Neural mobilisation effects in nerve function and nerve structure of patients with peripheral neuropathic pain: A systematic review with meta-analysis

Juliana Valentim Bittencourt; Leticia Amaral Corrêa; Maria Alice Mainenti Pagnez; Jéssica Pinto Martins do Rio; Gustavo Felicio Telles; Stephanie Mathieson; Leandro Alberto Calazans Nogueira

doi:10.1371/journal.pone.0313025

Abstract

Objective

To assess the effects of neural mobilisation on nerve function and nerve structure of patients with peripheral neuropathic pain.

Methods

A systematic review with meta-analysis was conducted. Medline, Embase, CINAHL, Cochrane Library, and World Health Organization International Clinical Trials Registry Platform were searched without restrictions. Eligibility criteria included controlled trials or quasi-experimental studies comparing neural mobilisation versus sham, active or inactive control in adults with peripheral neuropathic pain. Primary outcomes were the change in peripheral nerve cross-sectional area. Secondary outcomes included nerve echogenicity, nerve excursion and nerve conduction. Random effects meta-analysis was conducted. Risk of bias was assessed with the Cochrane Collaboration tool, and certainty of evidence was assessed using the Grading of Recommendations Assessment, Development, and Evaluation framework.

Results

Eleven randomised controlled trials and four quasi-experimental studies (total sample = 722 participants) were included. Thirteen studies included participants with carpal tunnel syndrome. Two studies examined the cross-sectional area, revealing improvements (i.e., a reduction) in the cross-sectional area after the neural mobilisation. Neural mobilisation improved motor [mean difference = 2.95 (95%CI 1.67 to 4.22)] and sensory conduction velocity in short-term [mean difference = 11.74 (95%CI 7.06 to 16.43)], compared to control. Neural mobilisation did not alter distal motor or sensory latency.

Conclusion

Neural mobilisation seems to improve (i.e., a reduced) the cross-sectional area (very low-quality evidence) and sensory conduction velocity (very low-quality evidence). Neural mobilisation was superior to control in improving motor conduction velocity in patients with peripheral neuropathic pain with moderate quality evidence. Distal motor or sensory latency presented similar results compared to other interventions. Our findings should be interpreted cautiously since most studies included patients with carpal tunnel syndrome.

Citation: Bittencourt JV, Corrêa LA, Pagnez MAM, do Rio JPM, Telles GF, Mathieson S, et al. (2024) Neural mobilisation effects in nerve function and nerve structure of patients with peripheral neuropathic pain: A systematic review with meta-analysis. PLoS ONE 19(11): e0313025. https://doi.org/10.1371/journal.pone.0313025

Editor: Catherine Doody, University College Dublin - National University of Ireland: University College Dublin, IRELAND

Received: April 16, 2024; Accepted: October 16, 2024; Published: November 8, 2024

Copyright: © 2024 Bittencourt et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Data Availability: All data underlying the findings described in this paper are freely available to other researchers within the paper itself.

Funding: This study was financed in part by the Fundação Carlos Chagas Filho de Amparo à Pesquisa do Estado do Rio de Janeiro (FAPERJ) [Grant number: E-26/211.104/2021 and grant number E-26/201.398/2021] and Coordenação de Aperfeiçoamento de Pessoal de Nível Superior - Brasil (CAPES) [Finance Code 001; Grant number: 88881.708719/2022-01, grant number: 88887.708718/2022-00, and grant number 88887.466981/2019-00].

Competing interests: The authors report no conflict of interest.

Introduction

Neuropathic pain is a significant cause of suffering and disability. The prevalence of chronic neuropathic pain ranges between 7% and 10% of the general population [1]. A neuropathic component is estimated to be in approximately one-third of the pain syndromes [2]. Neuropathic pain can be associated with musculoskeletal conditions, such as low back pain [3], whiplash disorders [4, 5], lateral epicondylalgia [6], and carpal tunnel syndrome [7]. Although neuropathic pain is commonly observed in musculoskeletal conditions, there is an inconsistent use of its terminology for diagnostic labels in clinical practice and scientific literature [8]. Peripheral neuropathic pain could be present as radicular pain without (e.g., pain travelling to the limbs in regions that are similar to dermatomes but not entirely identical) or with radiculopathy (e.g., pain alongside neurological deficits in dermatomal or myotomal distribution or impaired reflexes) [8]. Therefore, the complex nature of peripheral neuropathic pain underscores the need for tailored treatment approaches to address its multifaceted challenges.

Clinical guidelines and consensus statements recommend pharmacologic management as treatment for patients with neuropathic pain [9–12], including tricyclic antidepressants, serotonin-norepinephrine reuptake inhibitors, and gabapentin as first-line treatments [9, 10, 13]. Clinical guidelines also recommend non-pharmacological approaches, such as conservative treatments like exercise and manual therapy [14]. In cases where patients do not respond adequately to previous treatments, invasive procedures may be considered [15]. Given the adverse effects caused by pharmacological interventions, the recommendations available are still inconsistent [16]. Thus, effective and safe approaches are needed for patients with peripheral neuropathic pain.

Neural mobilisation is used to reach the neural structures or surrounding tissue and can be performed manually [17, 18]. Neural mobilisation promotes clinical benefits for patients with nerve-related conditions [19–21]. For instance, neural mobilisation benefits back and neck pain patients [19]. Similarly, neural mobilisation showed moderate effects on the joint flexibility of healthy participants and large effects on pain intensity and disability in low back pain [20]. Moreover, neural mobilisation showed moderate to large positive results on pain intensity and disability in musculoskeletal disorders patients [22]. Previous studies have also shown that neural mobilisation reduces intraneural oedema [23] and improves intraneural fluid dispersion [24, 25]. There was a simultaneous increase in the magnitude of neural adaptive movement with a straight leg elevation test and the resolution of the radicular and low back pain symptoms [26]. Although high-quality evidence demonstrates the clinical benefit of the neural mobilisation techniques, the effects of the method on nerve function and structure have not yet been adequately explored and summarised.

Peripheral nerves and their mechanical properties have been studied extensively. Healthy peripheral nerves present a tubular form, alternating hypoechogenic and hyperechogenic zones corresponding to nerve and perineural fibres visible on ultrasonography imaging (USI) [27]. Changes in nerve structure are commonly observed in patients with peripheral neuropathies. For instance, patients with carpal tunnel syndrome showed an increase in the cross-sectional area of the median nerve, increased nerve swelling at the wrist, nerve hypoechogenicity, disturbance of the fascicular structure, reduced nerve slipping, and increased vascularity [28]. Similarly, patients with fibular nerve entrapment neuropathy demonstrated an increase in the cross-sectional area of the nerve and an increased fibular to popliteal fossa swelling ratio [28]. Several instruments have been used to assess peripheral nerve structure and function. Nerve conduction tests (i.e., electroneuromyography (ENMG)) and imaging exams (i.e., USI and magnetic resonance imaging (MRI)) are most commonly used. The cross-sectional area and echogenicity of the peripheral nerves can be quantified by USI [28, 29]. ENMG may be used in the classification of neuropathies [30] in the assessment of nerve conduction [31], and ENMG findings are correlated with structural abnormalities in the nerve [32]. The USI usually measures the excursion of the peripheral nerves [33, 34]. Also, the MRI method has been used in peripheral neuropathies to offer more quantitative features [35], such as nerve volume, cross-sectional area, diffusion properties of water molecules along the nerve fibres, and the presence of oedema or inflammation. This systematic review aimed to assess the effects of neural mobilisation on nerve function and nerve structure of patients with peripheral neuropathic pain.

Materials and methods

Protocol and registration

A systematic review was reported following the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) guidelines [36] (See S1 File). The protocol was registered in advance with the international Prospective Register of Systematic Reviews (PROSPERO registration number: CRD42022337067).

Data sources and searches

We performed electronic searches of Medline, Embase, Cumulative Index to Nursing and Allied Health Literature, and the Cochrane Central Register of Controlled Trials. We performed the initial electronic search from inception to 1^st November 2023 without restrictions on language, publication period, or publication status. We used keywords, Medical Subject Headings (MeSH), and other index terms, as well as combinations of these terms and appropriate synonyms across all included databases. The Medline search strategy is provided in the S2 File.

We searched clinical trial databases (ClinicalTrials.gov, World Health Organization International Clinical Trials Registry Platform (apps.who.int/trialsearch/) to identify potentially eligible additional published or unpublished data. We conducted manual search of the reference lists of included studies and previous systematic reviews related to this topic for any potentially eligible studies.

Eligibility criteria

We included controlled trials or quasi-experimental studies, which assessed the neurophysiological effects of neural mobilisation in patients with peripheral neuropathic pain, including radicular pain with or without radiculopathy. Participants were adults (aged 18 years or over) with one or more clinically diagnosed peripheral neuropathic pain (e.g., carpal tunnel syndrome, sciatica, cubital tunnel syndrome, low back pain with radicular symptoms, cervicobrachial pain). As diagnostic criteria for peripheral neuropathic pain varies in the literature, we considered studies that defined peripheral neuropathic pain via clinical diagnosis, nerve conduction studies, or imaging exams. We included studies that used slider or tensioner techniques as treatment. Neurodynamic tests (e.g., straight leg raises, slump test and upper limb neurodynamic tests) are examples of movements used in the sliders and tensioners techniques. We considered studies with neural mobilisation prescribed or performed by a health professional and with any duration of treatment or follow-up. The eligible comparison conditions included sham neural mobilisation or active (e.g., walking, aerobics exercises, stretching exercises, balance training, tai chi, yoga, Pilates) or inactive control (e.g., usual care, wait-list control, education booklets, education group, telephone counselling, storytelling).

Some conditions were excluded, such as those related to metabolic disorders (e.g., peripheral diabetic neuropathy), neuropathies associated with viral infections (e.g., post-herpetic neuralgia, HIV, leprosy) and chemotherapy-induced peripheral neuropathies. Moreover, studies were excluded if participants had non-specific or mechanical spinal pain, central spinal canal stenosis, cerebral palsy, paraplegia or quadriplegia, and other major conditions (e.g., fractures, dislocations). We did not include editorials, comments, letters, correspondence, abstracts, case reports, clinical observations, reviews, or studies with animals.

Study selection

Records found through searching were exported to EndNote reference management software (version X9), and two independent review authors (J.V.B. and L.A.C.) screened all search results for potentially eligible studies (See S3 File). Potentially eligible articles based on the title, abstract, and full text were sequentially screened. A third independent review author (L.A.C.N) resolved any disagreement about eligibility (See S1 Table).

Data extraction

We extracted data from each included study using a standardised extraction form proforma. Two independent review authors (J.V.B. and L.A.C.) extracted all data, and a third author (L.A.C.N.) revised the data in case of disagreements. The data extracted included details about the study characteristics (i.e., authors, publication year, and country of origin), study design, participant characteristics (i.e., number of participants and clinical condition), detailed treatment performed, control group information, outcomes, follow-up time points, primary results, and conclusions. We extracted pre-treatment and post-treatment means, standard deviations, and 95% confidence intervals for outcomes of interest. We obtained data from the trial registry where data were not available in the published manuscript. The authors were contacted in the event of missing data.

Outcomes measures

The primary outcome measures were the nerve structure, such as a reduction in the cross-sectional area of the nerve measured by USI, MRI, or other imaging exams.

The secondary outcome measure of nerve structure was echogenicity, as measured by USI. We were also interested in the effects on nerve function, explicitly improving nerve excursion (measured by USI or other imaging exams) and nerve conduction (measured by electromyography or other nerve conduction tests). We categorised follow-up outcome data of individual studies into short-term outcomes (defined as those occurring in less than 3 months), intermediate outcomes (between 3 and 12 months), and long-term outcomes (as those occurring more than 12 months after randomisation).

Data synthesis

We calculated changes from the baseline. We used Cochrane’s RevMan calculator to estimate the change from baseline standard deviations, where they were not reported.

Meta-analysis was conducted when an outcome was reported in two or more studies. In cases where meta-analysis was not possible, descriptive analyses were performed. The studies were grouped according to the similarity of the outcomes, and it was not necessary to convert the values to a common metric.

Data analysis

The flow of studies was summarised in a study flow diagram following the PRISMA statement [36]. Study characteristics were reported descriptively. Continuous outcomes are presented as mean differences (MDs) with 95% confidence intervals (CIs) between the intervention and control groups. The meta-analysis was performed using a random effects model (See S2 Table). The heterogeneity analysis was performed using the I² values and considered as moderate I² value of 30% to 60%, substantial 50% and 90%, and considerable heterogeneity in values more than 75%, following The Cochrane Handbook of Systematic Reviews of Interventions recommendations [37].

Risk of bias and certainty of evidence

We assessed the risk of bias using the original Cochrane Risk of Bias (ROB) tool for randomised trials [38] and the Risk of Bias in Non-randomised Studies (ROBINS-I) tool for studies that did not use randomisation to allocate interventions [39]. The classification of the ROB tool includes seven items assessing the risk of bias: selection bias (random sequence generation and allocation concealment), performance bias (blinding of participants), detection bias (blinding of outcome assessment), attrition bias (incomplete outcome data), reporting bias (selective reporting), and other sources of biases. The judgment for each item was classified as low risk, high risk or unclear risk of bias [38]. ROBINS-I tool includes seven items assessing the risk of bias in domains: bias due to confounding, bias in the selection of participants into the study, bias in classification of interventions, bias due to departures from intended interventions, bias due to missing data, bias in the measurement of outcomes, and bias in the selection of reported results. Despite the availability of an updated version of the Cochrane risk-of-bias tool for randomised trials (RoB 2), we choose to use the ROB, as RoB 2 presents challenges with low interrater reliability in its application [40]. Two reviewers (JVB and LAC) assessed the risk of bias for each study, and a third reviewer (LACN) revised it in case of disagreements.

The overall quality of evidence was assessed by the Grading of Recommendations Assessment Development and Evaluation (GRADE) [41]. We considered the following items: study design, risk of bias, imprecision, indirectness, inconsistency, and publication bias. The overall quality of evidence per outcome was determined as high, moderate, low, or very low. We present a summary of the overall strength of evidence available using the GRADE Summary of Findings table produced using GRADEproGTD (https://www.gradepro.org/).

Results

The database search retrieved 2,060records, and the manual search retrieved ten. Of these, we selected 25 for full-text assessment. A total of 15 studies (11 controlled trials and four quasi-experimental studies) fulfilled the inclusion criteria (Fig 1).

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Fig 1. Flow diagram of search results and studies included.

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Characteristics of the studies

Included studies were conducted in 9 different countries, namely Italy [42], Portugal [43], Canada [44], Turkey [7, 45, 46], United States [47], Australia [23], Sweden [48], Poland [49–51], and Iran [52–54]. The studies included were published between 2005 and 2023. Of these, two studies were published in 2009 [47, 48], two in 2018 [46, 50], two in 2019 [43, 51] and two in 2020 [44, 52]. Ten studies [7, 42, 43, 45–48, 52–54] used tensioning mobilisation techniques, three investigations [49–51] used sliding and tensioning techniques, and two studies [23, 44] used sliding mobilisation techniques. The characteristics of the included studies are presented in Table 1.

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Table 1. Descriptions of studies on participants with peripheral neuropathic pain.

https://doi.org/10.1371/journal.pone.0313025.t001

Characteristics of interventions

A controlled trial compared neural mobilisation versus no treatment in 103 patients with carpal tunnel syndrome [51]. One study compared the effect of neural mobilisation in patients with carpal tunnel syndrome [53]. Similarly, another study compared the effect of neural mobilisation in patients with carpal tunnel syndrome and healthy participants [42]. Another study performed neural mobilisation in patients with sciatica and controls [43]. Two studies compared the effect of neural mobilisation in a group of patients with carpal tunnel syndrome with no comparison group [44]. Five studies compared a group of neural mobilisations versus other interventions [23, 45, 46, 49, 54], and two studies compared different regimes of neural mobilisation [7, 52] for participants with carpal tunnel syndrome. Two studies [47, 50] investigated the effects of neural mobilisation compared to the sham technique in participants with carpal tunnel syndrome. One study compared the impact of adding neural mobilisation to information versus other approaches with no neural mobilisation to participants with cubital tunnel syndrome [48].

Eight studies [42, 43, 49–54] offered neural mobilisation individually and in person, performed by a physiotherapist. Five studies [7, 23, 44, 45, 48] provided a neural mobilisation program that could be carried out at home. The neural mobilisation session lasted from 3 to more than 20 minutes. The frequency of neural mobilisation treatment ranged from only one session to seven sessions per week. Treatment periods varied between one session and 12 weeks.

Outcomes

Cross-sectional area.

Two studies examined the cross-sectional area [46, 53]. One study found improvements (i.e., a reduction) in the median cross-sectional area after neural mobilisation with or without kinesiotaping in patients with carpal tunnel syndrome. Both groups reduced the cross-sectional area in the short-term, but there was no statistically significant difference in the cross-sectional area between the groups [46]. One study reported a significant cross-sectional decrease in the median nerve immediately after the treatment of neural mobilisation in a non-randomised study [53].

Nerve motor conduction–Distal motor latency.

Pooled results showed that neural mobilisation did not improve distal motor latency in the short-term (Mean Difference (MD) [95% CI] = 0.05 metre per second (m/s) [-0.42, 0.52]). However, there was substantial heterogeneity (I² = 97%) (Fig 2A). Two hundred and forty-nine participants were involved in the neural mobilisation group, and two hundred and thirty in the control group.

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Fig 2. Forest plots: Neural mobilisation versus control group.

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Six controlled trials tested distal motor latency in the short-term. One study showed that a significant improvement was not found in distal motor latency in groups in the short-term [7]. Another study reported a decreased distal motor latency in both groups (i.e., manual therapy with neural mobilisation or electrophysical modalities) in the short-term [49]. The authors showed an improvement of the distal motor latency only for the neural mobilisation group compared to sham [50]. Similarly, one study revealed that distal motor latency was significantly improved only in the routine physiotherapy plus neural mobilisation group [54]. Also, one study reported a lower value of distal motor latency with neural mobilisation compared to the control group in the short-term [51]. Another study showed decreased distal motor latency in both groups (i.e., neural mobilisation or mechanical interface mobilisation) with no difference in the between-group comparison [52]. Overall, these studies did not improve distal motor latency in the short-term.

Nerve motor conduction–Motor conduction velocity.

Neural mobilisation improved motor conduction velocity in short-term (MD [95% CI] = 2.95 m/s [1.67, 4.22]) with no heterogeneity (I² = 0%) (Fig 2B). Two hundred and six participants were involved in the neural mobilisation group, and one hundred eighty-seven in the control group.

Three controlled trials tested motor conduction velocity in the short-term [49–51]. One study showed no significant difference post-treatment between-group comparison (i.e., manual therapy with neural mobilisation or electrophysical modalities) in motor conduction velocity [49]. Another study demonstrated a superior effect on motor conduction velocity of the neural mobilisation compared to sham after the treatment [50]. Moreover, the authors reported no significant differences between neural mobilisation and the control groups for motor conduction velocity [51]. Overall, these studies successfully improved motor conduction velocity in the short-term.

Nerve sensory conduction–Distal sensory latency.

Neural mobilisation did not improve distal sensory latency in the short-term (MD [95% CI] = -0.20 m/s [-0.24, 0.16]) with no heterogeneity (I² = 0%) (Fig 2C). Forty-three participants were involved in each group.

Three controlled trials analysed the distal sensory latency in the short-term [7, 52, 54]. One study revealed that the treatment combinations were effective in all groups, but there was no significant difference in the between-group comparison [7]. Moreover, there are significant differences within groups for group 1 (splinting and neural mobilisation) and group 3 (splinting, neural mobilisation, and ultrasound therapy) considering the baseline versus immediately after the treatment period and baseline versus after 8 weeks follow-up [7]. Another study showed no significant improvement in distal sensory latency for the mechanical interface group. In the nerve mobilisation group, there was a significant improvement in distal sensory latency. Moreover, there was no significant difference between the two groups in distal sensory latency immediately after the treatment period (p > 0.05) [52]. Finally, one study found that there was no significant change in distal sensory latency in the control group (routine physiotherapy) or treatment group (routine physiotherapy plus neural mobilisation group) [54]. These studies did not improve distal sensory latency in the short-term treatment period.

Nerve sensory conduction–Sensory conduction velocity.

Neural mobilisation improved sensory conduction velocity in the short-term (MD [95% CI] = 11.74 m/s [7.06, 16.43]) with considerable heterogeneity (I² = 77%) (Fig 2D). Two hundred and six participants were involved in the neural mobilisation group, and one hundred and eighty-two in the control group.

Three controlled trials tested sensory conduction velocity in the short-term [49–51]. One study showed that in the manual therapy group (i.e., neural mobilisation), sensory conduction velocity was increased by 34%. Still, there was no change in nerve sensory conduction in the electrophysical modalities group [49]. The authors detected a superior effect on sensory conduction velocity of the neural mobilisation compared to sham after the treatment [50]. Also, another study identified a greater effect favoured neural mobilisation in sensory conduction velocity after ten weeks of treatment (neural mobilisation group: 38.3 m/s, SD = 11.1 vs. control group: 25.9 m/s, SD = 7.72, p < .01) [51]. Overall, these studies were successful in improving sensory conduction velocity in the short-term.

Descriptive analysis

Studies ineligible for pooling.

Median nerve cross-sectional area was measured in two studies, but one study did not have control group data [53]. Three outcomes (median nerve signal intensity, sciatic nerve stiffness, and median nerve integrity) were measured from individual studies with no chance of performing a meta-analysis [23, 43, 44, 46]. One study measuring sensory conduction velocity was ineligible for pooling because of the lack of control group data [42].

Risk of bias and overall quality of evidence.

According to the overall evaluation of the risk of bias of the controlled trials included, the risk of bias tool indicated that six articles had a high risk of bias [7, 45, 46, 48, 50, 52] and five had a low risk of bias [23, 47, 49, 51, 54] (Fig 3). Most studies scored low risk of bias in domains of random sequence generation, allocation concealment, blinding of participants and personnel, blinding of outcome assessment and other sources of bias. A high risk of bias was found frequently in incomplete outcome data. Further information in relation to the risk of bias in controlled trials and motivation for judgments can be found in S4 and S5 Files. Our results revealed that the three studies presented a low risk of bias in the domains of bias due to the selection of participants, bias in the classification of interventions, bias due to deviations from intended interventions, and bias due to missing data. Moreover, three of the four quasi-experimental studies had a serious risk of bias due to the confounding domain, and in the domain of bias in the measurement of outcomes, all studies present a moderate risk of bias. The overall classification showed that of the four quasi-experimental studies, one had a moderate risk of bias [44], and three had a serious risk of bias [42, 43, 53] (Fig 3).

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Fig 3. Risk of bias for included controlled trials and quasi-experimental studies.

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We considered the quality of evidence very low for three pooled outcomes (cross-sectional area, distal motor latency, distal sensory latency, and sensory conduction velocity) and moderate for motor conduction velocity (Table 2).

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Table 2. GRADE summary of findings.

https://doi.org/10.1371/journal.pone.0313025.t002

Discussion

This systematic review investigated the effects of neural mobilisation on nerve function and nerve structure of patients with peripheral neuropathic pain. Utilising nerve conduction tests such as electroneuromyography and imaging exams like ultrasonography and magnetic resonance imaging emerged as the predominant methods for evaluating nerve structure and function in this context. Nearly all studies (86%) investigated the effects of neural mobilisation in patients with carpal tunnel syndrome. The median cross-sectional area improvement should be interpreted cautiously since only a high-risk-of-bias study assessed this outcome using neural mobilisation in both groups treated. Neural mobilisation improves motor and sensory conduction velocity in the short-term despite the lack of improvement in distal motor latency in the short-term and distal sensory latency immediately after the treatment period. The improvement in the motor conduction velocity was rated with moderate quality of evidence, and the other outcomes were rated with very low quality of evidence. Despite most studies showing promising results, only a minority (33%) were considered to have a low risk of bias, suggesting a need for cautious interpretation.

We recognise the strengths and limitations of the present review. To the best of our knowledge, this is the first study that investigated the effect of neural mobilisation on the nerve structure and function of patients with peripheral neuropathic pain. We included only controlled trials and quasi-experimental studies in the systematic review as they provided the best evidence on the effectiveness of neural mobilisation treatment in the nerve function and nerve structure in peripheral neuropathic pain patients. However, including experimental studies that encompass not only neural mobilisation but also other forms of therapy may hamper the identification of the particular effect of the intervention. Nonetheless, the trials in the conservative treatment of radicular pain commonly use a combination of therapeutic options. Including studies with patients with radicular pain without radiculopathy in this systematic review may represent a shortcoming to the nerve function and structure assessment.

Although our search strategy captured several eligible studies, limited evidence was available on the change of nerve cross-sectional area outcome, with studies predominately providing data on our secondary outcomes (nerve conduction tests). The current body of evidence highlights this research area has focused on patients with carpal tunnel syndrome, and only one study has investigated the sciatic nerve. Less than half (n = 7, 50%) of the included studies were published in the last five years, and the investigation in this field needs to implement methodological improvements since 64% of the studies had a high or serious risk of bias.

Neural mobilisation potentially reduces the cross-sectional area of the nerve. Our review found two studies supporting the decrease of the cross-sectional area as a marker of improvement after neural mobilisation in patients with carpal tunnel syndrome [46, 53]. Previous studies described a cross-sectional area reduction after surgical procedures for patients with carpal tunnel syndrome [55–57]. Thus, the positive sonography outcome after neural mobilisation is likely due to the favourable clinical findings previously demonstrated in many systematic reviews [19, 20, 22]. Furthermore, a notable relationship exists between the nerve cross-sectional area and nerve conduction studies in patients with carpal tunnel syndrome [58, 59].

Nerve conduction studies are helpful to investigate motor and sensory conduction velocity in patients with radiculopathies. The current investigation found that neural mobilisation improves motor and sensory conduction velocity in the short-term. We confirmed the positive effect of neural mobilisation on nerve conduction velocity described in two previous systematic reviews that focussed on carpal tunnel syndrome [60, 61], using a robust meta-analysis with the change from baseline and expanded the findings to the improvement of the cross-sectional area of the median nerve. Moreover, another systematic review found very low-quality evidence that neural mobilisation did not affect distal motor latency in patients with carpal tunnel syndrome [62], similar to our findings. Thus, neural mobilisation leads to a partial recovery of nerve function in patients with carpal tunnel syndrome and possibly in other peripheral neuropathies. The improvement in the nerve conduction velocity may represent a remyelination process after the therapeutic since the conduction velocity evaluates the demyelination of the large-diameter fibres. The current systematic review expands on the effect of neural mobilisation on nerve function and nerve structure for two other clinical conditions. One study described improved nerve conduction velocity of patients with cubital tunnel syndrome who had impairment in the baseline assessment submitted to elbow brace, neural mobilisation, or clinical information interventions [48].

In clinical practice, the findings from this systematic review suggest that neural mobilisation may be an intervention for patients with peripheral neuropathic pain, particularly those with carpal tunnel syndrome. Improving motor and sensory conduction velocity in the short term indicates a potential benefit in promoting nerve recovery. Clinicians should consider incorporating neural mobilisation into their treatment plans for these patients, keeping in mind the limitations of the current evidence, including the predominance of studies focused on carpal tunnel syndrome and the high risk of bias in many studies. The observed reduction in nerve cross-sectional area after neural mobilisation in carpal tunnel syndrome patients highlights a potential positive impact on nerve structure. However, given the limited research on other peripheral neuropathies and the need for high-quality, well-designed studies to minimise bias, clinicians should approach the integration of neural mobilisation into practice with a balanced consideration of the available evidence and patient-specific factors. The identified biases, such as lack of blinding and incomplete outcome data, underscore the importance of future research efforts in addressing these methodological shortcomings and enhancing the overall quality of evidence in this field.

Few studies have investigated neural mobilisation and its effectiveness in nerve structure and function of patients with peripheral neuropathic pain, considering the same aspects (patient population, technique used, outcome evaluation tool, and follow-up time). Therefore, controlled trials with detailed neural mobilisation schema measured by objective outcomes must facilitate clinicians’ decision-making. In this systematic review, the most commonly observed bias was the lack of blinding of the participant or therapist who administered the therapy, incomplete outcome data and selective reporting. Hence, future high-quality studies should be designed to minimise this bias. Finally, nerve structure and function parameters are essential in understanding how the nervous system behaviours and their changes can have various implications. These parameters revealed that certain aspects of the nerve’s physiology or signal transmission have been altered after the neural mobilisation treatment.

Conclusion

Neural mobilisation seems to improve the cross-sectional area, albeit with very low-quality evidence, affecting the certainty of these findings. Neural mobilisation was superior to control in improving motor conduction velocity in patients with peripheral neuropathic pain with moderate quality evidence. Neural mobilisation was superior in improving sensory conduction velocity and presented similar results in distal motor and distal sensory latency compared to controls in patients with peripheral neuropathic pain based on very low-quality evidence. Caution is needed to generalise the results since most investigations focused on patients with carpal tunnel syndrome.

Supporting information

S1 File. This is the PRISMA 2020 checklist.

https://doi.org/10.1371/journal.pone.0313025.s001

(DOCX)

S2 File. This is the search strategy.

https://doi.org/10.1371/journal.pone.0313025.s002

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S3 File. This is the list of the studies.

https://doi.org/10.1371/journal.pone.0313025.s003

(XLSX)

S4 File. This is the risk of bias of randomised clinical trials studies and motivation for judgments.

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S5 File. This is the risk of bias of randomised clinical trials studies and motivation for judgments.

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S1 Table. Reason for exclusion of full-text studies.

https://doi.org/10.1371/journal.pone.0313025.s006

(DOCX)

S2 Table. Data extracted from each study for the meta-analysis.

https://doi.org/10.1371/journal.pone.0313025.s007

(DOCX)

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Figures

Abstract

Objective

Methods

Results

Conclusion

Introduction

Materials and methods

Protocol and registration

Data sources and searches

Eligibility criteria

Study selection

Data extraction

Outcomes measures

Data synthesis

Data analysis

Risk of bias and certainty of evidence

Results

Characteristics of the studies

Characteristics of interventions

Outcomes

Cross-sectional area.

Nerve motor conduction–Distal motor latency.

Nerve motor conduction–Motor conduction velocity.

Nerve sensory conduction–Distal sensory latency.

Nerve sensory conduction–Sensory conduction velocity.

Descriptive analysis

Studies ineligible for pooling.

Risk of bias and overall quality of evidence.

Discussion

Conclusion

Supporting information

S1 File. This is the PRISMA 2020 checklist.

S2 File. This is the search strategy.

S3 File. This is the list of the studies.

S4 File. This is the risk of bias of randomised clinical trials studies and motivation for judgments.

S5 File. This is the risk of bias of randomised clinical trials studies and motivation for judgments.

S1 Table. Reason for exclusion of full-text studies.

S2 Table. Data extracted from each study for the meta-analysis.

References