Abstract
Background
It is difficult to gain an overview of musculoskeletal extremity complaints in childhood although this is essential to develop evidence-based prevention and treatment strategies. The objectives of this systematic review were therefore to describe the prevalence and incidence of musculoskeletal extremity complaints in children and adolescents in both general and clinical populations in relation to age, anatomical site and mode of onset.
Methods
MEDLINE and EMBASE were electronically searched; risk of bias was assessed; and data extraction was individually performed by two authors.
Results
In total, 19 general population studies and three clinical population studies were included with children aged 0-19 years. For most of the analyses, a division between younger children aged 0-12 years, and older children aged 10-19 years was used. Lower extremity complaints were more common than upper extremity complaints regardless of age and type of population, with the most frequent pain site changing from ankle/foot in the youngest to knee in the oldest. There were about twice as many non-traumatic as traumatic complaints in the lower extremities, whereas the opposite relationship was found for the upper extremities in the general population studies. There were relatively more lower extremity complaints in the general population studies than in the clinical population studies. The review showed no pattern of differences in reporting between studies of high and low risk of bias.
Conclusions
This review shows that musculoskeletal complaints are more frequent in the lower extremities than in the upper extremities in childhood, and there are indications of a large amount of non-traumatic low intensity complaints in the population that do not reach threshold for consultation. A meta-analysis, or even a simple overall description of prevalence and incidence of musculoskeletal extremity complaints in children and adolescents was not feasible, due to a large variety in the studies, primarily related to outcome measurements.
Electronic supplementary material
The online version of this article (10.1186/s12891-017-1771-2) contains supplementary material, which is available to authorized users.
Keywords: Musculoskeletal injury, Musculoskeletal pain, Paediatrics, Prevalence, Incidence
Background
Recently, the Global Burden of Disease studies reported musculoskeletal pain as one of the leading causes of years lived with disability [1] and this constitutes a substantial burden on society [2]. Therefore, it is important to design better prevention strategies and early effective treatment. To do that, more basic knowledge about the epidemiology of musculoskeletal complaints in children and adolescents must be obtained first.
The epidemiology of spinal pain in children is well-described [3–5], whereas less attention has been given to musculoskeletal extremity complaints (MEC) in children. Furthermore, musculoskeletal problems in childhood might not only lead to musculoskeletal complaints in adulthood, but could also be a barrier for physical activity and thus have a negative influence on general health [6]. It has been shown that physical activity is important for health in children and adolescents [6–9], and in addition the amount of physical activity in childhood is considered to be a predictor of the amount of physical activity in adults [9], which is important in prevention of many lifestyle disorders, e.g. diabetes and cardiovascular disease [8, 9].
Various terms have been used in relation to MEC, starting from the less severe ache to injury or more severe musculoskeletal disorders. Commonly, MEC are divided into traumatic and non-traumatic complaints, where a traumatic complaint has been defined as an injury resulting from a specific identifiable event, whereas a non-traumatic complaint is not related to an identifiable event [10]. In research of MEC, focus has traditionally been on either specific groups of athletes, or injuries reported at emergency departments, and patterns of paediatric injuries in relation to sport are therefore well described [11–13]. While this type of research provides valid information about specific injuries, mainly injuries of a traumatic onset, they do not represent the full picture of MEC in the general population. Specifically, none of these methods collect valid information about non-traumatic complaints in the general population, which has been shown to represent a large part, close to two thirds, of MEC [14, 15]. The prevalence and treatment strategies of some types of specific injuries, e.g. fractures [16] and ankle distortions [17–19] are well described, but such knowledge has not been accumulated for many other types of MEC, e.g. overuse injuries and non-specific minor complaints. To inform the development of evidence-based prevention and treatment strategies, the first step is to increase knowledge about types and frequency of MEC in childhood. At present it is difficult to gain an overview of the extent of various types of complaints in relation to mode of onset (traumatic vs. non-traumatic), different anatomical locations and histological involvement. Therefore, the objectives of this systematic review were to investigate the prevalence and incidence of musculoskeletal extremity complaints in children and adolescents in both general and clinical populations in relation to age, distribution between different complaint sites, and types of complaints (traumatic vs. non-traumatic). Furthermore, differences between general and clinical populations will be explored.
Methods
Case terminology
Different traditions and interest in different levels of complaint-severity are reasons for various terms used in research about musculoskeletal extremity complaints: injury, disorder, discomfort, complaint, pain, ache etc. In this review we analysed musculoskeletal extremity complaints in the general population, and therefore found a broad term of musculoskeletal extremity complaint (MEC) to be most comprehensive and this will be used throughout the rest of this article, regardless of the term used in the referenced articles. When possible, the MEC were divided according to causation, and were categorised as either traumatic or non-traumatic. A traumatic complaint was defined as an injury resulting from a specific identifiable event, whereas a non-traumatic episode was not related to an identifiable event [10]. For example, a traumatic complaint could be pain due to fall from a horse, and a non-traumatic complaint could be pain of unspecific origin developed over a longer period of time.
Identification of studies
The search was made in collaboration with a research librarian. Two electronic databases, MEDLINE and EMBASE, were searched for articles published before September 2015. The following search terms were used both as MeSH terms and free text in MEDLINE, and as Subject heading and abstract term in EMBASE: “prevalence”, “incidence”, “musculoskeletal disorder”, “musculoskeletal injury”, “musculoskeletal pain”, “extremity”, “limb”, “children”, “adolescents”, “paediatric”. As free text/abstract term “toddlers” and “teenager” were searched as well. Different forms of spelling and synonyms were used. The full search strategy is seen in Additional file 1. In addition, the reference lists of the relevant obtained articles were screened for additional relevant articles.
Inclusion criteria
The article had to report the prevalence or incidence of musculoskeletal disorders, complaints, injuries, pain or other description of complaints in the upper and/or lower extremities in general or clinical populations of children and adolescents. All levels of prevalence and incidence rates were included, and could be both parental reported or self-reported values. All study designs were included, but they had to be published in English, Swedish, Norwegian or Danish.
Exclusion criteria
Special settings or groups, e.g. children with other diseases such as diabetes or other chronic diseases, or children from a specific sport setting (e.g. football players) were excluded, because their pattern of injuries might not be comparable to rest of the population.
Selection of studies
The first and third author (SF and LH) reviewed the titles and abstracts and identified relevant articles to be read in full text. Inclusion of articles based on full text was decided by agreement between the first and third author (SF and LH).
Assessment of quality
We were not aware of quality assessment tools specifically designed for studies of prevalence and/or incidence, since most quality assessment tools are designed for studies of associations or comparative effectiveness in either observational studies [20–23] or randomised clinical trials [24]. Therefore the quality of the included articles was assessed by a modified version of the Quality In Prognosis Studies (QUIPS) tool (Additional file 2), which was originally developed to assess bias in studies of prognostic factors [25]. This tool identifies six domains to consider when evaluating risk of bias in studies of prognostic factors: ‘Study Participation’, ‘Study Attrition’, ‘Prognostic Factor Measurement’, ‘Outcome Measurement’, ‘Study Confounding’ and ‘Statistically Analysis and Reporting’ [25]. Three of these domains: ‘Study Participation’, ‘Outcome Measurement’ and ‘Statistical Analysis and Reporting’ were considered to be important, relevant and adequate for studies investigating prevalence, whereas the attrition domain was also included for studies investigating incidence, due to the main interest in relation to representativeness of the population of interest and the validity of the outcome measurement. In the ‘Statistical Analysis and Reporting’ domain, the items “strategy for model building is appropriate and is based on a conceptual framework or model” and “the selected statistical model is adequate for the design of the study” were not relevant and therefore ignored in the assessment. ‘Study Attrition’ is irrelevant for cross-sectional studies of prevalence and was therefore not included in the assessment of these studies, and ‘Prognostic Factors Measurement’ and ‘Study Confounding’ were not relevant either, since our results did not include analyses of prognosis or associations. The domains are described in detail by Hayden et al. [25].
Each of the three (four) domains was categorized as “yes”, “partly” or “no” according to whether the level of quality was adequately fullfilled or not. In evaluation of risk of bias in studies of prevalence and incidence, the most important parameter to consider is whether the study sample is representative of the source population, thus leaving ‘Study Participation’ and ‘Study Attrition‘ the most important domains in this review. This is supported by ‘Study Participation’ being the most frequently used parameter across different tools of evaluation of quality and susceptibility to bias in observational studies [26]. Therefore, ‘Study Participation’ and ‘Study Attrition‘ (if included) needed to be considered as satisfactory (“yes”) for the study to be classified in the low risk of bias category. Furthermore, the other two domains had to be at least partly fulfilled. If ‘Study Participation’ and ‘Study Attrition’ (if included) was not considered satisfactory (“no”) the study was categorized as high risk of bias, regardless the judgements in the other domains. If ‘Study Participation’ and ‘Study Attrition’ (if included) was only partly fulfilled and both the other domains were not fulfilled, the study was classified as high risk as well. All other combinations were considered to be medium risk of bias.
Data extraction
The studies were divided into general population studies and clinical population studies. Data were extracted to a descriptive table, a modified version of the STROBE statement [27]. The following relevant items from the STROBE Statement were included in the table: study design, setting, age, study size including response rates, data sources/types of measurement, area of complaint and main results. In addition, type of prevalence or incidence, mode of data acquisition and the level of bias were added to the table.
Review process
Data extraction and assessment of quality were individually performed by two authors (SF and KBD) and results compared. In case of disagreement, the third author (LH) was consulted and consensus reached. The review was conducted according to the PRISMA guidelines, and the PRISMA checklist can be seen in Additional file 3.
Analyses
General population and clinical population studies
Obviously, clinical populations cannot be used to assess prevalence of disease. However, they can be used to identify the type of complaints, for which care is sought. Therefore both general population studies and clinical population studies were included in the review, but data were reported separately.
Follow-up studies considered as two cross-sectional studies
Some of the general population studies had a longitudinal design. Due to the focus on prevalence and incidence rates, these studies were considered as series of cross-sectional studies and each time point reported separately. If the study included any type of intervention, only baseline estimates were reported.
Data evaluated in relation to age
It is known that the prevalence of MEC change with age [28]. Therefore, to give the most relevant description, results were reported by age groups. Cut points between age groups were based on reporting in the included articles.
Prevalence and incidence of MEC reported by anatomical site
In the general population studies the use of self-reported questionnaires by children and parents did not make it possible to report specific diagnoses, and therefore the results in this review were simply reported by anatomic site. Wrist, hand and fingers were combined into one anatomic site called “wrist/hand/fingers”, and likewise for the ankle and foot, called “ankle/ft”.
To make the reported findings comparable to the general population studies, the diagnoses found in the clinical population studies were converted into similar anatomical sites.
Distribution of non-traumatic versus traumatic complaints
Where possible, the difference between rates of non-traumatic and traumatic complaints was reported.
Distribution of lower extremity complaints versus upper extremity complaints
Some of the studies reported combined prevalence or incidence rates of the complete upper or lower extremity regions. To identify a possible pattern in distribution of MEC, ratios between the prevalence or incidence rates of the upper and lower extremities were calculated.
Results
In total, 2660 titles were found in MEDLINE, EMBASE and by reference searches. After checking for duplicates and screening of titles and abstracts, 29 articles were found assessable for full-text review. Seven of these were subsequently excluded because results were not representative of the general population [16, 29–32], or because classification into anatomic region or site was not possible [33, 34], thus 22 studies were included in the final analyses (Fig. 1).
Assessment of quality
The quality assessment categorized fourteen articles to have low risk of bias [14, 15, 35–46], two to have medium risk of bias [47, 48] and six as having high risk of bias [49–54] (Table 1). The clinical population studies were all in the low risk category. There was no disagreement in the independent quality assessments by the two authors (SF and KBD) regarding most of the articles, with the exception of two instances [47, 50] within the ‘study participation’ domain which were solved through discussion without need of mediation by the third author.
Table 1.
Author and year of publication | Study Participation | Study Attrition | Outcome Measurement | Statistical Analysis and Reporting | Risk of bias assessment |
---|---|---|---|---|---|
General population studies | |||||
Abujam et al. 2014 [49] | No | N/A | Yes | Yes | High |
Adams et al. 2013 [35] | Yes | N/A | Yes | Yes | Low |
Auvinen et al. 2009 [50] | No | N/A | Partly | Yes | High |
Bishop et al. 2012 [51] | No | N/A | Yes | Yes | High |
Diepenmaat et al. 2006 [36] | Yes | N/A | Yes | Yes | Low |
Ehrmann Feldman et al. 2002 [37] | Yes | Yes | Partly | Yes | Low |
El-Metwally et al. 2006 [15] | Yes | N/A | Yes | Yes | Low |
Hoftun et al. 2011 [38] | Yes | N/A | Yes | Yes | Low |
Hulsegge et al. 2011 [47] | Partly | Yes | Partly | Yes | Medium |
Jespersen et al. 2014 [14] | Yes | Yes | Yes | Yes | Low |
Jespersen et al. 2015 [39] | Yes | N/A | Yes | Yes | Low |
Krul et al. 2009 [40] | Yes | N/A | Yes | Yes | Low |
Mikkelsson et al. 1997 [41] | Yes | N/A | Yes | Yes | Low |
Molgaard et al. 2011 [48] | Partly | N/A | Yes | Yes | Medium |
Rathleff et al. 2013 [42] | Yes | N/A | Yes | Yes | Low |
Shrier et al. 2001 [43] | Yes | Yes | Partly | Yes | Low |
Slowinska et al. 2015 [68] | No | N/A | Yes | Partly | High |
Smedbraten et al. 1998 [52] | No | N/A | Yes | Yes | High |
Verhagen et al. 2009 [54] | Yes | No | Yes | Yes | High |
Clinical studies | |||||
Bot et al. 2005 [44] | Yes | N/Aa | Yes | Partly | Low |
Henschke et al. 2014 [45] | Yes | N/Aa | Yes | Yes | Low |
Van der Waal et al. 2006 [46] | Yes | N/Aa | Yes | Yes | Low |
aAttrition bias may be present, but very small. If present, it will be on general practitioners level, and not on patient level
Description of included articles
The search resulted in 19 general population studies and three clinical population studies (Table 2). All the included studies covered children and adolescents of both sexes. Most of the studies were conducted in the northern part of Europe, but also other parts of the world were represented with three studies from North America [35, 43, 55], one from Australia [45] and one from India [49]. Of the 19 general population studies, seven were prospective, four with one follow up evaluation [37, 43, 50, 51], and three studies reporting incidence over time [14, 39, 54]. In most of the studies, data were collected via questionnaires, either self-reported or filled in by parents, but telephone interviews, mobile phone text messages and diagnoses from general practice were also used. The 22 studies used 14 different outcome measurements such as point prevalence, twelve month prevalence and incidence per 1000 exposure hours. Estimates are simply presented in the tables as they appear in the original articles because prevalence and incidence rates were reported in very different ways. For the same reason, meta-analysis was not possible, and even a reliable range of an estimate of frequency, i.e. incidence or prevalence, could not be presented either. However, the findings relating to differences in frequency between different age groups, between different anatomical sites and between different populations, are independent of the absolute prevalence or incidence rates and are therefore presented in detail. We attempted to report findings of younger children and older children separately, but due to different cut points in age between the studies, it was not possible to do this. Throughout most of the analyses, a division between younger children aged 0–12, and older children aged 10–19 was used, but to accommodate all studies, some results were reported for the following age groups: 0–9, 9–12, 10–19, 6–17 and 2–19. A summary of findings is presented in Tables 3, 4, 5 and 6.
Table 2.
Author and year of publication | Study Design | Setting | Age/ grade |
Measurements (how did they ask?) | Study Size | Baseline response rate | Follow up response rate | Prevalence/incidence | Type of complaints | Main result (text) | Bias |
---|---|---|---|---|---|---|---|---|---|---|---|
General population studies | |||||||||||
Abujam et al. 2014 | Cross-sectional | India School based | 6–17 yrs | Questionnaire filled in by children or parents if the child was less than 14 years | 2059 | ? | Lifetime prevalence | Heel/ Ankle pain or swelling |
N (%) 72 (3.5%) |
High | |
Adams et al. 2013 | Cross-sectional | US Cohort - Kaiser Permanente Southern California |
2–19 yrs | ICD-9 codes | 913,178 | 1 yrs. prevalence | Lower extremity Injuries or pain Upper extremity: Injuries or pain |
5.8% 5.1% |
Low | ||
Auvinen et al. 2009 | Prospective cohort | Finland 2-years Birth Cohort |
16–18 yrs | Self-reported questionnaire | 7344 | 7344/ 9215 (80%) |
2012/ 2969 (68%) |
6-month prevalence |
Shoulder pain Elbow pain Wrist pain Knee pain Ankle pain |
Prevalence % (N) F: female, M: male Age: 16 yrs. 18 yrs. F: 52 (506) 63 (616) M: 33 (253) 40 (307) F: 2 (22) 4 (35) M: 5 (37) 5 (37) F: 16 (156) 23 (219) M: 15 (114) 20 (150) F: 18 (178) 21 (201) M: 18 (141) 17 (129) F: 16 (150) 19 (179) M: 18 (142) 15 (116) |
High |
Bishop et al. 2012 | Prospective cohort | England Cohort -Avon Longitudinal Study of Parents and Children |
5–13 yrs | Questionnaire filled in by chief carer | 9380 | 9380/ 13,988 (67%) |
6502/ 13,988 (46%) |
Often prevalence |
Total replied, n(%) arms, n(%) leg(s), n(%) Total replied, n(%) arms, n(%) leg(s), n(%) Total replied, n(%) arms, n(%) leg(s), n(%) |
Age 5* Age 6* 9380 (100.0) 8599 (100.0) 13 + 227 = 240 (2.6) 14 + 299 = 313 (3.6) 1142 + 227 = 1369 (14.6) 1204 + 299 = 1503 (17.5) Age 7* Age 8* 8325 (100.0) 7872 (100.0) 10 + 333 = 343 (4.1) 13 + 475 = 488 (6.2) 1226 + 333 = 1559 (18.7) 1188 + 475 = 1663 (21.1) Age 11* Age 13*6996 (100.0) 6502 (100,0) 22 + 635 = 657 (9.4) 33 + 730 = 763 (11.7) 1386 + 635 = 2021 (28.9) 1342 + 730 = 2072 (31.9) |
High |
Diepenmaat et al. 2006 | Cross-sectional | Holland School based questionnaire |
12–16 yrs | Self-reported questionnaire | 3485 | 3485/ 4898 (71%) |
Monthly prevalence, pain lasting a day or longer | Arm pain | Male: 4.2% Female: 3.6% |
Low | |
Ehrmann Feldman et al. 2002 | Prospective cohort | Canada High school based | 7.-9. grade | Self-reported questionnaire | 810 | 810/ 948 (85%) |
502/ 810 (62%) |
6 months and 12 months Incidence | Upper limb Arm Shoulder |
6 monthsb 12 monthsb
19.9% 13.3% 9% 7% 8% 5% |
Low |
El-Metwally et al. 2006 | Cross-sectional | Finland 2-years Birth Cohort |
9–11 yrs | Self-reported questionnaire | 1756 | 1756/ 1823 (96%) |
Weekly prevalence, within the last 3 months | Prevalence N(%) Lower limb pain Ankle-foot pain Knee pain Thigh pain Leg pain Hip pain |
Traumatic Non-traumatic Both groups 105 (6.0) 216 (12.3) 321 (18.3) 32 (1.8) 154 (8.8) 186 (10.6) 37 (2.1) 181 (10.3) 218 (12.4) 15 (0.9) 166 (9.5) 181 (10.3) 30 (1.7) 89 (5.1) 119 (6.8) 13 (0.7) 47 (2.7) 60 (3.4) |
Low | |
Hoftun et al. 2011 | Cross-sectional | Norway Health Study |
13–18 yrs | Self-reported questionnaire | 7373 | 7373/ 7913 (93%) |
Weekly prevalence, within the last 3 months | Upper extremity Lower extremity |
13–15 yrs. (n % 95% CI): 16–18 yrs. (n % 95% CI): 163 4.0 (3.4–4.6) 129 3.9 (3.3–4.6) 522 12.8 (11.8–13.8) 282 8.6 (7.6–9.6) |
Low | |
Hulsegge et al. 2011 | Cross-sectional | Holland Cohort of pregnant women - Prevention and Incidence of Asthma and Mite Allergy |
11 yrs | Questionnaire answered by parents and child |
2638 | 2638/ 3963 = (67%) |
1-year prevalence | Upper extremity Lower extremity |
4,8% (Boys: 3.1%, girls: 6.3%) 10,9% (Boys: 10.4%, Girls: 11.2%) |
Medium | |
J espersen et al. 2014 | Prospective | Denmark School based cohort - Childhood Health, Activity and Motor Performance School Study |
6–12 yrs | Repeated text messages and ICD-10 diagnosis given by clinicians |
1259 | 90% for sports schools 71% for normal schools |
Weekly mean incidence Weekly mean prevalence |
Upper extremity Lower extremity Upper extremity Lower extremity |
Injury: 0.2 (± 4.0) Overuse injury: 0.04 (± 2.0) Traumatic injury: 0.1 (± 3.5) Injury: 1.0 (± 9.7) Overuse injury: 0.7 (± 8.2) Traumatic injury: 0.3 (± 5.2) Injury: 0.5 (± 7.2) Overuse injury: 0.2 (± 4.9) Traumatic injury: 0.3 (± 5.8) Injury: 4.1 (± 19.9) Overuse injury: 3.2 (± 17.7) Traumatic injury: 1.1 (± 10.4) |
Low | |
Jespersen et al. 2015 | Prospective | Denmark School based cohort - Childhood Health, Activity and Motor Performance School Study |
6–12 yrs | Repeated text messages and ICD-10 diagnosis given by clinicians |
1259 | 90% for sportsschools 71% for normal schools |
Incidence Rate | Shoulder/ Upper Arm Elbow/under Arm Hand/wrist Finger Hip/Groin Thigh Knee Lower leg Achilles Heel Ankle Foot |
Overuse Traumatic0.03 (0.02–0.05) 0.03 (0.02–0.04) 0.01 (0.00–0.02) 0.02 (0.01–0.03)0.01 (0.00–0.01) 0.08 (0.06–0.10)0.00 (0.00–0.01) 0.05 (0.03–0.07)0.05 (0.04–0.07) 0.01 (0.00–0.01)0.04 (0.03–0.06) 0.03 (0.02–0.04)0.31 (0.27–0.35) 0.09 (0.07–0.11)0.05 (0.03–0.06) 0.01 (0.00–0.02) 0.06 (0.04–0.08) 0.000.36 (0.31–0.4) 0.000.01 (0.00–0.01) 0.18 (0.15–0.21)0.09 (0.07–0.11) 0.07 (0.05–0.09) |
Low | |
Krul et al. 2009 | Cross-sectional | Holland -Second Dutch National Survey in generel practice | 2–17 yrs | Interview aboutself-reported musculoskeletal symptoms. In children younger than 12 years interview was carried out with a parent. | 2459 | 2459/ 2719 (90%) |
2 weeks prevalence | Upper extremity All ages 2–11 y 12–17 y Lower extremity All ages 2–11 y 12–17 y Hip and knee All ages 2–11 y 12–17 y Ankle and foot All ages 2–11 y 12–17 y |
% (n) 1.2 (26) 0.4 (5) 2.7 (21) 6.9 (147) 4.1 (57) 12.4 (90) 3.5 (75) 1.8 (25) 6.5 (50) 3.4 (72) 2.4 (32) 5.5 (40) |
Low | |
Mikkelssona et al. 1997 | Cross-sectional | Finland -School based cohort | 3.-5. grade | Self-reported questionnaire | 1756 | 1756/ 2141 (82%) |
1628/ 1756 (92%) |
Weekly prevalence Relative frequency (%) with 95% CI | Upper extremity Lower extremity |
Boys: 7 (6–9)b
Girls: 5.5 (4–7)b Boys: 19 (16–22)b Girls: 18 (15–20)b |
Low |
Molgaard et al. 2011 | Single-blind case control (case-cohort) | Denmark High School based |
16–18 yrs | Self-reported questionnaire | 299 | 227/ 299 (76%) |
Monthly-prevalence | Non-traumatic knee pain | 57/227 = (25%) | Medium | |
Rathleff et al. 2013 | Cross-sectional | Denmark – Cohort - Adolescent Pain in Aalborg 2011, |
12–19 yrs | Self-reported questionnaire | 4007 | 2953/ 4007 (73%) |
Point prevalence | Knee Shoulder Foot Shin Hip/groin Forearm/hand Thigh Elbow |
Any frequency: 32.3 (30.6–34.0) 13.3 (12.1–14.5) 11.5 (10.4–12.7) 6.2 (5.4–7.1) 5.9 (5.0–6.7) 4.4 (3.7–5.1) 2.7 (2.2–3.2) 2.6 (2.1–3.2) |
Low | |
Shrier et al. 2001 | Prospective cohort | Canada High School based |
12–18 yrs | Self-reported questionnaire | 810 | 810/948 (85%) | 502/810 (62%) | Incidence 6 months 12 months (once a week the last 6 months) |
Lower extremity Foot/ankle Knee Leg Hip |
6 monthsb 12 monthsb
% % 21 16 14 8 13 11 11 6 7 4 |
Low |
Smedbraten et al. 1998 | Cross-sectional | Norway School based |
10–15 yrs | Self-reported questionnaire | 569 | 569/661 (86%) |
Prevalence Usually pain |
Shoulder Elbow Hand Hip Knee Ankle Foot |
Boys (n = 282) Girls (n = 287) % % 6 14 4 4 5 7 5 7 32 29 7 12 8 11 |
High | |
Slowinska et al. 2015 | Cross-sectional | Poland School based |
6–7 yrs | Questionnaire filled in by parents | 1509 | 1509/ 2748 (55%) |
Prevalence often |
Knee Hands |
Often 11% 3% |
High | |
Verhagen et al. 2009 | Prospective cohort | Holland school based (iplay study) |
10–12 yrs | Injuries during physical activity monitored by teachers |
996/ (996 + 95) (91%) |
Incidence Rate | Shoulder Upper arm/elbow Lower arm/wrist/hand Upper leg/hip Knee Lower leg/ankle Foot |
0.03 × 0.48 = 0.01c
0.03 × 0.48 = 0.01c 0.22 × 0.48 = 0.11c 0.06 × 0.48 = 0.03c 0.11 × 0.48 = 0.05c 0.25 × 0.48 = 0.12c 0.15 × 0.48 = 0.07c |
High | ||
Clinical population studies | |||||||||||
Bot et al. 2005 | Cross-sectional | Holland Second Dutch National Servey of generel practice | 0–19 yrs | ICPC codes | 375,899(all ages) | Incidence per 1000 person years | L08 Shoulder complaint L09 Arm complaint L10 Elbow complaint L11 wrist complaint L12 Hand/finger complaint L92 Shoulder syndrome |
Age group (years) Sex 0–9 (95% CI) 10–19 (95% CI) M: 0.6 (0.3–0.9) M: 4.0 (3.2–4.9) F: 0.7 (0.4–1.1) F: 4.8 (3.9–5.7) M: 2.0 (1.4–2.6) M:2.3 (1.7–3.0) F:2.3 (1.7–2.9) F: 2.8 (2.1–3.5) M: 1.3 (0.9–1.8) M: 2.3 (1.7–3.0) F: 1.7 (1.2–2.3) F: 1.9 (1.3–2.4) M: 1.8 (1.3–2.4) M: 6.3 (5.3–7.4) F: 2.1 (1.5–2.7) F: 7.9 (6.8–9.1) M: 5.0 (4.1–5.9) M: 8.7 (7.5–9.8) F: 3.9 (3.1–4.7) F: 9.1 (7.8–10.3) M: 0.1 (0.0–0.3) M: 1.4 (0.9–1.9) F: 0.0 ((0.0–0.1) F: 1.9 (1.3–2.4) |
Low | ||
Henschke et al. 2014 | Cross-sectional | Australia national study in general practice – Bettering the Evaluation and Care of Health |
5–17 yrs | ICPC-2 codes | 65,279 encounters | Management rate per 100 encounters (encs.) | Lower Limb Upper Limb Lower Limb Upper Limb Lower Limb Upper Limb |
Age: 5–9 Boys Girls Number 118121 Rate/100 encs. 1.72 1.85 (95% CI) (1.39–2.06) (1.51–2.19) Number 89 90 Rate/100 encs. 1.30 1.38 (95% CI) (1.02–1.58) (1.09–1.66) Age: 10–14 Boys Girls Number 311254 Rate/100 encs 5.33 4.40 (95% CI) (4.72–5.95) (3.85–4.96) Number 257188 Rate/100 encs 4.41 3.26 (95% CI) (3.85–4.97) (2.76–3.76) Age: 15–17 Boys Girls Number 169134 Rate/100 encs 4.55 2.26 (95% CI) (3.84–5.26) (1.87–2.65) Number 169 82 Rate/100 encs. 4.55 1.38 (95% CI) (3.83–5.27) (1.08–1.69) |
Low | ||
van der Waal et al. 2006 | Cross-sectional | Holland Second Dutch National Servey of generel practice |
0–19 yrs | ICPC codes | 375,899(all ages) | Incidence per 1000 person years | L13 Hip complaints L14 Leg/thigh complaints L15 Knee complaints L16 Ankle complaints L17 Foot/toe complaints L77 sprain of ankle/ft L78 sprain/strain of knees Acute meniscus/ligament knee L97 Chronic int knee derangement |
Age group (years) 0–9 (95% CI) 10–19 (95% CI) M: 4.0 (3.2–4.8) M: 2.1 (1.5–2.7) F: 4.9 (3.9–5.8) F: 2.2 (1.6–2.8) M: 4.1 (3.3–4.9) M: 5.1 (4.2–6.0) F: 4.2 (3.4–5.1) F: 4.3 (3.4–5.1) M: 3.6 (2.8–4.3) M: 17.0 (15.3–18.6) F: 2.7 (2.1–3-4) F: 16.7 (15.0–18.3) M: 2.4 (1.8–3.0) M: 5.3 (4.4–6.2) F: 1.9 (1.3–2.5) F: 5.0 (4.1–5.9) M: 9.2 (8.0–10.4) M: 16.2 (14.6–17.8) F: 8.5 (7.2–9.7) F: 14.3 (12.7–15.8) M: 3.6 (2.8–4.3) M: 15.4 (13.8–17.0) F: 3.8 (3.0–4.6) F: 16.4 (14.7–18.0) M: 0.9 (0.54–1.33) F: 6.0 (5.0–7.0) F: 0.4 (0.1–0.7) F: 3.7 (2.9–4.5) M: 0.1 (−0.03–0.2) F: 1.2 (0.8–1.7) F: 0 F: 0.8 (0.5–1.2) M: 0.4 (0.1–0.6) F: 4.3 (3.4–5.1) F: 0.6 (0.3–0.9) F: 7.0 (5.9–8.1) |
Low |
ICD-10: International Classification of Diseases – 10
ICPC: International Classification of Primary Care
a Only baseline were reported
b percentages taken from Fig. 1 in the original article
c percentage taken from Fig. 1 in the original article times the total incidence rate per 1000 exposure hours (0.48)
Table 3.
0–9 years of age | 9–12 years of age | 2–19 years of age | |||||||
---|---|---|---|---|---|---|---|---|---|
Incidence | Prevalence, % | Incidence | Prevalence, % | Prevalence, % | |||||
Anatomic Region/ Site | Weekly, % | IRa | Often | Weekly | 12 months | IRa | 2 weeks | Weekly | 12 months |
Upper extremity in general |
0.2 [14] | 2.6–6.2 [51] | 0.5 [14] | 4.8 [47] | 0.4 [40] | 5.5–7 [41] | 5.1 [35] | ||
Shoulder | 0.06 [39] | 0.01 [54] | |||||||
Elbow | 0.03 [39] | 0.01 [54] | |||||||
Wrist/hand/fingers | 0.14 [39] | 3 [53] | 0.11 [54]b | ||||||
Lower extremity in general |
1.0 [14] | 14.6–21.1 [51] | 4.1 [14] | 10.9 [47] | 4.1 [40] | 18.3 [15]18–19 [41] | 5.8 [35] | ||
Hip/groin | 0.06 [39] | 0.03 [54] | 3.4 [15] | ||||||
Thigh | 0.07 [39] | 10.3 [15] | |||||||
Knee | 0.40 [39] | 11 [53] | 0.05 [54] | 1.8 [40]c | 12.4 [15] | ||||
Shin | 0.12 [39] | ||||||||
Ankle/ft | 0.71 [39] | 0.19 [54]d | 2.4 [40] | 10.6 [15] |
[x]: reference number of included study
Bold: the study received high risk of bias in the quality assessment
a Incidence Rate per 1000 physical activity units
b Anatomical site relates to both lower arm, wrist, hand and fingers
c Anatomical site relates to both hip and knee
d Anatomical site relates to both shin and ankle/ft
Table 4.
10–19 years of age | 6–17 years of age | ||||||||
---|---|---|---|---|---|---|---|---|---|
Incidence, % | Prevalence, % | Prevalence, % | |||||||
Anatomic Region/Site | 6 months | 12 months | Point | Often/ usually |
Weekly | 2 weeks | Monthly | 6 months | Lifetime |
Upper extremity in general |
19.9 [37] | 13.3 [37] | 9.4–11.7 [51] | 3.9–4.0 [38] | 2.7 [40] | 3.6–4.2 [36] | |||
Shoulder | 8 [37] | 5 [37] | 13.3 [42] | 6–14 [52] | 33–63 [50] | ||||
Arm | 9 [37] | 7 [37] | |||||||
Elbow | 2.6 [42] | 4 [52] | 2–5 [50] | ||||||
Wrist/hand/fingers | 4.4 [42] | 5–7 [52] | 15–23 [50] | ||||||
Lower extremity in general |
21 [43] | 16 [43] | 28.9–31.9 [51] | 8.6–12.8 [38] | 12.4 [40] | ||||
Hip/groin | 7 [43] | 4 [43] | 5.9 [42] | 5–7 [52] | |||||
Thigh | 2.7 [42] | ||||||||
Knee | 13 [43] | 11 [43] | 32.3 [42] | 29–32 [52] | 6.5 [40]a | 25 [48] | 17–21 [50] | ||
Shin | 6.2 [42] | ||||||||
Ankle/ft | 14 [43] | 8 [43] | 11.5 [42] | 7–12 [52] | 5.5 [40] | 15–19 [50] | 3.5 [49] |
[x]: reference number of included study
Bold: the study received high risk of bias in the quality assessment
a Anatomical site is relates to both hip and knee
Table 5.
0–9 years of age | 10–19 years of age | |||
---|---|---|---|---|
Incidence, % | Incidence, % | |||
Anatomic Region/Site | Per 1000 person years | Management rate per 100 encountersa | Per 1000 person years | Management rate per 100 encountersa |
Upper extremity in general | 1.30–1.38 [45] | 1.38–4.55 [45] | ||
Shoulder | 0.0–0.7 [44] | 1.4–4.8 [44] | ||
Arm | 2.0–2.3 [44] | 2.3–2.8 [44] | ||
Elbow | 1.3–1.7 [44] | 1.9–2.3 [44] | ||
Wrist/hand/finger | 1.8–5.0 [44] | 6.3–9.1 [44] | ||
Lower extremity in general | 1.72–1.85 [45] | 2.26–5.33 [45] | ||
Hip/groin | 4.0–4.9 [46] | 2.1–2.2 [46] | ||
Thigh | 4.1–4.2 [46] | 4.3–5.1 [46] | ||
Knee | 0.0–3.6 [46] | 0.8–17.0 [46] | ||
Ankle/ft | 1.9–9.2 [46] | 5.0–16.2 [46] |
[x]: reference number of included study
a Management rate per 100 encounters: diagnoses recorded at general practitioners per 100 consecutive encounters
Table 6.
Anatomic Region/Site | Non-traumatic | Traumatic | Ratio Non-traumatic: Traumatic |
---|---|---|---|
Upper extremity in general | 0.04 [14]a
0.2 [14]b |
0.1 [14]a
0.3 [14]b |
1:2.5 1:1.5 |
Shoulder | 0.03 [39]c | 0.03 [39]c | 1:1 |
Elbow | 0.01 [39]c | 0.02 [39]c | 1:2 |
Hand/wrist/fingers | 0.01 [39]c | 0.13 [39]c | 1:13 |
Lower extremity in general | 12.3 [15]b
0.7 [14]a 3.2 [14]b |
6.0 [15]b
0.3 [14]a 1.1 [14]b |
1:0.5 1:0.4 1:0.3 |
Hip | 2.7 [15]b
0.05 [39]c |
0.7 [15]b
0.01 [39]c |
1:0.3 1:0.2 |
Thigh | 9.5 [15]b
0.04 [39]c |
0.9 [15]b
0.03 [39]c |
1:0.1 1:0.8 |
Knee | 10.3 [15]b
0.31 [39]c |
2.1 [15]b
0.09 [39]c |
1:0.2 1:0.3 |
Shin | 0.11 [39]c | 0.01 [39]c | 1:0.01 |
Ankle/Foot | 8.8 [15]b
0.46 [39]c |
1.8 [15]b
0.25 [39]c |
1:0.2 1:0.5 |
[x]: reference number of included study
a weekly incidence
b weekly prevalence
c Incidence Rate - per 1000 physical activity units
General population studies
In both the younger (aged 0–12) and the older children (aged 10–19), lower extremity complaints were more common than upper extremity complaints, and ankle/ft and knee were the most frequent sites of MEC. Among the younger children, two studies reported ankle/ft complaints to be about twice as frequent as knee complaints [39, 54], whereas the last study reported almost similar prevalence rates for the two sites [15] (Table 3). Among the older children, five of the six included studies reported 0.2 to 2.8 times more knee complaints than ankle/ft complaints [40, 42, 43, 50, 52] (Table 4). In the upper extremities, wrist/hand/fingers was the most common site of complaint in younger children [39, 54] (Table 3), whereas shoulder complaints were more common among older children [42, 50, 52] (Table 4). The least frequent anatomical site of complaint reported in both younger and older children was the elbow (Tables 3 and 4).
Clinical population studies
Also in the clinical population studies, lower extremity complaints were more frequent than complaints from the upper extremities [44–46]. Two of the three clinical population studies were based on data from the same cohort of children, but one reported on upper extremities [44] and the other on lower [46]. In the younger children the incidence rate of ankle/ft complaints was about three times higher than for the knee, whereas the incidence rates were almost equal for the two pain sites in the older children [46]. In the upper extremity, wrist/hand/fingers was the most common site in both age groups [44]. The least frequent site of complaint was the shoulder in the younger group, and shoulder and hip/groin in the older age group (Table 5).
Traumatic versus non-traumatic complaints
In the younger children, three of the general population studies classified the complaints of the lower extremities into traumatic or non-traumatic mode of onset [14, 15, 39], but two of these were based on the same cohort of children [14, 39]. All three reported about two times more non-traumatic complaints compared to traumatic complaints (1:0.5 [15], 1:0.3 and 1:0.4 [14], respectively). One of the studies also reported mode of onset in upper extremities and found the opposite relationship, with non-traumatic complaints less frequently reported than traumatic complaints (1:1.5 and 1:2.5, for prevalence and incidence respectively) [14] (Table 6). There were no reports of mode of onset in other studies, neither in the older age group nor in the clinical population studies.
General population studies versus clinical population studies
Comparing lower and upper extremities in general, MEC were reported up to ten times more often from the lower than from the upper extremities (mean ratio 1:4.0; range 1:1.1 to 1:10.3) in the general population studies (Tables 3 and 4), whereas the difference was much smaller in the clinical population studies with ratios from 1:1.2 to 1:1.6 (mean 1:1.4) (Table 5). In the general population studies, the difference was more significant in the younger children (mean ratio 1:5.1; range 1:2.3 to 1:10.3) than in the older children (mean ratio 1:2.5; range 1:1.1 to 1:4.6).
Consequences of quality
No pattern of differences in reporting could be detected between studies of high and low risk of bias.
Discussion
In the general population studies, ankle/ft and knee were the most frequently reported anatomical complaint sites. We found relatively more ankle/ft complaints in the younger children and more knee complaints in the older age group, and this pattern has to our knowledge not been reported before. The dominance of ankle/ft and knee complaints was similar to what was found in a review of sports-related injuries in children and adolescents [11] indicating either that many of these complaints often are related to sport, or that sports participation actually reveals otherwise unnoticed injuries. A possible explanation for the changing complaint pattern with age could be the development of the musculoskeletal system due to pubertal growth including a general rapid physical growth [56]. One consequence of this could be that the calcaneal growth plate is stressed by the Achilles tendon (Sever’s disease) in younger children whereas, when the child matures, the growth of the immature skeleton more commonly leads to apophysitis around the anterior knee located to the tibial tubercle or the inferior patellar pool, leading to more knee complaints in older child. Another shift with age was the relatively high occurrence of shoulder complaints in older children, whereas this was very rare in younger children. One explanation could be that teenagers in general spend more time in front of desktops or tablets, which might lead to posture related pain especially in the neck/shoulder region [57]. Whether these complaints actually relate to the shoulder joint or whether it is more related to the upper spine or the trapezius muscle is uncertain. It might be difficult for children and adolescents to distinguish between those two sources of pain, and it has been documented previously that neck and back pain increase with age during adolescence [4, 58]. If that is the case, the self-reported shoulder complaints are overestimated. To gain more reliable knowledge in this area, detailed questionnaires, including mannequin drawings, or interviews should be used in future studies.
In the clinical population studies, a similar pattern was seen for the lower extremities, but wrist/hand/fingers was the second most frequently reported site among young children, and the third most frequent in the older age group. However, this was based on only one study [44], albeit of high quality. In a review of fractures, Clark et al. also reported this area (the distal radius, fingers and carpal bones) to be the most common [16], indicating a certain susceptibility to both severe and more trivial injuries in the hand and wrist.
We found that lower extremity complaints were much more common than upper extremity complaints in the general population studies, whereas the clinical population studies showed a smaller difference in frequency between the two regions. Furthermore, the three studies reporting mode of onset, reported twice as many non-traumatic compared to traumatic complaints in the lower extremities. These two findings might indicate an overrepresentation of less severe complaints and/or more non-traumatic complaints in the lower extremities. In sports medicine, data collection traditionally has been based on diagnoses from emergency departments or among athletes requiring medical attention or time-loss definitions, and therefore reports of minor complaints have not been collected [59, 60]. In 1989, Backx et al. found that only 31% of all sports injuries led to health care usage [61], e.g. were serious enough to warrant consultation.
Recently Clarsen et al. developed a new tool to register overuse injuries in sport and compared it to the traditional time-loss registration of injuries. They found a completely different pattern of injuries in sport with especially more shoulder, knee and low back injuries [62], which support the thesis that some shoulder and knee complaints do not reach the threshold for health care consultation. In relation to reports of shoulder complaints, we also noted that prevalence rates were relatively high compared to incidence rates, which might indicate that these complaints are more long-lasting than other complaints which have smaller differences between prevalence and incidence rates. However, it could also be due to the misclassification mentioned earlier and actually relate to the neck or Trapezius area.
Most of the studies were conducted in the northern part of Europe and different patterns of complaints could possibly be present in other parts of the world. The type of injury might be related to the prevalent type of sport, and obviously there are large geographical differences in sport activities. Likewise, the threshold for reporting pain and the pattern of health care consumption are strongly culturally dependent, and therefore caution should be exercised when extrapolating results to other parts of the world.
The largest challenge of this review was the heterogeneity of outcomes; pooling of results to obtain reliable combined estimates of prevalence and incidence was impossible to conduct. The included 22 articles in this review used 14 different outcome measures, and this prevented meaningful combined estimates of prevalence or incidence.
The variation in outcome measurement and lack of knowledge in this area, also made it difficult to assess the risk of bias in the ‘Outcome measurement’ domain, which might have resulted in a too positive bias rating. Although the QUIPS tool has been validated [25] the modified version tool used in this review has not, which might be considered as a limitation of this review. Finally, it would have been appropriate to repeat the literature search in other databases. However, it is our experience that epidemiological articles can be found in the two databases that were used, MEDLINE and EMBASE, and therefore we do believe that the performed literature search can be justified, although we realize that potential relevant articles can have be missed.
Another issue in relation to heterogeneity is that there are challenges with use of questionnaires within this age group. In seven of the 19 general population studies, questionnaires or text messages were answered by parents [14, 39, 40, 47, 49, 51, 53]. Therefore, the concordance between parents’ and children’s reporting is important to understand. In general, agreement between children and parents is poor, especially in relation to minor complaints, whereas more severe complaints result in a better agreement [63–65]. Another potential problem is that the questionnaires have rarely been validated in the appropriate age groups, and finally the risk of recall bias might differ between children and adults. Harel et al. evaluated recall periods of 2 weeks to 12 months in children and adolescents in the US and found that reporting of severe injuries are not strongly affected by recall bias [66]. Another study by Moshiro et al., with a recall period of twelve months, found the same in an all-age cohort from Tanzania [67]. On the other hand, Harel et al. also concluded that reporting of minor complaints are affected by memory, especially if the recall period exceeds five months [66]. This indicates that to collect reliable estimates of minor symptoms the recall period needs to be relatively short. On this note, severity of complaint also needs to be considered, and this was often not the case in the included studies. In four of the 19 general population studies, participants were asked to categorize the complaints according to either severity or frequency, e.g. if the complaint was experienced never, once a month or once a week [15, 38, 41, 42], and in three other studies, consulting a physician was used as a measure of severity [47, 50, 54], but in the remaining studies no severity measures were reported.
Thus, in future studies data should be collected in a standardized way with due consideration to demarcation of the area, the parent/child reporting relationship, the severity and the frequency of pain. It became apparent during this review, that there is a strong need for better and more homogenous data collection methods. We therefore think it is time to make an effort to standardize future studies in relation to data collection with due to consideration to demarcation of the area, the severity and frequency of pain, and the parent/child reporting relationship. Furthermore, common age group definitions should be agreed upon. This could for example be obtained through a Delphi process followed by a cross-cultural adaption of age-standardized questionnaires.
Fortunately, the profound heterogeneity did not affect the comparisons between anatomical sites, age groups etc. However, another difficulty encountered was that different terms of MEC complicated the literature search and therefore we are aware that there might be articles missing. Hopefully, the assistance of a research librarian and a wide search strategy has minimized the effect of this difficulty.
Conclusion
In general, ankle/ft and knee were the most frequent sites of musculoskeletal extremity complaints regardless of age and type of population. However, in the general population studies, there were relatively more non-traumatic complaints of the lower extremities than in the clinical population studies, indicating a large amount of non-traumatic low intensity complaints in the general population that do not reach threshold for consultation.
We intended to describe the prevalence and incidence of musculoskeletal extremity complaints in children and adolescents, but a meta-analysis, or even a simple overall description of prevalence and incidence, was not feasible, due to study heterogeneity, primarily related to outcome. Future research should use standardised and validated outcome measures and investigate the possible consequences of the low intensity complaints in large longitudinal cohorts to establish if there is a potential for prevention of long-term sequelae through early detection and intervention.
Additional files
Acknowledgements
We would like to acknowledge research librarians Johan Wallin and Majbritt Johansen for their help with the literature search.
Funding
Not applicable.
Availability of data and materials
Not applicable.
Abbreviation
- KBD
Kristina Boe Dissing
- LH
Lise Hestbæk
- MEC
Musculoskeletal extremity complaint
- QUIPS
Quality In Prognosis Studies
- SF
Signe Fuglkjær
Authors’ contributions
LH and SF conceived the study idea. SF, LH and KBD participated in the interpretation of the results and for the first draft of the manuscript. All authors read, revised and approved the final version of the manuscript.
Ethics approval
Not applicable.
Consent for publication
Not applicable.
Competing interests
The authors declare that they have no competing interests.
Publisher’s Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Footnotes
Electronic supplementary material
The online version of this article (10.1186/s12891-017-1771-2) contains supplementary material, which is available to authorized users.
Contributor Information
Signe Fuglkjær, Email: sfuglkjaer@health.sdu.dk.
Kristina Boe Dissing, Email: kbdissing@health.sdu.dk.
Lise Hestbæk, Email: l.hestbaek@nikkb.dk.
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