Manipulation and mobilization for treating chronic low back pain: a systematic review and meta-analysis

The systematic review builds upon previous systematic reviews of manipulation and mobilization for chronic low back pain (up through 2000), such as Bronfort et al. [] and Shekelle et al. [, , ]. We designed a broad search strategy that did not define the specific population (ie, not using the word chronic or non-specific) or intervention (ie, spanning across multiple professions). In addition, we placed no limitations on control or comparators, outcomes, or study designs, so that the breadth and variations across the research could be discovered, and the literature could inform the appropriate definitions and subgroups to consider for analysis given that inconsistencies are present. We searched PubMed or MEDLINE, Cochrane, Embase, CINAHL, PsycINFO, and ICL from January 2000 through March 2017. We drew on reference lists and consultation with subject matter experts to ensure comprehensiveness (Fig. 1). Because the National Institutes of Health–funded project focused on both chronic neck pain and chronic low back pain, we executed the search to meet both needs together (Table 1).

A scoping review of the literature informed the definitions of chronicity used in the review. It also clarified what is considered non-specific, and what subgroups should be considered for systematic review and meta-analysis. We reviewed articles and categorized studies according to specific populations, interventions, control or comparators, outcomes, and study designs. We excluded studies clearly not related to back pain or to an intervention involving mobilization or manipulation. We presented findings to an internal steering committee (ISC) and an external advisory committee (EAC), where evidence-informed definitions and specific research questions were devised based on the evidence base for carrying out systematic review and meta-analysis (Table 1).

Six reviewers used study eligibility criteria to independently screen the literature in duplicate. Disagreements about inclusion were resolved through discussion and consensus, or if necessary, by the ISC. The eligibility criteria included (1) a population experiencing chronic [, ] and non-specific [] low back pain (as defined in Table 1); (2) an intervention, with the involvement of a therapist, consisting of either (i) manipulation (labeled as thrust), (ii) mobilization (labeled as non-thrust), or (iii) a multimodal integrative practice including manipulation or mobilization components, labeled as a multimodal “program” if the observed effect could not be attributed directly to the thrust or non-thrust intervention (eg, a study of chiropractic plus acupuncture vs. usual care would be multimodal and labeled as a “program” separate from chiropractic plus acupuncture vs. acupuncture); (3) compared with a sham treatment, no treatment, or other active therapies, such as exercise, physiotherapy, or physical therapy; (4) an RCT, involving adult human subjects (age 18 years or older); and (5) at least one pain outcome measuring a reduction in pain intensity or severity, such as the visual analog scale (VAS) or numeric rating scale (Table 1).

Six reviewers participated in data extraction and quality assessment of the individual studies. Population characteristics, treatment intervention(s), control or comparators, and outcomes were described for each included study. Quality assessment was performed in duplicate by reviewers; disagreements were tracked and resolved by the ISC. Risk of bias was assessed using the Scottish Intercollegiate Guidelines Network (SIGN 50) checklist for RCTs []. We assessed external validity using the External Validity Assessment Tool (EVAT) [], which measures the generalizability of research to other individuals (external validity) and other settings (model validity) outside the confines of a study.

The primary analysis was based on trials reporting a continuous outcome measure for pain intensity, disability, or health-related quality of life (HRQoL) [] up to 1 month after the end of treatment. Subgroups were constructed to transparently report those studies where (1) chronicity duration is greater than 3 months or greater than 12 months, (2) intervention consisting of thrust or non-thrust, (3) and were compared with sham or no-treatment or another active intervention, for each outcome assessed. Secondary analyses were based on trials reporting a continuous measure for pain, disability, or HRQoL at follow-up points closest to 3, 6, and 12 months after treatment. Single treatment (one dose over one day) studies were excluded from any analysis. Data synthesis and analysis methods for those multimodal interventions where the effects of manipulation or mobilization could not be distinguished from the total program were not applied as these studies involved more pragmatic, program-type interventions and were heterogeneous from study to study. For simplicity and because many types and styles were included in systematic review, the authors chose to refer to the manipulation therapies as “thrust” and mobilization therapies as “non-thrust” (Table 1). We grouped studies in this way in order to attempt to create homogeneous subsets of studies, allowing us to ask questions about how interventions compare (eg, thrust vs. sham or no treatment, thrust vs. other active therapies); dose regimens and practitioner-specific techniques remained heterogeneous across studies (Supplementary Data Files 1 and 2). Some subgroups were judged too heterogeneous to pool in any meaningful way.

For all studies where data were available, we extracted sample size, mean, and standard deviation for each treatment group, at each time point reported. An unbiased estimate using the Hedges' effect size [] and 95% lower and upper limits was computed using intergroup differences between groups at those time points. For a reduction in pain intensity or disability, a negative effect size favors the thrust or non-thrust intervention more than the comparison arm (active comparator, sham, or no treatment group). For an increase in HRQoL, a positive effect size indicates benefit in thrust or non-thrust treatment group more than the comparison arm. This was done regardless of whether the study was considered for meta-analysis or not.

We considered a minimum of three studies judged similar enough in terms of the population, intervention, control or comparator, and outcome measure as sufficient for pooling data for meta-analysis. Standardized mean differences (SMDs) were computed using Comprehensive Meta-Analysis, Version 3.3.070 (CMA; Biostat, Englewood, NJ, USA). Meta-analyses of SMD were performed with the generic inverse model of REVMAN. Because we expected heterogeneity, we used random-effects models; statistical heterogeneity was examined by I² with low, moderate, and high I² values of 25%, 50%, and 75%, respectively. Publication bias was assessed using the Begg adjusted rank correlation test [] and the Egger regression asymmetry test []. Pooled effect sizes for pain and disability outcomes were translated into the VAS (0–100) using a standard deviation of 25 points, and the Roland-Morris Disability Questionnaire (0–24), using a standard deviation of 6 points, respectively, for clinical interpretation [].

We assessed confidence in the effect estimates using the Grading of Recommendations, Assessment, Development and Evaluation (GRADE) approach based on the following criteria: risk of bias, inconsistency, indirectness, imprecision, and publication bias, for each outcome [].

Characteristics of included studies are detailed in Supplementary Data Files 1 and 2. The included RCTs examining either a uni- or multimodal intervention of thrust or non-thrust for patients with chronic low back pain were published between 2000 and 2014. No studies meeting eligibility criteria were found between 2015 and 2017. The total number of participants across the 51 unique studies was 8,748, ranging from 19 to 1,334 participants in each study. The average age of participants was 42 years, ranging from 29 to 59 years. On average, there were more females than males. For the unimodal (Supplementary Data File 1) studies, participants reported average pain duration of 3 months or more in 60% of included studies, 6 months or more in 12% of studies; in 28% of studies, participants described chronic pain as more than 1 year. Multimodal studies (Supplementary Data File 2) reported participant average pain duration of 3 months or more in 30% of the included studies; fewer studies described participants' chronic pain lasting 6 months (19%). Lastly, 51% of included studies described participants' chronic pain as lasting more than 1 year.

Of the 25 unimodal studies, 60% were identified as thrust interventions, 28% were non-thrust interventions, and 12% used a combination of both. Some of these studies were multimodal by design, but were included in this subgroup for the purposes of analysis because the effect of each intervention could be distinguished. A variety of interventions were combined to serve more as “programs” for the included multimodal studies. The most prevalent interventions used in combination with a thrust or non-thrust intervention were prescribed exercises; others included stretches, massage, ultrasound, education, or advice therapy. Combined treatment dosages varied from one session for 3 minutes to 16 sessions of 45 minutes each over the course of 8 weeks. The majority of studies (84%) had active control or comparators (eg, acupuncture, physical therapy, exercise, usual care); the remaining studies compared the intervention with sham or no treatment. Active control or comparator dosages varied from one session for 3 minutes to 16 sessions of 45 minutes each over the course of 8 weeks.

The studies reported outcomes related to pain intensity or severity, disability, and HRQoL, all of which were considered critical outcomes for evaluation. The most common outcome measures were evaluated using the VAS (26 of 51) and the numeric pain rating scale (12 of 51) for pain reduction, the Roland-Morris Disability Questionnaire (21 of 41) or Oswestry Disability Index for disability (16 of 41), and the Short Form-36 for HRQoL (15 of 17) (Supplemental Data Files 1 and 2).

Overall, risk of bias was not considered serious across either the unimodal or the multimodal studies. Of the 25 unimodal RCT studies [, , , , , , , , , , , , , , , , , , , , , , , , ], 3 (12%) were given a SIGN 50 score of high quality (++) [, , ], 18 (72%) as acceptable quality (+) [, , , , , , , , , , , , , , , , , ], and 4 (16%) as low quality (0) [, , , ]. Among the 26 multimodal studies, 3 (12%) were rated high quality (++) [, , ], 20 (77%) acceptable quality (+) [, , , , , , , , , , , , , , , , , , , , ], and 3 (11%) low quality (0) [, , , ]. The most prevalent poorly addressed quality criteria related to pitfalls in reporting group differences, intention-to-treat analyses, and multisite similarities, respectively. Overall, all EVAT categories were addressed adequately. The source population (44 of 51) and recruitment of participants (39 of 51) were transparently described and reflective of the population from which they were drawn. Twenty-three of 51 studies described the staff, places, and facilities where treatment occurred, but other studies lacked the details required to fully understand the clinical applicability to real-world settings. The majority of studies involved physical therapists, chiropractors, physicians, naturopathic, or osteopathic clinicians. In some, multiple therapists delivered the interventions. Practitioner characteristics were well described in many of studies. Treatment locations varied, including private clinics, university settings, hospitals, or other medical facilities (Table 2).

Of the 25 unimodal RCTs, 5 reported that no adverse events occurred during the study period; 2 reported minor adverse events—typically worsening symptoms. Another study reported that 2% of patients experienced serious adverse events. However, none of these symptoms was determined to be treatment-related, and the frequency of adverse events in the treatment and control groups was not significantly different. The remaining 17 studies did not provide any information on adverse events in the publications.

None of the multimodal studies reported a serious adverse event. Ten studies failed to report on adverse events and 10 reported that none had occurred. Of the remaining six, the adverse events were noted as mild, including temporary treatment-related soreness, tiredness, or worsening of existing complaints. Of studies that did report adverse events, the authors failed to describe how an event was determined to be adverse, how data were collected, and the intervals for data collection. It appears that this is perhaps spontaneous self-reporting by the subjects in the studies (Supplementary Data Files 1 and 2).

The authors relied on the Food and Drug Administration's definition of an adverse event as any adverse experience during treatment resulting in death, life-threatening adverse experience, hospitalization or prolongation of existing hospitalization, or persistent or significant disability or incapacity (Supplementary Data Files 1 and 2). Of the non-RCT studies examined for the larger project effort, the majority neglected to report on adverse events. Those that did reported either new complaints or worsening of existing complaints after initial treatment; however, these complaints were not associated with worse long-term outcomes and were unlikely to be serious [, , ].

Studies comparing thrust or non-thrust with a sham or no treatment control were heterogeneous and could not be pooled for analysis in any meaningful way. In addition, dose studies that are included in the systematic review were heterogeneous and omitted from any analysis. As noted previously, we excluded multimodal studies from analysis because of their inherent heterogeneity. The remainder of studies for consideration consisted of those thrust and non-thrust interventions compared with another active therapy, consisting of exercise or physical therapy where treatment was over multiple sessions and post-treatment assessment was closest to 1 month (4–8 weeks from baseline) across outcomes of pain reduction, disability, and enhanced HRQoL.

Overall, risk of bias was not of serious concern across analyses or subgroups pooled for each outcome assessed. As expected, we detected statistically significant heterogeneity across the overall analysis for a reduction in pain (p=.009) and a reduction in disability (p=.0001). Heterogeneity was likely due to pooling various types of intervention techniques, dose regimens, and their comparators. Within the subgroups when compared with active comparators, heterogeneity remained significant for thrust versus other active therapies. The comparators in these studies consisted of various exercise regimens and physical therapy. There were too few studies to pool according to specific chronicity duration or according to specific predefined dosing cutoffs. The results appeared precise; however, sample size pooled remains small. We detected no publication bias according to either the Begg or Egger test for either the overall analysis or according to subgroups (data not shown). Overall, confidence in the reported effects was graded as moderate for a reduction in pain and disability after treatment.

The European Workgroup guidelines recommend a referral for spinal manipulation therapy, including mobilization, for patients who are suffering from chronic back pain []. In the United States, similar recommendations exist in favor of manual therapies including manipulation and mobilization for chronic low back pain [, , ]. However, the recommendations regarding manual therapies for chronic low back pain continue to show some variation depending on country or region of origin. In most guidelines, manipulation is recommended or presented as a therapeutic option. Other guidelines do not recommend it. It is not known why there are such inconsistencies across guidelines [, , ]. Guidelines may have depended largely on panelists' interpretations, which have been based on insufficient or inconclusive evidence or reflected methodological flaws in the reported studies. Other factors that may influence guideline recommendations include local and national political variance or bias [].

Similar to the practice guidelines, recent systematic reviews have reported favorable evidence for treating chronic non-specific low back pain using manipulation and mobilization, including chiropractic [, ], osteopathic manipulation therapy [], and physical therapy []. However, as with practice guidelines, these systematic reviews conclude that the scientific evidence is challenged by heterogeneity in the types of populations and interventions being studied, lacks long-term outcomes, includes insufficient data to explore subgroup effects, and has methodological bias that can limit and complicate the interpretation of the results []. Indeed, most systematic reviews conclude that it is difficult to draw definitive conclusions regarding the risk-benefit of manual therapies in patients with chronic non-specific pain.

As stated previously, we relied on the evidence provided by Bronfort et al. [] and Shekelle et al. [, , ] as a starting point for our analysis. We used the definitions of manipulation and mobilization based on Bronfort et al. [] and Coulter et al. []. However, our methodology generated a list of terms a priori to consider for inclusion criteria to meet our definitions. Therefore, our comprehensiveness may have increased the number of RCTs in this report but may have also increased the heterogeneity for the pooled estimates across those studies. Bronfort et al. [] identified 31 total low back pain trials. Of these, 11 trials (n=1,472) assessed chronic low back pain and 14 trials (n=3,068) investigated a mix of patients with acute and chronic low back pain.