Systematic literature review of patient-reported outcome measures used in assessment and measurement of sleep disorders in chronic obstructive pulmonary disease

Adam P Garrow; Janelle Yorke; Naimat Khan; Jørgen Vestbo; Dave Singh; Sarah Tyson

doi:10.2147/COPD.S68093

. 2015 Feb 9;10:293–307. doi: 10.2147/COPD.S68093

Systematic literature review of patient-reported outcome measures used in assessment and measurement of sleep disorders in chronic obstructive pulmonary disease

Adam P Garrow ^1,², Janelle Yorke ^2,^✉, Naimat Khan ¹, Jørgen Vestbo ³, Dave Singh ¹, Sarah Tyson ¹

PMCID: PMC4330032 PMID: 25709424

Abstract

Background

Sleep problems are common in patients with chronic obstructive pulmonary disease (COPD), but the validity of patient-reported outcome measures (PROMs) that measure sleep dysfunction has not been evaluated. We have reviewed the literature to identify disease-specific and non-disease-specific sleep PROMs that have been validated for use in COPD patients. The review also examined the psychometric properties of identified sleep outcome measures and extracted point and variability estimates of sleep instruments used in COPD studies.

Methods

The online EMBASE, MEDLINE, PsycINFO, and SCOPUS databases for all years to May 2014 were used to source articles for the review. The review was performed according to Preferred Reporting Items for Systematic Reviews and Meta-Analyses guidelines. Criteria from the Medical Outcomes Trust Scientific Advisory Committee guidelines were used to evaluate the psychometric properties of all sleep PROMs identified.

Results

One COPD-specific and six non-COPD-specific sleep outcome measures were identified and 44 papers met the review selection criteria. We only identified one instrument, the COPD and Asthma Sleep Impact Scale, which was developed specifically for use in COPD populations. Ninety percent of the identified studies used one of two non-disease-specific sleep scales, ie, the Pittsburgh Sleep Quality Index and/or the Epworth Sleep Scale, although neither has been tested for reliability or validity in people with COPD.

Conclusion

The results highlight a need for existing non-disease-specific instruments to be validated in COPD populations and also a need for new disease-specific measures to assess the impact of sleep problems in COPD.

Keywords: sleep, symptom assessment, chronic obstructive pulmonary disease, systematic review

Introduction

Sleep problems are a common and important, but poorly understood and under-researched, aspect of chronic obstructive pulmonary disease (COPD). After breathlessness and fatigue, sleep disturbance is considered to be the third most common symptom experienced by people with respiratory disease¹ and is also predictive of exacerbations, respiratory-related emergency hospital visits, and all-cause mortality.² Insomnia describes any reported difficulty a person has with sleep³ and has four elements: difficulties falling asleep, interrupted sleep, trouble staying asleep, and still feeling tired and worn out even after a usual amount of sleep.³^–⁵ Around 10% of the adult population is affected by insomnia, but the occurrence is much higher in people with COPD, where estimates range between 16% and 75%.⁶ The benefits of sleep are well known, and long-term interruption of normal sleeping patterns has a detrimental impact on physical, emotional, and social functioning, and is also associated with anxiety, depression, bodily pain, and a wide variety of pre-existing chronic medical conditions.⁴ In addition to insomnia, narcolepsy (suddenly falling asleep at inappropriate times), restless legs syndrome, and obstructive sleep apnea are the most common sleep disorders found in the general population,⁶ and people with COPD are disproportionately affected. Restless legs syndrome involves a need to move the legs, usually at night-time, is associated with marked sleep disturbance, and affects 7%–14% of the general population and 29% of patients with COPD.⁷^,⁸ Obstructive sleep apnea is the periodic interruption of airflow in the upper airway during sleep and affects 3%–7% of the general population⁹ and 25%–29% of people with COPD.¹⁰ A summary of the occurrence of four common sleep disorders in COPD populations is provided in Table 1.⁸^,¹¹^–¹³

Table 1.

Summary of the occurrence of common sleep disorders in COPD populations

Sleep disorder	Author	Occurrence in COPD
Insomnia (chronic sleep disturbance with impaired daytime functioning)	Budhiraja et al¹¹	27%
Excessive sleepiness	Ali Zohal et al¹²	35%
Restless legs syndrome	Kaplan et al⁸	29%
Obstructive sleep apnea	McNicholas¹³	1%

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Abbreviation: COPD, chronic obstructive pulmonary disease.

Given the importance of sleep disorders in COPD, being able to accurately classify their nature and severity is important in the management of COPD. Although self-reported sleep disorders are associated with COPD symptoms and poorer health-related quality of life,¹⁴ their relationship with traditional diagnostic markers of lung function (such as forced expiratory volume in one second, forced vital capacity, and oxygen saturation) is weak.¹⁵ This emphasizes the need for clinical instruments to accurately assess the impact of the disease and its treatment on a patient’s health and well-being through patient-reported outcome measures (PROMs)¹⁶^,¹⁷ as well as recording changes in physiological function.

Many of the instruments that have measured sleep disturbance in epidemiological studies were originally developed for people with a range of psychological conditions and/or pre-existing sleeping disorders.¹⁸^,¹⁹ However, the validity of these measures cannot be assumed to transfer between clinical populations.¹⁹ Thus, the aim of this review was to identify and evaluate the suitability of published measures of sleep disturbance for use in people with COPD in order to make recommendations for best practice for clinical and research purposes. Our objectives were to:

Identify which patient-reported outcome sleep measures have been used in people with COPD
Identify which instruments have been developed and validated specifically for people with COPD
Summarize the evidence for reliability and validity of sleep instruments in COPD patients
Examine associations with sleep disturbance recorded by sleep instruments used in clinical studies of COPD patients.

Materials and methods

Ethical approval was not needed to undertake this review, which was performed according to Preferred Reporting Items for Systematic Reviews and Meta-Analyses guidelines.²⁰

Search strategy

In this study, we conducted a systematic computerized literature review designed to identify all PROMs concerned with sleep problems experienced by people with COPD. The search included all instruments that had been developed and validated in people with COPD as well as generic instruments that had been developed for use in other disease areas and then administered to adult COPD patients.

Stage 1: Identification of sleep outcome measures used in COPD

The first stage of the search was to identify sleep outcome measures that had been used in COPD. This was conducted using EMBASE, MEDLINE, and PsycINFO electronic databases for all years up to May 2014 using both key words, ie, the Medical Subject Headings (MeSH) “COPD” AND “sleep” and expanded to include all recognized subheadings. All titles, abstracts, and full texts from the identified papers were examined by the lead author (APG) for reference to specific sleep instruments or data indicating that at least one sleep outcome measure had been used. A list of sleep outcome measures was then produced. The reference lists and citations of selected articles were also searched to identify any additional sleep PROMs not found by the electronic database search.

Stage 2: Selection and evaluation of sleep instruments used in COPD

A SCOPUS database search was carried out on each of the detected sleep outcome measures to identify all publications in which the original paper had been cited. The search included the following related terms:

Construct-related terms: sleep problems
Population terms: COPD patients (in the title, abstract, text, or reference section)
Outcome-related terms: development, validation, or psychometric properties of sleep PROMs designed specifically for people with COPD. Sleep outcome measures not specifically designed for people with COPD but used in a COPD patient group whether psychometric data were reported or not
Method-related terms: instrument* OR measure* OR question* OR scale OR assess
Quality assessment terms: valid* or reliab* or evaluat* OR psychometric.

We also screened the reference lists and citations of included articles to identify additional relevant publications.

Eligibility criteria

To be included in the review, all identified articles had to meet the following inclusion criteria: the article described PROMs that either had been specifically designed and validated for use in patients with COPD or included a generic instrument that had been administered to COPD patients; information on at least one measurement property of the outcome measure was reported; the study sample consisted of adults with a clinical diagnosis of COPD; a full text of the original publication was published electronically, in English, in a peer-reviewed journal.

Articles were excluded if reference to COPD and/or sleep only appeared in the text or reference section. Similarly, we excluded all articles with mixed study samples where the results from COPD patients were not reported separately. Review articles, protocols, and case studies were also excluded. Two investigators (APG and JY) read independently all titles, abstracts, and full texts of all the retrieved articles to determine which were eligible for review. Any disagreements were resolved at a consensus meeting.

Methodological quality assessment

The COSMIN (COnsensus-based Standards for the selection of health Measurement INstruments) checklist²¹ is a standardized tool for evaluating the methodological quality of PROMs. COSMIN checklists are used to evaluate the measurement properties of instruments in terms of their internal consistency, reliability, measurement error, content validity, structural validity, hypothesis testing, cross-cultural validity, criterion validity, and responsiveness to change. As it was anticipated that the number of PROMs that had been developed and validated for use in COPD populations was likely to be very small, rather than using the full COSMIN checklist we used four PROM characteristics recommended by the US Food and Drug Administration²² to evaluate the measurement properties of identified sleep PROM instruments in relation to their use in COPD patients, ie, conceptual and measurement model, reliability, validity, and responsiveness to change.

Conceptual model

Identified articles were examined for descriptions of concepts contained within the instrument, including the rationale and process for deriving scale scores from raw scores, identifying and dealing with floor and ceiling effects, and scale variability.

Reliability

Articles were scrutinized for estimates of reliability, including inter-item correlations, test-retest repeatability, internal consistency, and/or kappa statistics.

Validity

Any reference to content, construct, and criterion-related validity were noted. When considering construct validity, we also recorded methods to differentiate between people with different levels of lung function or disease severity, such as the Global Initiative for Chronic Obstructive Lung Disease staging system that classifies people with COPD according to the results of pulmonary tests. Where available, we also collected data regarding the relationships between sleep outcome instruments and other established COPD outcome measures (such as the St George’s Respiratory Questionnaire,²³ the Medical Research Council Dyspnea scale,²⁴ and routine clinical tests). Any analyses intended to examine dimensionality using factor analysis or Rasch analysis were noted, along with any assessments of differential item functioning that evaluated group differences in PROM item responses.

Responsiveness to change

All data relating to the ability of the instrument to detect changes over time in terms of sleep disturbance were noted. Where correlations between changes in scores of two measures are reported, these had to relate to predefined hypotheses.

Results

The stage 1 database search identified articles referring to COPD and sleep (Medline 804, EMBASE 2,314, and PsycINFO 59) from which one COPD-specific and six non-disease-specific sleep instruments were identified (Table 2).²⁵^–³¹ In stage 2, the SCOPUS search found 10,602 articles citing any of the seven sleep outcome measures, 270 of which referred to COPD. After applying the exclusion criteria, 44 manuscripts were selected for review (Figure 1). Nearly 90% of the reviewed publications either used the Pittsburgh Sleep Quality Index (PSQI;³⁰ 19/44, 43.1%) or the Epworth Sleepiness Scale (ESS; 20/44, 45.5%).²⁸ The 19-item PSQI measures sleep quality in seven domains and the ESS assesses the likelihood of a person dozing off or falling asleep in eight common life situations. Most studies involved patients with moderate-severe COPD recruited from hospital outpatient or specialist respiratory clinics.

Table 2.

Number of papers found and excluded or included in the review

Outcome measures	SCOPUS references (n)	References to COPD (n)	Excluded	Reviewed
COPD and Asthma Sleep Impact Scale²⁵	8	6	5	1
Basic Nordic Sleep Questionnaire²⁶	200	6	5	1
Berlin Questionnaire²⁷	720	22	21	1
Epworth Sleepiness Scale²⁸	4,720	153	133	20
International Restless Legs Syndrome²⁹	548	4	3	1
Pittsburgh Sleep Quality Index³⁰	4,144	71	52	19
Sleep Disorders Questionnaire³¹	262	8	7	1
Total	10,602	270	226	44

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Abbreviation: COPD, chronic obstructive pulmonary disease.

Flow diagram showing the total number of studies screened, assessed for eligibility and included in the review.

**Abbreviation:** COPD, chronic obstructive pulmonary disease.

COPD-specific sleep outcome measures

After assessing the methodological properties of the identified PROMs, only one instrument appeared to have been developed and validated for use in COPD patients, ie, the COPD and Asthma Sleep Impact Scale (CASIS).²⁵

The CASIS is a seven-item measure of sleep impairment during the previous week. Five items relate to disturbance falling asleep or staying awake during the day. The remaining two items concern sleep quality. The items are scored on a five-point scale ranging from 0 if the item never applies, to 4 if the item applies very often. A total raw score is produced from the sum of the seven individual scores which is then linearly transformed to a 0–100 total scale score. A mean CASIS score of 43.3±24.7 was reported in patients with mild COPD. The results of the original psychometric testing of the CASIS (Table 3), showed that the scale had good internal consistency (Cronbach’s alpha 0.91), test-retest reproducibility (intraclass coefficient 0.84), and concurrent validity (correlated with the St George’s Respiratory Questionnaire, r=0.68).

Table 3.

Psychometric properties of COPD and Asthma Sleep Impact Scale

Conceptual and measurement model
Rationale for deriving scale scores	Items generated from focus group discussions in UK and US samples
Scale structure	15 item scale scored 1= never to 5= very often – transferred onto a 0–100 scale
Variability	Mean score COPD patients (n=112) 47.1±24.0
Reliability
Inter-intra observer repeatability	Not tested
Item correlations	9 items highly correlated r>0.75; 6 items indicating item redundancy
Internal consistency	Cronbach’s alpha 0.91
Stability over time	2-week test-retest repeatability ICC 0.84
Validity
Convergent validity	Correlated with SGRQ r=0.68 P=0.0001 Correlations between CASIS scores and number of bad days r=0.61, overall health status (0.5), and higher mean CASIS scores in COPD patients receiving oxygen treatment (51.4 vs 43.3) Correlates with living with COPD questionnaire 0.58
Responsiveness to change	Not tested

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Abbreviations: COPD, chronic obstructive pulmonary disease; CASIS, COPD and Asthma Sleep Impact Scale; ICC, intra-class correlation coefficient; SGRQ, St George’s Respiratory Questionnaire.

None of the non-disease-specific sleep scales reported any tests of reliability or validity to justify their use in the COPD population. Significant associations were observed in only 8/20 (40%) of studies where the ESS was compared with other COPD-related outcome measures. For example, the prevalence of daytime sleepiness (ESS >10) was significantly greater in patients diagnosed with insomnia.¹¹ Compared with people who had obstructive sleep apnea/hypopnea syndrome, COPD patients were more likely to be affected by daytime sleepiness.³² Significant differences in mean ESS scores were observed between patients with COPD and restless legs syndrome compared with controls who had restless legs syndrome.³³ However, no differences in daytime sleepiness were observed in a study that compared use of temazepam between COPD patients and controls.³⁴ Similarly, no significant differences in ESS scores were detected in patients with and without restless legs syndrome³⁵ (Table 4).

Table 4.

Summary of studies that used the Epworth Sleepiness Scale

Reference	Study focus	COPD study sample	Measures of COPD severity	ESS (mean ± SD/median and range)	ESS >10 (%)	Associations with ESS score
Aras et al³⁶	RLS symptoms in COPD patients during an exacerbation period	22 male inpatients	GOLD stage IV: FEV₁ 30% or 50% plus chronic respiratory failure; mean FEV₁ 39.4%±9.97%	Not reported	Not reported	Free thyroxine values negatively correlated with ESS (r_s =−0.481 P=0.043)
Bednarek et al⁴⁶	Prevalence of SDB and COPD in a representative urban sample aged 41–72 years	676 participants from the electoral register	FEV₁/FEV <0.7, 10.6%	6.4±3.9	Not reported	Mean ESS in people with excessive sleep disorder: men 12.6±2.0 versus women 12.9±2.4 (P>0.05)
Budhiraja et al¹¹	Prevalence of insomnia in patients with COPD, and characteristics associated with insomnia in COPD patients	183 hospital patients	GOLD stage I, 3%; stage II, 39%; stage III, 29%; stage IV, 28%; % predicted post-bronchodilator FEV 45.9±18.6. FEV₁/FVC ratio 49.6±12.5	Not reported	Not reported	Daytime sleepiness (ESS >10) greater in patients with insomnia (36.5% versus 14.6%, P=0.004)
Cavalcante et al³⁵	Occurrence and associations with RLS in a COPD population	104 hospital outpatient attenders	mMRC 0 (4.8%); 1 and 2 (48.1%); 3 (34.6%); 4 (12.5%)	6.9±5.1	20.2	No difference in mean values between patients without RLS (6.6±4) versus with RLS (7.7±6.0). ESS positively correlated with BMI (P<0.003)
De Lima et al⁴⁷	Whether clinically stable COPD patients without cognitive symptoms may present with subtle cognitive impairments	30 hospital outpatients	Mean FEV₁ 42.1±15.9	6.7±3.7	Not reported	Not reported
Kapella et al³⁹	Feasibility and assessment of the impact of a CBT intervention for people with COPD and insomnia	23 patients recruited from advertisements and word of mouth	FEV₁/FVC ratio <70% ¹	9.2±5.0	Not reported	Not reported
Karachaliou et al³²	Association between OSAHS-related symptoms and physician-diagnosed asthma and COPD	1,501 primary care patients (323 with COPD)	GOLD stage I, 28.8%; stage II, 53.3%; stage III, 15.2%; stage IV, 2.8%	Not reported	Not reported	Increased odds of people with COPD having an ESS score ≥10; OR 2.04, 95% CI (1.33–3.14)
Lewis et al⁴⁸	Variability of nocturnal desaturation in COPD over a 3-week period and impact the variability may have on clinical decision-making	26 stable COPD hospital outpatients	Mean post-bronchodilator FEV₁ 28.6%	4.1±6.2; range 0–11	Not reported	Not reported
Lewis et al⁴⁹	Prevalence and clinical impact of nocturnal desaturation in a typical outpatient population with COPD	59 COPD outpatients	Mean predicted FEV₁ 37.2±14.9; FVC 1.9 ±0.9; FVC predicted 62.1±17.6; TB90% 38.4±34.9	5.0; range 2.0–8.0	Not reported	No significant difference between desaturators and nondesaturators (P=0.88)
Lo Coco et al³³	Prevalence, severity, and associations with RLS in COPD patients	87 COPD outpatients	GOLD stage II, 42.5%; stage III, 40.2%; stage IV, 17.3%	8.98±3.89	Not reported	Significant difference in mean ESS score between COPD with RLS and controls with RLS 11.81±1.09 versus 8.62±3.66 (P=0.009)
McNicholas et al⁵⁰	Placebo-controlled, double-blind trial of severe, stable COPD patients comparing the effect of tiotropium on sleeping oxygen saturation	56 hospital outpatients	FEV₁ <65% predicted; FEV₁/FVC <70%; Awake paO₂ <9.98 kPa (75 mmHg) prior to entry	5.7 in intervention group versus 6.4 in control group	Not reported	None reported
Nunes et al⁵¹	Sleep quality in COPD patients at home using actigraphy and association between sleep quality and daytime somnolence	26 hospital patients	GOLD stage II, 50%; stage III, 3 8.5%; stage IV, 11.5%; FEV₁% predicted 47.62±16.04	8.27±4.4	61.5	No difference between COPD and controls (8.27±4.4 versus 6.07±3.9, P=0.12). No difference in proportion with ESS ≥10 COPD (61% versus controls 86%; P=0.09)
Oliveira et al⁵²	Evaluate accuracy of a portable monitoring device in detection of OSA in patients with COPD	26 hospital outpatients	FEV₁/FVC 0.6±0.10; FEV₁ (%) post-BD 55±0.08; FVC (%) post-BD 77±8.9	10.5±4.1	Not reported	None reported
Scharf et al⁵³	Correlation between disturbed sleep and COPD	180 pulmonary clinic patients	GOLD stage I, 10.6%; stage II, 3 0.6%; stage III, 46.1%; stage IV, 12.8%. FEV₁ % predicted 47.6±15.2	7.0±4.8	24.7	No associations with ESS and other symptoms
Soriano et al⁵⁴	Natural history of the most common respiratory chronic conditions, including COPD and OSA	500 primary care patients	GOLD stage I (27%); stage II (58%); stage III (15%)	Not reported	29.2	None reported
Stege et al³⁴	Effects of long-term use of a benzodiazepine (temazepam) on breathing, dyspnea, and gas exchange during sleep, sleep quality, and sleepiness	14 respiratory clinic patients	FEV₁ % predicted 33.5±9.2; FEV₁/FVC% 32.7±13.0; FEV₁ (L) 0.99 ±0.30	6.0±4.0	50.0	No difference between temazepam (5.0±4.0) and controls (6.0±4.0; P=0.13)
Toraldo et al⁵⁵	Pattern of daytime clinical variables that distinguish desaturator patients from nondesaturator COPD patients using cluster analysis	51 consecutive hospital patients	FEV₁ % predicted 53 (SE 1.5); FEV₁/FVC ratio 37.6 (SE 0.5); FVC % predicted 81.5 (SE 1.2); AHI 2.8 (SE 0.1). Daytime paO₂ values 60–70 mmHg	3.9 (SE ±0.1)	None	No difference between desaturators and nondesaturators, both 3.8 (± SE 0.4)
Toraldo et al⁵⁶	Effect of regular use of nCPAP in patients with overlap syndrome	12 hospital outpatients	FEV₁ (%) 60.3±1.3; FEV₁/FVC (%) 69.5±0.7	16.58±0.86	Not reported	Reductions in ESS score between baseline and 3 months (16.6±0.86 versus 11.7±0.46; P=0.0001); 3 months and 12 months (11.7±0.46 versus 5.7±0.4; P=0.0001), and 12 and 24 months (5.67±0.4 versus 4.75±0.49; P=0.033)
Trauer et al⁵⁷	Relationship between 24-hour oximetry and resting partial pressure of oxygen	35 community-living patients	GOLD stage II, 20%; stage III, 4 9%; and stage IV, 31%; FEV₁ % predicted 37.5±13.2	Median 4 (IQR 2, 8)	Not reported	Negative correlation between ESS and time below 90% SpO₂ −24 hours −0.18 (0.29); waking hours −0.13 (0.46); sleeping hours −0.17 (0.24)
Tsolaki et al⁵⁸	Effect of non-invasive ventilation as an additional treatment for severe COPD patients	24 hospital outpatients	FEV₁ (%) 34.7±11.3; FVC (%) 50.8±15.7	9.2±3.7	Not reported	Significant reductions in ESS score between baseline and 1 month in patients who received noninvasive ventilation (10.3 versus 4.9; P=0.0001). ESS was an independent predictor of the Mental Component Score of the SF-36 (P<0.001)

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Abbreviations: AHI, apnea-hypopnea index; BD, bronchodilator; BMI, body mass index; CI, confidence interval; OR, odds ratio; COPD, chronic obstructive pulmonary disease; RLS, restless legs syndrome; SDB, sleep-disordered breathing; CBT, cognitive behavioral therapy; OSAHS, obstructive sleep apnea/hypopnea syndrome; mMRC, modified Medical Research Council Dyspnoea scale; FVC, forced vital capacity; FEV₁, forced expiratory volume in 1 second; GOLD, Global initiative for chronic Obstructive Lung Disease; SpO₂, oxygen saturation; ESS, Epworth Sleepiness Scale; SE, standard error; pO₂, oxygen partial pressure; paO₂, arterial oxygen tension; IQR, interquartile range; TB90%, time spent with saturation below 90%; SF-36, Short-Form 36 Health Survey; nCPAP, nasal continuous positive airway pressure; SD, standard deviation; OSA, obstructive sleep apnea.

For the PSQI, significant associations were noted in 11/19 (57.9%) of the relevant studies. PSQI scores were found to be significantly higher in patients with restless legs syndrome.³⁶ PSQI total scores also correlated with total scores from the St George’s Respiratory Questionnaire³⁷^,¹⁴ and the Fatigue Severity Scale.³⁵ In contrast, no correlation was observed between PSQI and St George’s Respiratory Questionnaire scores in an investigation of factors affecting health status in COPD patients with comorbid anxiety or depression.³⁸ Further, although significant PSQI score reductions were observed in patients receiving a course of cognitive behavioral therapy (where the primary outcome was insomnia),³⁹ no reductions in pre- and post-sleep quality were observed in a randomized controlled trial that compared cognitive behavioral therapy with usual care, where sleep was a secondary outcome measure to anxiety and depression⁴⁰ (Table 5).

Table 5.

Summary of papers that used the Pittsburgh Sleep Quality Index

Reference	Study focus	COPD study sample	Measures of COPD severity	PSQI (mean ± SD)	PSQI >5 (%)	Associations with PSQI score
Akinci and Yildirim³⁷	Associations between quality of life and breathlessness, fatigue, sleep quality, and FEV₁ % predicted in patients with COPD	79 stable hospital outpatients	FEV₁ (%) 51.5±16.1 (range 18–80); FEV₁/FVC (%) 63.4±9.3 (range 34.6–70.2)	7.1±3.9	Not reported	Correlations between SGRQ and PSQI total scores (0.428, P<0.001); daytime dysfunction (0.400, P<0.001); sleep disturbance (0.481, P<0.001), habitual sleep efficiency (0.271, P<0.05); sleep latency (0.309, P<0.01); subjective sleep quality (0.421, P<0.001) but not sleep duration or use of sleep medication
Aras et al³⁶	RLS symptoms in COPD patients during an exacerbation	22 male inpatients	GOLD stage IV: FEV₁ 30% or 50%, plus chronic respiratory failure; mean FEV₁ 39.4%±9.97%	6.0±3.81	Not reported	PSQI score was higher in patients with RLS symptoms (7.76±3.74) compared with patients without RLS symptoms (3.44±2.18; P<0.05)
Cavalcante et al³⁵	Occurrence and associations with RLS in a COPD population	104 hospital outpatients	mMRC 0 (4.8%); 1 and 2 (48.1%); 3 (34.6%); 4 (12.5%)	7.6 ±4.3	59.6%	PSQI correlated with Fatigue Severity Scale (P<0.005). Patients with RLS had poor quality sleep (P<0.002). PSQI score correlated with mMRC (P<0.005); higher BMI (P=0.01); serum ferritin (P=0.005). mMRC and creatinine influenced PSQI sleep quality
Hynninen et al³⁸	Factors affecting health status in COPD patients with comorbid anxiety or depression	58 hospital outpatients/responders to newspaper advertisements	29 (50%) had mild-moderate COPD and 29 (50%) had severe/very severe COPD. Mean FEV₁ 53.79±23.96; 50% had FEV₁ ≥50%	Men 8.1±3.6; women 9.2±3.8	Not reported	PSQI total scores not correlated with SGRQ. PSQI daytime functioning correlated with SGRQ total (0.57, P≤0.001); symptoms (0.374, P≤0.01); activity (0.364, P<0.01); impact (0.56, P≤0.001). PSQI sleep disturbance correlated with SGRQ total (0.404 P≤0.01); symptoms (0.378, P<0.01), and impact (0.409, P≤0.01)
Hynninen et al⁴⁰	Effect of CBT on anxiety and depression compared with usual care and associations with age and sex	25 hospital patients/respondents to newspaper advertisements	FEV₁ (%) 59.8±21.1	9.8±4.4	Not reported	No significant difference between pre- and post-treatment sleep quality or at 6 months follow-up as a result of the CBT intervention
Ito et al⁵⁹	Prevalence and associations between depression and sleep disorders in COPD patients and whether depression and sleep disorders are risk factors for exacerbations, hospitalization, and mortality due to COPD	85 hospital patients	GOLD stage I, 21.2%; stage II, 38.8%; stage III, 28.2%; stage IV, 11.8%. Mean post-BD FEV₁ 1.6±0.7 L; FVC 3.3±0.9 L; FEV₁/FVC % 47.1±13.9	5.5±3.3	43.5%	PSQI scores higher in COPD versus non-COPD patients (5.5±3.3 versus 4.1±2.6; P=0.0076). An increase in RR in patients with COPD versus non-COPD controls (RR 1.82, 95% CI 1.03–3.22; P=0.042). A weak correlation between PSQI scores and CESD scores (r=0.22; P=0.044). Annual number of exacerbations was higher in COPD patients with depression (3.3±3.5) compared with patients having sleep problems alone
Kapella et al³⁹	Feasibility and impact of a CBT intervention for people with COPD and insomnia	23 patients recruited from advertisements and word of mouth	FEV₁/FVC ratio <70% predicted. Mean FEV₁ % predicted 62±18; mean FEV₁/FVC 50±10	11.0±3.6	Not reported	PSQI scores reduced following COPD treatment (11.0±3.6 versus 6.5±3.4; P=0.0002). Within group effect size 1.02
Lewis et al⁴⁸	Variability of nocturnal desaturation in COPD as measured by OPO and the impact the variability may have on clinical decision-making	26 stable hospital outpatients	Mean FEV₁ % 28.6±10.6	Not reported	Not reported	No significant association between PSQI and resting pO₂ (P=0.89)
Lewis et al⁴⁹	Prevalence and clinical impact of nocturnal desaturation in COPD outpatients	59 consecutive outpatient and pulmonary rehabilitation patients	FEV₁ <60% predicted and FEV₁/FVC <70% predicted; mean FEV₁ % predicted 37.2±14.9; mean FVC % predicted 37.2±14.9; mean FEV₁ 0.9±0.4 L	Median 7 (IQR 4, 11)	61%	No significant difference in PSQI total score between desaturators and nondesaturators (8 [IQR 4, 11] versus 7 [IQR 4, 11]; P=0.63)
Nisbet et al⁶⁰	Occurrence of overnight desaturation; if resting oxygen saturation predicts overnight desaturation and whether desaturation correlates with HRQoL and sleep quality	38 consecutive outpatient and pulmonary rehabilitation patients	FEV₁ <60% predicted and FEV₁/FVC ratio <70% predicted. Mean FEV₁ (L) 0.8±0.37; mean FVC (L) 2.1±0.65	7.1±3.99	Not reported	No significant difference in PSQI total score between desaturators and nondesaturators (6.7±3.78 versus 7.1±3.99; P=0.82)
Nunes et al¹⁴	Impact of sleep quality on HRQoL in COPD	30 hospital COPD patients	GOLD stage II, 50.0%; stage III, 33.3%; stage IV, 16.7%; mean FEV₁% predicted 48.55±17.27 FEV₁/FVC % 52.11±9.85	7.37±3.6	70.0%	Significant positive correlation between PSQI total score and SGRQ total score (r=0.42; P=0.02) and impact domain score (r=0.47; P=0.01); global PSQI score was a predictor of SGRQ total score (adjusted r² 0.373, P=0.001) and SGRQ impact score (adjusted r² 0.329, P=0.001)
Nunes et al⁵¹	Sleep quality in COPD patients at home using actigraphy and association between sleep quality and daytime somnolence	26 stable respiratory outpatients	GOLD stage II, 50%; stage III, 38.5%; stage IV, 11.5%; mean FEV₁ % predicted 47.62±16.04	6.96±3.5	57.7%	Mean PSQI total score significantly worse in COPD than in controls (6.96±3.5 versus 4.8±2.4; P=0.043); no significant correlation between PSQI and actigraphy variables
Oh et al⁶¹	Characteristics of fatigue in patients with chronic lung disease	128 hospital patients, 80% of whom had COPD, 13% had bronchiectasis, and 4% had interstitial lung disease	Mean FEV₁ 64.5±28.8	Mean score 1.9±0.7 (range 0–3)	Not reported	In the regression analysis, sleep quality was not independently associated with fatigue; standardized β coefficient 0.02: t=0.25 P=0.8
Reishtein⁶²	Impact of dyspnea, fatigue, and sleep difficulty on functional performance	30 home and 47 clinic patients	FEV₁ <60% predicted; mean FEV₁ 41.2±11.79	8.69±4.33	Not reported	Weak non-significant correlation between sleep difficulty and functional performance (−0.17, P>0.05)
Scharf et al⁵³	Extent of sleep problems in COPD; predictors of HRQoL and the contribution of sleep disturbance to HRQoL	180 pulmonary clinic patients	GOLD stage I, 10.6%; stage II, 30.6%; stage III, 46.1%; stage IV, 12.8%; mean FVC% predicted 64.7±16.3; FEV₁/FVC % 57.5 ±12.3; FEV₁ (L) 1.24±0.50 FVC (L) 2.17±0.70	11.0±5.4	77.7	HRQoL and SGRQ scores significantly associated with PSQI (adjusted r² HRQoL 0.24 and SGRQ 0.23 both P<0.0001). HRQoL and SGRQ were independently associated with PSQI score (r² 0.06, P=0.0002 and r² 0.05, P=0.0005, respectively)
Suh et al⁶³	Effect of anxiety on heart rate variability, depression, and sleep in COPD	30 COPD pulmonary rehabilitation patients and 30 non-COPD controls	COPD patients with anxiety PSQI 12.0 (4.06) versus healthy patients with anxiety 7.8 (4.02) GOLD criteria: stage I, 13.3%; stage 2, 43.3%; stage 3, 30%; stage 4, 13.3%	12.0±4.02	Not reported	COPD patients with anxiety had poorer sleep quality than non-COPD controls with anxiety (12.0 versus 7.8; t=2.74, P=0.01). The COPD only group had significantly lower PSQI scores than COPD anxiety group (6.9 versus 12.0; t=−3.49, P=0.002)
Soler et al⁶⁴	PR improves sleep quality in chronic lung disease	46 obstructive 13 restrictive 5 mixed	FEV₁ % predictive Obstructive 44.2 (12.3) Restrictive 82.2 (6.8) Mixed 62.7 (11.5)	6.6 (3.9) obstructive 8.2 (3.7) restrictive 6.6 (4.7) mixed	58	Poor sleep quality was reported by 58% of patients before PR and 47% after PR (P<0.001)
Halvani et al⁶⁵	Evaluation of exogenous melatonin administration in improvement of sleep quality in patients with COPD	48 stable hospital patients	Confirmed diagnosis of GOLD stage II, GOLD stage IV	Intervention 11.63±3.96 Controls 10.66±2.48	Not reported	Melatonin group Baseline 11.63±3.96; follow-up 8.7±4.15 (P=0.002). Placebo group Baseline 10.66±2.48; follow-up 10.11±2.66 (P=0.065)
Bhatt et al⁶⁶	NPPV in subjects with stable COPD	15 stable hospital patients who received NPPV versus 12 controls	FEV₁/FVC ratio <0.70 PaCO₂ <52 mmHg	3.7 (3.0) NPPV 6.1 (3.2) Controls	Not reported	Results after 6 months NPPV 3.7 (3.0) versus 3.4 (2.0; P=0.2) Controls 6.1 (3.3) vs 5.7 (3.2) P=0.77

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Abbreviations: BMI, body mass index; CI, confidence interval; COPD, chronic obstructive pulmonary disease; RLS, restless legs syndrome; mMRC, modified Medical Research Council Dyspnea scale; FVC, forced vital capacity; FEV₁, forced expiratory volume in 1 second; GOLD, Global initiative for chronic Obstructive Lung Disease; IQR, interquartile range; nCPAP, nasal continuous positive airway pressure; PR, pulmonary rehabilitation; RR, relative risk; BD, bronchodilator; CBT, cognitive behavioral therapy; SD, standard deviation; NPPV, noninvasive positive pressure ventilation; PaCO₂, partial pressure of carbon dioxide; HRQoL, health-related quality of life; PSQI, Pittsburgh Sleep Quality Index; OPO, overnight pulse oximetry; SGRQ, St George’s Respiratory Questionnaire; CESD, Center for Epidemiologic Studies-Depression.

Table 6 shows the papers that used the four remaining generic outcome measures in studies of COPD patients.³³^,³⁵^,⁴¹^,⁴² With so few studies, there are currently insufficient data to evaluate the utility of these instruments; however, in one study,³³ International Restless Leg Study Group scores correlated significantly with ESS scores.

Table 6.

Summary of articles using generic sleep measures

Outcome measure and authors	Study focus	COPD study sample	Measures of COPD severity	Outcome reported (mean ± SD)	Associations
Berlin Questionnaire Cavalcante et al³⁵	Occurrence and associations with RLS in a COPD population	104 hospital outpatient attenders	mMRC 0 (4.8%); 1 and 2 (48.1%); 3 (34.6%); 4 (12.5%)	30 (29%) of patients had a high probability of OSA	Risk of OSA not associated with RLS (P=0.25)
BNSQ Saaresranta et al⁴¹	Sleep quality and excessive daytime sleepiness in ambulatory patients with moderate to severe COPD	15 consecutive female clinic outpatients	FEV₁ predicted <65% of daytime hypoxemia (PaO₂ <10.0 kPa) and/or hypercapnia (PaCO₂ >6.0 kPa); FEV₁ % 36±12; FVC % 63±14; FEV₁ (L) 0.73±0.45 (range 0.25–1.8); FVC (L) 1.3±0.45	BNSQ 9.9±3.0	BNSQ score higher than controls (9.9±3.0 versus 7.6±3.2; P=0.025) and correlated with insulin levels (r=0.59, P=0.027) and body movements (r=0.52, P=0.047)
IRLSG Lo Coco et al³³	Prevalence, severity, and associations with RLS in COPD patients	87 COPD outpatients	GOLD stage II, 42.5%; stage III, 40.2%; stage IV, 17.3%	IRLSG score 32 (36.8%)	IRLSG score in COPD patients 20.5±2.8 versus 18.0±3.5 in controls (P=0.016); moderate correlation between ESS and IRLSG score (Spearman correlation 0.489, P=0.01)
SDQ Valipour et al⁴²	Differences in symptoms and polysomnographic parameters in COPD patients	52 consecutive hospital outpatients	FEV₁% predicted 60±10; FVC % predicted 93±12; FEV₁/FVC 60±8	SA 36.0±6.9 PLM 25.2±7.1 PSY 18.0±6.0 Narcolepsy 22.1±5.5	COPD patients had higher scores in PLM (25.2±7.1 versus 21.1±6.2, P=0.0003) and PSY (18.0±6.0 versus 15.3±5.0, P=0.035) Minimum SaO₂ had an independent effect on SDQ subscale scores: SA (P=0.045), PLM (P=0.051), PSY (P=0.037), and narcolepsy (P=0.053) Mean overnight SaO₂ was a significant predictor of PSY score (P=0.015)

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Abbreviations: BNSQ, Basic Nordic Sleep Questionnaire; COPD, chronic obstructive pulmonary disease; PLM, periodic limb movement; SDQ, Sleep Disorders Questionnaire; PSY, psychiatric sleep disorder; RLS, restless leg syndrome; IRLSG, International Restless Leg Study Group; SA, sleep apnea; FVC, forced vital capacity; FEV₁, forced expiratory volume in 1 second; OSA, obstructive sleep apnea; mMRC, modified Medical Research Council Dyspnea scale; GOLD, Global initiative for chronic Obstructive Lung Disease; SaO₂, arterial oxygen saturation; ESS, Epworth Sleepiness Scale; PaCO₂, partial pressure of carbon dioxide; PaO₂; hypercapnia PaCO.

Although the results provide some evidence of the validity of measures of sleep disturbance in people with COPD, none of the above sleep measures were specifically evaluated for people with COPD. Similarly, we did not find any articles that provided data on test-retest, intrarater, or inter-rater reliability or responsiveness to change among COPD patient groups.

The point estimates of sleep disturbance from clinical studies of COPD patients using the ESS and the PSQI are shown on Tables 4 and 5. In 13/15 of the studies using the ESS, the mean/median scores were less than 10, ie, below the accepted cutoff value for excessive daytime sleepiness.²⁸ Most of the observed PSQI scores were above 5, ie, above the cutoff value representing poor quality sleep.³⁰ Point and upper and lower quartile estimates for the ESS and PSQI are displayed on Figures 2 and 3.

Point estimates and variability in studies that used the ESS.

**Abbreviation:** ESS, Epworth Sleepiness Scale.

Point estimates and variability in studies that used the PSQI.

**Abbreviation:** PSQI, Pittsburgh Sleep Quality Index.

Discussion

Sleep disturbances are an important problem that can seriously impact on physical and mental well-being as well as quality of life for people with COPD. This review identified seven outcome measures that have been used in COPD populations but none has been sufficiently validated to satisfy US Food and Drug Administration requirements to support labeling claims in medical product development. Only one measure, the CASIS, included item response theory modeling when evaluating the psychometric evaluation of the instrument. Incorporating item response theory is now considered to be an essential component in the design and validation of all PROMs.¹⁹

The majority of sleep studies in COPD have relied on two general measures of sleep dysfunction, the ESS and the PSQI, and although both of these instruments have been extensively used in a variety of clinical populations, neither has been validated for use in COPD patients.

As far as we are aware, this is the first systematic review of sleep measures in COPD. A strength of this study was the comprehensiveness of our literature search. We believe that we have identified all of the main PROMs of sleep disorders that have been used in COPD populations. Nevertheless, as we did not search all electronic databases or carry out a hand search, there is the possibility that we may have missed some relevant articles, particularly those that appeared in non-English language journals. However, by cross-checking the reference lists of all included papers and that of a recent systematic review of instruments designed to measure sleep dysfunction in adults,¹⁵ we believe we have minimized the loss of any important papers.

The review identified only one PROM, ie, the CASIS, which has been specifically designed and validated for use in COPD patients. In each item of the CASIS, patients are advised to “[…] think about the impact of breathing problems/COPD/asthma on your sleep during the past week […]” Most items, however, are general in nature and relate to the frequency of symptoms such as falling asleep, staying awake, and waking up feeling rested. Only one item relates specifically to breathing problems, ie, shortness of breath, coughing, and chest tightness. Further, as these symptoms are all contained within the same item, it is not possible to differentiate patients who may have different severity of symptoms; for example, between patients who wake up at night only with shortness of breath or wake up with both shortness of breath and coughing. Since the publication of the original paper, the CASIS has not been used in any intervention studies, so further evidence is needed to confirm the utility of this instrument in guiding the clinical management of COPD patients and in research.

This review has highlighted the current reliance of sleep research on generic sleep measures and the paucity of disease-specific instruments currently available to assess the patient’s experience of sleep in relation to COPD. By definition, generic measures tend to cover broad aspects such as functional status and perceptions and are more likely to identify aspects that are not disease-related. Because instruments validated in one population may not perform well in specific populations under investigation, separate validation of generic measures in each population is recommended.⁴³ Similarly, given that disease-specific measures are generally more responsive to change, outcomes based solely on generic measures are unlikely to detect treatment-related improvements.⁴⁴ These deficiencies could call into question findings from previous research on the impact of sleep problems in COPD. The need for validated COPD-specific sleep outcome measures was emphasized in an expert panel meeting held in 2011.⁴⁵ While appreciating the multifactorial nature of sleep disturbance in COPD, the panel highlighted the need for an instrument to classify patients according to their night or daytime symptoms, which is not possible using existing PROMs for sleep. Development work on new COPD sleep PROMs to address these limitations is currently being carried out by the authors of this review.

Conclusion

This review highlights the complexity of sleep assessment, the inadequacy of non-disease-specific measures to capture problems experienced by people with COPD, and the absence of robust and validated methods of assessing and classifying symptoms associated with disrupted sleep in COPD. In studies using non-disease-specific sleep measures, there is a pressing need for these to be validated with COPD populations and/or for new disease-specific PROMs to be developed.

Acknowledgments

This partnership received financial support from the Knowledge Transfer Partnerships (KTP) program. The project was also supported by the UK Medical Research Council. KTP aims to help businesses to improve their competitiveness and productivity through the better use of knowledge, technology, and skills that reside within the UK knowledge base. KTP is funded by the Technology Strategy Board along with other government funding organizations.

Author contributions

All authors contributed to the design of the review. APG carried out the literature searches, produced draft manuscripts for review, and edited the manuscript prior to submission. JY read and verified the suitability of the articles for review and also participated in consensus meetings. ST provided guidance and editorial support during preparation of the review. All authors contributed and approved the final version of the manuscript. ST and JY are guarantors of the paper, taking responsibility for the integrity of the work as a whole from inception to the published article.

Disclosure

The authors report no conflicts of interest in this work.

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PERMALINK

Systematic literature review of patient-reported outcome measures used in assessment and measurement of sleep disorders in chronic obstructive pulmonary disease

Adam P Garrow

Janelle Yorke

Naimat Khan

Jørgen Vestbo

Dave Singh

Sarah Tyson

Abstract

Background

Methods

Results

Conclusion

Introduction

Table 1.

Materials and methods

Search strategy

Stage 1: Identification of sleep outcome measures used in COPD

Stage 2: Selection and evaluation of sleep instruments used in COPD

Eligibility criteria

Methodological quality assessment

Conceptual model

Reliability

Validity

Responsiveness to change

Results

Table 2.

Figure 1.

COPD-specific sleep outcome measures

Table 3.

Table 4.

Table 5.

Table 6.

Figure 2.

Figure 3.

Discussion

Conclusion

Acknowledgments

References

ACTIONS

PERMALINK

RESOURCES

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