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Non-Surgical Interventions for Adolescents with Idiopathic Scoliosis: An Overview of Systematic Reviews

Abstract

Background

Non-surgical interventions for adolescents with idiopathic scoliosis remain highly controversial. Despite the publication of numerous reviews no explicit methodological evaluation of papers labeled as, or having a layout of, a systematic review, addressing this subject matter, is available.

Objectives

Analysis and comparison of the content, methodology, and evidence-base from systematic reviews regarding non-surgical interventions for adolescents with idiopathic scoliosis.

Design

Systematic overview of systematic reviews.

Methods

Articles meeting the minimal criteria for a systematic review, regarding any non-surgical intervention for adolescent idiopathic scoliosis, with any outcomes measured, were included. Multiple general and systematic review specific databases, guideline registries, reference lists and websites of institutions were searched. The AMSTAR tool was used to critically appraise the methodology, and the Oxford Centre for Evidence Based Medicine and the Joanna Briggs Institute’s hierarchies were applied to analyze the levels of evidence from included reviews.

Results

From 469 citations, twenty one papers were included for analysis. Five reviews assessed the effectiveness of scoliosis-specific exercise treatments, four assessed manual therapies, five evaluated bracing, four assessed different combinations of interventions, and one evaluated usual physical activity. Two reviews addressed the adverse effects of bracing. Two papers were high quality Cochrane reviews, Three were of moderate, and the remaining sixteen were of low or very low methodological quality. The level of evidence of these reviews ranged from 1 or 1+ to 4, and in some reviews, due to their low methodological quality and/or poor reporting, this could not be established.

Conclusions

Higher quality reviews indicate that generally there is insufficient evidence to make a judgment on whether non-surgical interventions in adolescent idiopathic scoliosis are effective. Papers labeled as systematic reviews need to be considered in terms of their methodological rigor; otherwise they may be mistakenly regarded as high quality sources of evidence.

Protocol registry number

CRD42013003538, PROSPERO

Introduction

Non-surgical interventions for the treatment of adolescents with idiopathic scoliosis in current practice today typically constitute a variety of physical modalities; these include braces, scoliosis-specific exercises as well as diverse physical therapy modalities such as manual therapy and electrical stimulation [1][5]. Other forms of non-surgical therapies reported in the literature include podiatric treatments such as heel lifts as well as different types of osteopathic and chiropractic interventions. Additionally, complementary and alternative interventions have also been reported [6][8]. Non-surgical interventions for adolescents with idiopathic scoliosis as a whole remains a contentious issue, with conflicting recommendations put forward from clinical research studies and as well as experts in the field. Interestingly authors have reported both very negative as well as very positive statements (Table 1).

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Table 1. Opinions regarding non-surgical interventions for adolescents with idiopathic scoliosis.

https://doi.org/10.1371/journal.pone.0110254.t001

The statements above reflect the clinical equipoise currently represented by surgeons, physicians, physical therapists and other health care professionals to the non-surgical treatment approaches of AIS, especially regarding scoliosis-specific exercise treatments (SSEs). These interventions, defined as “curve-specific movements performed with the therapeutic aim of reducing the deformity” [16], consist of individually adapted exercises that are taught to patients in a centre that is totally dedicated to scoliosis treatment. The patients learn an exercise protocol that is personalized according to medical and physiotherapeutic evaluations. SSEs have traditionally been used in continental Europe by different specialized scoliosis centers or “schools” [1], either as a sole treatment or supplementing orthotic brace treatment [17], [18]. Further as stated above, other types of non-surgical interventions reported in the literature include manual therapies [6], [7] different types of chiropractic and osteopathic interventions as well as numerous unorthodox complementary and alternative forms of treatments [8] have been applied to different patient groups in different contexts.

Physiotherapy interventions are typically not regarded as effective in Anglo-Saxon countries [1], [2], despite the fact that the evidence-base for the inefficacy of exercise treatments seems questionable [2]. Bracing meanwhile has been recommended as the standard treatment [1], [3], [19][21], despite a weak evidence-base being reported [4], [22] prior to the latest and very recent publication from a multicenter controlled trial [23]. The general recommendations on the non-surgical management of AIS [5], [10], [21] put forwards by the different scoliosis societies [3], [24], tend to contain conflicting information and generally do not distinguish between different approaches and types of braces, as well as between the use of rigid and soft braces [4], [25], [26]. The physiotherapists’ role is typically seen by surgeons and physicians as complementary to the multidisciplinary team that cares for braced patients [27]. Nonetheless, the interest in scoliosis-specific exercise interventions has in recent years become more widespread, with the availability of thematic issues within healthcare journals relevant to spinal conditions [28], [29], courses on the PT management of scoliosis becoming increasingly available as well as high profile RCTs currently being funded and conducted in the United Kingdom [30], Canada [31], and Sweden [32].

Why is this overview of systematic reviews needed?

In view of the existing prejudices and considerable variations in recommendations [3], [24] and opinions, both between and within different professional groups, especially with regards to the effectiveness of bracing, as opposed to the merits of SSE and other non-surgical forms of interventions, systematic reviews remain important sources of evidence for all engaged in AIS therapy.

In recent years two Cochrane reviews [16], [33] several other systematic reviews (SRs) (PEDro database indexed 17 SRs in April 2014) as well as papers labeled as “evidence-based” have been published (Tables S1 and S2). These have included the measurement of numerous outcome measures as well as different inclusion criteria and study designs, with each review reaching different conclusions. The effectiveness of non-surgical interventions for the treatment of adolescents with idiopathic scoliosis remains highly controversial with the evidence-base for informing service users, practitioners and stakeholders confusing and unclear.

Within the existing literature (with the exception of a few structured abstracts provided by the DARE database) the authors were unable to find any high quality methodological evaluations of published SRs. The latter were either accepted at face value [29], [34], [35] criticized without further explicit analyses [36], [37] or the results were discussed only in terms of the research designs of included studies [16], [33].

Even on initial reading of the available SRs it appeared that large and significant differences with regards to the way they were conducted i.e. their methodological quality were present. It is important to consider that not ALL papers labeled as “systematic” or “evidence-based” actually DO meet the criteria for a systematic review. These inconsistencies strongly suggested that a comprehensive and systematically undertaken methodological analysis of currently published systematic reviews addressing the non-surgical management of AIS was urgently needed and warranted.

Objectives

The primary objective of this study was to provide a comprehensive and systematic analysis of the scope, objectives, methodology and findings from published SRs regarding non-surgical interventions of AIS, through conducting an overview of systematic reviews.

The second objective was to establish, which papers currently labeled as “systematic reviews” or having the layout of a systematic review did NOT on further analysis meet the minimal criteria for a SR, and were in fact opinion based papers rather than well conducted secondary research studies.

Finally the third objective was to analyse and compare findings from different SRs addressing the same types of interventions, to enable judgments to be made regarding the evidence-base for their use within clinical practice.

Materials and Methods

This paper reports on a section of an overview of systematic reviews evaluating the effectiveness of non-surgical management for adolescent idiopathic scoliosis, including screening and treatment methods, and is registered at PROSPERO, CRD York, CRD42013003538 (Protocol S1).

The PRISMA statement for undertaking and reporting systematic reviews [38], [39] was followed. Further the proposal for the applicability of the PRISMA statement items for overviews of systematic reviews was consulted and adhered to [40].

Criteria for inclusion of systematic reviews

Study designs.

Systematic reviews were considered eligible if they included primary papers of any types of experimental and observational study designs. These liberal criteria were introduced in order to allow the authors to evaluate all published SRs addressing the subject matter.

Papers were reported as systematically developed reviews if they reported on methods to search, identify and select papers, and critically appraised relevant evidence [41]. If found, these minimal criteria were also applied to reviews of evidence, prepared for or reported in, systematically developed clinical practice guidelines and recommendations, on the condition that they were reported in full. Exclusion criteria were; reports from any types of primary studies, expert opinions, narrative reviews and other types of non-systematic reviews (e.g. critical reviews), letters to the editor and editorials. Systematic overviews of reviews were excluded from analysis, but included in the discussion.

Population.

The population included adolescents of both genders with AIS, diagnosed and managed between the ages of 10 to 18 years of age, with no restriction as to bone age (Risser sign). Curves of at least 11°, the borderline for the deformity to be diagnosed as scoliosis, measured on the A–P radiograph with the Cobb method, were eligible. All SRs addressing mild, moderate and/or severe AIS (11–24°, 25–44°, and 45°Cobb and greater, respectively) were included. Reviews on-early-onset (infantile or juvenile) scoliosis, as well as studies reporting on scoliosis secondary to other conditions, e.g. Duchenne dystrophy, cerebral palsy, spinal cord injury, neurofibromatosis were excluded.

Interventions.

Eligible SRs addressed non-surgical interventions applied as a sole treatment or as combinations of different non-surgical interventions, and included:

  1. braces of any type (both rigid and soft) and mode of application (any number of hours a day, or night-time),
  2. any approach (s), or “school” of scoliosis-specific exercise treatment of AIS, regardless of the severity of the deformity, both as a single intervention, or as part of a group of different complex interventions, e.g. supplementing brace treatment (add-on treatment), chiropractic, manual therapy, electrical stimulation or general conditioning (usual) exercises.
  3. SRs on any other non-surgical interventions were also considered.

Generalized and non-curve-specific exercises or other physiotherapeutic interventions administered to patients with AIS for other reasons, e.g. respiratory physiotherapy, spinal stabilization exercises or electrical stimulation due to low back pain or leg pain, were not the subject of this paper and were excluded. Studies relating to pre- or postoperative physiotherapeutic management of AIS patients, as well as to the natural history or observation (“watchful waiting”) as a form of therapy, were not included.

SRs on diagnostics, prognosis, economic analysis, or other research questions other than non-surgical interventions, were considered ineligible. These also applied for SRs or guidelines potentially including systematic reviews of evidence regarding screening for AIS. This subject matter has been reported separately [42].

Comparative interventions.

The types of comparative interventions considered eligible were all non-surgical interventions as described below:

  1. bracing, or scoliosis-specific exercises versus scoliosis-specific exercises plus other interventions, or different forms of these interventions (e.g. different modes of exercises, or different types of braces),
  2. other forms of non-surgical interventions applied for scoliosis curve correction, e.g. chiropractic, manual therapy, electrical stimulation,
  3. natural history or observation.

Natural history or observation were not eligible as a “tested” intervention, but were considered as comparators or comparative interventions (I and C in the PICO scheme, respectively).

Outcomes.

All outcomes that addressed the effectiveness, as well as adverse effects of non-surgical interventions, both within the short and long term, were analyzed. These included both patient-centered (e.g. pain, quality of life, depression, sense of stigmatization) as well as surrogate, secondary or intermediate outcomes (e.g. curve progression, angle of trunk rotation, jaw deformity). The number of surgeries, or numbers needed to treat to avoid one surgery (need for surgery) as a criterion of failure of the non-surgical interventions were considered as well.

Search methods for identification of papers

Electronic searches.

The databases and other resources searched, as well as the order of searching, are detailed in Table 2. The search strategies, key words and limits used are detailed separately in Table S3. Searches in the general bibliographic databases were limited from 1980 or from the inception of a database (SportsDiscus –2001) to the latest possible current date. All SRs currently indexed in databases of SRs, databases separately indexing SRs and in guideline registries were considered. Time limits did not apply for websites of institutions, as these websites were assessed for current content. Electronic searches were last conducted between the 15 and 31 March, 2014.

Hand searching.

Hand searches of reference lists of included SRs, as well as in other relevant reviews, recommendations, guidelines, editorials, and other relevant papers, were conducted.

Process of study selection

The initial search and screening of titles and abstracts to identify papers requiring closer scrutiny to assess their eligibility, was conducted by MP using the pre-defined criteria. This was conducted within databases and specialty websites, in the order presented in Table 2. The two authors then independently hand-searched the reference lists of all included reviews and proceeded to select the full papers potentially meeting all the inclusion criteria. Any disagreements were resolved through discussion. The PRISMA search flow diagram for the selection of included studies is shown in Figure 1.

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Figure 1. PRISMA flow diagram for the selection of included studies.

https://doi.org/10.1371/journal.pone.0110254.g001

As the aim of this overview was to analyze existing SRs, potential authors of unpublished SRs were not contacted neither were searches for gray literature, registered titles and review protocols conducted. The exception was one SR [43] for whom the first author was contacted with a request for supporting material mentioned in the paper which was not available from the publisher. An update of a Brace Cochrane review [33], co-authored by JB-S, being currently under review, was also considered.

Process for the assessment of the methodological quality of included reviews

The “Assessment of Multiple Systematic Reviews”, (AMSTAR) risk of bias tool [44] was used to assess the methodological quality of included reviews. The AMSTAR tool is considered to be a valid and reliable instrument for assessing the methodological quality of reviews [45]. It comprises eleven items addressing criteria relating to the assessment of methodological rigor (Table 3). The items are scored “yes”, “no”, “cannot answer”, or “not applicable”. The maximum score is 11. Scores 0–4, 5–8, and 9–11 indicate low, moderate, and high quality reviews, respectively [46]. The appraisal was conducted independently by MP and JB-S. Exceptions were the Cochrane reviews [16], [33], that were included and coauthored by JB-S, when MP and a collaborator (IC) (invited for this purpose) performed the independent appraisals. Assessments were conducted using guidelines for scoring AMSTAR questions [44][46]. Disagreements were resolved by discussion.

The level of evidence from each included SRs was assessed, considering the types of primary (and, in individual reviews, also secondary) studies included, using the Oxford Centre for Evidence Based Medicine (OCEBM) [47], [48] and the Joanna Briggs Institute (JBI) [49], [50] classifications.

Data extraction and management.

The data was independently extracted by MP and JB-S, using predefined data extraction forms (Tables 4 and 5). Discrepancies were resolved through discussion.

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Table 4. Content (PICO) characteristics of included reviews.

https://doi.org/10.1371/journal.pone.0110254.t004

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Table 5. Methodological characteristics of included systematic reviews.

https://doi.org/10.1371/journal.pone.0110254.t005

Data synthesis.

All the data extracted from the SRs was grouped by intervention and adverse effects. Narrative summaries of the review questions as well as eligibility criteria, populations studied, outcome measures and findings were then listed separately for individual reviews, and presented in Table 4.

The methodological characteristics of the included SRs – sources searched, selection criteria, methods of quality assessment of included studies, methods of data extraction and synthesis, and methodological limitations of the SRs were reported in the same order and can be seen in Table 5.

Results

Search

After removal of duplicates, 469 titles or titles and abstracts were screened for inclusion, 360 titles and/or abstracts were excluded, 110 full text papers were analyzed and 21 SRs were included for data synthesis and quality analysis (Figure 1). Four guideline documents addressing the subject matter were found, but none of them met the inclusion criteria.

The SRs that were included are listed in Table S1 with reasons for inclusion in cases where this was not clear. Excluded papers are listed, with the research designs classified, and the rationale for exclusion explained in Table S2.

Eighteen SRs addressed the effectiveness of non-surgical interventions: five SRs addressed SSE methods [33], [51][54], four evaluated manual therapies [6], [7], [55], [56] and five addressed bracing [16], [24], [36], [43], [57]. Four SRs compared the effectiveness of different interventions: bracing, therapeutic SSEs, lateral electrical surface stimulation (LESS), observation and/or surgery, or else their combinations (e.g. bracing plus exercises) [17], [26], [37], [58]. One review evaluated usual physical activity [59]. Two SRs addressed side effects: low bone status [60] and malocclusion [61] in braced patients. Overall the reviews addressed numerous, patient-centered and surrogate short and long-term outcomes. The types of interventions examined, types of participants, outcomes and authors’ conclusions are presented in detail in Table 4.

Other reviews found

Complementary and alternative medical interventions (CAM).

Whilst primary studies of non-surgical CAM interventions have been reported in the literature (acupuncture, herbal treatment, or Pilates [8]) no SRs (secondary analyses) addressing any of these approaches could be found.

Overviews of reviews.

Two overviews of reviews evaluating non-surgical interventions for AIS were found: a narrative review [62], a systematic overview of systematic reviews [63] which included one eligible SR [6] among other SRs regarding manipulative therapies in various pediatric conditions. This SR was also found through the search process and was included in the analysis.

Methodological quality of included reviews

AMSTAR scores.

Analysis with the AMSTAR tool revealed that the large majority of included reviews, 16 out of 21 included reviews were of low methodological quality, with scores ranging from 0 [36] through 1 [17], [54], 2 [6], [25], [26], [43], [53], [61] and 3 [55], [57], [60] to 4 points [51], [56], [58], [59]. Three moderate quality SRs scored 5 [37], 6 [52] and 7 [7]. Two SRs (Cochrane reviews) [16], [33] were of high methodological quality, and scored 9. Table 3 provides details of the AMSTAR quality assessment for each included SR, with explanations regarding the scoring decisions.

Narrative content analyses of methodological issues in included reviews.

The SRs differed with regards to the sources of data as well as the databases searched. Three SRs were based on searches of one database [57], [58] or a textbook (?!) that was used by Rowe et al. [26] and seven SRs [6], [36], [37], [51], [54], [56], [57] were based exclusively on electronic searches. The only SRs where authors and investigators were contacted as a method of retrieving data were the Cochrane reviews [16], [33].

Eighteen SRs included only AIS patients. Two of these reviews [16], [33] were Cochrane reviews of randomized controlled trials (RCTs) and other prospective controlled studies. One SR [37] analyzed RCTs and nonrandomized controlled trials. Fourteen SRs included a diverse mix of primary studies that included both experimental and observational designs. One SR [59] considered both primary studies of various designs and narrative reviews. The remaining three SRs [7], [55], [56] considered an AIS population that was included within other pediatric conditions: one review was a SR [7] of RCTs and included one RCT on AIS, one SR included different controlled studies amongst them a single pilot RCT on AIS [55], and one [56] included a case study on AIS.

Seven SRs [7], [16], [33], [37], [55][57] included the analyses of the methodological quality of individual studies, using validated scoring tools. In six SRs hierarchies of levels of evidence (LoE) [17], [25], [54], [59] or strengths of evidence (SoE) [36], [43] were used as a way (or rather instead of) assessing the methodological quality of primary studies. In one SRs [37] the LoE hierarchy assessment supplemented the quality appraisal of the included reports. One SR [56] provided LoEs for all the included studies, but a quality assessment for the RCTs only.

One of the SRs [26] included a meta-analysis, one SR comprised a pooled prevalence estimates [25], whilst in another SR the authors had performed a pooled proportions of data [58]. The remaining papers provided descriptive analyses of individual studies.

A detailed narrative analysis of the methodological issues within the included SRs can be seen in Table 5.

Levels of evidence, findings and conclusions

The evidence from included reviews is summarized in Table 6, according to each non-surgical intervention and in the order of descending levels of evidence.

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Table 6. Evidence from systematic reviews on non-surgical interventions in AIS, in the order of descending levels of evidence.

https://doi.org/10.1371/journal.pone.0110254.t006

Discussion

A brief summary of evidence from the reviews that were included is provided below.

Scoliosis-specific exercises (SSE)

Romano et al. (2012) [33] high quality, AMSTAR score 9/11, 1/1a level of evidence SR.

A recent (2012), rigorous Cochrane review [33] provided no convincing evidence from RCTs for or against these interventions in terms of curve progression as a primary outcome, and no evidence of risks or side effects from performing scoliosis-specific exercises.

Lower quality, lower level of evidence SRs [51][54], AMSTAR scores 4, 6, 2 and 1.

A series of three other low to moderate quality SRs [51][53] recommended the use of SSE exercises based on level 1b evidence. Conversely another recent (2012), though very low quality SR [54] concluded that there was no evidence to support their use.

Manual therapies

Posadzki et al. (2013) [7] higher quality SR, AMSTAR score 7/11.

A recent (2013) SR [7] found one high quality RCT showing no evidence to support osteopathic manual therapy as an effective treatment for mild AIS.

Low quality reviews [6], [55], [56], AMSTAR scores 2, 3 and 4.

Two other SRs [6], [55], though of lower quality, and lower level of evidence, provided similar conclusions. Conversely another low quality SR by McKennedy et al. [56] reported “very promising” findings from one pilot RCT.

Bracing

Negrini et al. (2010) [16] high quality, AMSTAR score 9/11, 1/1a level of evidence SR.

A Cochrane review from 2010 [16] found very low quality evidence supporting the effectiveness of bracing in reducing curve progression, and low quality evidence favoring hard braces as compared to soft braces. The update of this SR currently under review (JB-S, personal communication) found low to very low quality of evidence in favor of effectiveness of bracing in terms of reducing curve progression, with quality of life not highly impacted by bracing according to these studies.

Lenssick et al. (2005) [37] moderate quality SR, AMSTAR score 5/11.

In a moderate quality SR of prospective controlled trials from 2005 [37], Lennsick et al. concluded, that due to the lowpower, weak methodological quality and clinical heterogeneity of the included studies, drawing firm conclusions was impossible. However the effectiveness of bracing and SSE treatments in reducing curve progression appeared promising. The authors did not formulate such claims with regards to electrical stimulation however. This SR scored 5 out of 11 with AMSTAR (moderate quality SR) although crucial elements of a SR were clearly reported within this review. Further although the assessment of publication bias was discussed in the paper the actual data was missing. Additionally even though a comprehensive search process was reported, this did not fully meet AMSTAR criteria [44][46].

Low quality reviews [17], [25], [26], [36], [43], [57], [58], AMSTAR scores 4, 2 and 1.

The remaining SRs that met the inclusion criteria [17], [25], [26], [36], [43], [57], [58], were of low, or very low [17], [36] quality, and were classified using the OCEBM [47], [48] and JBI criteria [49], [50] as evidence of lower levels (Table 6).

The first SR on the conservative treatment of AIS by Focarile et al., that was found, dates back to 1991 [58]. It achieved an AMSTAR score of 4 and the conclusions of this review supported the use of braces. The meta-analysis by Rowe et al. from 1997 [26], evaluated different programs of bracing and of LESS. The results indicated that braces were effective only if they were worn 23 hours a day, but the results demonstrated no significant differences between LESS and observation. The Rowe et al. SR achieved only an AMSTAR score of 2. This was quite unexpected and remarkable, as this review, published in 1997, was based on evidence found within a textbook! What was even more surprising was the fact that the review was then used as a basis for producing the guidelines and recommendations [42], including the 2004 US Preventive Services Task Force recommendations, still current in 2014 [36]. A review published after this in 2008 [17] by Weiss and Goodall, evaluated the effectiveness of different methods of non-surgical treatment individually; first bracing, and then the outpatient and inpatient rehabilitation of AIS (these included SSEs typically used in Europe). This paper suggested that inpatient rehabilitation was effective but only achieved a score of 1 with AMSTAR.

The lowest quality SR by Sanders et al. [36] (2012) suggested that bracing may reduce the need for surgery, but other SRs [33], [43], [57] were not so convincing in their conclusions. Two of the SRs also considered patient-centered outcomes [43], [57] but found no firm evidence that bracing may negatively influence the quality of a patient’s life. The SR by Davies et al. [43] from 2011 further questioned the cost – effectiveness balance of bracing considering that there was no credible evidence of its effectiveness. Interestingly, their conclusions as to the quality of the available evidence were similar not only to those reported 20 years earlier in the 1991 review by Focarile et al. [58] but also to those from the high [33] and low [57] quality recent SRs by Negrini et al. and Maruyama et al.

Usual physical activity

Green et al. (2009) [59] low quality review, AMSTAR score 4/11.

One low quality review [59] (that scored 4 on AMSTAR), comprised five primary studies as well as six narrative reviews. A comparison of the study findings as well as different recommendations, found within this review provides cautious (grade D, Oxford CEBM) recommendations for the participation of AIS patients in sports who were either meaningfully observed or treated with braces. This paper however, rather than providing findings from a so called ‘systematic review’ primarily summarizes opinions formulated by undertaking a more biased narrative review and discusses findings from individual observational studies (three case-control studies, a survey and a case report), both of which provided low quality evidence of level 3 and 4 and 5, respectively [47][50]. Whilst this review provided information on the levels of evidence of the primary papers included, it did not sufficiently nor rigorously assess the methodological quality of these studies.

Adverse effects

Two low quality reviews that addressed the adverse effects of brace wear were found by Li et al. [60] and Saccucci et al. [61], from 2008 and 2011, respectively. The 2008 review (AMSTAR score 3), based on the findings from five observational studies (one cross-sectional, one case-controlled, and three uncontrolled follow-up studies)concluded that there was no convincing evidence to support the assumption that brace wear may be associated with the loss of bone mineral density. The other review, by Saccucci et al. (AMSTAR score 2) included a narrative report on a case study from 1969. The authors suggested that there was an association between wearing the original Milwaukee brace (with a jaw support) and malocclusion. However, these claims now have only a historical meaning, as subsequently a large clinical controlled trial published in 1972 (also reported by Sacucci et al.), showed no such adverse effects associated with the use of the improved, thoraco-lumbo-sacral (TLSO) and soft (SpineCor) braces as none of these types of braces have a jaw support. The review by Saccucci et al. was very haphazardly conducted and very poorly reported with no clear data on the correlation of bracing and dental occlusion that could be determined.

Additional non-surgical interventions not addressed in SRs

Other non-surgical interventions were reported in the literature, e.g. chiropractic and complementary and alternative medicine methods (acupuncture, Pilates exercises, or herbal therapy) [6][8], however no secondary analyses addressing those approaches were found.

Quality analyses

As reported in detail in the Results section, and in Tables 35, the methodological quality of the majority (16 out of 21) of the retrieved SRs was disappointingly low, regardless of the limitations that were independent from the study authors – such as the number, quality, design and comparability of eligible primary studies. In many SRs there was no second independent reviewer and blind study selection and/or data extraction, no lists of included and excluded studies, no comprehensive search for evidence, and, perhaps most importantly, no quality assessment of included studies conducted. The reviews instead reported only (more or less detailed) study characteristics. In some of the reviews the level of evidence hierarchy classification (categories of studies) were reported as a quality assessment suggesting perhaps a lack of knowledge amongst clinicians conducting SRs regarding systematic review methodology. Further, a number of excluded reviews (Table S2) were called “systematic” but actually comprised only a structured and systematic literature search, and then presented a narrative discussion of a few papers of diverse designs. The only SR with a meta-analysis by Rowe et al. [26] was seriously flawed methodologically (AMSTAR score 2 out of 11, Table 3) with findings and conclusions that were biased (Table 5). This review (as well as the SR by Focarile et al. [58]) did not differentiate between juvenile and adolescent IS. As these conditions differ in their clinical characteristics therefore their findings can be regarded as even less credible.

The low methodological quality found within a large proportion of the so called systematic reviews in this area, is in general very disappointing, especially when comparing these findings to recent overviews that have confirmed the good methodological quality of systematic reviews within the areas of rehabilitation [64] and orthopedics [65]. These results suggest that not only are good RCTs and prospective studies with a control group needed, but also as important, there is a fundamental need to improve the quality not only of conducting, but also writing and presenting systematic reviews in the subject matter addressed within this paper. It would also be suggested that education in the conduct and presentation of state of the art systematic reviews are prioritized within medical and health care education.

Quality of reviews vs quality of reporting.

The objective of this current paper was to evaluate the methodological quality of systematic reviews, not the quality of reporting. However, it must also be acknowledged that clear reporting does not necessarily result in a high quality review. Some reviews were clearly reported, but nonetheless had a number of methodological limitations.

The high quality reviews [16], [33] did not meet the AMSTAR criteria [44][46], regarding the assessment of the likelihood of publication bias as well as the criteria on the reporting of conflicts of interest statements within individual primary studies. These issues indicate minor limitations in reporting, rather than the processes undertaken to conduct and develop the systematic review, in terms of the AMSTAR criteria [45]. The moderate quality reviews [7], [37], [52] generally met the substantial criteria for a valid systematic review, but did not meet some of the criteria for comprehensively conducting and reporting (Tables 35), such as providing the ‘a priori design’ of the review (e.g. in a SR protocol), comprehensive searching, regardless of the publication status (gray literature) and language restrictions, as well as providing lists of included and excluded publications. The lower quality SRs were either clearly reported, but appeared less careful with the reporting of the methodological process undertaken [25], [43], [52], were haphazardly undertaken [61], had language limitations [58], [61] and/or were written in a way that did not follow contemporary reporting criteria [26], [58].

Types of reviews and outcome measures

Although systematic reviews of uncontrolled observational studies, especially of retrospective designs may be developed according to standard criteria [66], this does not eliminate the bias resulting from the methodological constraints of the included studies. Another issue is the type and meaning of primary and secondary outcome measures. Curve progression as a criterion of treatment success is considered a primary outcome measure within many SRs (e.g. [6], [25], [26], [51][53], Table 4). In point of fact however, primary, patient-centered outcomes, (considered in the available Cochrane reviews [16], [33] as well as in a number of other SRs [43], [57]) are outcomes that are of most concern to the patients themselves; these include such outcomes as for example neuromotor control, balance, back pain, or respiratory function. Curve progression, in terms of patient-centered outcomes, is regarded by the Cochrane Back Research Group (CBRG) as a surrogate, or as a secondary end-point or outcome measure. The effects of brace treatment have to date been controversial as to the impact on patients’ and families’ quality of life and other adverse events [12], [67]. Furthermore, a cost-utility analyses indicated that outcome measures need to be patient-centered and that both outcomes and costs are measured and assessed in the long-term [68], [69].

Quality of reviews and levels of evidence

An issue not covered through the appraisal with the AMSTAR tool – the research design of primary studies included within a review – necessarily influences the level of evidence derived from a SR, and is addressed and interpreted differently within different classifications of the hierarchy of levels of evidence currently available. Significant difficulties were encountered when trying to categorize the levels of evidence (LoE) of the SRs that were included. This was due to the very unclear characteristics of the large majority of the SRs in terms of the study designs that were included for analysis (Table 5).

The current Oxford CEBM classification [47], [48] categorizes SRs of RCTs as a step 1 (or level 1) evidence for questions regarding treatment benefits and common harms. However it does not list SRs of other types of research designs besides RCTs for treatment benefits, and only lists SRs of nested case-control studies as step 2 (level 2) of evidence. Conversely the latest Joanna Briggs Institute’s “New Levels of Evidence” document [49], [50] classifies SRs of different types of studies with the highest sub-level for each of 5 levels of evidence, where a SR comprised of RCTs is allocated a level 1a, and SRs of expert opinion (!) is considered to be a level 5a of evidence (although it is unclear to the authors of this paper how a SR of expert opinion should be conducted).

Furthermore it is worth noting the fact that, a systematic review that includes either an inferential statistical analysis (meta-analysis), or alternatively is a qualitative systematic review, is not a criterion that influences the current levels of evidence achieved in either the OCEBM or the JBI classifications. In fact, the three quantitative reviews by Dolan and Weinstein [25], Focarile et al. [58] and Rowe et al. [26], which included pooled data syntheses (meta-analysis) and were included in the present study, all scored as low quality SRs with AMSTAR while the most rigorous, high level evidence reviews of clinical trials [7], [16], [33] did not include any meta-analyses. As a point in fact very few SRs (those of moderate and high methodological quality (Table 3) – considered the research study designs of included studies as important criteria for the conduction of a valid and reliable SR [70].

Comparisons with other studies

No overview of systematic reviews addressing the effect of non-surgical interventions on patients with AIS could be found. However, an analysis of one of the included SRs [6] was reported in an overview of systematic reviews addressing manual therapy in various pediatric conditions [63]. Additionally brief critiques of one of the included SRs [26] were found in two of the SRs that were analyzed [22], [37]. Finally, critical abstracts of two of the included SRs [26], [51] are provided in the DARE database. Generally, the assumptions and analyses within the DARE database correspond with the findings of this study.

Limitations of the study

As is typical for systematic overviews of systematic reviews, an analysis of the overall methodological quality of all the included systematic reviews (not the primary studies included in the reviews) was conducted within this study. Thus, information regarding the design and methodology of individual primary studies were, except in very unclear cases, based on the quality appraisals reported within the systematic reviews that were included and analyzed. With the exception of one review [43], the authors were not contacted.

Evidence from very recent primary studies and unpublished updated SR.

Recently, the first multicenter randomized controlled BrAIST trial evaluating the effectiveness of bracing on AIS [23], as well as a randomized controlled trial on the effectiveness of a scoliosis-specific exercise program [71], both found the interventions to be effective. Conversely a very recent prospective controlled trial by Sanders et al. (2014) [72] claimed that only highly compliant patients may avoid surgery through brace wear. Furthermore, an update of a Cochrane review considered in this paper [33], currently under review (JB-S, personal communication), demonstrates improvements in terms of the evidence-base in this subject matter, however the Negrini (2014, unpublished) Cochrane brace review included seven prospective trials (five RCTs) of different quality, which reached different conclusions. These add to, and seem to alter, the evidence-base regarding brace and exercise treatments. However, the assessment of methodological quality of primary and unpublished studies was beyond the scope of this study.

Conclusions

  • The methodological quality of systematic reviews in the area of non-surgical interventions for of AIS is generally low;
  • Findings from higher quality reviews that consider numerous outcome measures, indicate that generally there is insufficient evidence to enable researchers and clinicians as well as service users to make a judgment on whether non-surgical interventions in AIS are effective;
  • Individual, highly cited and older reviews, demonstrating the effectiveness of rigorously applied braces and physiotherapy, were found to be of low methodological quality; so it is unclear to what extent the results of these reviews are valid;
  • Readers need to be aware that papers entitled as systematic reviews may not necessarily meet the criteria to be classified as systematic reviews or in other words, papers entitled as systematic reviews need to be considered in terms of their methodological rigor; otherwise they may be low quality sources of evidence that are mistakenly regarded as high quality ones.

To the authors’ best knowledge, this is the first comprehensive, explicit and systematic overview of systematic reviews addressing diverse non-surgical interventions for adolescents with idiopathic scoliosis. The authors believe that the findings of this overview will be of significant benefit to patients and parents, clinicians, researchers and commissioners of health services in this field.

Supporting Information

Table S3.

Details of the electronic search and selection process.

https://doi.org/10.1371/journal.pone.0110254.s003

(DOCX)

Acknowledgments

The authors would like to thank Dr Igor Cieśliński for his contribution to the AMSTAR assessment of the included Cochrane reviews.

Author Contributions

Conceived and designed the experiments: MP. Performed the experiments: MP JB-S. Analyzed the data: MP JB-S. Contributed to the writing of the manuscript: MP JB-S. Registered the protocol: MP. Prepared data extraction tables: MP.

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