. If positive expectations are indeed connected to improved back pain outcomes then helping a person to have positive expectations of their own recovery may help them to recover.

For this review, we examined three types of recovery expectations and their relation to back pain outcomes: general expectations of recovery (e.g. will your back pain last only a short time?), self‐efficacy expectations (e.g. do you believe you will be able to return to your normal activities?) and treatment expectations (e.g. will physiotherapy improve your back pain?).

What are the main results of this review?

We reviewed 4635 references and included 60 relevant studies. These studies included information about 30,530 people with low back pain. They looked at people's expectations of their own recovery and how that was related to their pain, limitations in activities and return to work one year after their back pain episode.

Overall, we found good evidence that positive expectations of recovery are related to a higher likelihood of returning to work. The evidence about positive recovery expectations with other recovery, limitations in activities and pain intensity outcomes is not as strong. We did not find any studies that showed that positive expectations of recovery were related to worse low back pain outcomes.

How up‐to‐date is this review?

The review authors searched for studies that had been published up to 12 March 2019.

Summary of findings

for the main comparison.

Individual recovery expectations as a prognostic factor for low back pain
Patient or population: People with non‐specific low back pain presenting to healthcare, occupational, general or mixed populations
Prognostic factor: Individual recovery expectations (measured dichotomously or continuously, as noted)
Outcomes Reported adjusted
associations,
# studies
(# participants)
Phase of investigation,
# studies exploratory;
confirmatory
(# participants)
Meta‐analysis,
# study groups
(# participants)
Meta‐analysis relative effect
 (95% CI) Quality of the evidence
 (GRADE) Comments
(rating of factors considered)
WORK PARTICIPATION
Follow‐up: closest to 12 months
Positive: 16 (4324)
Neutral: 5 (2473)
Negative: 0
16 E (5529);
5 C (1268)
13 (4777)a OR 2.43 (1.64 to 3.62)a ⊕⊕⊕⊝
 moderate Limitations (ROB): Serious
Inconsistency: No serious
Indirectness: No serious
Imprecision: No serious
Publication/reporting bias: Serious
Effect size reported: Mod‐Large
Dose effect: N/A
Confirmatory evidence: Available
IMPORTANT RECOVERY
Follow‐up: closest to 12 months
Positive: 6 (7265)
Neutral: 6 (996)
Negative: 0
12 E (8261);
0 C
5 (1820)a OR 1.89 (1.49 to 2.41)a ⊕⊕⊝⊝
 low Limitations (ROB): Serious
Inconsistency: No serious
Indirectness: No serious
Imprecision: No serious
Publication/reporting bias: Serious
Effect size reported: Mod‐Large
Dose effect: N/A
Confirmatory evidence: Not available
FUNCTIONAL LIMITATIONS
Follow‐up: closest to 12 months
Positive: 6 (1397)
Neutral: 4 (2079)
Negative: 0
6 E (2825);
4 C (651)
3 (1435)b OR 1.40 (0.85 to 2.31)b ⊕⊝⊝⊝
 very low Limitations (ROB): Serious
Inconsistency: Serious
Indirectness: No serious
Imprecision: Serious
Publication/reporting bias: Serious
Effect size reported: Small
Dose effect: N/A
Confirmatory evidence: Available
PAIN INTENSITY
Follow up: closest to 12 months
Positive: 5 (1510)
Neutral: 4 (1216)
Negative: 0
4 E (1174);
5 C (1552)
3 (1555)b OR 1.15 (1.08 to 1.23)b ⊕⊕⊝⊝
 low Limitations (ROB): Serious
Inconsistency: No serious
Indirectness: No serious
Imprecision: No serious
Publication/reporting bias: Serious
Effect size reported: Small
Dose effect: N/A
Confirmatory evidence: Available
GRADE Working Group grades of evidence
 High quality: Further research is very unlikely to change our confidence in the estimate of effect.
 Moderate quality: Further research is likely to have an important impact on our confidence in the estimate of effect and may change the estimate.
 Low quality: Further research is very likely to have an important impact on our confidence in the estimate of effect and is likely to change the estimate.
 Very low quality: We are very uncertain about the estimate.
C = confirmatory phase study; E = exploratory phase study; OR = odds ratio; ROB = risk of bias

aDichotomous measure of expectations (adjusted results; follow‐up closest to 12 months). 
 bContinuous measure of expectations (scale /10; adjusted results; follow‐up closest to 12 months).

Background

Description of the health condition and context

Low back pain is one of the most common health conditions, and has high socioeconomic impact (Freburger 2009; Hoy 2010; Lim 2012). Approximately 540 million people are estimated to have nonspecific low back pain (GBD Collaborators 2016; Hartvigsen 2018b), and low back pain was identified in the most recent Global Burden of Disease study as the leading cause of disability globally (GBD Collaborators 2016). There is evidence that the prevalence and associated costs of low back pain are rising (Freburger 2009).

Researchers define low back pain as pain on the posterior aspect of the body from the lower margin of the twelfth ribs to the lower gluteal folds, with or without pain referred to the leg(s), that is severe enough to limit usual activities for more than one day (Dionne 2008). Most people who experience low back pain have ‘non‐specific low back pain’, a diagnosis of exclusion that includes heterogeneous presentation and symptoms not attributed to a recognisable, known specific pathology (for example, fracture, rheumatoid arthritis, infection, neoplasm, or metastasis).

Most the social and economic costs associated with low back pain are attributed to a small number of sufferers who have prolonged disability and require increased use of health services and time off work (Freburger 2009; Hayden 2010). Most individuals experiencing a new episode of low back pain will recover within a few weeks. However, a quarter to a third will continue to report low back pain after 12 months (Hayden 2010). Recurrences are common and individuals who develop chronic, longstanding low back pain tend to show a more persistent course (Hayden 2010); studies of chronic low back pain indicate that 42% to 75% from general populations (Hestbaek 2003), and 60% to 80% from healthcare consulting populations (Hayden 2010) will continue to have low back pain after one year.

Consideration of prognosis and prognostic factors are important in low back pain research and treatment. It has not been possible to identify a specific cause for most cases of low back pain, and interventions with strong evidence of effectiveness have not been identified. Research studies have found many factors to be associated with a poor outcome in low back pain, often with conflicting results (Hayden 2007). A ‘review of reviews’ study found that several factors were consistently reported to be associated with a poor outcome, including individual characteristics (older age, poor general health), factors related to the back pain episode characteristics (baseline disability, sciatica), and psychological characteristics (increased stress, negative cognitive characteristics), as well as social supports and the work environment (poor relations with colleagues, heavy physical demands, receipt of compensation) (Hayden 2009). However, there is still substantial inconsistency in findings reported across low back pain studies. There is also a need for more attention to be paid to the collection and consideration of prognostic factors within research studies, which could include considering prognostic factors in trial randomisation strategies, or adjusting for these factors in analyses. High‐quality evidence about prognostic factors associated with outcomes can improve management of low back pain by helping healthcare providers and patients to understand the likely prognosis, and can inform other research. This could include the development/refinement of outcome prediction models to identify subgroups of people with low back pain, identification of treatment effect modifiers, and influencing the development of new treatment strategies considering modifiable prognostic factors that potentially cause poor outcomes (Riley 2013).

Description of the prognostic factor

This Cochrane Review explores individual recovery expectations, a potentially modifiable prognostic factor that has shown promise in existing low back pain prognostic factor reviews (Fadyl 2008; Iles 2008; Iles 2009). Recovery expectations are what the individual ‘expects will occur’ in the future from their health condition. We referred to the Social Cognitive Theory (Bandura 1977; Bandura 2004) to develop a theoretical framework that guided our assessment of evidence about individual recovery expectations. In this model, individual recovery expectations involve cognitive processing and may be informed by past personal experience, knowledge and beliefs, and suggestions from or observations of other people. We consider three types of related individual recovery expectations relevant to the low back pain field: general expectations, self‐efficacy expectations, and treatment expectations. General expectations are broadly‐defined recovery expectations, related to a future low back pain outcome; an example of a single‐item question is: “I expect to return to work within six months”, or “My low back pain will last a short time”. Self‐efficacy expectations are a person’s perceptions about their ability to execute behaviours to achieve a future outcome; for example: “I believe that I will be able to do my usual work activities to return to my job”, or “I am confident that I will be able to learn to cope with the pain and get back to my normal activities”. Treatment expectations are expectations of future low back pain outcomes specifically related to ongoing treatment; for example: “My treatment will help improve my low back pain”, or “My treatment can prevent my back pain from getting worse”. Figure 1 presents our conceptual framework of the relationship between individual recovery expectations (hereafter referred to as ‘expectations’) and low back pain outcomes.

1.

1

Conceptual framework of the relationship between recovery expectations and LBP outcomes.

Health outcomes

Expectations may be related to low back pain outcomes through several possible pathways. These include modifying individual coping behaviours, withdrawal related to fear of pain or low mood, or by influencing treatment compliance or seeking health care. In Social Cognitive Theory, Bandura proposed that self‐efficacy expectations can modify individual behaviours by determining the amount of effort that a person will exert to cope with their health condition (Bandura 1977; Bandura 2004). Following the fear‐avoidance model (Vlaeyen 2000), processes related to the fear of pain may lead to avoiding movements and activities based on fear, hypervigilance to illness information, muscular reactivity, and disuse/deconditioning, all potentially leading to worse health outcomes (Price 1999). Furthermore, expectations may be associated with changes to treatment received due to modified compliance, overuse, or non‐compliance with medications and advice, or changes in health consulting behaviours, which may influence health outcomes.

Alternatively, expectations, which are influenced by what people know about themselves and their circumstances, may reflect at least in part a realistic evaluation of their likely prognosis. This would mean that attempts to modify expectations may constitute false reassurance and, at best, have no impact on outcomes.

Why it is important to do this review

Many primary studies using various research methods, including exploratory and confirmatory study design phases, have investigated the relationship between expectations and low back pain outcomes. The results of several studies suggest an association between expectations and low back pain outcomes. Kapoor 2006 reported that there was a medium to large effect size between negative patient expectations and return‐to‐work outcomes in an acute low back pain population. Other researchers have observed similar relationships between expectations and return‐to‐work outcomes in chronic low back pain populations (for example, Hagen 2005; Reme 2009; Sandstrom 1986; Schultz 2005). However, some studies have reported weak or no relationships between expectations and return‐to‐work outcomes (for example, Gross 2005; Schultz 2002). Gross 2005 found no significant association between work‐related recovery expectations and working status at one‐year follow‐up in a sample with subacute occupational low back pain.

Three focused systematic reviews have synthesised evidence about recovery expectations (Fadyl 2008; Hallegraeff 2012; Iles 2009). Fadyl 2008 reviewed the literature and included 10 studies that investigated how expectations relate to return‐to‐work outcomes after injuries (including, but not limited to, low back pain). These authors reported that evidence is limited, and they recommended further investigation. Hallegraeff 2012 conducted a review to assess whether negative expectations in people with acute low back pain resulted in increased odds of being off work. Ten studies were included and synthesised; the authors of this review concluded that the odds of not returning to work were twice as high for people with negative recovery expectations. Iles 2009 aimed to determine the predictive strength of negative recovery expectations for the outcome ‘activity limitations’ in people with acute or subacute non‐specific low back pain. The review included 10 studies and reported that recovery expectations measured within the first three weeks of low back pain onset are strong predictors of activity limitations. The literature searches of these reviews are now out of date. Furthermore, existing reviews about recovery expectations have not explored the impact of different types or measures of expectations, different populations (setting or duration of symptoms or both), or different outcomes (pain, functional limitations, return to work). These factors may explain some inconsistencies of results reported in the literature.

Objectives

To synthesise evidence on the association between recovery expectations and disability outcomes in adults with low back pain, and explore sources of heterogeneity.

Methods

We conducted this review within the framework of the Cochrane Back and Neck Group (Furlan 2015) and report it according to PRISMA guidelines (Moher 2009), while supplementing as necessary for a prognostic factor systematic review. Similar to systematic reviews of intervention studies, there are six key steps to prognosis reviews:

  1. Defining the review question

  2. Identifying studies

  3. Selecting studies

  4. Critically appraising studies

  5. Collecting data

  6. Synthesising and interpreting results

We considered each of these steps and used best methods to limit potential biases.

We conducted a focused systematic review (as opposed to a broad review that investigates evidence on many prognostic factors) to facilitate the most complete assessment and interpretation of the evidence available (Hayden 2009).

Criteria for considering studies for this review

Our review includes prognostic study evidence with the definitions of eligible participants (low back pain), the potential prognostic factor of interest (expectations), outcomes, and study designs described below (Table 2).

1. Components of the systematic review question.

Review question component Description
Population Adults with non‐specific low back pain (grouped as acute (< 6 weeks), subacute/chronic (≥ 6 weeks), and mixed duration), in any setting (grouped as worker, healthcare and general population settings)
Prognostic factor/comparator Individual recovery expectations, measured at an early point in management, with any reference period (grouped as 1 month, 6 months, or none/unclear reference period)
Primary outcomes Work participation, functional limitations, important recovery, or pain intensity
Time periods Short (closest to 3 months), medium (closest to 6 months), long follow‐up (closest to 12 months)a, and very long follow‐up (greater than 16 months)

a12 month follow‐up period prioritised for primary analyses

Types of study designs

We include published reports of prospective and retrospective longitudinal studies investigating the prognosis of low back pain with baseline (defined as each study onset) measurement of participant characteristics and at least three months’ follow‐up to study participant outcomes. We included publications presenting analyses of randomised controlled trials (RCTs) if they reported on the association between expectations and low back pain outcomes in the study population or a subgroup. We separately describe studies that included treatment effect modification analyses and also met our study selection criteria. We did not include treatment effect modification (interaction) evidence in our syntheses, but included data about the association between expectations and low back pain outcomes when available in these studies.

We separately considered phases of prognostic factor investigation: Phase 1 (exploratory), and Phase 2 (confirmatory) studies, which provide different levels of evidence (Hayden 2008). Exploratory studies identify associations of many potential prognostic factors and outcomes. While exploratory studies are necessary to identify new prognostic factors, they provide the least conclusive information about the independence of a variable as a valid prognostic factor, since results are often presented unadjusted or not adequately adjusted for known covariates. Studies in this exploratory phase of investigation often have widely varying results, as spurious associations are common due to the high number of factors explored, and studies may overstate their conclusions (Hayden 2008). Confirmatory studies, with analyses planned a priori, test the independence of the association between one specific (or just a few) prognostic factor(s) and the outcome of interest. These studies aim to measure the independent (additional) prognostic effect of a factor while controlling for known covariates (i.e. existing or established prognostic factors in the field). We classified included studies according to the authors’ objectives and approach to design and analysis, and considered the phase of investigation of studies in our assessment of the strength of the evidence available.

Target population

We included studies involving any population of adult participants with non‐specific low back pain, including general populations, occupational, and non‐surgical clinical populations. We included studies if they investigated mixed‐pain populations (including conditions other than low back pain, such as thoracic or neck pain, or healthy controls) only if the majority (more than 75%) of the study population was experiencing non‐specific low back pain, or subgroup information was presented for this population. We included studies where the operationalisation of low back pain was based on symptoms, signs, or consequences of low back pain such as sick leave, medical consultation, or treatment. We included studies with participants at any point in the course of low back pain from acute to subacute/chronic. We aimed to separately consider worker, healthcare and general populations, and explored subgroup analyses with acute (less than six weeks), subacute/chronic (six weeks or more), and mixed‐duration low back pain populations. We planned to use sensitivity analyses to explore the robustness of results, excluding studies with mixed pain or specific low back pain populations.

We excluded studies that involved a majority of individuals with low back pain caused by specific pathologies (including nerve root impingement, fracture, ankylosing spondylitis, spondyloarthritis, infection, neoplasm, or metastasis), or specific conditions (for example, pregnancy).

Types of index prognostic factors

We included studies that assessed expectations at baseline or an early point in patient management (i.e. at initial consultation). We defined expectations as ‘what participants expect will occur from their low back pain condition’. Included measures of expectations captured two things: 1. individual participant cognition (for example beliefs, perceptions, anticipations, expectations), and 2. related to a future outcome (for example pain, functional limitations, work participation). We separately considered evidence on general expectations, self‐efficacy expectations, and treatment expectations, when possible. We excluded current state or trait type of self‐efficacy measures, and expectations from outside perspectives (for example, healthcare provider expectations), as well as measures of expected ‘process of care’ if they did not refer to a future primary outcome of interest. We included studies investigating treatment expectations if the variable was assessed as a prognostic factor.

We included studies of expectations assessed using any measurement approach: one‐dimensional measurement of expectations, for example: “Do you expect that you will have recovered in six months?”, and more complex measurements, for example, using multidimensional validated measurement tools such as the Credibility/Expectancy Questionnaire (Smeets 2008), the Back Pain Self‐Efficacy Scale (Levin 1996), or the Pain Self‐Efficacy Questionnaire (Nicholas 2007). We used subgroup and sensitivity analyses to explore the impact of different and more robust measurement approaches, and the expectations reference time period (one month, six months, none or unclear reference period), when available.

Types of outcomes

Primary outcomes

We included studies with at least one of the following primary outcomes, according to the International Classification of Functioning, Disability and Health (ICF) framework (WHO 2002):

  1. Work participation, measured as return to work, absenteeism, or time on benefits (Steenstra 2012). If multiple measures were available, we selected dichotomous return‐to‐work measures over time to return to work or time on sick leave;

  2. Important recovery in functional limitations, pain intensity (as described below), and/or work participation;

  3. Functional limitations, measured by a low back pain‐specific scale (for example, the Roland‐Morris Disability Questionnaire (RMDQ) (Roland 2000), or the Oswestry Disability Index (ODI) (Fairbank 1980));

  4. Pain intensity, measured by a visual analogue scale (VAS) or other pain scale (for example, numerical rating scale (NRS), or McGill pain score (Melzack 1975)).

We recorded study‐reported associations of expectations with outcomes analysed using continuous measures of functional limitations or pain intensity (for example, RMDQ on a 24‐point scale, or pain VAS on a 10‐point scale), and with the measure dichotomised to reflect improvement at the described time points as reported in primary studies ("important recovery"). We included any study‐defined definition of improvement, but prioritised and separately considered evidence from studies that used an ideal definition of ‘improvement’ ‐ clinically important individual patient response where improvement in score is 30% or more of its baseline value, with a minimum value of 20‐point (/100) in pain and 10‐point (/100) in functioning (Kovacs 2007; Ostelo 2008).

We grouped outcome data into four time periods for analyses: short (closest to three months), medium (closest to six months), long follow‐up (closest to 12 months), and very long follow‐up (more than 16 months). For primary analyses, balancing homogeneity with availability of data, we used available study data from the time period closest to 12 months (defined as ‘long, closest to 12 months’).

Secondary outcomes

We identified the following secondary outcomes, when they were available in included studies:

  1. Global improvement or perceived recovery;

  2. Health‐related quality of life (for example SF‐36 (as measured by the general health sub‐scale) (Ware 1992), EuroQol (EuroQol Research Foundation 2019), general health (for example, as measured on a VAS scale) or similarly validated index);

  3. Satisfaction with treatment;

  4. Mood (for example, depression, measured with the Center for Epidemiologic Studies Depression Scale (CES‐D) (Radloff 1977));

  5. Healthcare use, including costs.

We excluded studies if they did not measure at least one of our primary outcomes; this is justified, as our primary outcomes were selected by our team as the most important patient‐oriented low back pain outcomes for prognosis, capturing body function, functional limitation and participation restriction (WHO 2002).

Search methods for identification of studies

The search strategy included electronic searches and additional strategies to retrieve as many relevant publications as possible.

Electronic searches

We conducted focused and broad electronic searches with the help of an experienced Information Scientist, using indexed terms and free‐text words, with no date or language restrictions. We searched the following sources from database inception to 12 March 2019.

  1. MEDLINE from Ovid MEDLINE(R) Epub Ahead of Print, In‐Process & Other Non‐Indexed Citations, Ovid MEDLINE(R) Daily and Ovid MEDLINE(R) (1946 to 12 March 2019);

  2. Embase from Embase.com (1974 to 12 March 2019);

  3. CINAHL from EBSCOhost with Full Text (1981 to 12 March 2019);

  4. PsycINFO from EBSCOhost (1887 to 12 March 2019).

Our focused search strategy included terms related to low back pain (Cochrane Back and Neck Group recommended strategy) (Furlan 2015), expectations, and prognostic study methods (prognosis strategy of Wilczynski 2004); see Appendix 1 for the full focused MEDLINE, Embase, CINAHL, and PsycINFO strategies.

We previously observed, in a ‘review of reviews’ on low back pain prognosis, the possible introduction of ‘positive study’ bias in review search strategies that include prognostic factor terms (Hayden 2009). We therefore also included results of a broad search in MEDLINE and Embase (Hayden 2007). This search strategy included terms related to low back pain and prognostic study methods, without focused terms related to expectations (Appendix 2).

Searching other resources

Recognising potential limitations of electronic search strategies, we supplemented our search to identify potentially relevant studies from other sources:

  1. Reference searches of relevant reviews, including previously published systematic reviews of expectations and low back pain or musculoskeletal pain (Darlow 2012; Fadyl 2008; Hallegraeff 2012; Iles 2009; Parsons 2007), identified broad systematic reviews of low back pain prognosis or prognostic factors (for example, Haskins 2012; Hendrick 2011; Menezes Costa 2012; Ramond 2011), and reference lists of all included studies for search up to 1 February 2018.

  2. Citation searches of relevant recovery expectation measurement tools (Devilly 2000; Levin 1996; Lim 2007; Metcalfe 2005; Nicholas 2007; Sarda 2007; Smeets 2008; Tate 1999).

  3. Review of personal files of investigators, which included authors of previous focused reviews of expectations (Iles 2009; Parsons 2007).

The comprehensive search was executed and downloaded into EndNote X8 for electronic bibliographic management.

Data collection

Selection of studies

We used an online electronic systematic review software package (DistillerSR) to organise and track the selection process. Two review authors (from MW, RO, JAH) or other contributor (from MT, JC, AS, EWP) with accelerated screening (i.e. consensus of two review authors required to exclude, one review author required to move a citation forward) conducted initial screening of titles identified through electronic searches, followed by screening titles and abstracts of citations for relevance, using a pre‐tested electronic form. We advanced studies if they comprehensively investigated prognostic factors or prediction models associated with any one of our primary outcome measures in a non‐specific low back pain population or subgroup. We resolved disagreements by consensus and by recourse to a third review author. We retrieved all articles in full deemed to be relevant, or for which the relevance could not be determined from the abstract.

A challenge in prognostic factor systematic reviews is that determination of whether a study measured a specific prognostic factor often requires full‐text screening to avoid potential reporting bias (i.e. a study finding a positive association is more likely to report this association in the title or abstract). We acknowledged this potential bias and screened full‐text publications meeting other inclusion criteria using electronic and handsearching. We included low back pain prognostic studies that investigated expectations and their association with at least one of our primary outcomes of interest. Two review authors (from MW, RO, JAH) or other contributor (from MT, JC, AS, EWP) independently confirmed study relevance with the full text, including discussion and consensus with a third review author when necessary.

We linked multiple publications of the same or overlapping participant data as one study, and identified the primary study as the publication presenting the most relevant data for our review question (i.e. reporting the independent association of expectations with low back pain outcome).

Data extraction and management

We extracted data and reached consensus using electronic extraction forms in MS Access and DistillerSR for studies identified in searches to 1 February 2018. We tested and modified the data extraction forms a priori. For each included study we extracted participant characteristics (population source and setting, inclusion criteria, and duration of low back pain episode at baseline), prognostic factor(s) (the expectation constructs as described above, including measurement approach, timing of measurement, prevalence of positive/negative expectations), outcomes (measures assessed and the incidence of poor outcome), study design, follow‐up period(s), and all unadjusted and adjusted associations reported between the prognostic factor(s) and outcomes, with details on any adjustment factors used.

If multiple measures of expectations were available in a single study, we extracted information about all measures and associations with outcomes. For primary analyses, we chose the ‘best’ measurement based on evidence of validity and reliability, and prioritised the order: general, self‐efficacy, treatment expectations. If studies presented multiple measures of general expectations with work participation outcomes, we selected the expectations measure referencing a return‐to‐work event (e.g. return‐to‐work confidence, expected time to return to work) rather than tied to pain or functional limitations (i.e. risk of persistent pain).

One review authors (MW) and one other contributor (from MT, JC, AS, EWP) independently extracted information; we used a consensus method with a third review author (JAH) consulted in the case of disagreements.

Assessment of risk of bias in included studies

One review author (MW) and one other contributor (from AS, JC, EWP) independently, with consensus and a third review author (JAH) as necessary, assessed each study’s risk of bias using the Quality in Prognosis Studies (QUIPS) tool (Hayden 2013), appropriate for prognostic factor review questions. This approach has been recommended by the Cochrane Prognosis Methods Group, used in several reviews (for example, Dawes 2016; Jimenez 2009; Lamberink 2017), and has acceptable inter‐rater reliability. We assessed each study’s risk of bias considering six domains: study participation, study attrition, prognostic factor measurement, outcome measurement, study confounding, and statistical analysis and reporting; Appendix 3 presents a copy of the QUIPS tool modified for this review. We describe each of the six domains, paraphrased from Hayden 2013, in Appendix 4. The reviewers considered all available publications of the same study in assessments. We assessed risk of bias for the study overall, based on the primary outcome at highest risk of bias, rather than separately by outcome measure. We were not blinded to study authors, institution, or journal of publication, due to feasibility.

For each of the six domains, we assessed responses to the prompting together (while considering missing or poorly‐reported information) to inform the 'Risk of bias' judgement. We recorded information and methodological comments supporting the item assessment, and then judged using the QUIPS tool by rating each domain as having high, moderate, or low risk of bias. We then judged a study’s overall validity, and gave it an overall low risk of bias if we had rated all of the six bias domains as having low risk of bias. We used subgroup analyses to explore the impact of biases on the observed size and direction of effect across each of the six 'Risk of bias' domains.

Measures of association to be extracted

We extracted all unadjusted and adjusted measures of association (i.e. prognostic effect estimates) from included studies, and we recorded how expectations were measured and reported. We converted effect sizes, as necessary, to the natural log scale to avoid possible selection bias by allowing us to use data from as many studies as possible. We calculated standard errors (SEs) by log‐transforming study‐reported confidence intervals (or other measures of variance) and subsequently using an appropriate conversion formula. We used odds ratios (ORs) in the natural log scale as the common measure of the relationship between expectations and outcome. We used relative risks and hazard ratios (HRs) to estimate ORs (Symons 2002) and we converted standardised regression coefficients for continuous outcomes to natural log ORs for synthesis (Borenstein 2009; Peterson 2005). If available in sufficient numbers, we had planned to separately extract and analyse continuous outcomes on a continuous scale, and HRs for studies providing this measure of association.

When data were available, we separately synthesised adequately‐adjusted associations between expectations and low back pain outcomes from unadjusted associations. In our conceptual framework (Figure 1), we defined five domains of other covariates important for this review question: individual demographics, social support, work factors and environment, psychological factors, and low back pain complaint factors. We defined ‘minimally adjusted’ study analyses as those presenting adjusted analyses controlling for one or two of these domains, and ‘adequately adjusted’ study analyses as those presenting adjusted analyses controlling for three or more of these domains. For consistency, we recalculated associations to be in the same direction on the natural log scale, as necessary, with effect sizes above 0 indicating that better expectations are associated with a better prognosis.

Studies included in this review collected and analysed the association between expectations and low back pain outcomes at the individual participant level. Some studies presented data stratified for specific characteristics, creating independent subgroups (men and women, or treatment groups). For the three studies where this occurred (Kongsted 2014; Opsahl 2016; Tran 2015), we presented the data separately in meta‐analyses, labelled as 'groups'.

Dealing with missing data

We included studies that investigated the relationship between expectations and low back pain outcomes, even if there were incomplete data provided about the size of the effect (for example, if the factor is mentioned only as being 'non‐significant' in the analyses, but no information about the size of the effect was reported), or if assumptions were necessary to calculate a measure of variance (for example, if data were incomplete, but the standard error could be calculated from a presented P value). Data reported and necessary data conversions are described in Tables 2 to 5. In sensitivity analyses we excluded studies from meta‐analyses if they presented data requiring conversions with uncertain assumptions.

Assessment of heterogeneity

Our secondary objective was to explore sources of heterogeneity to identify the impact of differences in participants, measurement of expectations, low back pain duration, outcome, follow‐up length, study design, and risk of bias on the association between expectations and low back pain. We synthesised associations within these clinically‐relevant subgroups. To assess statistical heterogeneity across studies included in a particular meta‐analysis, we inspected forest plots and quantified heterogeneity using the I2 statistic and Tau2 (the estimate of between‐study variance).

Assessment of reporting deficiencies

We examined potential publication bias for meta‐analyses containing 10 or more studies by visually examining asymmetry in funnel plots, and with Egger's test (Egger 1997). We considered potential publication bias as part of the rating of certainty of the evidence.

Data synthesis

Data synthesis and meta‐analysis approaches

We conducted meta‐analyses when valid data were available about the prognostic association between expectations and each of our primary outcomes (work participation, important recovery, functional limitations, and pain). We separately synthesised dichotomous and continuous measures of expectations (0 ‐ 10 scale) as they were reported in included studies, as well as for unadjusted and adjusted analyses, when available. To include the most and sufficiently similar studies available, our primary analyses used data from: the longest follow‐up period closest to 12 months, the best measure/type of expectations, and the best adjusted model results.

We conducted meta‐analyses using Review Manager 5 with a random‐effects generic inverse variance meta‐analysis model, which accounts for any between‐study heterogeneity in the prognostic effect. We pooled effect sizes as natural log ORs and SEs, and converted these pooled estimates to ORs and 95% CIs for ease of interpretation. We present results of forest plots of meta‐analyses in the text of this review when three or more studies were available for meta‐analyses in primary analyses, and when at least three studies were available for two or more subgroups in subgroup analyses. We considered differences to be statistically significant at the 5% level. We defined the clinical importance of observed associations based on effect size as small (OR < 1.5), moderate (1.5 ≤ OR ≤ 2), or large (OR > 2) (modified from Hartvigsen 2004 and Hemingway 1999).

To allow for fuller interpretation of the evidence available, we also present the results using a narrative approach. For each comparison, we summarise the number of studies that reported positive, neutral or negative associations between expectations and the outcome of interest. Studies reporting a statistically significant relationship between positive expectations and a good outcome were recorded as ‘positive’; studies reporting a statistically significant relationship between negative expectations and a good outcome were recorded as ‘negative’; we recorded non‐significant associations as ‘neutral’, with moderate or large effect sizes (OR ≥ 1.5) reported as clinically important.

Subgroup analyses and investigation of heterogeneity

For our primary work participation outcome, we explored heterogeneity with subgroup analyses using meta‐analyses, and with the narrative synthesis approach. We defined subgroups according to population (acute (less than six weeks), subacute/chronic (six weeks or more) and mixed duration), specific types of measures of expectations (general expectations, self‐efficacy expectations, and treatment expectations), the expectations reference time period (short (four weeks or less), long (three to six months), or no/unclear reference period), and outcome measurement (specific follow‐up periods). We also conducted separate meta‐analyses based on assessments of the study phase (exploratory and confirmatory) and according to risk of bias (by each domain, and overall). We planned to separately consider general, worker, and healthcare source populations.

Sensitivity analyses

We used sensitivity analyses to explore the impact of our judgements of study risk of bias, alternatively including studies rated as low or moderate risk of bias for all domains to indicate overall low risk of bias. Sensitivity analyses also explored the impact of data conversions in cases where we were required to make assumptions about normality and proportionality of data; in sensitivity analysis we excluded studies where the standard error was calculated from a P value. There were not sufficient numbers of studies available to allow other planned sensitivity analyses for studies including only low back pain populations versus studies including a small proportion of mixed pain populations, surgical candidates or individuals with lumbar disc herniation.

Rating of certainty of evidence and 'Summary of findings' tables

We judged and report the overall quality of evidence for our primary outcomes using a modified GRADE (Guyatt 2011) approach that was previously used in another prognostic factor review (Huguet 2013), rating the overall strength of evidence as ‘high’, ‘moderate’, ‘low’ or ‘very low’, considering phase of investigation, internal validity, size and precision of effect, heterogeneity, generalisability, potential reporting bias, and the size of the observed effect. See Appendix 5, reproduced from Huguet 2013.

Results

Results of the search

We identified 7225 records in our searches: 4807 from electronic database searching, 1469 from citation searches of expectations measures and tools, and 949 from references of other published low back pain prognosis systematic reviews. There were 4635 unique citations, of which we excluded 3727 citations at title/abstract screening. We screened 924 full‐text publications (including 16 papers added from reference lists of included studies). We excluded publications after brief full‐text screen (798 publications; mainly due to not including a measure of expectations), or with comprehensive review of the full‐text publication (29 publications: no appropriate measure of expectations (20), not low back pain (5), primary outcome not available (2), follow‐up period not available (2)); see the ‘Characteristics of excluded studies’ table. We included 60 studies (in 85 publications) that met our inclusion criteria (Figure 2). Sixteen publications are awaiting assessment. In an updated search (12 March 2019) we found 10 studies likely to be eligible for inclusion, and two were publications probably linked to included studies. Four studies were not published in English (Characteristics of studies awaiting classification).

2.

2

PRISMA flow diagram showing identification and selection of included studies.

Of the 60 included primary studies reported here, we identified 60% (36 studies) from our electronic searches, 28% (17 studies) from other relevant low back pain prognosis or expectations reviews, 8% (5 studies) from reference searches of included studies, and 3% (2 studies) from searches of expectations measures.

Included studies

Sixty studies (30,530 participants) provided information about expectations and low back pain outcomes and were included in this review (Table 3: Descriptive summary of included studies) Beneciuk 2017; Besen 2015; Bishop 2015; Butler 2007; Carriere 2015; Casey 2008; Demmelmaier 2010; Dionne 1997; Downie 2016; Du Bois 2008; Enthoven 2006; Enthoven 2016; Foster 2008; George 2010; Gervais 1991; Glattacker 2013; Goldstein 2002; Gross 2010; Grotle 2006; Haas 2014; Hagen 2005; Haldorsen 1998; Harkapaa 1996; Hazard 1996; Henschke 2008; Heymans 2006; Hildebrandt 1997; Jellema 2002; Jensen 2000; Jensen 2013; Karjalainen 2003; Kongsted 2014; Leboeuf‐Yde 2004; Lindell 2010; Macedo 2014; Magnussen 2007; Michaelson 2004; Morlock 2002; Myers 2007; Niemisto 2004; Opsahl 2016; Opsommer 2017; Petersen 2007; Rasmussen‐Barr 2012; Reeser 2001; Reiso 2003; Reme 2009; Rundell 2017; Sandstrom 1986; Schultz 2004; Shaw 2009; Sherman 2009; Steenstra 2005; Tran 2015; Truchon 2012; Turner 2008; Underwood 2007; Van Hooff 2014; Van Wijk 2008; Yelland 2006. Forty‐four studies (73%) were published more than five years ago (before 2013). Thirty‐four studies (56%) were cohort study design and 27 studies (45%) were re‐analyses of randomised controlled trials (one study included both, combining data from a cohort study and a randomised controlled trial). The sample size of included studies ranged from 52 (Sandstrom 1986) to 5220 (Rundell 2017), with a median of 257 participants (interquartile range (IQR): 132 to 592). Studies were conducted in the USA (16 studies), Norway (8), Sweden (7), the Netherlands (6), Canada (5), Australia (4), the United Kingdom (4), Finland (3), Denmark (3), Germany (2), Switzerland (1), and Belgium (1).

2. Descriptive summary of included studies.
Study variables All included studies
(n = 60)
Synthesis studies
(n = 52)
n % n %
Year published Older (before 2013) 44 73.3% 37 71.2%
Recent (2013 ‐ 2018) 16 26.7% 16 30.8%
Sample size (median, IQR) 257 132 ‐ 592 312 166 ‐ 627
Population source Healthcare 37 61.7% 33 63.5%
Occupational 16 26.2% 14 26.4%
General 3 4.9% 3 5.7%
Mixed 3 4.9% 1 1.9%
Not specified 1 1.6% 1 1.9%
Duration of LBP Acute 5 8.2% 4 7.5%
Subacute 5 8.2% 5 9.4%
Chronic 22 36.7% 20 38.5%
Mixed 19 31.1% 14 26.4%
Not specified 9 14.8% 9 17.0%
Type of expectations measure General expectations 42 68.9% 36 67.9%
Self‐efficacy expectations 12 19.7% 12 22.6%
Treatment expectations 17 28.3% 14 26.9%
Number of expectations measures 1 44 73.3% 39 75.0%
2 13 21.3% 11 20.8%
3 2 3.3% 2 3.8%
4 1 1.6% 0 0.0%
Prognostic factor study phase Exploratory/TEM 3 5.0% 3 5.8%
Exploratory 44 73.3% 37 71.2%
Confirmatory 13 21.3% 12 22.6%
Outcomes assessed Pain 31 51.7% 24 46.2%
Functional limitations 36 60.0% 30 57.7%
Work participation 35 58.3% 31 59.6%
Satisfaction 5 8.3% 2 3.8%
Global improvement 9 15.0% 8 15.4%
Health‐related quality of life 6 10.0% 4 7.7%
Cost 7 11.5% 6 11.3%
Mood 3 4.9% 3 5.7%
Follow‐up times available Short (3 ‐ 4 months) 29 48.3% 24 46.2%
Moderate (5 ‐ 8 closest to 6 months) 16 26.2% 13 24.5%
Long (8 ‐ 16 closest to 12 months) 40 65.6% 35 66.0%
Very long (> 16 months) 7 11.5% 7 13.2%
Low risk of bias by QUIPS domain Study Participation 18 30.0% 17 32.7%
Study Attrition 36 60.0% 33 63.5%
Prognostic Factor Measurement 27 45.0% 24 46.2%
Outcome Measurement 54 90.0% 46 88.5%
Study Confounding 28 46.7% 27 51.9%
Statistical Analyses & Reporting 41 68.3% 38 73.1%
All QUIPS ROB domains rated low or moderate 36 60.0% 34 65.4%
All QUIPS ROB domains rated low 2 3.3% 2 3.8%

LBP = low back pain; ROB = risk of bias; TEM = treatment effect modification; QUIPS = Quality in Prognosis Studies Tool

The study populations had similar numbers of men and women (median, 47% men; IQR 41% to 55%) and mean age ranged from 34 to 74 years. Study populations were mostly chronic (37%; 22 studies) or mixed duration of low back pain (31%; 19 studies), from healthcare (62%; 37 studies) or occupational settings (26%; 16 studies). General expectation was the most common type of expectation measured (70%; 42 studies); 16 studies measured more than one type of expectation. There were 62 distinct measures of expectations used across the 60 studies (46 individual items and 16 multi‐item scales). Of general measures, 24 studies referenced expectations of return to work, 21 referenced functioning, recovery, or pain reduction, and three referenced expectations related to multiple study outcomes (i.e. duration of symptoms, activity restrictions and job limitations). Commonly‐used measures of expectations included: chance of return to work within six months (9 studies, 7 measured on 0 ‐ 10 scale as Örebro Musculoskeletal Pain Questionnaire (Linton 1998), item 16), perceived risk of pain persistence (9 studies), for example, "In your view, how large is the risk that your current pain may become persistent?" (Örebro Musculoskeletal Pain Questionnaire, item 15 measured on a 0 ‐ 10 scale), and expected helpfulness of treatment (5 studies), for example, "How helpful do you think x treatment will be?" (measured on a 0 ‐ 10 scale in three of the five studies). Our primary outcomes, work participation (58%; 35 studies), functional limitations (60%; 36 studies), and pain intensity (52%; 31 studies), were each assessed in most included studies. Secondary outcomes were reported in a small number of included studies: global improvement (15%; 9 studies), health‐related quality of life (10%; 6 studies), satisfaction (8%; 5 studies), mood (5%; 3 studies), healthcare costs (12%; 7 studies). Details of individual study characteristics are described in the Characteristics of included studies.

Forty‐seven of the 60 included studies were exploratory phase (44 exploratory, 3 exploratory and treatment effect modification; 78%), and 13 (22%) were confirmatory studies, designed to assess the independent association between expectations and low back pain outcome. Confirmatory‐phase evidence was available for all primary outcomes other than important recovery outcomes (for work participation: five confirmatory studies, 1268 participants; functional limitations: four confirmatory studies, 651 participants; pain intensity: five confirmatory studies, 1552 participants).

Of the 60 included studies, 52 had usable data for synthesis (87%; 28,885 participants), reported in 55 separate study groups. The characteristics of the 52 studies were similar to all included studies (Table 3). Reasons that data were not usable for synthesis included: follow‐up times more than three months measured but relevant data not presented (4 studies), expectation measures had relevant data reported only as part of a more comprehensive tool (2 studies), expectation measures were used to define clusters for analyses (1 study) and not presenting sufficient data on the association between expectations and low back pain outcome (1 study). There was considerable heterogeneity in measurement of prognostic factors and outcome measures in studies with data available for synthesis. Many studies categorised expectation measures for their main analyses: 21 included studies with usable data reported a dichotomous measure of expectations (40%; 13 studies/14 groups for work participation, six studies for important recovery, three studies for function, one study for pain). We describe measures and prognostic factor cut‐points in detail with individual study results for each primary outcome in Table 4; Table 5; Table 6; Table 7.

3. Reported associations for studies measuring work participation outcomes.
Study Sample size Expectation measure Outcome measure Outcome follow‐up period Study reported effect; variance measure Common effect size (lnOR)a Standard error Reported direction of associationb
Besen 2015 241 General: How soon do you expect to be able to resume your normal job without any limitations? (6‐pt; 0 ‐ 2 days up to > 60 days); reverse coded for analysis (higher = better) Return to work 3 months StB; P 1.24 0.63 +
Butler 2007 173 General: Expectations of recovery (5‐pt), dichotomised as positive (≥ get better soon) vs negative (≤ get better slowly) Unstable employment pattern 12 months OR; P 0.14 0.41 Ø
Carriere 2015 108 General: Likelihood of return to work in next month (0 ‐ 100), dichotomised as low (< 62.5) vs high (≥ 62.5) Successful return to work 12 months OR; 95% CI 0.04 0.01 +
Demmelmaier 2010 77 General: Pain expectations (sum of 2 7‐pt rating scales; 1 adapted from OMPQ; 0 ‐ 12, higher = worse) On sick leave 12 months Pc N/Ad N/A Ø
Du Bois 2008 186 General: Return to work certainty within 6 months (0 ‐ 10), dichotomised as not very sure (< 10) vs very sure (10) Non‐return to work 3 months OR; 95% CI 1.53 0.41 +
Gervais 1991 135 Self‐efficacy: Self‐Efficacy and Results Expectancies Inventory (unclear scale; higher = better)) Non‐full‐time return to work 6 months OR; P −0.34 0.20 Ø
Gross 2010 298 General: Work‐related Recovery Expectations Questionnaire (average of 3 Likert scales, 1 ‐ 5, higher = worse) Time to suspension of time‐loss benefits 12 months HR; 95% CI 0.19 0.07 +
Haldorsen 1998 84 General: Do you believe that you will be back to work after a couple of weeks? (5‐pt scale, higher = worse) Non‐return to work 12 months F, P 0.84d 0.43 +
Hagen 2005 457 General: Belief that back pain will disappear from Graded Reduced Work Ability Scale (1‐6), dichotomized at median as don't believe back pain will disappear Non‐return to work 12 months OR; 95% CI 0.59 0.30 +
Harkapaa 1996 175 General: Health Optimism Index (5‐20); reverse coded for analyses (higher = better) Return to work 12 months Pc N/A N/A +
Heymans 2006 268 General: When do you think you will be able to work full‐time again? (8‐pt, < 1 week to > 12 months, and no idea) Time to full return to work 12 months HR; 95% CI 0.05 0.02 +
Jensen 2000 107 Self‐efficacy: Belief in ability for learning to cope with the pain (unclear scale, higher = better) Receiving disability pension 6 months OR; 95% CI 0.21 0.77 Ø
Jensen 2013 282 General: Expectations of return to work within 6 months (10‐pt), dichotomised as not convinced (< 8) vs convinced (8 ‐ 10) Non‐return to work 12 months OR; 95% CI 1.08 0.33 +
Lindell 2010 123 General: Self‐prediction of probability of return to work at some time in the future (5‐pt Likert), dichotomised as high probability (≥ rather probable) vs low probability (≤ rather improbable) Stable return to work 12 months OR; 95% CI 1.65 0.62 +
Magnussen 2007 79 General: Do you believe that you will ever be able to return to work?, dichotomised as yes vs no/don't know Entered a return to work process 12 months OR; 95% CI 1.93d 0.66 +
Opsahl 2016ae 286 General: Predicted extent of return to work (4‐pt), dichotomised as high vs low/moderate degree Return to work 12 months OR; 95% CI 1.21 0.38 +
Opsahl 2016be 283 General: Predicted extent of return to work (4‐pt), dichotomised as high vs low/moderate degree Return to work 12 months OR; 95% CI 1.43 0.40 +
Opsommer 2017 98 General: In your estimation, what are the chances that you will be able to work in 6 months? (0 ‐ 10, higher = better) Time to return to work 12 months Harrell's C statistic; 95% CI N/Ad N/A +
Petersen 2007 153 General: Certainty of working 6 months after treatment (0 ‐ 10), dichotomised at median as low vs high Sick‐listed 14 months OR; 95% CI 1.87 0.78 +
Reiso 2003 153 General: Self‐predicted work status in 4 weeks (3‐pt), dichotomised as full return to work vs not full return to work Return to work for at least 60 calendar days 24 months HR; 95% CI 1.17 0.29 +
Reme 2009 173 General: Expectation to return to work within the next few weeks, dichotomised as negative (no/no opinion) vs positive (yes) Non‐return to work 12 months OR; 95% CI 0.64 0.38 Ø
Sandstrom 1986 52 Self‐efficacy: I am afraid to start working again because I don't think I will be able to manage (7‐pt) Not sick‐listed 12 months MD; P 2.35d 0.71 +
Schultz 2004 214 General: Expectations of recovery scale (8 items, unclear scale, higher = worse) Return to work 3 months B; SE 0.25 0.06 +
Steenstra 2005 515 General: Expected duration of sick leave >10 days vs ≤ 10 days Any return to work 6 months HR; 95% CI 1.04 0.17 +
Truchon 2012 530 General: Return to work expectations (time, unclear scale, higher = worse) Work absence 12 months B; SE 0.25 0.00 +
Turner 2008 1885 General: Certainty of working in 6 months (0 ‐ 10), dichotomised as low/no response (0 ‐ 6) vs very high Receiving wage replacement compensation 12 months OR; 95% CI 0.26 0.21 Ø

Table 3. Description of the reported associations between the primary expectations measure and return to work participation outcomes, including presentation as common natural log odds effect size and standard error. Results presented are from the best adjusted multivariate model, when available, selecting the available study time period in study closest to 12 months (positive association in 19 studies (20 groups), no association in 6 studies).

aAll reported associations have been converted to the natural log odds (lnOR) scale and the same direction when possible; lnOR > 1 indicates a positive direction of association between expectations and outcome.
 bDirection of association: + = positive, associated with better outcome; Ø = neutral, no association with outcome; ‐ = negative, associated with worse outcome
 cStudy where results are from unadjusted models.
 dStatistical significance only reported for this study.
 eOpsahl 2016a were women; Opsahl 2016b were men.
 lnOR = natural log of the odds ratio; StB = standardized beta coefficient; OR = odds ratio; P = p‐value; OMPQ = Orebro Musculoskeletal Pain Questionnaire; N/A = data not available or data conversions were not appropriate, but direction of association is reported; HR = hazard ratio; F = F‐statistic one‐way ANOVA; MD = mean difference; B = beta coefficient; SE = standard error.

4. Reported associations for studies measuring important recovery outcomes.
Study Sample size Expectation measure Outcome measure Outcome follow‐up period Study reported effect; variance measure Common effect size (lnOR)a Standard error Reported direction of associationb
Beneciuk 2017 688 General: Expectations of recovery (0 ‐ 10, categorised into tertiles, higher = worse) Non‐recovery in disability (RMDQ ≥ 7) 3 months OR; 95% CI 0.53c 0.24 +
Besen 2015 359 General: Sum of 3 items on likely duration of symptoms (5‐pt; 0 ‐ 2 days up to > 60 days; 3 ‐ 15) Unresolved pain (NRS ≥ 5), function (> 50% RMDQ items endorsed), or return to work (unable to resume full duty work) 3 months OR; 95% CI 0.19c 0.03 +
Downie 2016 653 General: Risk of persistence (0 ‐ 10, higher = worse) Belonging to a persistent pain cluster (NRS ≥ 5 at baseline and follow‐up) vs rapid recovery (NRS ≤ 1 at follow‐up) 3 months RR; 95% CI 0.51 0.21 +
Enthoven 2016 422 Expectations of recovery in 3 months (1 ‐ 5) Belonging to a high pain trajectory cluster (consistent high pain) vs low pain trajectory cluster (0 ‐ 1 on 10‐pt NRS after 6 months) 36 months OR; 95% CI 1.25c 0.26 +
Enthoven 2006 141 Treatment: Expectations of restoration (5‐pt), dichotomised as quite improved/partial relief/no expectations of being restored vs completely restored Non‐recovery in disability (> 20% on ODI) 12 months OR; 95% CI 0.17 0.54 Ø
Foster 2008 806 General: Revised Illness Perceptions Questionnaire, timeline acute/chronic item (5‐pt Likert), dichotomised as least helpful perceptions (lower quartile) vs most helpful perceptions (upper quartile) Non‐recovery in disability (< 30% change in RMDQ) 6 months RR; 95% CI 0.61 0.15 +
Harkapaa 1996 175 General: Health Optimism Index (5 ‐ 20); reverse‐coded for analyses (higher = better) Positive change in disability at follow‐up (≥ 3 increase in FCI disability score) 12 months OR; 95% CI 0.20 0.07 +
Henschke 2008 969 General: Perceived risk of persistence (0 ‐ 10, higher = worse) Complete recovery (pain/function/return to work) 12 months HR; 95% CI 0.08 0.02 +
Michaelson 2004 129 Optimism Index (average of 10 items, unclear scale, higher = better) Reduced pain (decrease in VAS ≥ 25) 12 months Pd N/A N/A Ø
Niemisto 2004 196 General: Self‐rated prognosis of work ability after 2 years (item from Workability index (1 ‐ 7) dichotomised as poor vs good or moderate Poor recovery (pain/function) 12 months OR; 95% CI 0.75 0.44 Ø
Petersen 2007 158 General: Certainty of working 6 months after treatment (0 ‐ 10), dichotomised at median as low vs high Poor recovery (< 15% improvement from baseline disability in Low Back Pain Rating Scale) 14 months OR; 95% CI 0.59 0.43 Ø
Rasmussen‐Barr 2012 71 Treatment: Expectation of treatment (unclear scale); dichotomised as good/improved, similar vs not improved/not good for analyses Poor recovery in disability (ODI ≥ 20) 12 months OR; 95% CI 0.47c 0.56 Ø
Rundell 2017 4143 General: Expectation for recovery (0 ‐ 10, higher = better) Persistent disability (RMDQ ≥ 4) 6 and 12 months OR; 95% CI 0.16 0.01 +
Shaw 2009 519 General: Likelihood of full return to work within 4 weeks (4‐pt), dichotomised as definitely vs unlikely/not sure Unresolved pain (NRS ≥ 5), function (> 50% RMDQ items endorsed), or return to work (unable to resume full duty work) 3 months RR; 95% CI 0.99 0.37 +
Van Hooff 2014 524 Pain Self‐Efficacy Questionnaire (0 ‐ 60, higher = better) Successful recovery (ODI ≤ 22) 12 months Chi2; P 1.68c 0.51 +
Yelland 2006 110 Treatment: Desired improvement in function to make treatment worthwhile (0 ‐ 100%, 10% change required, higher = better) Achieving minimum worthwhile reduction in disability determined at baseline (rated 0 ‐ 100%) 12 months OR; 95% CI 0.17 0.09 Ø

Table 4. Description of the reported associations between the primary expectations measure and important recovery outcomes, including presentation as common natural log odds effect size and standard error. Results presented are from the best adjusted multivariate model, when available, selecting the available study time period in study closest to 12 months (positive association in 10 studies; no association in 6 studies).

aAll reported associations have been converted to the natural log odds (lnOR) scale and the same direction when possible; lnOR > 1 indicates a positive direction of association between expectations and outcome.
 bDirection of association: + = positive, associated with better outcome; Ø = neutral, no association with outcome; ‐ = negative, associated with worse outcome
 cStudy where results are from unadjusted models.
 dStatistical significance only reported for this study.
 lnOR = natural log of the odds ratio; RR = relative risk; OR = odds ratio; RMDQ = Roland Morris Disability Questionnaire; NRS = pain numeric rating scale; ODI = Oswestry Disability Index; FCI = Functional Capacity Index; VAS = pain visual analog scale; P = p‐value; N/A = data not available or conversions were not appropriate, but direction of association is reported.

5. Reported associations for studies measuring functional limitations.
Study Sample size Expectation measure Outcome measure Outcome follow‐up period Study reported effect; variance measure Common effect size (lnOR)a Standard error Reported direction of associationb
Bishop 2015 420 Self‐efficacy: Chronic Pain Self‐Efficacy for Pain Management subscale (0 ‐ 100, higher = better) RMDQ (0 ‐ 24, higher = worse) 6 months B; SE 0.07 0.02 +
Casey 2008 84 General: Pain Behaviour and Perception Inventory, pain permanence subscale (−2 to +2, higher = worse) Pain‐Disability Index (0 ‐ 70, higher = worse) 3 months B; SE 5.64 1.43 +
Demmelmaier 2010 256 General: Pain expectations (sum of 2 7‐pt rating scales; 1 adapted from OMPQ; 0 ‐ 12, higher = worse) Disability score from Graded Chronic Pain Scale (0 ‐ 30, higher = worse) 12 months B; SE 1.04 0.39 +
Dionne 1997 490 General: Expectation of continued pain (4‐pt) RMDQ (16‐item, higher = worse) 24 months Pc N/Ad N/A Ø
Goldstein 2002 650 Treatment: Treatment confidence, NRS (0 ‐ 10, higher = better) RMDQ (0 ‐ 24, higher = worse) 6 months B; 95% CI 0.65 0.43 Ø
Karjalainen 2003 161 General: Perceived risk of not recovering (0 – 10, 2‐unit change required, 5‐pt, higher = worse) ODI (0 ‐ 100, higher = worse) 12 months B; 95% CI 2.21 0.34 +
Kongsted 2014 928 General: Likelihood of recovery (0 ‐ 10, higher = better) RMDQ (0 ‐ 24, higher = worse) 12 months R2; P N/Ad N/A +
Macedo 2014 172 Self‐efficacy: Pain Self‐Efficacy Questionnaire (0 ‐ 100), dichotomised at median as high vs low for analyses Patient‐Specific Functional Scale (0 ‐ 10, higher = better) 12 months B; 95% CI 1.11d 0.50 +
Morlock 2002 111 Treatment: Expected benefit from treatment (5 items, each 1 ‐ 5; 0 ‐ 100 reported, higher = better) NASS scale (0 ‐ 100, higher = worse) 12 months B; P 14.20 5.51 +
Myers 2007 365 General: How much improvement do you expect in 6 weeks? (0 ‐ 10, higher = better) Improvement in RMDQ (0 ‐ 23, higher = better) 3 months B; 95% CI 0.59 0.20 +
Sherman 2009 638 Self‐efficacy: Likelihood of self‐managing future back pain (unclear scale, higher = better), dichotomised as top tertile vs low two tertiles RMDQ (0 ‐ 23, higher = worse) 12 months B; SE 0.20 1.00 Ø
Tran 2015ae 63 Treatment: How helpful do you expect yoga to be for your back problems? (0 ‐ 10, higher = better) Change in RMDQ (0 ‐ 24, higher = better) 3 months MD; P −0.43d 0.55 Ø
Tran 2015be 30 Treatment: How helpful do you expect yoga to be for your back problems? (0 ‐ 10, higher = better) Change in RMDQ (0 ‐ 24, higher = better) 3 months MD; P −0.28d 0.5 Ø
Underwood 2007 700 Treatment: Treatment helpfulness (3‐pt, not helpful, helpful, very helpful), very helpful vs not helpful compared here RMDQ (0 ‐ 24) 12 months B; 95% CI 0.60 0.54 Ø

Table 5. Description of the reported associations between the primary expectations measure and function outcomes, including presentation as common natural log odds effect size and standard error. Results presented are from the best adjusted multivariate model, when available, selecting the available study time period in study closest to 12 months (positive association in 9 studies; no association in 5 studies (6 groups)).

aAll reported associations have been converted to the natural log odds (lnOR) scale and the same direction when possible; lnOR > 1 indicates a positive direction of association between expectations and outcome.
 bDirection of association: + = positive, associated with better outcome; Ø = neutral, no association with outcome; ‐ = negative, associated with worse outcome
 cStatistical significance only reported for this study.
 dStudy where results are from unadjusted models.
 eTran 2015a received twice‐weekly yoga; Tran 2015b received once‐weekly yoga.
 lnOR = natural log of the odds ratio; RMDQ = Roland Morris Disability Questionnaire; B = beta coefficient; SE = standard error; OMPQ = Orebro Musculoskeletal Pain Questionnaire; P = p‐value; N/A = data not available or data conversions were not appropriate, but direction of association is reported; NRS = pain numeric rating scale; ODI = Oswestry Disability Index; NASS = North American Spine Society scale; MD = mean difference.

6. Reported associations for studies measuring pain intensity outcomes.
Study Sample size Expectation measure Outcome measure Outcome follow‐up period Study reported effect; variance measure Common effect size (lnOR)a Standard error Reported direction of associationb
Casey 2008 84 General: Pain Behaviour and Perception Inventory, pain permanence subscale (−2 to +2, higher = worse) Descriptor Differential Scale (0 ‐ 20, higher = worse) 3 months B; SE 0.86 0.56 Ø
Demmelmaier 2010 256 General: Pain expectations (sum of 2 7‐pt rating scales; 1 adapted from OMPQ; 0 ‐ 12, higher = worse) Pain scale from Graded Chronic Pain Scale (0 ‐ 30, higher = worse) 12 months B; SE 0.95 0.35 +
Glattacker 2013 81 General: Revised Illness Perceptions Questionnaire, timeline acute/chronic item (5‐pt Likert, higher = worse) LBP Intensity VAS (0 ‐ 100, higher = worse) 6 months St B; P 0.24 0.10 +
Goldstein 2002 650 Treatment: Treatment confidence NRS (0 ‐ 10, higher = better) LBP Intensity Change in NRS (0 ‐ 10, higher = worse) 6 months B; 95% CI 0.28 0.19 Ø
Haas 2014 391 Treatment: Confidence in treatment, average of 2 6‐pt Likert scales (1 ‐ 6, higher = better) Von Korff (0 ‐ 100, higher = worse) 3 months B; 95% CI 0.05 0.04 Ø
Jensen 2000 107 Self‐efficacy: Belief in ability for learning to cope with the pain (unclear scale, higher = better) SF‐36 Bodily Pain Scale (0 ‐ 100, higher = better) 6 months B; 95% CI 9.44 3.94 +
Karjalainen 2003 161 General: Perceived risk of not recovering (0 – 10, 2‐unit change required, 5‐pt, higher = worse) LBP Intensity NRS (0 ‐ 10, higher = worse) 6 months B; 95% CI 0.32 0.12 +
Kongsted 2014ac 200 General: Likelihood of recovery (0 ‐ 10, higher = better) LBP Intensity NRS (0 ‐ 10, higher = worse) 3 months B; 95% CI 0.19 0.07 +
Kongsted 2014bc 705 General: Likelihood of recovery (0 ‐ 10, higher = better) LBP Intensity NRS (0 ‐ 10, higher = worse) 3 months B; 95% CI 0.12 0.04 +
Macedo 2014 172 Self‐efficacy: Pain Self‐Efficacy Questionnaire (0 ‐ 100), dichotomised at median as high vs low for analyses LBP Intensity NRS (0 ‐ 10, higher = worse) 12 months B; 95% CI 0.92d 0.58 Ø
Tran 2015ae 63 Treatment: How helpful do you expect yoga to be for your back problems? (0 ‐ 10, higher = better) Change in NRS (0 ‐ 10, higher = better) 3 months MD; P −0.20d 0.45 Ø
Tran 2015be 30 Treatment: How helpful do you expect yoga to be for your back problems? (0 ‐ 10, higher = better) Change in NRS (0 ‐ 10, higher = better) 3 months MD; P −0.43d 0.44 Ø

Table 6. Description of the reported associations between the primary expectations measure and pain intensity outcomes, including presentation as common natural log odds effect size and standard error. Results presented are from the best adjusted multivariate model, when available, selecting the available study time period in study closest to 12 months (positive association in 5 studies (6 groups); no association in 5 studies (6 groups)).

aAll reported associations have been converted to the natural log odds (lnOR) scale and the same direction when possible; lnOR > 1 indicates a positive direction of association between expectations and outcome.
 bDirection of association: + = positive, associated with better outcome; Ø = neutral, no association with outcome; ‐ = negative, associated with worse outcome
 cKongsted 2014a was a general practice cohort; Kongsted 2014b was a chiropractic practice cohort.
 dStudy where results are from unadjusted models.
 eTran 2015a received twice‐weekly yoga; Tran 2015b received once‐weekly yoga.
 lnOR = natural log of the odds ratio; B = beta coefficient; SE = standard error; LBP = low back pain; VAS = pain visual analogue scale; StB = standardized beta coefficient; P = p‐value; NRS = pain numeric rating scale; SF‐36 = 36‐item Short Form survey; MD = mean difference.

We analysed and reported the association between expectations and low back pain outcomes as unadjusted results (71%; 37 studies), or adjusted results (85%; 44 studies), or both. Of the 44 studies with adjusted results, we judged 26 to be adequately adjusted (59%), 17 to be minimally adjusted (39%) and one to have unclear adjustment (2%). Two studies (4%) reported only the statistical significance of the association between expectations and low back pain outcome (no measure of effect size for any outcomes), with no mention of clinical significance. There were too few homogeneous studies for synthesis of secondary outcomes.

The analytic approach differed considerably across studies, as did the reported effect size types and measures of variance (Table 4; Table 5; Table 6; Table 7). We considered any data presentations where the regression effect and confidence interval and/or standard error and/or exact P value were not fully reported to be incomplete. We considered conversions of odds ratios, risk ratios, hazard ratios and beta coefficients (standardised and non‐standardised) to be based on acceptable assumptions, and all other effect conversions to be uncertain. Among all associations reported across outcomes in primary meta‐analyses, there were seven removed in a sensitivity analysis from unadjusted data, and one removed from adjusted data.

Risk of bias assessment of included studies

We assessed risks of bias across six domains, using the QUIPS tool for each of the 60 included studies (Table 8). In total, review authors agreed on 278 of 360 items prior to consensus, resulting in a Kappa score of 0.56 (95% CI 0.46 to 0.66). Agreement on the six QUIPS domains ranged from 65% (Prognostic factor measurement) to 88% (Study confounding).

7. QUIPS Risk of bias domain summary by study.

Study Year Study Participation Study Attrition Prognostic Factor
Measurement
Outcome Measurement Study Confounding Statistical Analysis
and Reporting
Beneciuk 2017 2017 Moderate Moderate Moderate Low High Low
Besen 2015 2015 Moderate Moderate Low Low Low Low
Bishop 2015 2015 High Moderate Low Low Low Low
Butler 2007 2007 Moderate Moderate Moderate Low Low Low
Carriere 2015 2015 Low Moderate Moderate Moderate Low Low
Casey 2008 2008 Moderate Moderate Low Low Moderate Low
Demmelmaier 2010 2010 High High High Low Moderate Moderate
Dionne 1997 1997 Moderate Low Moderate Low High Low
Downie 2016 2016 Moderate Low Low Moderate Low Low
Du Bois 2008 2008 Moderate Low Moderate Low Moderate Moderate
Enthoven 2006 2006 Low Low Moderate Low Low Low
Enthoven 2016 2016 Moderate Low Low Low High Moderate
Foster 2008 2008 Moderate High Low Low Low Low
George 2010 2010 Low Low Moderate Low High Low
Gervais 1991 1991 Low Low Low Low Moderate Low
Glattacker 2013 2013 Moderate Moderate Low Low Low Low
Goldstein 2002 2002 Moderate Low Low Low Moderate Low
Gross 2010 2010 Moderate Low Low Low Low Low
Grotle 2006 2006 High Moderate Moderate Low Moderate Low
Haas 2014 2014 High Low Low Low Moderate Low
Hagen 2005 2005 Moderate Low Moderate Low Low Low
Haldorsen 1998 1998 Moderate Low High Low High Moderate
Harkapaa 1996 1996 High Moderate Low Low Low Low
Hazard 1996 1996 Moderate Low Low Low Moderate Moderate
Henschke 2008 2008 Low Low Low Low Low Low
Heymans 2006 2009 Moderate Low Low Low Low Low
Hildebrandt 1997 1997 High Moderate Moderate Low High Moderate
Jellema 2002 2002 High Moderate Low Low High High
Jensen 2000 2000 Moderate Moderate Moderate Low Moderate Low
Jensen 2013 2013 Moderate Low Moderate Low Moderate Low
Karjalainen 2003 2003 Moderate Low Low Low Low Moderate
Kongsted 2014 2014 Low Moderate Low Low Low Low
Leboeuf‐Yde 2004 2004 Moderate Moderate Moderate Low Moderate Moderate
Lindell 2010 2010 Low Low Moderate Low Low Low
Macedo 2014 2014 Moderate Low Moderate Low High Low
Magnussen 2007 2007 Moderate Moderate Moderate Moderate High Low
Michaelson 2004 2004 Low Low Low Low Moderate Moderate
Morlock 2002 2002 Moderate High Low Low Low Moderate
Myers 2007 2007 Low Low Low Low Low Low
Niemisto 2004 2004 Low Low Moderate Low Low Moderate
Opsahl 2016 2016 Low Low Moderate Moderate Low Low
Opsommer 2017 2017 Low Moderate Low Moderate High Low
Petersen 2007 2007 Low Low Moderate Low Moderate Low
Rasmussen‐Barr 2012 2012 Low Moderate Moderate Low High Low
Reeser 2001 2001 Moderate High Low Low High Moderate
Reiso 2003 2003 Moderate Low Moderate Low Low Moderate
Reme 2009 2009 Low Low Moderate Low Low Moderate
Rundell 2017 2017 Moderate Moderate Low Low Moderate Low
Sandstrom 1986 1986 Moderate Low Moderate Low High Moderate
Schultz 2004 2004 High Low Low Low Moderate Moderate
Shaw 2009 2009 High Moderate Moderate Moderate Low Low
Sherman 2009 2009 Moderate Low Moderate Low Low Low
Steenstra 2005 2005 Low Low Moderate Low Moderate Low
Tran 2015 2015 Moderate Low Moderate Low Moderate Moderate
Truchon 2012 2012 Moderate Low High Low Low Low
Turner 2008 2008 Moderate Low Moderate Low Low Low
Underwood 2007 2007 Low Moderate Moderate Low Low Low
Van Hooff 2014 2014 Low Low Low Low Moderate Moderate
Van Wijk 2008 2008 Moderate Low High Low Low Low
Yelland 2006 2006 Moderate Low Low Low Moderate Low

Table 9 presents detailed information about 'Risk of bias' judgements for each included study. We rated 36 studies (60%) overall at low/moderate risk of bias, with all six domains judged to be at low or moderate risk of bias. We assessed only two studies (3%) as having low risk of bias for all of the six domains. Domains where we rated fewer than 50% of studies as having low risk of bias included: Study participation (55% moderate, 15% high risk of bias), Prognostic factor measurement (48% moderate, 7% high risk of bias), and Study confounding (32% moderate, 22% high risk of bias). Figure 3 shows a summary of the review authors' judgements about each 'Risk of bias' domain, presented as percentages across all included studies.

8. Detailed QUIPS risk of bias assessments by study.

Study ID: Beneciuk 2017
Domain Risk of bias level Support for judgement
Study Participation Moderate Participation rate 63%; non‐participants not adequately described
Study Attrition Moderate 80% follow‐up at 4 months, 76% at 1 year; dropouts were younger
Prognostic Factor Measurement Moderate PF with good face validity (expectations of recovery; 0 ‐ 10); data driven cut‐points used to categorise continuous measure of PF
Outcome Measurement Low Clinical rationale provided for categorisation of continuous outcome (RMDQ)
Study Confounding High Univariate only for PF association with outcome (TEM analysis)
Statistical Analysis and Reporting Low Appropriate analysis for research question and study design; no apparent selective reporting of results
Study ID: Besen 2015
Domain Risk of bias level Support for Judgement
Study Participation Moderate Participation rate unclear (volunteers); selection criteria and baseline sample adequately described
Study Attrition Moderate 72% follow‐up at 3 months; no reasons for loss, respondents had more organisational support, which may bias results
Prognostic Factor Measurement Low Valid and reliable measure of PF (RTW confidence, and RTW self‐efficacy scale)
Outcome Measurement Low Valid and reliable measurement of outcome (VAS, Quebec Back Pain Disability scale); work status, work modifications, duration of absences self‐reported with unclear measurement properties
Study Confounding Low Adequate adjustment (education, fear avoidance, catastrophising, race, ethnicity, income, organisational support, co‐worker support, pain)
Statistical Analysis and Reporting Low Appropriate analysis for research question and study design; no apparent selective reporting of results; conceptual framework for inclusion of covariates
Study ID: Bishop 2015
Domain Risk of bias level Support for judgement
Study Participation High Participation rate 38%; non‐participants not adequately described
Study Attrition Moderate 87% follow‐up; no information on attempts to collect outcome information from dropouts; dropouts were younger
Prognostic Factor Measurement Low Valid and reliable measure of PF (subscale of the Credibility Expectancy Questionnaire)
Outcome Measurement Low Valid and reliable measure of outcome (RMDQ)
Study Confounding Low Adequate adjustment (age, work status, LBP‐related benefits status, LBP‐related compensation status, reporting at least 1 comorbidity, reporting at least 1 co‐treatment, duration of LBP, clinic type, and healthcare sector)
Statistical Analysis and Reporting Low Appropriate analysis for research question and study design; no apparent selective reporting of results
Study ID: Butler 2007
Domain Risk of bias level Support for judgement
Study Participation Moderate Participation rate 51%; non‐participants not adequately described
Study Attrition Moderate 87% follow‐up at 1 month, 62% at 6 months, 42% at 1 year; no information on attempts to collect or possible reasons
Prognostic Factor Measurement Moderate Continuous measure of PF with good face validity (5‐point expectations of recovery) dichotomised for analyses without rationale provided
Outcome Measurement Low Unclear validity and reliability measurement of RTW outcome (unstable employment pattern)
Study Confounding Low Adequate adjustment (age, work status, LBP‐related benefits status, LBP‐related compensation) status, reporting at least 1 comorbidity, reporting at least 1 co‐treatment, duration of LBP, clinic type, and healthcare sector)
Statistical Analysis and Reporting Low Appropriate analysis for research question and study design; no apparent selective reporting of results
Study ID: Carriere 2015
Domain Risk of bias level Support for judgement
Study Participation Low Participants were consecutive referrals to a clinic
Study Attrition Moderate 78% follow‐up; no description of reasons
Prognostic Factor Measurement Moderate Data driven cut‐point used to categorise a continuous measure of PF with good face validity (likelihood of RTW; 0 ‐ 100)
Outcome Measurement Moderate Unclear measure of RTW status
Study Confounding Low Adeqaute adjustment (age, sex, work disability, pain severity, number of pain sites)
Statistical Analysis and Reporting Low Appropriate analysis for research question and study design; no apparent selective reporting of results
Study ID: Casey 2008
Domain Risk of bias level Support for judgement
Study Participation Moderate Participation rate unclear; selection criteria and baseline characteristics adequately described
Study Attrition Moderate 87% follow‐up; significant difference in those lost to follow‐up on pain constancy
Prognostic Factor Measurement Low Valid and reliable measure of PF (Pain Behaviour and Perception Inventory pain permanence subscale)
Outcome Measurement Low Valid and reliable measurement of outcome (mean VAS, PDI)
Study Confounding Moderate Minimal adjustment (previous pain, baseline pain, baseline disability, cumulative trauma, depressive symptoms, pain permanence beliefs, pain constancy beliefs, chronic pain intensity (3 months))
Statistical Analysis and Reporting Low Appropriate analysis for research question and study design; no apparent selective reporting of results
Study ID: Demmelmaier 2010
Domain Risk of bias level Support for judgement
Study Participation High Participation rate 39%; non‐participants not adequately described
Study Attrition High 37% follow‐up; no information provided on reasons or differences in characteristics
Prognostic Factor Measurement High Unclear measurement properties of PF; group median used to substitute missing data
Outcome Measurement Low Valid and reliable measurement of outcome (GCPS, sick leave yes/no)
Study Confounding Moderate Minimal adjustment (pain intensity baseline, disability, pain catastrophising, fear of movement, functional self‐efficacy)
Statistical Analysis and Reporting Moderate Appropriate analysis for research question and study design; possible selective reporting of results
Study ID: Dionne 1997
Domain Risk of bias level Support for judgement
Study Participation Moderate Participation rate 72%; non‐participants not adequately described
Study Attrition Low 92% follow‐up
Prognostic Factor Measurement Moderate Unclear validity and measurement properties (5‐point expectation of continued pain with no time period included)
Outcome Measurement Low Valid and reliable measurement of outcome (RMDQ)
Study Confounding High Univariate only available for our review question
Statistical Analysis and Reporting Moderate No conceptual framework; data driven based on P values of univariate associations
Study ID: Downie 2016
Domain Risk of bias level Support for judgement
Study Participation Moderate Participation rate 67%; non‐participants not adequately described
Study Attrition Low 96% follow‐up at 3 months
Prognostic Factor Measurement Low Continuous measure of PF with good face validity (risk of persistence; 0 ‐ 10)
Outcome Measurement Moderate Persistent high pain (≥ 5 on NRS) cluster and rapid recovery (< 1 on NRS) data available (clusters represent extremes)
Study Confounding Low Adequate adjustment (age, sex, taking paracetamol, compensable, pain intensity, duration, pain beyond knee, previous episodes, days of reduced activity, poor sleep quality, quality of life physical, quality of life mental, disability)
Statistical Analysis and Reporting Low While we were only able to use a subset of the data, authors used an appropriate analysis for research question and study design; no apparent selective reporting of results
Study ID: Du Bois 2008
Domain Risk of bias level Support for judgement
Study Participation Moderate Participation rate unclear; selection criteria and baseline sample adequately described
Study Attrition Low 100% follow‐up; work status recorded by the sickness fund
Prognostic Factor Measurement Moderate Continuous measure of PF with good face validity (10‐point Likert scale for probability of RTW within 6 months); dichotomised for analyses without rationale
Outcome Measurement Low Valid and reliable measurement of outcome (RTW at 3 months)
Study Confounding Moderate Minimal adjustment (pain below knee, pain interference)
Statistical Analysis and Reporting Moderate No conceptual framework; data driven based on P values of univariate associations
Study ID: Enthoven 2006
Domain Risk of bias level Support for judgement
Study Participation Low Participation rate 58%; inclusion criteria and non‐participants adequately described
Study Attrition Low 93% follow‐up at 1 year, 83% at 5 years
Prognostic Factor Measurement Moderate Continuous measure of PF with good face validity (5‐point expectations of restoration) dichotomised for analyses without rationale
Outcome Measurement Low Valid and reliable measurement of outcome (ODI, sick leave duration)
Study Confounding Low Adequate adjustment (age, sex, duration of current episode, similar problems during previous 5 years, exercise frequency before, exercise level before, dissatisfied with work, dissatisfied with workplace, more than one localisation, pain frequency, ODI score, well‐being, current sick leave)
Statistical Analysis and Reporting Low Appropriate analysis for research question and study design; no apparent selective reporting of results
Study ID: Enthoven 2016
Domain Risk of bias level Support for judgement
Study Participation Moderate Participation rate 53%; non‐participants not adequately described
Study Attrition Low 93% follow‐up at 3 months; reasons for loss provided
Prognostic Factor Measurement Low Continuous measure of PF with good face validity (5‐point expectations of recovery)
Outcome Measurement Low Valid and reliable measurement of outcome (NRS, RMDQ)
Study Confounding High Univariate only available for meta‐analyses
Statistical Analysis and Reporting Moderate No conceptual framework; data driven based on P values of univariate associations
Study ID: Foster 2008
Domain Risk of bias level Support for judgement
Study Participation Moderate Participation rate 51.4%; non‐participants not adequately described
Study Attrition High 65% follow‐up at 6 months; no information provided on reasons for loss
Prognostic Factor Measurement Low Valid and reliable measure of PF (IPQ‐R items) (Moss‐Morris 2002)
Outcome Measurement Low Valid and reliable measurement of outcome (pain duration); clinical rationale used to dichotomise RMDQ
Study Confounding Low Adequate adjustment (sex, education, catastrophising, fear avoidance, social class, pain intensity, RMDQ, pain duration, leg pain, distal pain, anxiety, depression, 4 more domains of CSQ, 6 domains of IPQR, passive coping)
Statistical Analysis and Reporting Low Appropriate analysis for research question and study design; no apparent selective reporting of results
Study ID: George 2010
Domain Risk of bias level Support for judgement
Study Participation Low Participation rate 81%
Study Attrition Low 67% follow‐up at 6 months; no differences found between dropouts and those with follow‐up data
Prognostic Factor Measurement Moderate Valid and reliable measure of PF (items from NASS lumbar spine outcome assessment instrument); dichotomised for analyses without rationale
Outcome Measurement Low Valid and reliable measure of outcome (von Korff)
Study Confounding High Univariate only
Statistical Analysis and Reporting Low Analysis not sufficient for our review question; combines 4‐week and 6‐month outcome data
Study ID: Gervais 1991
Domain Risk of bias level Support for judgement
Study Participation Low Participation rate 96%
Study Attrition Low 98% follow‐up
Prognostic Factor Measurement Low Valid and reliable measure of PF (self‐efficacy and results expectancies inventory)
Outcome Measurement Low Valid and reliable measurement of outcome (RTW time, recurrence, and at 6 months)
Study Confounding Moderate Minimal adjustment (diagnosis, lowest pain intensity, length of inactivity before treatment, negative life changes)
Statistical Analysis and Reporting Low Appropriate analysis for research question and study design; no apparent selective reporting of results
Study ID: Glattacker 2013
Domain Risk of bias level Support for judgement
Study Participation Moderate Participation rate 59%; non‐participants not adequately described
Study Attrition Moderate 74% follow‐up; no description of reasons; dropouts had higher baseline disability may bias results
Prognostic Factor Measurement Low Valid and reliable measure of PF (IPQ‐R items) (Moss‐Morris 2002)
Outcome Measurement Low Valid and reliable measurement of outcome (VAS, ODI, SF‐36 scales)
Study Confounding Low Adequate adjustment (baseline health, baseline mental health, age, sex, education, illness duration, psychological outcome expectation, process expectation, rehabilitation‐specific concerns, identify, consequences, personal control, treatment control, coherence, emotional representation, cause (overwork))
Statistical Analysis and Reporting Low Appropriate analysis for research question and study design; no apparent selective reporting of results
Study ID: Goldstein 2002
Domain Risk of bias level Support for judgement
Study Participation Moderate Participation rate 46.4%; reasons for not participating adequately described
Study Attrition Low 96% follow‐up
Prognostic Factor Measurement Low Continuous measure of PF with good face validity (NRS treatment confidence, 0 ‐ 10)
Outcome Measurement Low Valid and reliable measurement of outcome (NRS, RMDQ)
Study Confounding Moderate Minimal adjustment (baseline disability, age, gender, race, treatment group, duration of LBP episode)
Statistical Analysis and Reporting Low Appropriate analysis for research question and study design; no apparent selective reporting of results
Study ID: Gross 2010
Domain Risk of bias level Support for judgement
Study Participation Moderate Participants drawn from workers' compensation database; non‐participants not described
Study Attrition Low Claim‐based outcome measure; available for all participants included
Prognostic Factor Measurement Low Valid and reliable measure of PF (Work‐related Recovery Expectations Questionnaire)
Outcome Measurement Low Valid and reliable measurement of outcome (time to claim closure or suspension of time‐loss benefits, recurrence)
Study Confounding Low Adequate adjustment (age, sex, job attachment status, duration of injury, number of previous claims, urban/rural)
Statistical Analysis and Reporting Low Appropriate analysis for research question and study design; no apparent selective reporting of results
Study ID: Grotle 2006
Domain Risk of bias level Support for judgement
Study Participation High Participation rate unclear; supplemental recruiting from general population
Study Attrition Moderate 91% and 94% follow‐up at 1 year for each group; no reasons provided for loss to follow‐up
Prognostic Factor Measurement Moderate Valid and reliable measure of PF (Acute Low Back Pain Screening Questionnaire item), data driven cut‐point used for analyses
Outcome Measurement Low Valid and reliable measurement of outcome (NRS, days of participation restriction)
Study Confounding Moderate Minimal adjustment (age, sex)
Statistical Analysis and Reporting Low Analysis not sufficient for our study purposes only, expectations included as an item of a larger measure
Study ID: Haas 2014
Domain Risk of bias level Support for judgement
Study Participation High Participation rate 42%; recruitment from general population
Study Attrition Low 98% follow‐up
Prognostic Factor Measurement Low Valid and reliable measure of PF (Interstudy’s Low Back Pain TyPE Specification)
Outcome Measurement Low Valid and reliable measure of outcome (von Korff)
Study Confounding Moderate Minimal adjustment for relationship between baseline expectations and outcome (expectations at 6 and 12 weeks, doctor‐participant encounter at 6 and 12 weeks, LBP at 6 and 12 weeks)
Statistical Analysis and Reporting Low Appropriate analysis for research question and study design with conceptual model
Study ID: Hagen 2005
Domain Risk of bias level Support for judgement
Study Participation Moderate Participation rate unclear; selection criteria and baseline characteristics adequately described
Study Attrition Low 99% follow‐up at 1 year
Prognostic Factor Measurement Moderate Unclear validity, reliability of PF measurement and unclear measurement properties (Do you believe back pain will disappear?)
Outcome Measurement Low RTW determined from administrative claims database
Study Confounding Low Adequate adjustment (gender, age, education, group (intervention vs control), large reduced ability to regularly work, constant back strain > 50% of the working time, gastrointestinal problems, high chance externality (health locus of control), believe work will aggravate condition, pain when performing daily activities, state anxiety, other illnesses + 4 interaction terms)
Statistical Analysis and Reporting Low Appropriate analysis for research question and study design; no apparent selective reporting of results
Study ID: Haldorsen 1998
Domain Risk of bias level Support for judgement
Study Participation Moderate Participation rate 54%; non‐participants not adequately described; baseline sample adequately described
Study Attrition Low 100% follow‐up at 1 year
Prognostic Factor Measurement High Unclear validity, reliability of PF and unclear measurement properties of PF (If you continue working, what effect will that have on your complaints?)
Outcome Measurement Low Valid and reliable measurement of outcome (sick‐listed)
Study Confounding High Univariate only
Statistical Analysis and Reporting Moderate Appropriate analysis for research question and study design; possible selective reporting of results
Study ID: Harkapaa 1996
Domain Risk of bias level Support for judgement
Study Participation High Participation rate unclear; no description of non‐participants, limited description of participants
Study Attrition Moderate 74% follow‐up at 1 year; no information provided on reasons or differences in characteristics
Prognostic Factor Measurement Low Valid and reliable measure of PF (Optimism Index)
Outcome Measurement Low Valid and reliable measurement of outcome (work status), valid rationale used to categorise Functional Capacity Index
Study Confounding Low Adequate adjustment (age, sex, work status at baseline, baseline disability, others' locus of control)
Statistical Analysis and Reporting Low Appropriate analysis for research question and study design; no apparent selective reporting of results
Study ID: Hazard 1996
Domain Risk of bias level Support for judgement
Study Participation Moderate Participation rate 24%; non‐participants were described and compared with small mean differences
Study Attrition Low 98% follow‐up at 3 months
Prognostic Factor Measurement Low Valid and reliable measure of PF (Vermont Disability Prediction Questionnaire item)
Outcome Measurement Low Self‐report measure of RTW with unclear measurement properties
Study Confounding Moderate Insufficient data on which Vermont Disability Prediction Questionnaire domains included in final multivariate model; age and sex not included
Statistical Analysis and Reporting Moderate Analysis not sufficient for our study purposes only, expectations included as an item of a larger measure; no conceptual framework; data driven based on P values of univariate associations
Study ID: Henschke 2008
Domain Risk of bias level Support for judgement
Study Participation Low Participation rate 92.1%
Study Attrition Low 99% follow‐up
Prognostic Factor Measurement Low Continuous measure of PF with good face validity (NRS perceived risk of persistence, 0 ‐ 10)
Outcome Measurement Low Valid and reliable measurement of outcome (SF‐36, return to previous work status)
Study Confounding Low Adequate adjustment (age, sex, pain intensity, interference with function, pain control, tension/anxiety, feelings of depression, compensable LBP, currently taking medications for LBP, days of reduced activity due to LBP, leg pain, no of pain sites, duration of episodes)
Statistical Analysis and Reporting Low Appropriate analysis for research question and study design; no apparent selective reporting of results
Study ID: Heymans 2006
Domain Risk of bias level Support for judgement
Study Participation Moderate Participation rate unclear; selection criteria and baseline sample adequately described
Study Attrition Low 100% follow‐up (90% with complete baseline data)
Prognostic Factor Measurement Low Good face validity, unclear reliability of PF (time to RTW in categories and 5‐point scale for certainty of RTW)
Outcome Measurement Low Valid and reliable measurement of outcome (time to full RTW)
Study Confounding Low Adequate adjustment (job satisfaction, social support, pain radiation in 1 or both legs, pain intensity)
Statistical Analysis and Reporting Low Appropriate analysis for research question and study design; comprehensive method for backwards selection of variables
Study ID: Hildebrandt 1997
Domain Risk of bias level Support for judgement
Study Participation High Participation rate and recruitment approach unclear
Study Attrition Moderate 91% follow‐up; some non‐participants lost due to refusal to participate, and not adequately described
Prognostic Factor Measurement Moderate Mix of treatment and general expectations; unclear measurement properties of PF (RTW after treatment)
Outcome Measurement Low Valid and reliable measurement of outcome (VAS, sick‐listed Y/N)
Study Confounding High Univariate only
Statistical Analysis and Reporting Moderate Analysis not sufficient for our study purposes only, outcome measured at 6 and 12 months but not analysed; Only mean and standard deviation of expectations measure presented for success and failure in outcome
Study ID: Jellema 2002
Domain Risk of bias level Support for judgement
Study Participation High Participation rate unclear (workers volunteered)
Study Attrition Moderate 83% follow‐up; reasons for loss to follow‐up provided, but no information provided on differences in characteristics
Prognostic Factor Measurement Low Continuous measure of PF with good face validity (NRS treatment confidence, 0 ‐ 10)
Outcome Measurement Low Valid and reliable measurement of outcome (NRS, Quebec Back Pain Disability Scale, time lost from work)
Study Confounding High Univariate data only measures change in pain intensity with no other baseline variables taken into account; no data available for meta‐analyses
Statistical Analysis and Reporting High Analysis not sufficient for our study purposes only, outcome measured weekly and mean benefit over 6 months used for analysis
Study ID: Jensen 2000
Domain Risk of bias level Support for judgement
Study Participation Moderate Participation rate unclear; selection criteria and baseline characteristics adequately described
Study Attrition Moderate 69% follow‐up in sample 1, 100% in sample 2; no information provided on reasons or differences in characteristics
Prognostic Factor Measurement Moderate Unclear measurement properties of PF; unclear validity, reliability of PF (Belief that there is a treatment that could relieve condition; Belief in ability for learning to cope with the pain)
Outcome Measurement Low Valid and reliable measurement of outcome (SF‐36, days sick leave, disability pension Y/N)
Study Confounding Moderate Minimal adjustment (attending physician's judgement, attending physiotherapist's judgement of need and potential; insurance officer judgement of need and potential; screening physician judgement of need and of potential)
Statistical Analysis and Reporting Low Appropriate analysis for research question and study design; no apparent selective reporting of results
Study ID: Jensen 2013
Domain Risk of bias level Support for judgement
Study Participation Moderate Participation rate unclear; selection criteria and baseline characteristics adequately described
Study Attrition Low 100% follow‐up
Prognostic Factor Measurement Moderate Good face validity, unclear reliability of PF (time to RTW categories)
Outcome Measurement Low Valid and reliable measurement of outcome (successful RTW for at least 4 weeks)
Study Confounding Moderate Minimal adjustment (pain side flexion, blaming work for pain, drinking alcohol, radiculopathy, BMI, age, sex)
Statistical Analysis and Reporting Low Appropriate analysis for research question and study design; method for backwards selection of variables
Study ID: Karjalainen 2003
Domain Risk of bias level Support for judgement
Study Participation Moderate Participation rate unclear; selection criteria and baseline characteristics adequately described
Study Attrition Low 95% follow‐up
Prognostic Factor Measurement Low Continuous measure of PF with good face validity (NRS expectations of treatment effectiveness, 0 ‐ 10)
Outcome Measurement Low Valid and reliable measurement of outcome (NRS, ODI, sick leave because of back pain)
Study Confounding Low Adequate adjustment (gender, age, BMI, blue‐collar worker, duration of sick leave at baseline, radicular symptoms below the knee, intensity of pain at baseline, ODI, satisfaction with work, self‐rated health status for age)
Statistical Analysis and Reporting Moderate No conceptual framework; data driven based on P values of univariate associations
Study ID: Kongsted 2014
Domain Risk of bias level Support for judgement
Study Participation Low Participation rate 98%
Study Attrition Moderate Unclear attrition at 6 months and 1 year, 76% ‐ 83% follow‐up at 3 months; no information provided on reasons or differences in characteristics
Prognostic Factor Measurement Low Continuous measure of PF with good face validity (NRS)
Outcome Measurement Low Valid and reliable measure of outcomes (NRS and RMDQ)
Study Confounding Low Adequate adjustment (Model 1: age, gender, education, any sick leave previous month, LBP at baseline, leg pain at baseline, activity limitation at baseline, duration of LBP, number previous episodes of LBP, depression)
Statistical Analysis and Reporting Low Appropriate analysis for research question and study design; no apparent selective reporting of results
Study ID: Leboeuf‐Yde 2004
Domain Risk of bias level Support for judgement
Study Participation Moderate Participation rate unclear; selection criteria and baseline characteristics adequately described
Study Attrition Moderate 68% follow‐up at 3 months, 59% at 1 year; gender differences at each follow‐up from baseline, no reasons for loss reported
Prognostic Factor Measurement Moderate Validity, reliability and measurement properties of PF unclear (helpfulness of treatment, sick leave in 6 weeks, yes/no; 4‐point improvement of pain in 6 weeks)
Outcome Measurement Low Valid and reliable measurement of outcome (pain 0 ‐ 10, ODI), clinical rationale used to dichotomise for analyses
Study Confounding Moderate Minimal adjustment at 3 months (sex, pain severity, episode duration, neck pain) and 12 months (disability, activity limitation)
Statistical Analysis and Reporting Moderate Analysis not sufficient for our study purposes only, combines 4‐week, 3‐month and 12‐month outcome data; no conceptual framework; data driven based on P values of univariate associations
Study ID: Lindell 2010
Domain Risk of bias level Support for judgement
Study Participation Low Participation rate 85%
Study Attrition Low 99% follow‐up at 6 months, 98% at 1 year
Prognostic Factor Measurement Moderate Continuous measure of PF with good face validity (5‐point expectations of RTW) dichotomised for analyses without rationale provided
Outcome Measurement Low Valid and reliable measurement of outcome (successful RTW for at least 1 month)
Study Confounding Low Adequate adjustment (age, education, type of back pain, back pain domination, catastrophising, total prior sick‐listing)
Statistical Analysis and Reporting Low Appropriate analysis for research question and study design; method for backwards selection of variables
Study ID: Macedo 2014
Domain Risk of bias level Support for judgement
Study Participation Moderate Participation rate 68.5%; non‐participants not adequately described
Study Attrition Low 87% ‐ 93% follow‐up; no differences found between dropouts and those with follow‐up data
Prognostic Factor Measurement Moderate Valid and reliable measure of expectations (PSEQ) dichotomised for analyses without rationale provided
Outcome Measurement Low Valid and reliable measure of outcomes (NRS and Patient‐Specific Function Scale)
Study Confounding High Univariate only for PF association data (TEM analysis)
Statistical Analysis and Reporting Low Appropriate analysis for research question and study design; no apparent selective reporting of results
Study ID: Magnussen 2007
Domain Risk of bias level Support for judgement
Study Participation Moderate Participation rate unclear; adequate description of non‐participants but no reasons for not participating/exclusion
Study Attrition Moderate 91% follow‐up; reasons provided for not completing intervention but not questionnaire, no information on differences in characteristics
Prognostic Factor Measurement Moderate Unclear validity, reliability, and measurement of PF (ever RTW, "don't know" grouped with "no" for analyses)
Outcome Measurement Moderate Unclear validity and reliability measurement of RTW outcome (self‐report of being in a RTW process with unclear measurement properties; additional outcome ‐ RMDQ)
Study Confounding High Univariate only
Statistical Analysis and Reporting Low Appropriate analysis for research question and study design; no apparent selective reporting of results
Study ID: Michaelson 2004
Domain Risk of bias level Support for judgement
Study Participation Low Participation rate 98%
Study Attrition Low 75% follow‐up at 1 year; authors indicate no differences between dropouts and those with follow‐up data
Prognostic Factor Measurement Low Valid and reliable measure of expectations (Optimism Index)
Outcome Measurement Low Clinical rationale provided for categorisation of continuous outcome (VAS)
Study Confounding Moderate Minimal adjustment (age, sex, optimism index, MPI pain severity, pain intensity on average); no data available for meta‐analyses
Statistical Analysis and Reporting Moderate No conceptual framework; data driven based on P values of univariate associations
Study ID: Morlock 2002
Domain Risk of bias level Support for judgement
Study Participation Moderate Participation rate unclear; inclusion criteria adequately described, baseline sample not adequately described
Study Attrition High Unclear attrition; no information provided on reasons or differences in characteristics
Prognostic Factor Measurement Low Continuous PF measure with good face validity (combining 5 5‐point scales of treatment expectation)
Outcome Measurement Low Valid and reliable measurement of outcome (NASS)
Study Confounding Low Adequate adjustment (age, baseline NASS score, workers compensation status, gender, race, acuity, symptom location, Charlson Comorbidity Index)
Statistical Analysis and Reporting Moderate No conceptual framework; data driven based on P values of univariate associations
Study ID: Myers 2007
Domain Risk of bias level Support for judgement
Study Participation Low Participation rate 66%; selection criteria, reasons for not participating, and baseline characteristics adequately described
Study Attrition Low 99% at follow‐up
Prognostic Factor Measurement Low Continuous measure of PF with good face validity (NRS likelihood of recovery, 0 ‐ 10)
Outcome Measurement Low Valid and reliable measurement of outcome (RMDQ)
Study Confounding Low Adequate adjustment (age, race, income, baseline disability, depression, history of sciatica, 2nd time seeing doctor for LBP, baseline pain)
Statistical Analysis and Reporting Low Appropriate analysis for research question and study design; comprehensive method for backwards selection of variables
Study ID: Niemisto 2004
Domain Risk of bias level Support for judgement
Study Participation Low Participation rate 97%
Study Attrition Low 96% follow‐up
Prognostic Factor Measurement Moderate Independent measurement properties of PF unknown (item of Workability Index) dichotomised for analyses without rationale provided
Outcome Measurement Low Valid and reliable measurement of outcome (VAS, ODI, Work‐ability Index, number of days on sick leave)
Study Confounding Low Adequate adjustment (university education; VAS score; sick leave days during previous year; life control; SLUMP test)
Statistical Analysis and Reporting Moderate No conceptual framework; data driven based on P values of univariate associations
Study ID: Opsahl 2016
Domain Risk of bias level Support for judgement
Study Participation Low Participation rate 100%
Study Attrition Low 99% follow‐up
Prognostic Factor Measurement Moderate Low and moderate expectancies grouped for analyses due to data constraints (4‐point rating of extent of RTW)
Outcome Measurement Moderate Unclear measure of RTW status
Study Confounding Low Adequate adjustment (Model 1: age, education, fear avoidance, smoking status, intervention groups, subjective health complaint inventory total, ODI, Hopkins Symptom Checklist (HSCL‐25) (emotional distress), co‐worker social support)
Statistical Analysis and Reporting Low Appropriate analysis for research question and study design; no apparent selective reporting of results
Study ID: Opsommer 2017
Domain Risk of bias level Support for judgement
Study Participation Low Participation rate 89.5%
Study Attrition Moderate 79.5% follow‐up; coping strategies and fear avoidance higher (worse) in dropouts may bias results
Prognostic Factor Measurement Low Valid and reliable measure of PF (Orebro Musculoskeletal Pain Questionnaire items)
Outcome Measurement Moderate Unclear measure of RTW status
Study Confounding High Univariate only
Statistical Analysis and Reporting Low Appropriate analysis for research question and study design; no apparent selective reporting of results
Study ID: Petersen 2007
Domain Risk of bias level Support for judgement
Study Participation Low Participants were consecutive referrals to a clinic; sample adequately described
Study Attrition Low 93% follow‐up at 1y, 83% at 5 years
Prognostic Factor Measurement Moderate Continuous measure of PF with good face validity (11‐point box scale, certainty of RTW) dichotomised for analyses without rationale provided
Outcome Measurement Low Valid and reliable measurement of outcome (sick‐listed), valid rationale used to categorise Low Back Rating Scale for analyses
Study Confounding Moderate Minimal adjustment (baseline disability, on sick leave, low job satisfaction, pain below the knee)
Statistical Analysis and Reporting Low Appropriate analysis for research question and study design; comprehensive method for backwards selection of variables
Study ID: Rasmussen‐Barr 2012
Domain Risk of bias level Support for judgement
Study Participation Low Participation rate 93%
Study Attrition Moderate 86% follow‐up at 1 year; reasons provided, lost to follow‐up had lower physical health, may bias results
Prognostic Factor Measurement Moderate Unclear validity, reliability of PF and unclear measurement properties of PF
Outcome Measurement Low Valid and reliable measurement of outcome (VAS, ODI), valid rationale used to dichotomise scores for analyses
Study Confounding High Univariate only
Statistical Analysis and Reporting Moderate No conceptual framework; data driven based on P values of univariate associations
Study ID: Reeser 2001
Domain Risk of bias level Support for judgement
Study Participation Moderate Participation rate unclear (recruitment at appointment booking); selection criteria and baseline characteristics adequately described
Study Attrition High 35% completed questionnaires at all follow‐up times at were included; respondents were older, may bias results; no reasons for loss provided
Prognostic Factor Measurement Low Continuous PF measure with good face validity (combining 5 5‐point scales of treatment expectation)
Outcome Measurement Low Valid and reliable measurement of outcome (MODEMS Physical Health and Pain scale, MODEMS Physical Health and Disability scale)
Study Confounding High No statistical models were used to assess the association between the expectations and the outcomes of interest
Statistical Analysis and Reporting Moderate No statistical models were used to assess the association between the expectations and the outcomes of interest; possible selective and unclear reporting of results
Study ID: Reiso 2003
Domain Risk of bias level Support for judgement
Study Participation Moderate Participation rate unclear (referred from primary care); selection criteria and baseline sample adequately described
Study Attrition Low Primary outcome return to work for 60+ days supplied by national register; no loss to follow‐up
Prognostic Factor Measurement Moderate Measure of PF with good face validity (RTW, part‐time RTW, still on sick leave) dichotomised for analyses without rationale provided
Outcome Measurement Low Valid and reliable measure of RTW (working for at least 60 consecutive days) from national register
Study Confounding Low Adequate adjustment (age, gender, diagnosis, pain intensity, workability)
Statistical Analysis and Reporting Moderate No conceptual framework; data driven based on P values of univariate associations
Study ID: Reme 2009
Domain Risk of bias level Support for judgement
Study Participation Low Participation rate 65%; inclusion criteria, reasons for not participating, and baseline sample adequately described
Study Attrition Low 99% follow‐up at 3 months, 97% at 1 year
Prognostic Factor Measurement Moderate Unclear validity, reliability of PF measurement and unclear measurement properties of PF (Expectation to return to work within the next few weeks (yes/no))
Outcome Measurement Low Valid and reliable measurement of outcome (sick leave and non‐RTW from insurance claims, self‐reported sick‐listing)
Study Confounding Low Adequate adjustment (group, gender, age, education, workload, sleep problems, reduced ability to walk, physiotherapy, back pain intensity, pain during activity, pain during rest)
Statistical Analysis and Reporting Moderate No conceptual framework; data driven based on P values of univariate associations
Study ID: Rundell 2017
Domain Risk of bias level Support for judgement
Study Participation Moderate Unclear participation rate; baseline sample and selection criteria adequately described; unclear reasons for not participating
Study Attrition Moderate 79% follow‐up at both 6 months and 1 year; no information provided on reasons for differences in characteristics
Prognostic Factor Measurement Low Continuous measure of PF at 6‐ and 12‐month follow‐up with good face validity (confidence in recovery; 0 ‐ 10); categorised for 3‐month follow‐up
Outcome Measurement Low Valid and reliable measure of outcomes (NRS and RMDQ); clinical rationale provided for categorisation of continuous
Study Confounding Moderate Minimal adjustment (age, sex, education, race, employment status, marital status, study site)
Statistical Analysis and Reporting Low Appropriate analysis for research question and study design; no apparent selective reporting of results
Study ID: Sandstrom 1986
Domain Risk of bias level Support for judgement
Study Participation Moderate Reported as consecutive referrals, but baseline sample not adequately described
Study Attrition Low 100% follow‐up
Prognostic Factor Measurement Moderate Unclear validity, reliability of PF and unclear measurement properties of PF ("Afraid to start working again, because I don't think I will be able to manage")
Outcome Measurement Low Valid and reliable measurement of outcome (sick‐listed Yes/No)
Study Confounding High Unclear variables included in stepwise models
Statistical Analysis and Reporting Moderate No conceptual framework; data driven based on P values of univariate associations
Study ID: Schultz 2004
Domain Risk of bias level Support for judgement
Study Participation High Participation rate 43%; non‐participants not adequately described
Study Attrition Low 83% ‐ 92% follow‐up; no reasons for loss provided, but dropouts not significantly different from responders
Prognostic Factor Measurement Low Valid and reliable measure of PF (8 questions on RTW expectations)
Outcome Measurement Low Valid and reliable measurement of outcome (days lost due to low back disability in past 18 months, RTW status at 18 months)
Study Confounding Moderate Minimal adjustment (LBP subgroup, SF‐36 Health Transition, and Karasek’s coworker support scale)
Statistical Analysis and Reporting Moderate No conceptual framework; data driven based on P values of univariate associations
Study ID: Shaw 2009
Domain Risk of bias level Support for judgement
Study Participation High Participation rate unclear (volunteers); no description of eligible non‐participants; full baseline sample not described
Study Attrition Moderate 91% follow‐up at 3 months; non‐responders were different on age, gender, and education
Prognostic Factor Measurement Moderate Unclear validity and reliability of PF (full RTW at 4 weeks categorized, 'unlikely' grouped with 'not sure' for analyses)
Outcome Measurement Moderate Unclear validity and reliability measurement of RTW outcome (self‐report RTW with unclear measurement properties); valid and reliable measurement of pain, function (NRS, RMDQ)
Study Confounding Low Adequate adjustment (age, gender, education, income, race, body mass index, smoking status, cause of injury, pain intensity rating, changes in pain since onset, missed a day of work already, job tenure, negative supervisor response, physical job demands, prior back surgery, past work absence due to LBP, employer allows modified duty, job enjoyment, worries about re‐injury, frequency of moderate exercise, general health rating, felt downhearted and blue, felt under stress)
Statistical Analysis and Reporting Low Appropriate analysis for research question and study design; no apparent selective reporting of results
Study ID: Sherman 2009
Domain Risk of bias level Support for judgement
Study Participation Moderate Participation rate 78%; non‐participants not adequately described
Study Attrition Low 91% follow‐up 6 months and 1 year; reasons for loss provided and not likely to bias results
Prognostic Factor Measurement Moderate Unclear validity, reliability of PF measurement and unclear measurement properties of 1 of the 2 PFs (Likelihood of self‐managing future back pain)
Outcome Measurement Low Valid and reliable measurement of outcome (RMDQ)
Study Confounding Low Adequate adjustment (baseline RMDQ score, baseline bothersomeness score, any disability, SF‐36 mental health score, age, gender, education level, employment, medication use, duration of chronic LBP, pain travels below knee, days of LBP in last 3 months, intense LBP treatment, treatment group)
Statistical Analysis and Reporting Low Appropriate analysis for research question and study design; no apparent selective reporting of results; conceptual framework for inclusion of covariates
Study ID: Steenstra 2005
Domain Risk of bias level Support for judgement
Study Participation Low Workers on sick leave required to submit baseline form to their employer (full participation)
Study Attrition Low 100% follow‐up
Prognostic Factor Measurement Moderate Unclear validity, reliability of PF measurement (sick leave > 10 or not)
Outcome Measurement Low Valid and reliable measurement of outcome (RTW, lasting RTW, total days sick leave)
Study Confounding Moderate Minimal adjustment (treatment by GP or specialist, seeking OP care, the interaction between the self‐reported expected duration of sick leave and seeking OP care, complaints due to job stress, diminished mobility, and the interactions between expected duration of more than 10 days and seeking OP care and between seeking OP care and diminished mobility)
Statistical Analysis and Reporting Low Appropriate analysis for research question and study design; no apparent selective reporting of results; conceptual framework for inclusion of covariates
Study ID: Tran 2015
Domain Risk of bias level Support for judgement
Study Participation Moderate Participation rate 52%; non‐participants not adequately described
Study Attrition Low 96% follow‐up
Prognostic Factor Measurement Moderate Data‐driven cut‐point used to categorise a continuous measure of PF with good face validity (expectation of helpfulness of treatment; 0 ‐ 10)
Outcome Measurement Low Valid and reliable measure of outcomes (NRS and RMDQ)
Study Confounding Moderate Minimal adjustment (age, sex, education, treatment arm, baseline SF‐36 Physical Component Score, baseline RMDQ score); univariate data only available for meta‐analyses
Statistical Analysis and Reporting Moderate Only mean and SD presented for change in each outcome by high and low expectations are presented; results of multivariate linear regression not presented due to non‐significance of PFs
Study ID: Truchon 2012
Domain Risk of bias level Support for judgement
Study Participation Moderate Participation rate 77%; non‐participants not adequately described
Study Attrition Low 99% follow‐up
Prognostic Factor Measurement High Unclear validity, reliability of PF measurement and unclear measurement properties of PF (Return to work expectations (time))
Outcome Measurement Low Valid and reliable measurement of outcome (number of days of absence)
Study Confounding Low Adequate adjustment (work‐related fear avoidance beliefs, annual family income, level of education, work schedule (irregular), work concerns)
Statistical Analysis and Reporting Low Appropriate analysis for research question and study design; no apparent selective reporting of results; conceptual framework for inclusion of covariates
Study ID: Turner 2008
Domain Risk of bias level Support for judgement
Study Participation Moderate Participation rate 51%; participants and non‐participants adequately described; non‐participants older and higher disability
Study Attrition Low 100% follow‐up
Prognostic Factor Measurement Moderate Continuous measure of PF with good face validity (NRS likelihood of recovery, 0 ‐ 10) categorised for analyses without rationale
Outcome Measurement Low Valid and reliable measurement of outcome (wage replacement compensation for disability at 12 months)
Study Confounding Low Adequate adjustment (mental health, catastrophising, blame, relations with co‐workers, work fear‐avoidance, age, gender, race, education, pain intensity, RMDQ, "and other psychosocial variables")
Statistical Analysis and Reporting Low Appropriate analysis for research question and study design; no apparent selective reporting of results; conceptual framework for inclusion of covariates
Study ID: Underwood 2007
Domain Risk of bias level Support for judgement
Study Participation Low Participation rate unclear; baseline sample and inclusion criteria adequately described
Study Attrition Moderate 77% follow‐up at 3 months, 75% follow‐up at 1 year; no information provided on reasons or differences in characteristics
Prognostic Factor Measurement Moderate Unclear validity and reliability of PF measurement (3‐pt Likert on treatment helpfulness)
Outcome Measurement Low Valid and reliable measurement of outcome (modified von Korff, RMDQ)
Study Confounding Low Adequate adjustment (manipulation and exercise, manipulation, exercise, additional education, working, age, male, pain and disability, quality of life, beliefs, episode length)
Statistical Analysis and Reporting Low Appropriate analysis for research question and study design; no apparent selective reporting of results; conceptual framework for inclusion of covariates
Study ID: Van Hooff 2014
Domain Risk of bias level Support for judgement
  Low Participation rate 84%
  Low 87% follow‐up; authors indicate no differences between dropouts and those with follow‐up data
  Low Valid and reliable measure of PF (PSEQ)
  Low Valid and reliable measure of outcome (ODI); clinical rationale provided for categorisation of continuous outcome
  Moderate Minimal adjustment (function and employment); univariate only available for meta‐analyses
  Moderate Only mean and standard deviation of expectations measure presented for success and failure in outcome
Study ID: Van Wijk 2008
Domain Risk of bias level Support for judgement
Study Participation Moderate Participants from two trials (79% and 98% participation); selection criteria may lead to bias selected chronic group with no treatment response; response to facet joint block required
Study Attrition Low 100% follow‐up at 3 months, 82% at 1 year; reasons provided, no information on differences in characteristics
Prognostic Factor Measurement High Unclear which item of PCL is used for analyses, unclear description of PF
Outcome Measurement Low Valid and reliable measurement of outcome (VAS, Physical Activity Scale)
Study Confounding Low Adequate adjustment (baseline pain, 5 psychosocial domains: psychologically negative, adaptive manager, inflexible qualities, supporting partner, strong ego); no data available for meta‐analyses (expectations reported as part of a factor)
Statistical Analysis and Reporting Low Analysis not sufficient for our study purposes only, expectations used to define psychological profile clusters for analyses
Study ID: Yelland 2006
Domain Risk of bias level Support for judgement
Study Participation Moderate 80% participation among eligible; inclusion criteria of high disability and failure to respond to conservative treatment may lead to bias
Study Attrition Low 99% follow‐up at 6 months, 96% at 1 year
Prognostic Factor Measurement Low Continuous measure of PF with good face validity (% improvement expected with treatment; 0 ‐ 100)
Outcome Measurement Low Valid and reliable measurement of outcome (VAS)
Study Confounding Moderate Minimal adjustment (age, gender)
Statistical Analysis and Reporting Low Appropriate analysis for research question and study design; no apparent selective reporting of results

PF = prognostic factor; RMDQ = Roland Morris Disability Questionnaire; TEM = treatment effect modifier; RTW = return to work; VAS = pain visual analog scal; LBP = low back pain; PDI = Pain Disability Index; GCPS = Graded CHronic Pain Scale; NRS = pain numeric rating scale; ODI = Oswestry Disability Index; IPQ‐R = Illness Perception Questionnaire (revised); CSQ = Coping Strategies Questionnaire; NASS = North American Spine Society Outcome Assessment scale; SF‐36 = 36‐item Short Forum Survey; BMI = body mass index; PQEQ = Pain Self‐efficacy Questionnaire.

3.

3

QUIPS risk of bias graph: Review authors' judgements about each risk of bias domain presented as percentages across all included studies (n=60).

Findings

There were between 10 and 25 studies that provided sufficiently similar data about the association between expectations and each of our primary outcomes. There were zero to 12 studies (with 13 groups) available for each of our planned meta‐analyses. We report synthesis results in the text only when three or more studies contributed data to a meta‐analysis, as described in our protocol. All studies with multiple groups reported associations in the same direction for the multiple groups, so we present narrative syntheses at the study level. Overall, moderate‐quality evidence was available for work participation outcome, low‐quality evidence for important recovery outcome, very low‐quality evidence for functional limitations, and low‐quality evidence for pain intensity outcomes (Table 1). Among participants with non‐specific low back pain, positive expectations were associated with better outcomes for work participation (unadjusted and adjusted); findings for important recovery, functional limitations and pain intensity outcomes are less certain, as described below. No studies reported statistically significant or clinically important negative associations between expectations and any low back pain outcomes. There were insufficient studies presenting HRs to conduct a separate analysis.

Association of expectations with work participation

Overall there was moderate‐quality evidence for the association of expectations with work participation outcome (Table 1). Although there were serious limitations to the data due to moderate risk of bias for many included studies, and potential publication/reporting bias, the overall quality of evidence was raised by the availability of confirmatory evidence, consistently‐reported positive direction of effect, and moderate to large effect size for studies with data available for meta‐analysis; there was no serious indirectness of the evidence.

Twenty‐five studies (7058 participants) reported information about the association of expectations and work participation (Table 4). Of these, 18 studies (5978 participants) reported unadjusted results, with 17 reporting statistically significant positive associations of expectations with work participation and one study reporting neutral results (i.e. good expectations were statistically significantly associated with better work participation outcomes in almost all available studies). Four studies that reported positive associations for unadjusted analyses did not report adjusted results. Twenty‐one studies (6797 participants) reported adjusted results (adjusted for other important covariates), with 16 reporting statistically significant positive associations of expectations with work participation and five studies reporting results that were not statistically significant in either direction (i.e. neutral) (Table 1); 11 studies reported clinically important effect sizes.

Fifteen studies (16 groups; 5365 participants) provided sufficiently similar data to allow meta‐analysis for work participation outcomes. Pooled unadjusted results found expectations to be associated (statistically significant and clinically important) with work outcomes at the time point closest to 12 months, with expectations measured dichotomously (10 studies, 11 groups; 4528 participants): OR 4.11, 95% CI 3.46 to 4.89; I2 = 6% (Analysis 1.1; Figure 4). There were similar findings, but with smaller effect sizes (statistically significant and clinically important) and considerable heterogeneity, with pooled adjusted results, with expectations measured dichotomously (12 studies, 13 groups; 4777 participants): OR 2.43, 95% CI 1.64 to 3.62; I2 = 89%). Only two studies provided sufficient data for unadjusted and adjusted results with expectations measured continuously, not allowing for meaningful meta‐analysis (Analysis 1.2). Visual assessment of the funnel plot of adjusted results of the association between dichotomous expectations measures and work participation outcome suggests the presence of small‐study effects (Egger’s test bias coefficient = 2.79; P < 0.001), which raises the concern of potential publication or reporting bias (Figure 5).

1.1. Analysis.

Comparison 1 Are expectations associated with work participation (closest to 12 months)?, Outcome 1 Dichotomous measure of expectations.

4.

4

Forest plot: Are expectations associated with work participation (closest to 12 months)? Dichotomous measure of expectations; unadjusted results (10 studies; 11 groups 4,528 participants), and adjusted results (12 studies; 13 groups; 4,777 participants)

1.2. Analysis.

Comparison 1 Are expectations associated with work participation (closest to 12 months)?, Outcome 2 Continuous measure of expectations (/10).

5.

5

Funnel plot of comparison: Are expectations associated with work participation (closest to 12 months)? Dichotomous measure of expectations.

Association of expectations with important recovery

Overall we judged that there was low‐quality evidence for the association between expectations and important recovery outcomes. No confirmatory evidence of association was available for this outcome and there were serious limitations to the data, due to moderate risk of bias for many included studies, and potential publication/reporting bias. The overall quality of evidence was raised by a consistently‐reported positive direction of effect, and moderate to large effect size for studies with data available for meta‐analysis; there was no serious indirectness of the evidence (Table 1).

Sixteen studies (10,063 participants) reported usable information about the association of expectations and important recovery (Table 5). Of these studies, 11 (8,872 participants) reported unadjusted results with nine reporting statistically significant positive associations of expectations with important recovery and two studies reporting results that were not statistically significant in either direction. Three studies that reported positive associations for unadjusted analyses did not report adjusted results. Twelve studies (8261 participants) reported adjusted results, with six reporting positive association of expectations with important recovery and six studies reporting results that were not statistically significant in either direction (Table 1); six studies reported clinically‐important effect sizes.

Ten studies, 10 groups; 7766 participants provided sufficiently similar data allowing meta‐analysis for important recovery outcomes. Pooled unadjusted results found expectations to be associated with important recovery (statistically significant and clinically important) at the time point closest to 12 months, with expectations measured dichotomously (3 studies, 3 groups; 786 participants) (OR 2.40, 95% CI 1.32 to 4.37; I2 = 49%) (Analysis 2.1; Figure 6). We found similar results, but with smaller effect sizes and unimportant heterogeneity, with pooled adjusted results with expectations measured dichotomously (5 studies, 5 groups; 1820 participants) (OR 1.89, 95% CI 1.49 to 2.41; I2 = 0%) (statistically significant and clinically important), and continuously (4 studies, 4 groups; 1820 participants) (OR 1.15, 95% CI 1.07 to 1.24; I2 = 81%) (statistically significant, but not clinically important). Only one study provided unadjusted results with expectations measured continuously, not allowing for meaningful meta‐analysis (Analysis 2.2).

2.1. Analysis.

Comparison 2 Are expectations associated with important recovery (closest to 12 months)?, Outcome 1 Dichotomous measure of expectations.

6.

6

Forest plot of comparison: 2 Are expectations associated with important recovery (closest to 12 months)?, outcome: 2.1 Dichotomous measure of expectations.

2.2. Analysis.

Comparison 2 Are expectations associated with important recovery (closest to 12 months)?, Outcome 2 Continuous measure of expectations (/10).

Association of expectations with functional limitations

We judged the overall quality of the evidence to be very low for functional limitations outcome. There were serious limitations to the data, due to moderate risk of bias for many included studies, potential publication/reporting bias, and imprecision of the small estimate for studies available for meta‐analysis (Table 1).

Thirteen studies (5068 participants) reported usable information about the association of expectations and functional limitations (Table 6). Of these studies, nine (3267 participants) reported unadjusted results, with seven reporting statistically significant positive associations of expectations with functional limitations and two studies reporting results that were not statistically significant in either direction. Two studies that reported positive associations for unadjusted analyses did not report adjusted results. Ten studies (3476 participants) reported adjusted results, with six reporting statistically significant positive association of expectations with functional limitations and four studies reporting results that were not statistically significant in either direction (Table 1); seven studies reported clinically important effect sizes.

Seven studies, 8 groups; 3038 participants provided sufficiently similar data to allow meta‐analysis for functional limitations outcomes. For dichotomous measures of expectations, only one study provided unadjusted results and two studies provided adjusted results, not allowing for meaningful meta‐analysis (Analysis 3.1). Pooled unadjusted results found no relationship between expectations and functional limitations at the time point closest to 12 months with expectations measured continuously (3 studies, 4 groups; 1130 participants) (OR 1.56, 95% CI 0.72 to 3.41; I2 = 72%). We found similar results with pooled adjusted results with expectations measured continuously (3 studies, 3 groups; 1435 participants) (OR 1.40, 95% CI 0.85 to 2.31; I2 = 81%) (Analysis 3.2; Table 1).

3.1. Analysis.

Comparison 3 Are expectations associated with functional limitation outcomes (closest to 12 months)?, Outcome 1 Dichotomous measure of expectations.

3.2. Analysis.

Comparison 3 Are expectations associated with functional limitation outcomes (closest to 12 months)?, Outcome 2 Continuous measure of expectations (/10).

Association of expectations with pain intensity

We judged the overall quality of the evidence to be low for pain intensity outcomes. There were serious limitations to the data due to moderate risk of bias for many included studies, and potential publication/reporting bias. There was a small effect estimate observed from studies available for meta‐analysis (Table 1).

Ten studies (2900 participants) reported usable information about the association of expectations and pain intensity (Table 7). Of these studies, seven (1853 participants) reported unadjusted results, with four reporting statistically significant positive associations of expectations with improved pain intensity and three studies reporting non‐statistically significant, neutral results. Nine studies (2726 participants) reported adjusted results, with five reporting a statistically significant positive association of expectations with improved pain intensity and four studies non‐statistically significant, neutral results (Table 1); three studies reported clinically important effect sizes.

Four studies (6 groups, 1820 participants) provided sufficiently similar data to allow meta‐analysis for pain intensity outcomes. For dichotomous measures of expectations, only one study (1 group) provided unadjusted results and no study provided adjusted results, not allowing for meaningful meta‐analysis (Analysis 4.1). Pooled unadjusted results found expectations not to be significantly associated with pain intensity improvement at the time point closest to 12 months with expectations measured continuously (2 studies, 3 groups, 743 participants) (OR 1.13, 95% CI 0.48 to 2.67; I2 = 77%). We found evidence of a small prognostic effect with pooled adjusted results with expectations measured continuously (2 studies, 3 groups, 1555 participants) (OR 1.15, 95% CI 1.08 to 1.23; I2 = 0%) (Analysis 4.2; Table 1).

4.1. Analysis.

Comparison 4 Are expectations associated with pain outcomes (closest to 12 months)?, Outcome 1 Dichotomous measure of expectations.

4.2. Analysis.

Comparison 4 Are expectations associated with pain outcomes (closest to 12 months)?, Outcome 2 Continuous measure of expectations (/10).

Subgroup and sensitivity analyses

We conducted indirect subgroup comparisons for work participation outcomes at the follow‐up period closest to 12 months, using levels of evidence synthesis and meta‐analysis for low back pain duration, type of expectation, expectation reference time period, duration of follow‐up, exploratory versus confirmatory study design, and for studies judged to be at low or moderate/high risk of bias on each QUIPS domain. For low back pain duration, of the 21 studies (6797 participants) reporting usable adjusted results, one (241 participants) was conducted in an acute low back pain population (positive association of expectations with outcome), nine (2358 participants) in subacute/chronic populations (eight positive, one neutral), and 11 (4198 participants) included mixed‐duration low back pain populations (eight positive, four neutral). We found no difference in the effect size for study populations of subacute/chronic low back pain duration (4 studies, 1035 participants) (OR 2.34, 95% CI 1.61 to 3.40; I2 = 6%) and for study populations with mixed duration of low back pain (8 studies, 9 groups, 3742 participants) (OR 2.41, 95% CI 1.48 to 3.91; I2 = 91%); test for subgroup effect found no differences (Chi2 = 0.01; P = 0.93). No studies provided data for meta‐analysis in acute low back pain (Analysis 5.1).

5.1. Analysis.

Comparison 5 Work participation outcome (closest to 12 months); dichotomous measure of expectations (adjusted): Subgroup analyses, Outcome 1 Low back pain duration.

No information was available for types of expectation measures other than general recovery. Association of general expectations with work participation outcome was reported with usable adjusted results in 18 studies (6503 participants) (15 with positive association of expectations with outcome, three reporting neutral results), four studies (535 participants) reported associations for self‐efficacy expectation measures (two positive, two neutral), and two (375 participants) reported treatment expectations (one positive, one neutral). No studies provided data for meta‐analysis of self‐efficacy or treatment expectations measures (Analysis 5.2).

5.2. Analysis.

Comparison 5 Work participation outcome (closest to 12 months); dichotomous measure of expectations (adjusted): Subgroup analyses, Outcome 2 Recovery expectation types.

For expectations reference time period, of the 21 studies that report useable adjusted results, four (949 participants) referenced one month or less, four (2506 participants) referenced three to six months, and 13 (3342 participants) either referenced a continuum of time or no specific time. We found no significant difference in the adjusted effect sizes for expectations reference periods of one month or less (4 studies, 949 participants) (OR 2.02, 95% CI 1.00 to 4.09; I2 = 94%), three to six months (4 studies, 2506 participants) (OR 2.83, 95% CI 1.36 to 5.89; I2 = 75%) and no/unclear reference periods (4 studies, 5 groups, 1322 participants) (OR 2.55, 95% CI 1.53 to 4.25; I2 = 52%); test for subgroup effect found no differences (Chi2 = 0.45; P = 0.80) (Analysis 5.3).

5.3. Analysis.

Comparison 5 Work participation outcome (closest to 12 months); dichotomous measure of expectations (adjusted): Subgroup analyses, Outcome 3 Recovery expectation reference time periods.

For duration of follow‐up, five studies (1274 participants) reported short follow‐up of approximately three months (four with positive association of expectations with outcome, one with neutral association), six (4438 participants) reported moderate follow‐up of approximately six months (three positive, three neutral), 16 (5460 participants) reported long follow‐up of approximately 12 months (13 positive, three neutral), and four studies (502 participants) reported very long follow‐up greater than 16 months (one positive, three neutral). We found no significant difference in the adjusted effect sizes for follow‐up periods: short (3 studies, 816 participants) (OR 3.19, 95% CI 1.77 to 5.75; I2 = 41%), moderate (4 studies, 2696 participants) (OR 2.43, 95% CI 1.58 to 3.74; I2 = 45%), long (9 studies, 10 groups, 3923 participants) (OR 2.12, 95% CI 1.41 to 3.17; I2 = 82%) and very long (2 studies, 276 participants) (OR 3.10, 95% CI 1.87 to 5.12; I2 = 0%); test for subgroup effect found no differences (Chi2 = 1.98; P = 0.58) (Analysis 5.4).

5.4. Analysis.

Comparison 5 Work participation outcome (closest to 12 months); dichotomous measure of expectations (adjusted): Subgroup analyses, Outcome 4 Outcome follow‐up periods.

For exploratory versus confirmatory phases of study design, of the 21 studies (6797 participants) that reported usable adjusted results, 16 (5529 participants) were conducted using an exploratory approach (11 reported positive association of expectations with outcome, five reported neutral association), and five (1268 participants) were conducted using a confirmatory approach for individual expectations (all six reported positive associations). We found no difference in the effect size between exploratory studies (10 studies, 4100 participants) (OR 2.41, 95% CI 1.76 to 3.29; I2 = 57%) and confirmatory studies (2 studies, 3 groups, 677 participants) (OR 2.31, 95% CI 0.82 to 6.51; I2 = 91%); test for subgroup effect found no differences (Chi2 = 0.01; P = 0.94) (Analysis 5.5).

5.5. Analysis.

Comparison 5 Work participation outcome (closest to 12 months); dichotomous measure of expectations (adjusted): Subgroup analyses, Outcome 5 Study phase of investigation.

Results of subgroup analyses for studies rated as low, and moderate/high risk of bias in each QUIPS domain found that the observed direction of association was less consistent (< 75% in the same positive direction) for the Attrition and Confounding domains. The pooled adjusted effect size in studies judged to have low risk of bias due to Attrition was higher (10 studies, 11 groups, 4496 participants) (OR 2.72, 95% CI 2.05 to 3.60; I2 = 51%) than for studies judged to have moderate/high risk of bias on the same domain (2 studies, 281 participants) (OR 1.04, 95% CI 1.02 to 1.06; I2 = 0%); test for subgroup effect was statistically significant (Chi2 = 44.59; P < 0.001), and clinically important (Analysis 6.2). The pooled effect size in studies judged to have low risk of bias due to the Confounding domain was lower (8 studies, 9 groups, 3641 participants) (OR 2.03, 95% CI 1.34 to 3.07; I2 = 84%) than for studies judged to have moderate/high risk of bias on the same domain (4 studies, 1136 participants) (OR 3.10, 95% CI 2.36 to 4.07; I2 = 0%) by a clinically important amount, but the test for subgroup differences was not statistically significant (Chi2 = 2.78; P = 0.10) (Analysis 6.5). Subgroup analyses based on ratings of other QUIPS domains (Participation, Prognostic factor, Outcome, and Analysis and Reporting) found no difference in pooled effect sizes in studies judged to have low risk of bias and studies judged to have moderate/high risk of bias for the same domain (Analysis 6.1; Analysis 6.3; Analysis 6.4; Analysis 6.6).

6.2. Analysis.

Comparison 6 QUIPS ROB domain ratings (work participation outcome (closest to 12 months); dichotomous measure of expectations (adjusted)), Outcome 2 'Attrition' domain.

6.5. Analysis.

Comparison 6 QUIPS ROB domain ratings (work participation outcome (closest to 12 months); dichotomous measure of expectations (adjusted)), Outcome 5 'Confounding' domain.

6.1. Analysis.

Comparison 6 QUIPS ROB domain ratings (work participation outcome (closest to 12 months); dichotomous measure of expectations (adjusted)), Outcome 1 'Participation' domain.

6.3. Analysis.

Comparison 6 QUIPS ROB domain ratings (work participation outcome (closest to 12 months); dichotomous measure of expectations (adjusted)), Outcome 3 'Prognostic factor' domain.

6.4. Analysis.

Comparison 6 QUIPS ROB domain ratings (work participation outcome (closest to 12 months); dichotomous measure of expectations (adjusted)), Outcome 4 'Outcome' domain.

6.6. Analysis.

Comparison 6 QUIPS ROB domain ratings (work participation outcome (closest to 12 months); dichotomous measure of expectations (adjusted)), Outcome 6 'Analysis and Reporting' domain.

Removing studies with incomplete data requiring data conversions in five sensitivity analyses (one to two studies removed) made it no longer possible to conduct two meta‐analyses of unadjusted results. Removal did not change the conclusions of the meta‐analysis of the association of expectations with work participation outcome.

Discussion

Summary of main results

Our review provides up‐to‐date evidence about the prognostic association of individual recovery expectations and provides an exemplar for implementation of systematic review methods in prognosis. We included 60 studies, with 52 studies providing data for narrative syntheses, and 24 providing adjusted results for meta‐analyses. Despite limitations and heterogeneity of the evidence available, results were quite consistent across primary analyses, as well as subgroup and sensitivity analyses.

We found moderate‐quality evidence that positive expectations are strongly associated with better work participation outcomes with large observed association for people with non‐specific low back pain at one year. Other outcomes of interest, including important recovery outcomes (moderate observed association); functional limitations and pain intensity outcomes are less certain, respectively achieving low, very low and low quality of evidence. No studies reported statistically significant or clinically important negative associations between recovery expectations and any low back pain outcomes. Our subgroup analyses did not identify any significant differences in the association of recovery expectations and work participation outcome by low back pain duration, recovery expectations reference time period, length of follow‐up period or study phase of investigation, although some subgroups had few studies available.

Our results suggest that individual recovery expectations should be considered for inclusion in future prognosis and intervention research studies. There was considerable heterogeneity in how individual studies measured and analysed individual recovery expectations ‐ only eight measures were used in more than one included study. More consistent measurement of patient expectations will facilitate future syntheses. Most studies that we identified used single‐item measures of expectations. Single items have been found to be valid and reliable for related constructs (e.g. self‐esteem (Robins 2001)), so may be appropriate for measuring expectations as a clear concept with a relevant reference time period and outcome specified. Although not the focus of our review, we observed five multi‐item scales of recovery expectations used in included studies that reported evidence of reliability and construct validity (Anderson 1995; Devilly 2000; Nicholas 2007; Shaw 2011; Vlaeyen 1990).

Certainty of evidence available

Overall there was moderate‐quality evidence for the association of expectations with work participation. Although there were serious limitations to the data due to moderate risk of bias for many included studies, and potential publication/reporting bias, which is likely to be an important limitation in all prognostic factor systematic reviews, the overall quality of evidence was raised by the availability of confirmatory evidence, consistently‐reported positive direction of effect, and moderate to large effect size for studies with data available for meta‐analysis; there was no serious indirectness of the evidence. We judged the overall quality of the evidence to be low for important recovery outcomes, very low quality for functional limitations, and low quality for pain intensity outcomes.

Strengths and weaknesses of the review

Our systematic review has numerous strengths. We planned our review a priori with clearly‐defined selection criteria. We conducted a comprehensive literature search, using many additional sources to identify relevant studies, including reference searches of other low back pain prognostic factor systematic reviews, expectation measure citation searches, and our broad search of low back pain prognosis studies (limited to the year 2003). Indeed, we identified 38% of included studies from additional search strategies, emphasising the potential importance of such search strategies in prognostic factor reviews. Refining electronic search strategies to improve sensitivity (but not at the expense of specificity) is an area requiring future investigation. We carefully defined characteristics potentially related to heterogeneity, and explored the impact of these with subgroup and sensitivity analyses.

We used both narrative and meta‐analytic approaches to synthesise the available evidence, and judged the overall quality of the evidence available. Data for meta‐analysis were available from adjusted analyses for only 32 of 60 included studies (53%). Our narrative synthesis approach summarised consistency of results by counting studies that reported positive, neutral or negative associations of expectations with outcome (52 studies, 87%, with available evidence). Although this ‘vote counting’ approach is often considered a last resort in intervention reviews, we think that it allows for more complete reporting of results when interpreted cautiously alongside meta‐analysis. This is particularly important for prognostic factor reviews where reporting bias is likely (studies finding a statistically significant association are more likely to report results) and may lead to an overestimation of effect estimate.

Limitations of our review are mainly related to the quality of the evidence available. We suspect publication or reporting biases, or both, suggesting our results may be overestimated. Positive study bias is likely to be problematic in this (and most other) prognostic factor systematic reviews. Due to feasibility, our literature search for relevant studies included focused searches, i.e. including search terms related to the ‘expectations concept’ in our electronic search strategy. Studies that report a relationship between the prognostic factor and common outcomes are therefore more likely to have been identified in these searches due to reporting of this positive result in the study abstract. We tried to address this potential bias by using additional search strategies (a broad search of low back pain prognosis studies, citation searches of expectation measures and reference searches of other low back pain prognosis systematic reviews), as well as identifying and including studies that measured expectations, even if it was not reported or included in prognostic analyses (i.e. reported as not statistically significant). We also observed that some studies (fortunately, a small number) reported positive unadjusted association of expectations with an outcome of interest, but then did not report the association adjusted for other important covariates; this further contributes to likely overestimation of our adjusted results. Future work is required to investigate the impact and potential strategies to alleviate publication and reporting bias, as well as initiatives to require protocol registration and publication of prognostic studies (Peat 2014).

Our review found considerable heterogeneity in the measurement and analysis of prognostic factors and outcomes. For our work participation outcome we found increased statistical heterogeneity in the adjusted meta‐analysis (I2 of 89%) compared to the meta‐analysis of unadjusted associations (I2 = 6%); considerable heterogeneity remained in this analysis even when limited to studies that we considered to be ideally adjusted according to our prespecified theoretical framework (I2 = 84%). This unexpected result emphasises the many sources of heterogeneity in prognostic factor studies. We found expectations measured on a continuous scale to be less strongly associated with outcomes than dichotomous measures of expectations. Different cut‐points used to determine 'good' expectations from continuous scales for analyses may be fuelling this strength of association if cut‐points were chosen by authors based on statistical significance rather than clinical relevance. There was also heterogeneity in data due to different model‐building and covariate adjustment. We have tried to transparently present and explore potential impacts in our review by presenting unadjusted and adjusted results, as is recommended by Riley 2019. We defined a priori an approach to judge studies as being ‘minimally’ or ‘adequately’ adjusted and prioritised adequately‐adjusted estimates for synthesis. However, overall we judged only 59% of adjusted results to be adequately adjusted, so cautious interpretation of results is warranted. Our 'Risk of bias' and GRADE judgements considered these limitations.

We assessed risks of bias for the study overall, based on the primary outcome at highest risk of bias, rather than separately by outcome measure. This may have overestimated the risks of bias for some outcomes. However, this was relevant for only a small number of studies included in analyses (eight for narrative syntheses, and two for meta‐analyses) and did not impact our conclusions. As with any systematic review, when assessing the overall quality of evidence we need to consider many different parts of study design, conduct, and available results. We used an adaptation of GRADE (Huguet 2013) to provide a framework for interpreting overall quality of prognostic factor evidence; this requires further testing and guidance for prognosis reviews.

There were limitations with the internal validity of some included studies for our review purposes. Future prognosis studies in the field should pay particular attention to limit study attrition, improve reporting, collect expectations using more consistent measures, and adequately control for other established prognostic factors. These limitations apply to most reviews of prognostic factors and should be addressed as methods for conducting these types of reviews are developed and refined.

Applicability of findings to clinical practice and policy

The evidence available for this systematic review represents chronic low back pain populations in Europe, North America and Australia, with healthcare and occupational settings equally represented. Only five included studies were conducted in acute low back pain populations, with none reporting data appropriate for our primary meta‐analyses of expectations measured dichotomously and return to work. The applicability of our findings for people with acute pain and in developing nations is uncertain.

For applicability of the prognostic factor measures, we aimed to assess evidence about three types of recovery expectations: general expectations, self‐efficacy expectations, and treatment expectations. However, most of the evidence available with sufficient homogeneity for meta‐analysis was restricted to general expectations. It was not possible to conduct syntheses and subgroup analyses to compare the association of the different types of expectations with low back pain outcomes. The direction of associations for self‐efficacy and treatment expectations with outcomes was mostly positive, suggesting similar applicability of findings. Prognostic factor measures used in the included studies were often single items, which are low burden for inclusion in future research studies or subsequent clinical decision‐support tools.

Agreements and disagreements with other studies or reviews

Our systematic review provides substantially more evidence on the association between individual recovery expectations and low back pain outcomes than earlier systematic reviews, which were inconclusive, missing relevant studies, and are now out of date. In this systematic review we have drawn similar conclusions to previous reviews (Fadyl 2008; Hallegraeff 2012; Iles 2009), with more confidence supported by a larger number of available studies.

Recent studies investigating the relationship between individual recovery expectations and health outcomes in other fields have reported similar results, including cardiac surgery (Holmes 2016), and major orthopedic trauma outcomes (Busse 2019). A systematic review of measures of patient expectations affecting sick leave reported that people with a range of health conditions (musculoskeletal, mental health, cardiovascular and other) who had lower recovery expectations were less likely to resolve their claim or return to work (Ebrahim 2015).

Authors' conclusions

Implications for practice

Expectations are patient‐focused, supported by relevant theoretical literature and are potentially modifiable (Iles 2011), providing opportunity for relevant clinical messages and research directions. Our systematic review and meta‐analysis found moderate‐quality evidence that individual recovery expectations are probably strongly associated (after adjustment) with future work participation outcomes, adding prognostic value. Expectations may be associated with clinically important recovery outcomes (low‐quality evidence). The association of recovery expectations with other outcomes of interest is less certain.

Implications for research

Future studies are needed to comprehensively assess psychometric properties of measures of expectations, including comparing reliability and validity of simple single‐item measures with multi‐item scales, and to examine the impact of including recovery expectations information in clinical management. Prediction models and tools may be further improved for low back pain subgrouping and treatment matching with inclusion. Future studies may include testing the interaction effect between expectations and low back pain outcomes with specific types of treatments. Finally, there is a belief among many back pain stakeholders that expectations are potentially modifiable (Guzman 2007); evidence from our review provides support for further investigation of the effectiveness of new interventions to modify expectations as a mechanism to potentially improve low back pain patient outcomes, particularly for work participation outcomes.

Acknowledgements

The authors thank Leah Boulos (Maritime SPOR SUPPORT Unit) and Rachel Couban (formerly with the Cochrane Back Review Group) for their assistance with the search strategies; we thank Andrea Smith, Michelle Tougas, and Jenny Cartwright (formerly with the Department of Community Health & Epidemiology, Dalhousie University) for contributions to early review planning, study screening and data extraction; we thank Emma Wilson‐Pease for her assistance with study screening and data extraction; and we appreciate Jenna Ellis's assistance with summary forest plots.

We thank the Cochrane Back and Neck, and Cochrane Prognosis Methods Group peer reviewers and editors for their comments and helpful suggestions, including: Chris Maher, Professor, University of Sydney and Director, Institute for Musculoskeletal Health, Sydney; Tim Carey MD MPH University of North Carolina at Chapel Hill; Dr Marialena Trivella, Centre for Statistics in Medicine, University of Oxford; and Janet Gunderson.

Appendices

Appendix 1. Search strategies for focused search using population (‘back pain’), exposure (‘expectations’), and study design (‘prognosis’) terms

Searches developed by Rachel Couban, Trials Search Coordinator, Cochrane Back Review Group; revised and executed by Leah Boulos, Evidence Synthesis Coordinator, Maritime SPOR SUPPORT Unit

Database: MEDLINE (Ovid)

1. dorsalgia.ti,ab.

2. exp Back Pain/

3. back pain.ti,ab.

4. backache.ti,ab.

5. back ache.ti,ab.

6. lumb* pain.ti,ab.

7. coccyx.ti,ab.

8. coccydynia.ti,ab.

9. sciatica.ti,ab.

10. exp sciatic neuropathy/

11. sciatic neuropathy.ti,ab.

12. spondylosis.ti,ab.

13. lumbago.ti,ab.

14. back disorder*.ti,ab.

15. back injur*.ti,ab.

16. 1 or 2 or 3 or 4 or 5 or 6 or 7 or 8 or 9 or 10 or 11 or 12 or 13 or 14 or 15

17. expectancy.tw.

18. expectation*.tw.

19. exp Attitude to Health/

20. Health Knowledge, Attitudes, Practice/

21. self efficacy/

22. self efficacy.tw.

23. illness belief*.tw.

24. ((disab* or self* or injur*) adj3 percept*).tw.

25. (outcome adj3 expect*).tw.

26. (questionnaire* adj3 (belief* or hope* or perceive* or expect* or desire* or percept* or likelihood or likely or anticipat* or want* or certainty or self‐efficacy)).tw.

27. (recovery* adj3 (belief* or hope* or perceive* or expect* or desire* or percept* or likelehood or likely or anticipat* or want* or certainty or self‐efficacy)).tw.

28. (measure* adj3 (belief* or hope* or perceive* or expect* or desire* or percept* or likelihood or likely or anticipat* or want* or certainty or self‐efficacy)).tw.

29. 17 or 18 or 19 or 20 or 21 or 22 or 23 or 24 or 25 or 26 or 27 or 28

30. Cohort Studies/

31. incidence.tw.

32. Mortality/

33. Follow‐Up Studies/

34. prognos*.tw.

35. predict*.tw.

36. course.tw.

37. Survival Analysis/

38. 30 or 32 or 33 or 34 or 35 or 36 or 37 or 37

39. 16 and 29 and 38

Database: Embase (Embase.com)

1. dorsalgia:ti,ab

2. 'backache'/exp

3. 'back pain':ti,ab

4. backache:ti,ab

5. 'back ache':ti,ab

6. lumb* pain':ti,ab

7. coccyx:ti,ab

8. coccydynia:ti,ab

9. sciatica:ti,ab

10. 'sciatic neuropathy'/exp

11. 'sciatic neuropathy':ti,ab

12. spondylosis:ti,ab

13. lumbago:ti,ab

14. 'back disorder*':ti,ab

15. 'back injur*':ti,ab

16. #1 OR #2 OR #3 OR #4 OR #5 OR #6 OR #7 OR #8 OR #9 OR #10 OR #11 OR #12 OR #13 OR #14 OR #15

17. 'expectancy'/exp

18. expectancy

19. expectation*

20. 'attitude to health'/exp

21. 'attitude to disability'/exp

22. 'attitude to illness'/exp

23. 'self concept'/exp

24. 'self efficacy'

25. 'health belief'/exp

26. 'illness belief*'

27. (disab* OR self* OR injur*) NEAR/3 percept*

28. outcome NEAR/3 expect*

29. questionnaire* NEAR/3 (belief* OR hope* OR perceive* OR expect* OR desire* OR percept* OR likelihood OR likely OR anticipat* OR want* OR certainty OR 'self‐efficacy')

30. recovery* NEAR/3 (belief* OR hope* OR perceive* OR expect* OR desire* OR percept* OR likelihood OR likely OR anticipat* OR want* OR certainty OR 'self‐efficacy')

31. measure* NEAR/3 (belief* OR hope* OR perceive* OR expect* OR desire* OR percept* OR likelihood OR likely OR anticipat* OR want* OR certainty OR 'self‐efficacy')

32. #17 OR #18 OR #19 OR #20 OR #21 OR #22 OR #23 OR #24 OR #25 OR #26 OR #27 OR #28 OR #29 OR #30 OR #31

33. cohort analysis'/de

34. 'incidence'/de

35. 'mortality'/de

36. follow up'/de

37. 'survival'/de

38. 'prognosis'/de

39. prediction'/de

40. 'disease course'/de

41. #33 OR #34 OR #35 OR #36 OR #37 OR #38 OR #39 OR #40

42. #16 AND #32 AND #41

Database: CINAHL (with Full Text ‐ EBSCOhost)

1. dorsalgia

2. (MH "Back Pain+")

3. back pain

4. backache

5. back ache

6. lumb* W1 pain

7. lumb* N5 pain

8. (MH "Coccyx")

9. (MH "Sciatica")

10. sciatica

11. coccyx

12. coccydynia

13. (MH "Lumbar Vertebrae")

14. lumb* N2 vertebra

15. (MH "Thoracic Vertebrae")

16. (MH "Spondylolisthesis") OR (MH "Spondylolysis")

17. lumbago

18. S1 OR S2 OR S3 OR S4 OR S5 OR S6 OR S7 OR S8 OR S9 OR S10 OR S11 OR S12 OR S13 OR S14 OR S15 OR S16 OR S17

19. expectancy

20. expectation*

21. (MH "Attitude to Health")

22. (MH "Health Beliefs")

23. (MH "Health Knowledge")

24. (MH "Self‐Efficacy")

25. self efficacy

26. (MH "Attitude to Illness")

27. self perception

28. (MH "Self Concept")

29. S19 OR S20 OR S21 OR S22 OR S23 OR S24 OR S25 OR S26 OR S27 OR S28

30. "questionaire" OR (MH "Questionnaires+")

31. measurement

32. (MH "Recovery") OR "recovery"

33. S30 OR S31 OR S32

34. belief*

35. (MH "Hope") OR "hope"

36. desire*

37. likely

38. likelihood

39. (MH "Perception") OR "perception"

40. want*

41. anticipat*

42. certainty

43. S34 OR S35 OR S36 OR S37 OR S38 OR S39 OR S40 OR S41 OR S42

44. S33 AND S43

45. S29 OR S44

46. (MH "Prospective Studies+")

47. (MH "Incidence")

48. (MH "Mortality")

49. follow up stud*

50. prognos*

51. predict*

52. (MH "Prognosis")

53. course

54. S46 OR S47 OR S48 OR S49 OR S50 OR S51 OR S52 OR S53

55. S18 AND S45 AND S54

Database: PsycINFO (EBSCOhost)

1. DE "Back Pain"

2. DE "Lumbar Spinal Cord"

3. back pain

4. DE "Spinal Column"

5. lumb* N2 vertebra*

6. coccyx

7. sciatica

8. lumbago

9. dorsalgia

10. back disorder*

11. DE "Back (Anatomy)"

12. (disc OR disk) N1 degenerat*

13. (disc OR disk) N1 herniat*

14. (disc OR disk) N1 prolapse*

15. failed back

16. S1 OR S2 OR S3 OR S4 OR S5 OR S6 OR S7 OR S8 OR S9 OR S10 OR S11 OR S12 OR S13 OR S14 OR S15

17. expectancy

18. expectation*

19. DE "Expectations"

20. DE "Health Attitudes"

21. DE "Health Knowledge"

22. DE "Health Behavior"

23. DE "Health Literacy"

24. DE "Self‐Efficacy"

25. self efficacy

26. DE "Illness Behavior"

27. illness beliefs

28. (disab* OR self* OR injur*) N3 percept*

29. outcome* N3 expect*

30. questionnaire* N3 (belief* or hope* or perceive* or expect* or desire* or percept* or likelihood or likely or anticipat* or want* or certainty or self‐efficacy)

31. recovery* N3 (belief* or hope* or perceive* or expect* or desire* or percept* or likelihood or likely or anticipat* or want* or certainty or self‐efficacy)

32. measure* N3 (belief* or hope* or perceive* or expect* or desire* or percept* or likelihood or likely or anticipat* or want* or certainty or self‐efficacy)

33. S17 OR S18 OR S19 OR S20 OR S21 OR S22 OR S23 OR S24 OR S25 OR S26 OR S27 OR S28 OR S29 OR S30 OR S31 OR S32

34. DE "Cohort Analysis"

35. incidence

36. DE "Mortality Rate"

37. DE "Morbidity"

38. DE "Followup Studies"

39. prognos*

40. predict*

41. course

42. DE "Prognosis"

43. survival analysis

44. S34 OR S35 OR S36 OR S37 OR S38 OR S39 OR S40 OR S41 OR S42 OR S43

45. S16 AND S33 AND S44

Appendix 2. MEDLINE and Embase search strategies for broad search using population (‘back pain’), and study design (‘prognosis’) terms (limiting potential reporting bias)

Screen of citations took advantage of existing work (searches to 2003 (Hayden 2007)) resulting in required screen load in this project of approximately 3500 citations. Searches developed by Rachel Couban, Trials Search Coordinator, Cochrane Back Review Group.

Database: MEDLINE (Ovid)

1 dorsalgia.ti,ab.

2 exp Back Pain/

3 backache.ti,ab.

4 exp Low Back Pain/

5 (lumbar adj pain).ti,ab.

6 coccyx.ti,ab.

7 coccydynia.ti,ab.

8 sciatica.ti,ab.

9 sciatic neuropathy/

10 spondylosis.ti,ab.

11 lumbago.ti,ab.

12 back disorder$.ti,ab.

13 or/1‐12

14 Cohort Studies/

15 incidence.tw.

16 Mortality/

17 Follow‐Up Studies/

18 prognos$.tw.

19 predict$.tw.

20 course.tw.

21 Survival Analysis/

22 or/14‐21

23 13 and 22

Database: Embase

1 dorsalgia.mp.

2 back pain.mp.

3 exp LOW BACK PAIN/

4 exp BACKACHE/

5 (lumbar adj pain).mp.

6 coccyx.mp.

7 coccydynia.mp.

8 sciatica.mp.

9 exp ISCHIALGIA/

10 spondylosis.mp.

11 lumbago.mp.

12 back disorder$.ti,ab.

13 or/1‐12

14 cohort analysis/

15 incidence/

16 mortality/

17 follow up/

18 survival/

19 prognosis/

20 prediction/

21 disease course/

22 or/14‐21

23 13 and 22

Appendix 3. Modified QUIPS tool

Below we present a version of the QUIPS tool modified for this prognostic factor review. An electronic (MS Access) version of the full generic QUIPS tool is available at www.annals.org.

Summary: QUIPS identifies issues to consider for judging the overall risk of bias for a study. These issues will guide your thinking and judgement about the risk of bias within each of six domains. Some 'issues' may not be relevant to the specific study or the review research question. These issues are taken together to inform the overall judgement of potential bias for each of the six domains. Provide comments or text excerpts in the boxes below, as necessary, to facilitate the consensus process that will follow. Rate the adequacy of reporting for each applicable item as yes, partial, no or unsure, then (at the bottom of the page) rate potential risk of bias for each of the six domains as High, Moderate, or Low, considering all relevant issues.

BIAS: STUDY PARTICIPATION

Goal: To judge the risk of selection bias (likelihood that relationship between PF and outcome is different for participants and eligible non‐participants).

Issues to consider for judging overall rating of risk of bias Study methods and comments Rating of reporting
Source of target population The source population or population of interest is adequately described, including who the target population is (e.g. is the desired target population all workers? individuals filing compensation claims?), when (time period of study), where (location), and how (description of recruitment strategy).
 Comprehensive description would include characteristics of: individual (e.g. age, sex, depression), back pain (history of LBP, current functioning), work (type and characteristics of work environment), treatment (type and extent of care received) and social context (compensation status).    
Method used to identify population The sampling frame and recruitment (e.g. newspaper advertisement, presentation to a health clinic, or captured from a claims database) are adequately described, including methods to identify the sample sufficient to limit potential bias (number and types used, e.g. referral patterns in health care).    
Recruitment period Period of recruitment is adequately described.    
Place of recruitment Place of recruitment (setting and geographic location) are adequately described.    
Inclusion and exclusion criteria Inclusion and exclusion criteria are adequately described and should define a discreet group with LBP (e.g. the study may include physician diagnosis or explicit diagnostic codes).    
Adequate study participation There is adequate participation in the study by eligible individuals.    
Baseline characteristics The baseline study sample (i.e. individuals entering the study) is adequately described. Comprehensive description would include characteristics of: individual (e.g. age, sex, depression), back pain condition (history of LBP, current functioning), work (type and characteristics of work environment), treatment (type and extent of care received) and social context (compensation status).    

Summary study participation:

The study sample represents the population of interest on key characteristics, sufficient to limit potential bias of the observed relationship between PF and outcome.

Low risk of bias

Moderate risk of bias

High risk of bias

BIAS: STUDY ATTRITION

Goal: To judge the risk of attrition bias (likelihood that relationship between PF and outcome are different for completing and non‐completing participants).

Issues to consider for judging overall rating of risk of bias Study methods and comments Rating of reporting
Proportion of baseline sample available for analysis Response rate (i.e. proportion of study sample completing the study and providing outcome data) is adequate.    
Attempts to collect information on participants who dropped out Attempts to collect information on participants who dropped out of the study are described.    
Reasons and potential impact of subjects lost to follow‐up Reasons for loss to follow‐up are provided.    
Outcome and prognostic factor information on those lost to follow‐up Participants lost to follow‐up are adequately described for characteristics of: individual (e.g. age, sex, depression), back pain condition (history of LBP, current functioning), work (type and characteristics of work environment), treatment (type and extent of care received) and social context (compensation status).    

Summary study attrition:

Loss to follow‐up (from baseline sample to study population analysed) is not associated with key characteristics (i.e. the study data adequately represent the sample) sufficient to limit potential bias to the observed relationship between individual recovery expectations and LBP outcome.

Low risk of bias

Moderate risk of bias

High risk of bias

BIAS: PROGNOSTIC FACTOR (PF) MEASUREMENT

Goal: To judge the risk of measurement bias related to how individual recovery expectations were measured (differential measurement of the prognostic factor related to the level of outcome).

Issues to consider for judging overall rating of risk of bias Study methods and comments Rating of reporting
Definition of the PF A clear definition or description of individual recovery expectations is provided, capturing individual participant cognition (e.g. beliefs, perceptions, anticipations, expectations) and related to a future outcome. The description allows differentiation of general recovery expectations, treatment outcome expectations, and self‐efficacy expectations.    
Valid and reliable measurement of PF Method of 'individual recovery expectations' measurement is adequately valid and reliable to limit misclassification bias (e.g. may include relevant outside sources of information on measurement properties, also characteristics, such as limited reliance on recall).
 Examples of reliable and valid measurement of recovery expectations include the Revised Illness Perception Questionnaire to address recovery expectations (Timeline acute/chronic subscale) and treatment expectations (Treatment control subscale); and the Credibility/Expectancy Questionnaire.    
Continuous variables are reported or appropriate cut‐points (i.e. not data‐dependent) are used.    
Method and setting of PF measurement The method and setting of measurement of individual recovery expectations is the same for all study participants.    
Proportion of data on PF available for analysis Adequate proportion of the study sample has complete data for the 'individual recovery expectations' variable.    
Method used for missing data Appropriate methods of imputation are used for missing individual recovery expectations data.    

Summary prognostic factor measurement:

Individual recovery expectations are adequately measured in study participants to sufficiently limit potential bias.

Low risk of bias

Moderate risk of bias

High risk of bias

BIAS: OUTCOME MEASUREMENT

Goal: To judge the risk of bias related to the measurement of LBP outcome (differential measurement of outcome related to the baseline level of prognostic factor).

Issues to consider for judging overall rating of risk of bias Study methods and comments Rating of reporting
Definition of the outcome A clear definition of the LBP outcome is provided, including duration of follow‐up and ICF disability construct; return to work should be clearly defined if it means off work, work re‐integration, work maintenance, or advancement.    
Valid and reliable measurement of outcome The method of outcome measurement used is adequately valid and reliable to limit misclassification bias (e.g. may include relevant outside sources of information on measurement properties, also characteristics, such as blind measurement and confirmation of outcome with valid and reliable test).
 Valid and reliable LBP outcome measures include: pain intensity, measured by a visual analogue scale (VAS) or other pain scale (e.g. numeric rating scale, or McGill pain score), functional limitations, measured by a LBP‐specific scale (e.g. the Roland‐Morris Disability Questionnaire, or the Oswestry Disability Index). Administrative return to work outcomes are considered valid.    
Clear and appropriate cut‐points for continuous outcome measures (i.e. not data‐dependent) are used.    
Method and setting of outcome measurement The method and setting of outcome measurement is the same for all study participants.    

Summary outcome measurement:

LBP disability outcome is adequately measured in study participants to sufficiently limit potential bias.

Low risk of bias

Moderate risk of bias

High risk of bias

BIAS: STUDY CONFOUNDING

Goal: To judge the risk of bias due to confounding (i.e. the effect of PF is distorted by another factor that is related to PF and outcome).

Issues to consider for judging overall rating of risk of bias Study methods and comments Rating of reporting
Important confounders measured All important potential confounders are measured, including a reasonably comprehensive set of factors representing our domains of interest: individual demographics (e.g. age, sex, gender), social support (e.g., marital status, socioeconomic status), work factors and environment (e.g. occupation, physical demands, workplace culture), psychological factors (e.g. depression, anxiety, coping), and LBP complaint factors (e.g. baseline pain severity, baseline disability, duration of episode at baseline).    
Definition of the confounding factor Clear definitions of the important confounders measured are provided (e.g. including dose, level, and duration of exposures).    
Valid and reliable measurement of confounders Measurement of all important confounders is adequately valid and reliable (e.g. may include relevant outside sources of information on measurement properties, also characteristics, such as blind measurement and limited reliance on recall).    
Method and setting of confounding measurement The method and setting of confounding measurement are the same for all study participants.    
Method used for missing data Appropriate methods are used if imputation is used for missing confounder data.    
Appropriate accounting for confounding Important potential confounders are accounted for in the study design (e.g. matching for key variables, stratification, or initial assembly of comparable groups; see variables below).    
Important potential confounders are accounted for in the analysis (i.e. appropriate adjustment). Minimal control for potential confounding in included studies will consider 1 ‐ 2 of the domains of interest. Adequate control for confounding will consider at least three of the five domains of interest. The domains of interest are: individual demographics (e.g. age, sex, gender), social support (e.g. marital status, socioeconomic status), work factors and environment (e.g. occupation, physical demands, workplace culture), psychological factors (e.g. depression, anxiety, coping), and LBP complaint factors (e.g. baseline pain severity, baseline disability, duration of episode at baseline).    

Summary study confounding:

Important potential confounders are appropriately accounted for, limiting potential bias with respect to the relationship between individual recovery expectations and LBP outcome.

Low risk of bias

Moderate risk of bias

High risk of bias

BIAS: STATISTICAL ANALYSIS and REPORTING

Goal: To judge the risk of bias related to the statistical analysis and presentation of results.

Issues to consider for judging overall rating of risk of bias Study methods and comments Rating of reporting
Presentation of analytical strategy There is sufficient presentation of data to assess the adequacy of the analysis.    
Model development strategy The strategy for model building (i.e. inclusion of variables in the statistical model) is appropriate and is based on a conceptual framework or model.    
The selected statistical model is adequate for the design of the study.    
Reporting of results There is no selective reporting of results.    

Summary statistical analysis and reporting:

The statistical analysis is appropriate for the design of the study, limiting potential for presentation of invalid or spurious results, and selective reporting is unlikely.

Low risk of bias

Moderate risk of bias

High risk of bias

Appendix 4. Description of the six domains of the QUIPS

This description is paraphrased from Hayden 2013.

Study participation

The study participation domain addresses whether the study sample is representative of the population of interest. We will consider a study as having high risk of bias if the participation rate is low, a very selective rather than consecutive sample of eligible low back pain (LBP) individuals was recruited, or the study sample has a very different demographic and LBP characteristic distribution from our population of interest. Conversely, studies with high participation of eligible and consecutively‐recruited LBP individuals who have characteristics similar to those in the source population would have low risk of bias.

Study attrition

The study attrition domain addresses whether participants completing the study (i.e. with follow‐up data) represent the baseline sample. We will consider a study to have high risk of bias if it is likely that persons who completed the study differ from those lost to follow‐up in a way that distorts the association between individual recovery expectations and LBP outcome. Conversely, studies with complete follow‐up, or evidence that participants lost to follow‐up are likely to be missing at random, will have low risk of bias.

Prognostic factor measurement

The prognostic factor measurement domain addresses adequacy of measurement of our factor of interest, individual recovery expectations toward non‐differential measurement related to LBP disability. We will rate studies that use an unreliable method to measure individual recovery expectations or use different approaches for participants with different outcomes that may result in systematic misclassification as being at high risk of bias. Conversely, we will consider a study to have low risk of bias if individual recovery expectations are measured similarly (same method and setting) for all participants and use a valid, reliable measure, such as the Illness Perceptions Questionnaire.

Outcome measurement

The outcome measurement domain addresses the adequacy of LBP disability outcome measurement toward non‐differential measurement related to recovery expectations. A study will have high risk of bias if there is likely to be differential measurement of outcome; for example, participants with negative expectations for recovery are assessed using a different approach from those with positive expectations. We will consider a study to have low risk of bias if the outcome is measured using the same method/setting for all participants and uses a valid, reliable measure (e.g. pain intensity by a visual analogue scale (VAS) or associated disability using the Roland‐Morris Disability Questionnaire (RMDQ)).

Confounding

The study confounding domain addresses potential confounding, or distortion of the relationship between recovery expectations and LBP outcomes by another factor. A study will have high risk of bias if it does not control for any variables that have the potential to confound or explain the association between individual recovery expectations and outcome. Conversely, studies with adequate measurement of important potential confounding variables and inclusion of these variables in a prespecified multivariable analysis will have low risk of bias. ‘Minimal’ control for potential confounding in included studies will consider some (one or two) of the confounding domains of interest, but do not control for a more robust set of confounders. We will judge ‘adequate’ control for confounding based on our proposed theoretical framework of the relationship between individual recovery expectations and LBP outcomes (Figure 1). This will include studies that adequately assess potential confounders, not on the proposed causal pathway, representing at least three of these domains: individual demographics (for example, age, sex, gender), social support (for example, marital status, socioeconomic status), work factors and environment (for example, occupation, physical demands, workplace culture), psychological factors (for example, depression, anxiety, coping), and LBP complaint factors (for example, baseline pain severity, baseline disability, duration of episode at baseline).

Statistical analysis and reporting

The statistical analysis and reporting domain addresses the appropriateness of the study’s statistical analysis and completeness of reporting. We will consider a study to have low risk of bias if the statistical analysis is appropriate for the study design and data, if statistical model building is based on a conceptual framework or model (rather than a data‐driven approach), and if all primary outcomes are reported.

Appendix 5. Guide to judge the quality of evidence for prognosis

Starting GRADE Phase of investigation
HIGH Phase 3 Explanatory Study: Explanatory research aimed at understanding prognostic pathways; or
Phase 2 Explanatory Study: Explanatory research aimed at confirming independent associations between potential prognostic factor and the outcome
MODERATE Phase 1 Explanatory Study: Explanatory research aimed at identifying associations between potential prognostic factors and the outcome, or Outcome prediction research providing evidence about prognostic factor associations
 
Downgrade if: Upgrade if:
Study limitations Serious limitations when most evidence is from studies with moderate or unclear risk of bias for most bias domains Moderate or large effect For meta‐analysis: pooled effect is moderate or large
Very serious limitations when most evidence is from studies with high risk of bias for almost all bias domains For narrative summary: moderate or large similar effect is reported by most studies
Inconsistency Unexplained heterogeneity or variability in results across studies with differences in results not clinically meaningful. This may be supported by:
‐ For meta‐analysis: significant heterogeneity detected by test of heterogeneity and large I2 value
‐ For narrative summary: variations in effect estimates across studies with points of effect on either side of the line of no effect, and confidence intervals showing minimal overlap
Exposure‐gradient response For meta‐analysis: gradient is present between analyses for factors measured at different doses
For narrative summary: possible gradient exists within and between primary studies.
Indirectness The study sample, the prognostic factor, and/or the outcome in the primary studies do not accurately reflect the review question  
Imprecision For meta‐analysis: (1) insufficient sample size and (2) no precise estimate of the effect size in the meta‐analysis: confidence interval is excessively wide and overlaps the value of no effect and contains values implying that the factor plays an important role in protecting or putting the individual at risk
For narrative summary: Within‐study imprecision, (1) sample size justification is not provided and there are fewer than 10 outcome events for each prognostic variable (for dichotomous outcomes) OR there are fewer than 100 cases reaching endpoint (for continuous outcomes); and (2) no precision in the estimation of the effect size within each primary study, AND
Across‐study imprecision: there are few studies and small numbers of participants across studies
Publication bias: We recommend downgrading unless the value of the risk/protective factor in predicting the outcome has been repetitively investigated, ideally by phase 2 and 3 studies    
Table modified (with permission) from Table 4, Huguet 2013

Data and analyses

Comparison 1. Are expectations associated with work participation (closest to 12 months)?

Outcome or subgroup title No. of studies No. of participants Statistical method Effect size
1 Dichotomous measure of expectations 13   Odds Ratio (Random, 95% CI) Subtotals only
1.1 Unadjusted results 10   Odds Ratio (Random, 95% CI) 4.11 [3.46, 4.89]
1.2 Adjusted results 12   Odds Ratio (Random, 95% CI) 2.43 [1.64, 3.62]
2 Continuous measure of expectations (/10) 2   Odds Ratio (Random, 95% CI) Subtotals only
2.1 Unadjusted results 2   Odds Ratio (Random, 95% CI) 1.84 [0.53, 6.37]
2.2 Adjusted results 2   Odds Ratio (Random, 95% CI) 1.14 [0.95, 1.37]

Comparison 2. Are expectations associated with important recovery (closest to 12 months)?

Outcome or subgroup title No. of studies No. of participants Statistical method Effect size
1 Dichotomous measure of expectations 6   Odds Ratio (Random, 95% CI) Subtotals only
1.1 Unadjusted results 3   Odds Ratio (Random, 95% CI) 2.40 [1.32, 4.37]
1.2 Adjusted results 5   Odds Ratio (Random, 95% CI) 1.89 [1.49, 2.41]
2 Continuous measure of expectations (/10) 4   Odds Ratio (Random, 95% CI) Subtotals only
2.1 Unadjusted results 1   Odds Ratio (Random, 95% CI) 1.13 [1.11, 1.15]
2.2 Adjusted results 4   Odds Ratio (Random, 95% CI) 1.15 [1.07, 1.24]

Comparison 3. Are expectations associated with functional limitation outcomes (closest to 12 months)?

Outcome or subgroup title No. of studies No. of participants Statistical method Effect size
1 Dichotomous measure of expectations 3   Odds Ratio (Random, 95% CI) Subtotals only
1.1 Unadjusted results 1   Odds Ratio (Random, 95% CI) 3.03 [1.14, 8.08]
1.2 Adjusted results 2   Odds Ratio (Random, 95% CI) 1.66 [0.66, 4.22]
2 Continuous measure of expectations (/10) 4   Odds Ratio (Random, 95% CI) Subtotals only
2.1 Unadjusted results 3   Odds Ratio (Random, 95% CI) 1.56 [0.72, 3.41]
2.2 Adjusted results 3   Odds Ratio (Random, 95% CI) 1.40 [0.85, 2.31]

Comparison 4. Are expectations associated with pain outcomes (closest to 12 months)?

Outcome or subgroup title No. of studies No. of participants Statistical method Effect size
1 Dichotomous measure of expectations 1   Odds Ratio (Random, 95% CI) Subtotals only
1.1 Unadjusted results 1   Odds Ratio (Random, 95% CI) 2.51 [0.81, 7.82]
1.2 Adjusted results 0   Odds Ratio (Random, 95% CI) 0.0 [0.0, 0.0]
2 Continuous measure of expectations (/10) 3   Odds Ratio (Random, 95% CI) Subtotals only
2.1 Unadjusted results 2   Odds Ratio (Random, 95% CI) 1.13 [0.48, 2.67]
2.2 Adjusted results 2   Odds Ratio (Random, 95% CI) 1.15 [1.08, 1.23]

Comparison 5. Work participation outcome (closest to 12 months); dichotomous measure of expectations (adjusted): Subgroup analyses.

Outcome or subgroup title No. of studies No. of participants Statistical method Effect size
1 Low back pain duration 12   Odds Ratio (Random, 95% CI) Subtotals only
1.1 Acute low back pain population 0   Odds Ratio (Random, 95% CI) 0.0 [0.0, 0.0]
1.2 Subacute/Chronic low back pain population 4   Odds Ratio (Random, 95% CI) 2.34 [1.61, 3.40]
1.3 Mixed/Non‐specified low back pain population 8   Odds Ratio (Random, 95% CI) 2.41 [1.48, 3.91]
2 Recovery expectation types 12   Odds Ratio (Random, 95% CI) Subtotals only
2.1 General recovery expectations 12   Odds Ratio (Random, 95% CI) 2.43 [1.64, 3.62]
3 Recovery expectation reference time periods 12   Odds Ratio (Random, 95% CI) Subtotals only
3.1 Short (1 month or less) 4   Odds Ratio (Random, 95% CI) 2.02 [1.00, 4.09]
3.2 Long (3‐6 months) 4   Odds Ratio (Random, 95% CI) 2.83 [1.36, 5.89]
3.3 No / unclear reference period 4   Odds Ratio (Random, 95% CI) 2.55 [1.53, 4.25]
4 Outcome follow‐up periods 12   Odds Ratio (Random, 95% CI) Subtotals only
4.1 Short term follow‐up (3 mo) 3   Odds Ratio (Random, 95% CI) 3.19 [1.77, 5.75]
4.2 Moderate term follow‐up (5‐8 mo; closest to 6 mo) 4   Odds Ratio (Random, 95% CI) 2.43 [1.58, 3.74]
4.3 Long term follow‐up (8‐16 mo; closest to 12 mo) 9   Odds Ratio (Random, 95% CI) 2.12 [1.41, 3.17]
4.4 Very long term follow‐up (>16 mo) 2   Odds Ratio (Random, 95% CI) 3.10 [1.87, 5.12]
5 Study phase of investigation 12   Odds Ratio (Random, 95% CI) Subtotals only
5.1 Exploratory analyses 10   Odds Ratio (Random, 95% CI) 2.41 [1.76, 3.29]
5.2 Confirmatory analyses 2   Odds Ratio (Random, 95% CI) 2.31 [0.82, 6.51]

Comparison 6. QUIPS ROB domain ratings (work participation outcome (closest to 12 months); dichotomous measure of expectations (adjusted)).

Outcome or subgroup title No. of studies No. of participants Statistical method Effect size
1 'Participation' domain 12   Odds Ratio (Random, 95% CI) Subtotals only
1.1 Studies with low ROB 6   Odds Ratio (Random, 95% CI) 2.76 [1.48, 5.17]
1.2 Studies with moderate/high ROB 6   Odds Ratio (Random, 95% CI) 2.16 [1.41, 3.31]
2 'Attrition' domain 12   Odds Ratio (Random, 95% CI) Subtotals only
2.1 Studies with low ROB 10   Odds Ratio (Random, 95% CI) 2.72 [2.05, 3.60]
2.2 Studies with moderate/high ROB 2   Odds Ratio (Random, 95% CI) 1.04 [1.02, 1.06]
3 'Prognostic factor' domain 12   Odds Ratio (Random, 95% CI) Subtotals only
3.1 Studies with low ROB 0   Odds Ratio (Random, 95% CI) 0.0 [0.0, 0.0]
3.2 Studies with moderate/high ROB 12   Odds Ratio (Random, 95% CI) 2.43 [1.64, 3.62]
4 'Outcome' domain 12   Odds Ratio (Random, 95% CI) Subtotals only
4.1 Studies with low ROB 10   Odds Ratio (Random, 95% CI) 2.41 [1.76, 3.29]
4.2 Studies with moderate/high ROB 2   Odds Ratio (Random, 95% CI) 2.31 [0.82, 6.51]
5 'Confounding' domain 12   Odds Ratio (Random, 95% CI) Subtotals only
5.1 Studies with low ROB 8   Odds Ratio (Random, 95% CI) 2.03 [1.34, 3.07]
5.2 Studies with moderate/high ROB 4   Odds Ratio (Random, 95% CI) 3.10 [2.36, 4.07]
6 'Analysis and Reporting' domain 12   Odds Ratio (Random, 95% CI) Subtotals only
6.1 Studies with low ROB 9   Odds Ratio (Random, 95% CI) 2.26 [1.46, 3.50]
6.2 Studies with moderate/high ROB 3   Odds Ratio (Random, 95% CI) 3.03 [1.91, 4.78]

Characteristics of studies

Characteristics of included studies [ordered by study ID]

Beneciuk 2017.

Population (low back pain description; location; setting; data collection period) Randomized Controlled Trial: People consulting general practice for back pain; United Kingdom; Primary care; Data collection period not reported
Sample size 851
Prognostic factor (type, measure(s) of individual recovery expectations) GENERAL: Expectations of recovery (0 ‐ 10)
Notes Funding Source: The Arthritis Research United Kingdom; West Midlands North Comprehensive Local Research Network; North Staffordshire Primary Care Research Consortium
Conflict of Interest: None declared
aStudy includes a recovery outcome based on categorisation of work, pain, and/or function outcomes

Besen 2015.

Population (low back pain description; location; setting; data collection period) Prospective cohort: Volunteers seeking treatment for work‐related, acute back pain at private occupational medicine clinics; United States of America; Occupational; Data collection period not reported
Sample size 496
Prognostic factor (type, measure(s) of individual recovery expectations) GENERAL: How soon do you expect to be able to resume your normal job without any limitations? (6 pts)
 SELF‐EFFICACY: Return‐To‐Work Self‐Efficacy Scale (19 items, 1 ‐ 10)
Notes Funding Source: Not reported
Conflict of Interest: Not reported
aStudy includes a recovery outcome based on categorisation of work, pain, and/or function outcomes

Bishop 2015.

Population (low back pain description; location; setting; data collection period) Prospective cohort: People recruited from primary care research network, acupuncturist associations, and internet searches for hospital‐based services; United Kingdom; Secondary care; November 2008 ‐ October 2010
Sample size 420
Prognostic factor (type, measure(s) of individual recovery expectations) TREATMENT: Credibility Expectancy Questionnaire (3 items, 0 – 9)
 SELF‐EFFICACY: Chronic Pain Self‐Efficacy for Pain Management subscale (0 ‐ 100)
Notes Funding Source: Arthritis Research United Kingdom
Conflict of Interest: None declared

Butler 2007.

Population (low back pain description; location; setting; data collection period) Prospective cohort: Workers who filed claims for occupational back pain (with or without leg pain or sciatica); United States of America; Occupational; January 1st 1999 ‐ June 30th 2002
Sample size 1831
Prognostic factor (type, measure(s) of individual recovery expectations) GENERAL: Expectations of recovery (5 pts)
Notes Funding Source: Not reported
Conflict of Interest: Not reported

Carriere 2015.

Population (low back pain description; location; setting; data collection period) Prospective cohort: Consecutive referrals for work‐related back pain (primary diagnosis) to primary care physical therapy clinics; Canada; Primary care; Data collection period not reported
Sample size 109
Prognostic factor (type, measure(s) of individual recovery expectations) GENERAL: Likelihood of return to work (0 ‐ 100)
Notes Funding Source: Canadian Institute for Health Research; Institut de recherche Robert‐Sauve en sante et en securite du travail
Conflict of Interest: Not reported

Casey 2008.

Population (low back pain description; location; setting; data collection period) Prospective cohort: People presenting at an acute back pain clinic; United States of America; Secondary care; Data collection period not reported
Sample size 84
Prognostic factor (type, measure(s) of individual recovery expectations) GENERAL: Pain Behaviour and Perception Inventory pain permanence subscale (4 pts)
Notes Funding Source: Not reported
Conflict of Interest: Not reported

Demmelmaier 2010.

Population (low back pain description; location; setting; data collection period) Prospective cohort: 2 back pain groups, 1 with first‐episode pain, and 1 with long‐term pain; Sweden; General population; February 2005 ‐ February 2006
Sample size 379
Prognostic factor (type, measure(s) of individual recovery expectations) GENERAL (2): Pain expectations (2 items, 7 pts); Work expectations in 6 months (0 ‐ 6)
Notes Funding Source: The Olle Engkvist Building Foundation, Sweden
Conflict of Interest: Not reported

Dionne 1997.

Population (low back pain description; location; setting; data collection period) Prospective cohort: People consulting a primary care physician for back pain; United States of America; Primary care; 1989 ‐ 1990
Sample size 1213
Prognostic factor (type, measure(s) of individual recovery expectations) GENERAL: Expectation of continued pain (5 pts)
Notes Funding Source: Agency for Health Care Policy and Research; The National Institute for Dental Research; National Health Research and Development Program of Canada
Conflict of Interest: Not reported
aStudy does not present sufficient data to be included in meta‐analyses (univariate), but does provide some measure of statistical significance

Downie 2016.

Population (low back pain description; location; setting; data collection period) Randomized Controlled Trial: People seeking primary care for an episode of acute low back pain; Australia; Primary care; Data collection period not reported
Sample size 653
Prognostic factor (type, measure(s) of individual recovery expectations) GENERAL: Risk of persistence (0 ‐ 10)
Notes Funding Source: "No specific grant from any funding agency in the public, commerical, or not‐for‐profit sectors"
Conflict of Interest: None declared
aStudy includes a recovery outcome based on categorisation of work, pain, and/or function outcomes

Du Bois 2008.

Population (low back pain description; location; setting; data collection period) Prospective cohort: Workers entitled to sickness allowance; Belgium; Occupational; Data collection period not reported
Sample size 186
Prognostic factor (type, measure(s) of individual recovery expectations) GENERAL: Return to work within 6 months (0 ‐ 10)
Notes Funding Source: Not reported
Conflict of Interest: Not reported

Enthoven 2006.

Population (low back pain description; location; setting; data collection period) Randomized Controlled Trial: People with low back pain who were eligible for sick‐leave benefits; Sweden; Primary care; Data collection period not reported
Sample size 148
Prognostic factor (type, measure(s) of individual recovery expectations) TREATMENT: Expectations of treatment (5 pt)
Notes Funding Source: Not reported
Conflict of Interest: Not reported
aStudy includes a recovery outcome based on categorisation of work, pain, and/or function outcomes

Enthoven 2016.

Population (low back pain description; location; setting; data collection period) Prospective cohort: People consulting their general practitioner with a new episode of back pain; Netherlands; Primary care; Data collection period not reported
Sample size 675
Prognostic factor (type, measure(s) of individual recovery expectations) GENERAL: Expectations of recovery in 3 months (1 ‐ 5)
Notes Funding Source: Department of General Practice, Erasmus University Medical Center, Rotterdam, Coolsingel Foundation, Rotterdam, and the Dutch Arthritis Foundation
Conflict of Interest: Not reported

Foster 2008.

Population (low back pain description; location; setting; data collection period) Prospective cohort: Consecutive patients presenting to general practices with low back pain; United Kingdom; Primary care; September 2004 ‐ April 2006
Sample size 1591
Prognostic factor (type, measure(s) of individual recovery expectations) GENERAL: Revised Illness Perceptions Questionnaire, timeline acute/chronic item (5 pts)
 SELF‐EFFICACY: Pain Self‐Efficacy Questionnaire (10 items, 6 pts)
Notes Funding Source: Arthritis Research Campaign, United Kingdom; North Staffordshire Primary Care Research Consortium
Conflict of Interest: Not reported
aStudy includes a recovery outcome based on categorisation of work, pain, and/or function outcomes

George 2010.

Population (low back pain description; location; setting; data collection period) Randomized Controlled Trial: Consecutive patients seeking treatment for low back pain at university health clinics; United States of America; Primary care; Data collection period not reported
Sample size 105
Prognostic factor (type, measure(s) of individual recovery expectations) GENERAL: Expectations of recovery (1 ‐ 5)
Notes Funding Source: National Institutes of Health‐National Institute of Arthritis and Musculoskeletal and Skin Diseases Grant
Conflict of Interest: None declared

Gervais 1991.

Population (low back pain description; location; setting; data collection period) Prospective cohort: Male workers receiving workers' compensation reporting pain from thoracic (T9) to sacrum (S1) spine level; Canada; Occupational; Data collection period not reported
Sample size 135
Prognostic factor (type, measure(s) of individual recovery expectations) SELF‐EFFICACY: Self‐Efficacy and Results Expectancies Inventory (unclear scale)
Notes Funding Source: Comité d’attribution de fonds internes de recherche Research Fund of the University of Montreal
Conflict of Interest: Not reported

Glattacker 2013.

Population (low back pain description; location; setting; data collection period) Randomized Controlled Trial (control group only): People with chronic low back pain recruited from orthopedic rehabilitation centres; Germany; Secondary care; December 2008 ‐ April 2010
Sample size 105
Prognostic factor (type, measure(s) of individual recovery expectations) GENERAL: Revised Illness Perceptions Questionnaire, timeline acute/chronic item (5 pts)
Notes Funding Source: German Pension Insurance
Conflict of Interest: Not reported

Goldstein 2002.

Population (low back pain description; location; setting; data collection period) Randomized Controlled Trial: People who sought care for low back pain from their health maintenance organization provider; United States of America; Primary care; October 30th 1995 ‐ November 9th 1998
Sample size 681
Prognostic factor (type, measure(s) of individual recovery expectations) TREATMENT: Treatment confidence, Numeric Rating Scale (0 ‐ 10)
Notes Funding Source: Not reported
Conflict of Interest: Not reported

Gross 2010.

Population (low back pain description; location; setting; data collection period) Prospective cohort: Workers’ compensation claimants with back pain seen at a rehabilitation facility for return to work assessment; Canada; Secondary care; April 1st 2001 ‐ March 31st 2002
Sample size 298
Prognostic factor (type, measure(s) of individual recovery expectations) GENERAL: Work‐Related Recovery Expectations Questionnaire (3 items, 5 pts)
Notes Funding Source: Workers' Compensation Board of British Columbia; Workers' Compensation Board of Alberta
Conflict of Interest: Not reported

Grotle 2006.

Population (low back pain description; location; setting; data collection period) Prospective cohort: 2 samples, 1 with acute first‐time low back pain contacting primary health care, 1 with chronic low back pain recruited from a specialist back clinic; Norway; Mixed population; Data collection period not reported
Sample size 173
Prognostic factor (type, measure(s) of individual recovery expectations) GENERAL (2): Risk of persistent pain (0 ‐ 10), and Certainty of working in 6 months (0 ‐ 10)
Notes Funding Source: Not reported
Conflict of Interest: Not reported

Haas 2014.

Population (low back pain description; location; setting; data collection period) Randomized Controlled Trial: People with chronic low back pain recruited from general population; United States of America; General population; March 2007 ‐ May 2010
Sample size 391
Prognostic factor (type, measure(s) of individual recovery expectations) TREATMENT: Confidence in treatment (2 items, 6 pts)
Notes Funding Source: The National Center for Complementary and Alternative Medicine; National Institutes of Health
Conflict of Interest: None declared
aStudy does not present sufficient data to be included in meta‐analyses (univariate), but does provide some measure of statistical significance

Hagen 2005.

Population (low back pain description; location; setting; data collection period) Randomized Controlled Trial: People sick‐listed 8 to 12 weeks for low back pain (with or without radiating pain); Norway; Primary care; Data collection period not reported
Sample size 457
Prognostic factor (type, measure(s) of individual recovery expectations) GENERAL: Belief that back pain will disappear from Graded Reduced Work Ability Scale (1 ‐ 6)
Notes Funding Source: Norwegian Ministry of Health and Social Affairs
Conflict of Interest: Not reported

Haldorsen 1998.

Population (low back pain description; location; setting; data collection period) Randomized Controlled Trial: People who were employed and on sick leave for low back pain; Norway; Occupational; Data collection period not reported
Sample size 223
Prognostic factor (type, measure(s) of individual recovery expectations) GENERAL (2): Do you believe that you will be back to work after a couple of weeks? (5 pts), and Do you believe your complaints will be less during the first couple of weeks? (5 pts)
SELF‐EFFICACY: If you continue working, what effect will that have on your complaints? (5 pt)
Notes Funding Source: The Royal Norwegian Department of Health and Social Affairs
Conflict of Interest: None declared

Harkapaa 1996.

Population (low back pain description; location; setting; data collection period) Prospective cohort: People with chronic or recurrent low back pain referred to rehabilitation and receiving disability payments; Finland; Secondary care; Data collection period not reported
Sample size 175
Prognostic factor (type, measure(s) of individual recovery expectations) GENERAL: Health Optimism Index (5 ‐ 20)
Notes Funding Source: Not reported
Conflict of Interest: Not reported
aStudy includes a recovery outcome based on categorisation of work, pain, and/or function outcomes

Hazard 1996.

Population (low back pain description; location; setting; data collection period) Prospective cohort: Workers reporting occupational low back injury to the Department of Labor and Industry within 11 days of onset; United States of America; Occupational; September 1993 ‐ June 1994
Sample size 166
Prognostic factor (type, measure(s) of individual recovery expectations) GENERAL: Certainty of working in 6 months (0 ‐ 10)
Notes Funding Source: National Institute on Disability and Rehabilitation Research, United States Department of Education
Conflict of Interest: Not reported

Henschke 2008.

Population (low back pain description; location; setting; data collection period) Randomized Controlled Trial: Consecutive patients with non‐specific low back pain < 2 weeks duration recruited from the clinics of general practitioners, physiotherapists, and chiropractors; Australia; Primary care; November 2003 ‐ July 2005
Sample size 969
Prognostic factor (type, measure(s) of individual recovery expectations) GENERAL: Perceived risk of persistence (0 ‐ 10)
Notes Funding Source: National Health and Medical Research Council
Conflict of Interest: None declared
aStudy includes a recovery outcome based on categorisation of work, pain, and/or function outcomes

Heymans 2006.

Population (low back pain description; location; setting; data collection period) Randomized Controlled Trial: People who visited their occupational physician on sick leave for < 8 weeks; Netherlands; Occupational; October 2000 ‐ November 2002
Sample size 299
Prognostic factor (type, measure(s) of individual recovery expectations) GENERAL (2): When do you think you will be able to work fulltime again? (8 pts), and How certain are you about full work resumption at 6 months (5 pts); TREATMENT: Expected benefit from treatment (0 ‐ 10)
Notes Funding Source: The Netherlands Organization for Health Research and Development; Dutch Minisitry of Health, Welfare and Sport; Dutch Ministry of Social Affairs and Employment
Conflict of Interest: Not reported

Hildebrandt 1997.

Population (low back pain description; location; setting; data collection period) Prospective cohort: People recruited from a pain clinic with chronic back pain and at least 3 months of disability leave during the last year; Germany; Secondary care; Data collection period not reported
Sample size 90
Prognostic factor (type, measure(s) of individual recovery expectations) GENERAL: Expectation of ability to return to work after discharge from treatment (unclear scale)
Notes Funding Source: The Germany Ministry of Education, Research, and Technology
Conflict of Interest: Not reported

Jellema 2002.

Population (low back pain description; location; setting; data collection period) Prospective cohort: Employees of a home care organisation with current low back pain or ≥ 2 episodes in past year; Netherlands; Occupational; Data collection period not reported
Sample size 59
Prognostic factor (type, measure(s) of individual recovery expectations) TREATMENT (2): Confidence in reduction in pain by lumbar support (0 ‐ 10), and Confidence in improvement in function by lumbar support (0 ‐ 10)
Notes Funding Source: The Netherlands Organization for Health Research and Development
Conflict of Interest: Not reported

Jensen 2000.

Population (low back pain description; location; setting; data collection period) Randomized Controlled Trial and Prospective cohort: Employees of a homecare organisation with low back pain; Sweden; Secondary care; August 1995 ‐ September 1998
Sample size 235
Prognostic factor (type, measure(s) of individual recovery expectations) TREATMENT: Belief that there is a treatment that could relieve condition (unclear scale)
SELF‐EFFICACY: Belief in ability for learning to cope with the pain (unclear scale)
Notes Funding Source: AMF Insurance; SPP Insurance
Conflict of Interest: Not reported

Jensen 2013.

Population (low back pain description; location; setting; data collection period) Randomized Controlled Trial: People sick‐listed for low back pain (with or without radiculopathy); Denmark; Secondary care; 2004 ‐ 2009
Sample size 325
Prognostic factor (type, measure(s) of individual recovery expectations) GENERAL: Expectations about return to work within 6 months (10 pts)
Notes Funding Source: Municipality of Silkeborg; Municipality of Favrskov; Municipality of Skanderborg; Municipality of Denmark; The Central Denmark Region; The Danisk Working Environment Research Fund
Conflict of Interest: None declared

Karjalainen 2003.

Population (low back pain description; location; setting; data collection period) Randomized Controlled Trial: People with disabling low back pain for the preceding 4 to 12 weeks; Finland; Primary care; Data collection period not reported
Sample size 164
Prognostic factor (type, measure(s) of individual recovery expectations) GENERAL: Perceived risk of not recovering (0 – 10)
TREATMENT: Expectations about the effectiveness of treatment (0 – 10)
Notes Funding Source: Not reported
Conflict of Interest: Not reported
aStudy does not present sufficient data to be included in meta‐analyses (univariate), but does provide some measure of statistical significance

Kongsted 2014.

Population (low back pain description; location; setting; data collection period) Prospective cohort: People with low back pain consulting clinics in a research network; Denmark; Secondary care; September 2010 ‐ January 2012
Sample size 928a
Prognostic factor (type, measure(s) of individual recovery expectations) GENERAL: Likelihood of recovery (0 ‐ 10)
Notes Funding Source: Danish Chiropractors’ Foundation and Macroeconomic Policy Institute Almene Fond grant
Conflict of Interest: None declared
aKongsted 2014 was presented together, and separately as Kongsted 2014a (general practice cohort), and Kongsted 2014b (chiropractic practice cohort)

Leboeuf‐Yde 2004.

Population (low back pain description; location; setting; data collection period) Prospective cohort: Chiropractic patients who had recurrent low back pain with no chiropractic treatment in past 6 months ; Norway; Secondary care; Data collection period not reported
Sample size 843
Prognostic factor (type, measure(s) of individual recovery expectations) GENERAL (3): Will you be on sick leave in 6 weeks? (Yes/No/Don't know), Will you receive disability pension? (Yes/No/Don't know), and How will your low back pain be in 6 weeks? (5‐pt scale)
TREATMENT: Will chiropractic treatment help? (Yes/No/Don't know)
Notes Funding Source: Research Council of Norway; the Swedish Chiropractic Association
Conflict of Interest: Not reported

Lindell 2010.

Population (low back pain description; location; setting; data collection period) Randomized Controlled Trial: Primary care patients with non‐acute non‐specific spinal pain; Sweden; Primary care; August 2000 ‐ January 2004
Sample size 125
Prognostic factor (type, measure(s) of individual recovery expectations) GENERAL: Self‐prediction of probability of return to work at some time in the future (5 pts)
Notes Funding Source: Stockholm County Social Insurance Agency; Stockholm County Council; Swedish Ministry of Health and Social Affairs; Vardal Foundation; Cardionics; Pharmacia; Grunenthal Sweden
Conflict of Interest: None declared

Macedo 2014.

Population (low back pain description; location; setting; data collection period) Randomized Controlled Trial: People from physical therapy clinics with chronic low back pain, assessed to be capable of physical exercise; Australia; Primary care; October 2007 ‐ November 2009
Sample size 172
Prognostic factor (type, measure(s) of individual recovery expectations) SELF‐EFFICACY: Pain Self‐Efficacy Questionnaire (0 ‐ 100)
Notes Funding Source: Australia's National Health and Medical Research Council
Conflict of Interest: None declared

Magnussen 2007.

Population (low back pain description; location; setting; data collection period) Randomized Controlled Trial: Individuals receiving disability pension due to back pain for more than 1 year; Norway; Occupational; April 2004 ‐ August 2005
Sample size 431
Prognostic factor (type, measure(s) of individual recovery expectations) GENERAL: Do you believe you will ever be able to return to work? (Yes/No/Don't know)
Notes Funding Source: The Norwegian Foundation for Health and Rehabilitation
Conflict of Interest: Not reported

Michaelson 2004.

Population (low back pain description; location; setting; data collection period) Prospective cohort: People with chronic low back or neck pain referred to inpatient rehabilitation centre; Sweden; Secondary care; August 1997 ‐ November 1999
Sample size 167
Prognostic factor (type, measure(s) of individual recovery expectations) SELF‐EFFICACY: Optimism Index (10 items)
Notes Funding Source: VINNOVA; EG mal 1 Sapmi
Conflict of Interest: Not reported
aStudy includes a recovery outcome based on categorisation of work, pain, and/or function outcomes
bStudy does not present sufficient data to be included in meta‐analyses (multivariate), but does provide some measure of statistical significance

Morlock 2002.

Population (low back pain description; location; setting; data collection period) Prospective cohort: People in the physical therapy department of a multispecialty group practice; United States of America; Secondary care; Janaury 1999 ‐ June 1999
Sample size 111
Prognostic factor (type, measure(s) of individual recovery expectations) TREATMENT: Treatment expectations scale (5 items, 5 pts)
Notes Funding Source: Health Alliance Plan of Michigan
Conflict of Interest: Not reported

Myers 2007.

Population (low back pain description; location; setting; data collection period) Randomized Controlled Trial: Patients presenting for initial evaluation of low back pain and scored greater than 3 on a 0 – 10 pain scale; United States of America; Primary care; Data collection period not reported
Sample size 442
Prognostic factor (type, measure(s) of individual recovery expectations) GENERAL: how much improvement do you expect in 6 weeks (0 ‐ 10)
TREATMENT: How helpful do you think the specified CAM therapy would be for your current episode of back pain or sciatica? (0 ‐ 10)
Notes Funding Source: National Center for Complementary and Alternative Medicine; Bernard Osher Foundation; American Specialty Health
Conflict of Interest: None declared

Niemisto 2004.

Population (low back pain description; location; setting; data collection period) Randomized Controlled Trial: Employed people with low back pain (with or without sciatica) of at least 3 months’ duration with a score of > 16% on the Oswestry Disability Index; Finland; General; Data collection period not reported
Sample size 204
Prognostic factor (type, measure(s) of individual recovery expectations) GENERAL: Self‐rated prognosis for ability to work after 2 years (1 ‐ 7)
Notes Funding Source: Not reported
Conflict of Interest: Not reported
aStudy includes a recovery outcome based on categorisation of work, pain, and/or function outcomes

Opsahl 2016.

Population (low back pain description; location; setting; data collection period) Randomized Controlled Trial: Employees with long‐lasting low back pain recruited from 4 clinics; Norway; Occupational; Data collection period not reported
Sample size 286 (women); 283 (men)a
Prognostic factor (type, measure(s) of individual recovery expectations) GENERAL: To what extent do you think you will return to work? (4 pts)
Notes Funding Source: The Research Council of Norway
Conflict of Interest: None declared
aOpsahl 2016a (women) and Opsahl 2016b (men) are same study, presented separately

Opsommer 2017.

Population (low back pain description; location; setting; data collection period) Prospective cohort: People with chronic low back pain admitted to a rehabilitation centre; Switzerland; Primary care; February 2011 ‐ October 2013
Sample size 98
Prognostic factor (type, measure(s) of individual recovery expectations) GENERAL (2): In your view, how large is the risk that your current pain may become persistent? (0 ‐ 10), and In your estimation, what are the chances that you will be able to work in six months? (0 ‐ 10)
Notes Funding Source: The Swiss National Science Foundation; HES‐SO
Conflict of Interest: None declared

Petersen 2007.

Population (low back pain description; location; setting; data collection period) Randomized Controlled Trial: People referred to an outpatient rheumatology clinic for low back pain; Denmark; Secondary care; August 1996 ‐ December 1998
Sample size 260
Prognostic factor (type, measure(s) of individual recovery expectations) GENERAL: Certainty of working 6 months after treatment (11 pts)
SELF‐EFFICACY: Expecting problems coping with future tasks (11 pts)
Notes Funding Source: The Danish Physiotherapy Organization; Madsens Fund; The Danish Rheumatism Association
Conflict of Interest: None declared
aStudy includes a recovery outcome based on categorisation of work, pain, and/or function outcomes

Rasmussen‐Barr 2012.

Population (low back pain description; location; setting; data collection period) Randomized Controlled Trial: People with recurrent low back pain seeking care at a primary healthcare setting; Sweden; Primary care; Data collection period not reported
Sample size 71
Prognostic factor (type, measure(s) of individual recovery expectations) TREATMENT: Expectation of treatment (unclear scale)
Notes Funding Source: Capio Research Foundation
Conflict of Interest: None declared
aStudy includes a recovery outcome based on categorisation of work, pain, and/or function outcomes

Reeser 2001.

Population (low back pain description; location; setting; data collection period) Prospective cohort: People with acute low back pain from primary and tertiary care sites; United States of America; Mixed population; March 1999 ‐ March 2000
Sample size 128
Prognostic factor (type, measure(s) of individual recovery expectations) TREATMENT: Expectations of treatment (5 items, 5 pts)
Notes Funding Source: State Medical Society of Wisconsin Foundation; Pfizer, Inc.; Mercury Marine; Roche Pharmaceuticals; Deere & Company (Horicon); Monsanto Fund; Quad Graphics; Pharmacia
Conflict of Interest: Not reported

Reiso 2003.

Population (low back pain description; location; setting; data collection period) Prospective cohort: People with back disorders that primary healthcare doctors thought would certify them as sick for > 2 months; Norway; Primary care; September 1997 ‐ December 1998
Sample size 190
Prognostic factor (type, measure(s) of individual recovery expectations) GENERAL: Self‐predicted work status in 4 weeks (3 pts)
Notes Funding Source: The Norweigan Ministry of Health and Social Affairs
Conflict of Interest: None declared

Reme 2009.

Population (low back pain description; location; setting; data collection period) Randomized Controlled Trial: People sick‐listed for 8 ‐ 12 weeks with low back pain; Norway; Mixed population; April 2000 ‐ February 2004
Sample size 246
Prognostic factor (type, measure(s) of individual recovery expectations) GENERAL: Expectation to return to work within the next few weeks (Yes/No/No opinion)
Notes Funding Source: Norwegian Foundation for Health and Rehabilitation
Conflict of Interest: None declared

Rundell 2017.

Population (low back pain description; location; setting; data collection period) Prospective cohort: Older adults (≥ 65 years old) presenting to primary care settings for new back pain visit, any duration back symptoms; United States of America; Primary care; 2011 ‐ 2013
Sample size 5220
Prognostic factor (type, measure(s) of individual recovery expectations) GENERAL: Expectation for recovery (0 ‐ 10)
Notes Funding Source: The Agency for Healthcare Research and Quality
Conflict of Interest: JGJ has served on the Comparative Effectiveness Advisory Board for General Electric Healthcare, is a cofounder and stockholder of PhysioSonics and receives royalties for intellectual property; also serves as a consultant for HealthHelp a radiology benefits management company
aStudy includes a recovery outcome based on categorisation of work, pain, and/or function outcomes
bStudy does not present sufficient data to be included in meta‐analyses (univariate), but does provide some measure of statistical significance

Sandstrom 1986.

Population (low back pain description; location; setting; data collection period) Prospective cohort: People with non‐specific low back pain referred to Department of Orthopaedic Surgery; Sweden; Secondary care; Data collection period not reported
Sample size 52
Prognostic factor (type, measure(s) of individual recovery expectations) SELF‐EFFICACY: I am afraid to start working again because I don't think I will be able to manage (7 pts)
Notes Funding Source: The Goteborg Medical Society; The Asker Foundation; The Delegation for Social Research within the Swedish Ministry for Health and Social Affairs
Conflict of Interest: Not reported
aStudy does not present sufficient data to be included in meta‐analyses (multivariate), but does provide some measure of statistical significance

Schultz 2004.

Population (low back pain description; location; setting; data collection period) Prospective cohort: Workers’ Compensation Board low back injury claimants; Canada; Occupational; Data collection period not reported
Sample size 253
Prognostic factor (type, measure(s) of individual recovery expectations) GENERAL: Expectations of recovery scale (8 items, unclear scale)
Notes Funding Source: Workers' Compensation Board of British Columbia; Workers' Compensation Board of Alberta
Conflict of Interest: Not reported

Shaw 2009.

Population (low back pain description; location; setting; data collection period) Prospective cohort: People seeking treatment at occupational health clinics for work‐related, acute back pain; United States of America; Occupational; Data collection period not reported
Sample size 519
Prognostic factor (type, measure(s) of individual recovery expectations) GENERAL: Expectation of fully returning to work in 4 weeks (3 pts)
Notes Funding Source: Not reported
Conflict of Interest: Not reported
aStudy includes a recovery outcome based on categorisation of work, pain, and/or function outcomes

Sherman 2009.

Population (low back pain description; location; setting; data collection period) Randomized Controlled Trial: People with chronic non‐specific low back pain recruited from integrated healthcare systems; United States of America; Primary care; Data collection period not reported
Sample size 638
Prognostic factor (type, measure(s) of individual recovery expectations) TREATMENT: Expectation of acupuncture helpfulness (0 ‐ 10)
SELF‐EFFICACY: Likelihood of self‐managing future back pain (unclear scale)
Notes Funding Source: The National Center for Complementary and Alternative Medicine
Conflict of Interest: Project officer for funder involved in analysis and interpretation of data and review and approval of manuscript

Steenstra 2005.

Population (low back pain description; location; setting; data collection period) Prospective cohort: Hospital workers who reported sick leave due to nonspecific low back pain for more than 1 day; Netherlands; Occupational; January 1st 2009 ‐ January 1st 2001
Sample size 615
Prognostic factor (type, measure(s) of individual recovery expectations) GENERAL: Expected duration of sick leave > 10 days (Yes/No)
Notes Funding Source: Not reported
Conflict of Interest: Not reported

Tran 2015.

Population (low back pain description; location; setting; data collection period) Prospective cohort: People with chronic low back pain at an academic safety‐net hospital, and affiliated community health centers; United States of America; Primary care; Data collection period not reported
Sample size 63 (twice‐weekly yoga); 30 (once‐weekly yoga)a
Prognostic factor (type, measure(s) of individual recovery expectations) TREATMENT: How helpful do you expect yoga to be for your back problems? (0 ‐ 10)
Notes Funding Source: The National Center for Complementary and Alternative Medicine; The National Institiutes of Health
Conflict of Interest: None declared
aTran 2015a (twice‐weekly yoga) and Tran 2015b (once‐weekly yoga) are same study, presented separately
bStudy does not present sufficient data to be included in meta‐analyses (multivariate), but does provide some measure of statistical significance

Truchon 2012.

Population (low back pain description; location; setting; data collection period) Prospective cohort: Workers receiving income replacement benefits because of common low back pain; Canada; Occupational; Data collection period not reported
Sample size 535
Prognostic factor (type, measure(s) of individual recovery expectations) GENERAL: Return to work expectations (time) (unclear scale)
Notes Funding Source: Intitut de recherch Robert‐Sauve en sante et en securite du travail
Conflict of Interest: Not reported

Turner 2008.

Population (low back pain description; location; setting; data collection period) Prospective cohort: Workers with back injury claims with > 4 days of lost work time; United States of America; Occupational; July 2002 ‐ April 2004
Sample size 1885
Prognostic factor (type, measure(s) of individual recovery expectations) GENERAL: Certainty of working in 6 months (0 ‐ 10)
Notes Funding Source: National Institute for Occupational Safety and Health, US Department of Health and Human Services
Conflict of Interest: Not reported

Underwood 2007.

Population (low back pain description; location; setting; data collection period) Randomized Controlled Trial: Participants from general practices who consulted for simple low back pain that failed to resolve after their consultation; United Kingdom; Primary care; Data collection period not reported
Sample size 1334
Prognostic factor (type, measure(s) of individual recovery expectations) TREATMENT: Treatment helpfulness (3 pts)
Notes Funding Source: Not reported
Conflict of Interest: None delcared

Van Hooff 2014.

Population (low back pain description; location; setting; data collection period) Prospective cohort: People with chronic low back pain, not improved with conservative care, referred to a tertiary orthopaedic spine care hospital; Netherlands; Setting not specified; October 2006 ‐ January 2011
Sample size 524
Prognostic factor (type, measure(s) of individual recovery expectations) SELF‐EFFICACY: Pain Self‐Efficacy Questionnaire (0 ‐ 60)
Notes Funding Source: Not reported
Conflict of Interest: John O'Dowd is a direction of and shareholder in RealHealth Netherlands which was responsible for the assessments and treatment of patients
aStudy includes a recovery outcome based on categorisation of work, pain, and/or function outcomes
bStudy does not present sufficient data to be included in meta‐analyses (multivariate), but does provide some measure of statistical significance

Van Wijk 2008.

Population (low back pain description; location; setting; data collection period) Randomized Controlled Trials (2 trials): People with back pain and sciatica recruited from pain clinics; Netherlands; Secondary care; Data collection period not reported
Sample size 81
Prognostic factor (type, measure(s) of individual recovery expectations) GENERAL: Positive Expectations scale from Pain Cognitions List (5 pts)
Notes Funding Source: Dutch Health Insurance Council; Pain Expertise Center Nijmegen
Conflict of Interest: Not reported
aStudy does not present sufficient data to be included in meta‐analyses (multivariate)

Yelland 2006.

Population (low back pain description; location; setting; data collection period) Randomized Controlled Trial: People with treatment‐resistant chronic low back pain; Australia; Secondary care; Data collection period not reported
Sample size 110
Prognostic factor (type, measure(s) of individual recovery expectations) TREATMENT (2): Desired improvement in function to make treatment worthwhile (0% ‐ 100%), and Desired improvement in pain to make treatment worthwhile (0% ‐ 100%)
Notes Funding Source: Australian General Practice Evaluation Programme; The Australian Association of Musculoskeletal Medicine; The Musculoskeletal Research Foundation of Australia
Conflict of Interest: Not reported
aStudy includes a recovery outcome based on categorisation of work, pain, and/or function outcomes

Characteristics of excluded studies [ordered by study ID]

Study Reason for exclusion
Alyousef 2018 No or inappropriate measure of expectations
De Schepper 2016 No or inappropriate measure of expectations
Dozois 1995 No or inappropriate measure of expectations
Du Bois 2009 No appropriate follow‐up period
Elfering 2015 No or inappropriate measure of expectations
Estlander 1998 Population not majority low back pain
Feuerstein 2006 No primary outcome
Fitzpatrick 1987 No or inappropriate measure of expectations
Goossens 2005 Population not majority low back pain
Hurwitz 2005 No or inappropriate measure of expectations
Jellema 2007 No primary outcome
Kendell 2018 No or inappropriate measure of expectations
Lochting 2017 No or inappropriate measure of expectations
Lotters 2006 Population not majority low back pain
Lurie 2016 Population not majority low back pain
Maxwell 1998 No appropriate follow‐up period
Melloh 2011 No or inappropriate measure of expectations
Ng 2017 No or inappropriate measure of expectations
Reis 2007 No or inappropriate measure of expectations
Roberts 2015 No or inappropriate measure of expectations
Schultz 2008 No or inappropriate measure of expectations
Silvis 2016 No or inappropriate measure of expectations
Skargren 1998 Population not majority low back pain
Smeets 2008 Expectations not measured at baseline (after first treatment)
Soucy 2006 No or inappropriate measure of expectations
Staerkle 2004 No or inappropriate measure of expectations
Steenstra 2015 No or inappropriate measure of expectations
Vargas‐Prada 2013 No or inappropriate measure of expectations
Wolff 2018 No or inappropriate measure of expectations

Characteristics of studies awaiting assessment [ordered by study ID]

Ailliet 2018.

Notes Likely to be eligible for inclusion

Ashworth 2013.

Notes Likely to be linked to an included study

Barons 2014.

Notes Likely to be eligible for inclusion

Friedman 2018.

Notes Likely to be eligible for inclusion

Ganesh 2019.

Notes Likely to be eligible for inclusion

Glattacker 2018.

Notes Likely to be eligible for inclusion

Harter 2004.

Notes German language

Hartvigsen 2018a.

Notes Likely to be linked to an included study

Klyne 2018.

Notes Likely to be eligible for inclusion

Mehling 2015.

Notes Likely to be eligible for inclusion

Mendelson 1983.

Notes Likely to be eligible for inclusion

Pfingsten 1997.

Notes Likely to be eligible for inclusion

Pfingsten 1997a.

Notes German language

Pfingsten 1997b.

Notes German language

Thomas 2005.

Notes Likely to be eligible for inclusion

Weber 1998.

Notes German language

Differences between protocol and review

  • We modified our theoretical framework of the relationship between recovery expectations and low back pain outcomes to provide more detailed guidance about important domains of characteristics to consider in 'Risk of bias' assessment (e.g. other potentially important covariates).

  • We further operationalised the QUIPS ‘Confounding’ domain as follows, "We defined five domains of other covariates important for this review question: individual demographics (for example, age, sex, gender), social support (for example, marital status, socioeconomic status), work factors and environment (for example, occupation, physical demands, workplace culture), psychological factors (for example, depression, anxiety, coping), and low back pain complaint factors (for example, baseline pain severity, baseline disability, duration of episode at baseline). We defined ‘minimally adjusted’ study analyses as those presenting adjusted analyses controlling for 1‐2 of these domains, and ‘adequately adjusted’ study analyses as those presenting adjusted analyses controlling for 3 or more of these domains".

  • In the review we considered subacute and chronic populations together as subacute/chronic (≥ 6 weeks), whereas in the protocol we had planned to look separately at subacute (defined as 6 to 12 weeks) and chronic (> 12 weeks).

  • We clarified inclusion criteria as intended in our study protocol: we excluded studies if they did not measure at least one of our primary outcomes, which include body function, activity limitation and participation restriction domains of the International Classification of Functioning, Disability and Health.

  • For primary analyses, to balance homogeneity with availability of data, we used available study data from the time period closest to 12 months (defined as ‘long, closest to 12 months’); this was not predefined in the protocol.

  • We defined expectations reference time periods for subgroup analysis as: 1‐month, 6‐month, none or unclear reference period; this was not predefined in the protocol.

  • If available in sufficient numbers, we had planned to separately extract and analyse continuous outcomes on a continuous scale, and hazard ratios for studies providing this measure of association. This was not possible.

  • For consistency, we recalculated associations to be in the same direction, as necessary, with odds ratios above 1 indicating that better (positive) expectations are associated with a better (improved) outcome.

  • As defined in our protocol, but not clearly, we included an additional primary outcome, 'important recovery', that was available in studies as a dichotomous measure of clinically important recovery in functional limitations, pain intensity, and/or work participation.

  • We included an additional follow‐up period, 'very long' (> 16 months) that was not predefined in the protocol.

  • We did not conduct sensitivity analyses to explore the robustness of results excluding studies with mixed pain or specific low back pain populations as we had planned.

  • We added a note about the presentation of forest plots and MA results in text, “We present forest plots of meta‐analyses in the text of this review when three or more studies were available for meta‐analyses in primary analyses, and when at least three studies were available for two or more subgroups in subgroup analyses.”

  • There were not enough studies available to allow other planned sensitivity analyses for studies including only low back pain populations versus studies including a small proportion of mixed pain populations, surgical candidates or individuals with lumbar disc herniation.

  • Due to the format of our data, we used Egger's test for potential publication bias, although our protocol had described a plan to use Peter's test for dichotomous expectations measure and work participation outcome.This may contribute to a false‐positive result.

  • Our protocol included description of related methods projects, including investigation of the impact of various search strategies, and refinement and further guidance of the QUIPS tool. This work is ongoing and will be reported separately.

Contributions of authors

JAH is guarantor and conceived the review.

JAH, RR, RI, TP developed the protocol and JAH, MW, RO implemented the protocol.

MW, RO, JAH screened search results; MW and JAH carried out data extraction.

MW and JAH appraised the risks of bias and quality of the evidence.

MW and RO managed the data for the review and MW and JAH conducted analyses.

JAH and MW wrote the review report, with RO, RR, RI and TP providing methodological, clinical and general advice.

All authors reviewed the final version.

Sources of support

Internal sources

  • Cochrane Methods Innovation Fund, UK.

External sources

  • Canadian Institutes of Health Research, Canada.

Declarations of interest

JAH has no known conflicts of interest related to the topic of this review. She is a Co‐Convenor of the Cochrane Prognosis Methods Group and Advisory Board Member of Cochrane Back and Neck, however was not involved in editorial decisions involving this review. She has received peer‐reviewed funding from the Canadian Institutes of Health Research, the Nova Scotia Health Research Foundation, and Cochrane. She previously held a Canadian Chiropractic Research Foundation/Dalhousie University Research Professorship in Epidemiology.

MW has no known conflicts of interest related to this review.

RDR has no known conflicts of interest related to the topic of this review. He receives payments for training courses provided in‐house to other organisations; he receives funding from MRC and NIHR for other meta‐analysis projects and has received payment from BMJ for review preparation. He is a Co‐Convenor of the Cochrane Prognosis Methods Group, however was not involved in editorial decisions involving this review.

RI has no known conflicts of interest related to this review.

TP has no known conflicts of interest related to the topic of this review. She is employed full time by the Royal Holloway University of London and has received grants from Arthritis Research UK, and NIHR.

RO has no known conflicts of interest related to this review.

New

References

References to studies included in this review

Beneciuk 2017 {published data only}

  1. Beneciuk JM, Hill JC, Campbell P, Afolabi E, George SZ, Dunn KM, et al. Identifying treatment effect modifiers in the STarT Back trial: A secondary analysis. Journal of Pain 2017;18(1):54‐65. [DOI] [PMC free article] [PubMed] [Google Scholar]

Besen 2015 {published data only}

  1. Besen E, Young AE, Shaw WS. Returning to work following low back pain: towards a model of individual psychosocial factors. Journal of Occupational Rehabilitation 2015;25(1):25‐37. [DOI] [PMC free article] [PubMed] [Google Scholar]
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Hazard 1996 {published data only}

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Hildebrandt 1997 {published data only}

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Jellema 2002 {published data only}

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Jensen 2000 {published data only}

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Karjalainen 2003 {published data only}

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Leboeuf‐Yde 2004 {published data only}

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Macedo 2014 {published data only}

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Magnussen 2007 {published data only}

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Michaelson 2004 {published data only}

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Morlock 2002 {published data only}

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Myers 2007 {published data only}

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Niemisto 2004 {published data only}

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Petersen 2007 {published data only}

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Rasmussen‐Barr 2012 {published data only}

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Reme 2009 {published data only}

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Rundell 2017 {published data only}

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Shaw 2009 {published data only}

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References to studies excluded from this review

Alyousef 2018 {published data only}

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Feuerstein 2006 {published data only}

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Fitzpatrick 1987 {published data only}

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Hurwitz 2005 {published data only}

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