Open versus endoscopic carpal tunnel release: A systematic review and meta-analysis of randomized controlled trials

DOI: https://doi.org/10.21203/rs.2.22968/v1

Abstract

Background

Endoscopic carpal tunnel release (ECTR) and open carpal tunnel release (OCTR) both have advantages and disadvantages for the treatment of carpal tunnel syndrome (CTS). We compared the effectiveness and safety of ECTR and OCTR based on evidence from a high-level randomized controlled trial.

Methods

We comprehensively searched PubMed, EMBASE, Cochrane Library, Web of Science, and Medline to identify relevant articles published until August 2019. Data regarding operative time, grip strength, Boston Carpal Tunnel Questionnaire scores, digital sensation, patient satisfaction, key pinch strength, return to work time, and complications were extracted and compared. All mean differences (MD) and odds ratios (OR) were expressed as ECTR relative to OCTR.

Results

Twenty-eight studies were included in our meta-analysis. ECTR was associated with significantly higher satisfaction rates (MD, 3.13; 95% confidence interval [CI], 1.43 to 4.82; P = 0.0003), greater key pinch strengths (MD, 0.79 kg; 95% CI, 0.27 to 1.32; P = 0.003), earlier return to work times (MD, -7.25 days; 95% CI, -14.31 to -0.19; P = 0.04), higher transient nerve injury rates (OR, 4.87; 95% CI, 1.37 to 17.25; P = 0.01), and a lower incidence of scar-related complications (OR, 0.20; 95% CI, 0.07 to 0.59; P = 0.004). There were no significant differences between the two methods in terms of permanent nerve injury (OR, 1.93; 95% CI, 0.58 to 6.40; P = 0.28).

Conclusions

Overall, evidence from randomized controlled trials indicates that ECTR results in better recovery of daily life functions than OCTR, as revealed by higher satisfaction rates, greater key pinch strengths, earlier return to work times, and fewer scar-related complications. Our findings suggest that patients with CTS can be effectively managed with ECTR.

1. Background

Carpal tunnel syndrome (CTS), known as compressive median mononeuropathy at the wrist, causes tingling, numbness, and pain along the radial side of the hand (1). The reported estimates for its annual prevalence range from 0.18% to 5% (2–5). CTS can be treated surgically or non-surgically; however, non-surgical management that involves wrist splinting, corticosteroid injections, and physiotherapy, is preferred over surgical management for mild and moderate CTS (6,7). Surgical treatments for CTS, including the open carpal tunnel release (OCTR) and endoscopic carpal tunnel release (ECTR) approach, are generally reserved for patients with severe symptoms or those who experience conservative treatment failure (8,9).

OCTR is a well-established surgical treatment for CTS (10). However, it is associated with potential complications such as persistent weakness, pillar pain, formation of hypertrophic scars in the incisions that cross the wrist, scar tenderness, slow recovery, and a higher incidence of persistent pain (11). In an attempt to avoid these complications, Chow (12) first reported ECTR in 1989 for the treatment of CTS. This method allows for smaller skin incisions and better esthetic results than OCTR (1,13,14). Nevertheless, ECTR is technically difficult, time consuming, and associated with incomplete transverse carpal ligament release and neurovascular injury (15–19). Several meta-analyses have compared various measures of efficacy and safety between ECTR and OCTR (14,20–22). However, these investigations failed to separate subgroups according to different follow-up times and utilized limited evaluations of patient outcomes; therefore, it is not clear which approach is associated with better clinical results (23,24).

Therefore, we performed a meta-analysis of published results to compare the effectiveness and safety between ECTR and OCTR according to randomized controlled trial (RCT) evidence. Specifically, we sought to determine if ECTR was superior to OCTR in terms of patient satisfaction, functional recovery, and complications.

2. Methods

2.1. Literature search

The meta-analysis was performed according to the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) guidelines (25). Two authors independently used PubMed, EMBASE, Cochrane Library, Web of Science, and Medline databases to search for relevant publications. Publications from the inception of each database to August 10, 2019 were searched. The keywords used in the searches were “carpal tunnel” plus “open incision” and “carpal tunnel” plus “endoscopic.” To identify other relevant studies, we manually scanned the reference lists of the relevant articles that were discovered using these search terms.

2.2. Criteria for selected trials

A study was included if it was an RCT that compared OCTR and ECTR. The exclusion criteria were as follows: 1) descriptive or graphic outcomes with no standard deviation values, 2) studies that evaluated revision surgery, 3) studies that did not report the follow-up interval, 4) studies that reported only limited qualitative findings, 5) studies published in a language other than English or Chinese, and 6) abstracts, laboratory or anatomic studies, review or technique articles, commentaries, and nontherapeutic studies. Finally, two investigators independently reviewed all selected studies for inclusion.

2.3. Data extraction

Two independent reviewers extracted data from the included studies. Any discrepancy in data interpretation was resolved either by discussion or by involving a third reviewer until a consensus was reached for all items.

The data extracted from eligible studies included publication year, country of origin, sample size, intervention details, follow-up interval, and outcomes. If outcome data and measures of variance were reported graphically but were omitted from the body of the text, plot-digitizing software (Plot Digitizer Version 2.6.4; Joseph Huwaldt and Scott Steinhorst, http://www.plot-digitizer.com-about.com/) was used to quantify these data. The pooled analysis outcome parameters were as follows: operation duration; scores on several clinical indexes, including the Boston Carpal Tunnel Questionnaire Symptom Severity Scale (BCTQ-S), Boston Carpal Tunnel Questionnaire Functional Status Scale (BCTQ-F), Two-point Discrimination test, and Semmes-Weinstein monofilament test; grip strength; key pinch strength; time to return to work (RTW); patients’ subjective ratings of their satisfaction with symptom improvement following CTS release based on a scale of 0 to 100 points; and postoperative complications.

2.4. Quality assessment

The level of evidence was assessed according to the Grading of Recommendations Assessment, Development, and Evaluation (GRADE) guidelines (26). At least two reviewers independently assessed the risk of bias, and disagreements were resolved through discussion.

2.5. Statistical analysis

Continuous data were analyzed using the inverse-variance statistical method and computation of the mean difference (MD) and 95% confidence interval (CI). Dichotomous data were analyzed using the Mantel-Haenszel statistical method and computation of the odds ratio (OR) and 95% CI. All MD and OR values were calculated using the results from OCTR as the reference values. In addition, χ2 and I2 tests were used to assess statistical heterogeneity. Significant heterogeneity was indicated when the P value from the χ2 test was < 0.10 or when the I2 value exceeded 50%. If heterogeneity was present, a random-effects model was applied to assess the pooled result of the outcome measure; otherwise, a fixed-effects model was used. All tests were two-tailed, and the threshold for statistical significance was set at P < 0.05. The possibility of publishing bias was not assessed because of the limited number of studies included. The data were further analyzed using Review Manager (version 5.3; The Nordic Cochrane Centre, Cochrane Collaboration, Copenhagen, Denmark).

3. Results

3.1. Selected studies and characteristics

Figure 1 summarizes the number of articles identified, reviewed, and included in the final analysis. A total of 5,654 relevant articles were initially identified from PubMed (n = 1,416), EMBASE (n = 1,755), Cochrane Library (n = 248), Web of Science (n = 1,130), Medline (n = 1,105), and reference lists (n = 0). After exclusion of duplicates, 2,248 articles remained. Reviews of the titles and abstracts reduced the number of articles to 103, and a more detailed review reduced this number further to 28 articles for final inclusion in the meta-analysis. Twenty-seven articles were in English and one was in Chinese. The characteristics of the included articles are summarized in Table 1.

3.2. Quality assessment

According to the GRADE guidelines, 19 RCTs reported adequate methods for random sequence generation. Only 8 RCTs had low risks of detection bias for outcomes. The majority of RCTs (25/28) failed to report the blinding status of patients, study personnel, and outcome assessors. Attrition bias was judged as low risk for 22 RCTs. All RCTs were at a low risk of selective reporting of outcomes (Fig. 2).

3.3. Meta-analysis results

There were no significant differences in the operative time (MD, -5.81 min; 95% CI, -17.85 to 6.23; P = 0.34; n = 261; random-effects model, with a heterogeneity of I2 = 99%; P < 0.00001; Fig. 3) (27–30), grip strength at 3 months post-surgery (MD, 1.99 kg; 95% CI, -0.43 to 4.42; P = 0.11; n = 297; fixed-effects model, with a heterogeneity of I2 = 0%; P = 0.79; Fig. 4) (9,31), BCTQ-S score at 1 year post-surgery (MD, 0.15; 95% CI, -0.04 to 0.35; P = 0.13; n = 592; random-effects model, with a heterogeneity of I2 = 92%; P < 0.00001; Fig. 5) (24,32,33), and BCTQ-F score at 1 year post-surgery (MD, 0.17; 95% CI, -0.02 to 0.36; P = 0.08; n = 592; random-effects model, with a heterogeneity of I2 = 91%; P < 0.00001; Fig. 6) (24,32,33) between the ECTR and OCTR groups. Similarly, there were no differences in digital sensation, including the Semmes-Weinstein monofilament test score at 3 months post-surgery (MD, 0.06; 95% CI, -0.09 to 0.21; P = 0.43; n = 297; fixed-effects model, with a heterogeneity of I2 = 0%; P = 0.65; Fig. 7) (9,31) and Two-point Discrimination test score at 1 year post-surgery (MD, -0.16; 95% CI, -0.45 to 0.12; P = 0.26; n = 402; fixed-effects model, with a heterogeneity of I2 = 35%; P = 0.20; Fig. 8) (29,33,34), between the two groups.

3.3.1. Satisfaction rate

The overall level of satisfaction with the outcome was based on a scale of 0 to 100 points. Two articles provided comparative data on the satisfaction rate (31,33). A portion of the data from Zhang et al. (33) reported a satisfaction rate of up to 90%, with high heterogeneity; therefore, some of the satisfaction data from that study were excluded from the present meta-analysis. The pooled data of the two articles showed that the satisfaction rate in the ECTR group was significantly higher than that in the OCTR group (MD, 3.13; 95% CI, 1.43 to 4.82; P = 0.0003; n = 303; fixed-effects model, with a heterogeneity of I2 = 0%; P = 0.57) (31,33), and the clinical heterogeneity I2 was null (Fig. 9).

3.3.2. Key pinch strength

The pooled data showed that the key pinch strength of patients who were treated with ECTR was significantly greater than the key pinch strength of patients who were treated with OCTR at 3-months post-surgery (MD, 0.79 kg; 95% CI, 0.27 to 1.32; P = 0.003; n = 297; fixed-effects model, with a heterogeneity of I2 = 0%; P = 0.70) (9,31) (Fig. 10).

3.3.3. RTW

Four studies (30,35–37) evaluated the time needed to return to work for patients who underwent CTS. The pooled data showed that the RTW times were significantly faster in patients in the ECTR group than those in the OCTR group (MD, -7.25 days; 95% CI, -14.31 to -0.19; P = 0.04; n = 357; random-effects model, with a heterogeneity of I2 = 98%; P < 0.00001) (Fig. 11); however, divergences between studies resulted in large between-study heterogeneity.

3.3.4. Complications

Twenty-five studies (9,23,27-49) included complete complication rate data and were included in the pooled analysis of overall complications. The rates of transient nerve injury were higher in patients who underwent ECTR than those in patients who underwent OCTR (OR, 4.87; 95% CI, 1.37 to 17.25; P = 0.01; n = 2320; fixed-effects model, with a heterogeneity of I2 = 0%; P = 0.98) (Fig. 12); however, the studies provided evidence that the presence of permanent nerve injury was not significantly different between the two groups (OR, 1.93; 95% CI, 0.58 to 6.40; P = 0.28; n = 2320; fixed-effects model, with a heterogeneity of I2 = 29%; P = 0.24) (Fig. 13). The rates of scar-related complications (scar hypertrophy, scar hyperesthesia, scar pain) were lower in patients who underwent ECTR than those in patients who underwent OCTR (OR, 0.20; 95% CI, 0.07 to 0.59; P = 0.004; n = 2320; fixed-effects model, with a heterogeneity of I2 = 0%; P = 0.90) (Fig. 14). Other complications, such as hematoma, wound infection, superficial palmar arch injury, persistent symptoms, pillar pain, reflex sympathetic dystrophy, and tendon injury, were not significantly different between the two groups. The summary of all outcome variables is shown in Table 2.

4. Discussion

Since the development of ECTR by Chow (12) and Okutsu et al. (50) in 1989, there has been controversy regarding the superiority of ECTR over OCTR. Accordingly, many original articles have been published on this issue; moreover, several meta-analyses have compared ECTR with OCTR as treatment options for CTS (13,14,20–22,51–53). However, previous meta-analyses included fewer studies than ours, did not classify the data into subgroups according to different follow-up times, featured only a few assessments of patient outcome, and included central tendency data but not standard deviation. Therefore, we performed a large sample-size meta-analysis of published results to compare the effectiveness and safety of the two surgical approaches.

Our meta-analysis reviewed 28 RCTs that consisted of 2,320 idiopathic CTS hands treated with OCTR or ECTR. The results clearly indicated that there were no significant between-group differences in the operative time, grip strength, BCTQ-S score, BCTQ-F score, digital sensation scores, and the presence of permanent nerve injury. However, the ECTR group exhibited several clinically important advantages over the OCTR group, including higher patient satisfaction rates, greater key pinch strengths, earlier RTW times, and fewer scar-related complications.

Consistent with the present results, previous studies demonstrated that the satisfaction rates of patients in the ECTR group were higher than those of patients in the OCTR group (23,46,54). Compared with the standard open approach, reduction in scar tenderness after endoscopic release is plausible, owing to the generally small incisions, reduced scarring, mild wound-related complications (33), and improvements in the major functional outcomes (key pinch strength, activities of daily living, and RTW) (31). However, it should be noted that when assessing the patient satisfaction rates, a portion of the data published by Zhang et al. (33) exhibited high heterogeneity. Therefore, these data were excluded from the present meta-analysis. The high heterogeneity was mainly because of the fact that the data compared mini-incisions with endoscopic incisions. Mini-incisions are not directly comparable to the standard incisions in OCTR, as they yield a better appearance and tend to have fewer wound-related complications than standard incisions (55).

Herein, the key pinch strength of patients in the ECTR group was significantly greater than that in the OCTR group at 3 months postoperatively (9,31). Additionally, previous studies reported that OCTR was associated with considerable morbidity, including increased and prolonged scar tenderness (11). Furthermore, other studies revealed that patients who underwent ECTR experienced fewer limitations in their ability to perform daily life activities than did patients who underwent an open technique (35,56–58). Michelotti et al. (54) reported early differences in grip and pinch strength after ECTR; however, data were lost as the follow-up duration increased. Further studies should include a more uniform follow-up duration, and additional controlled studies with longer follow-up durations are required to clarify the effects of each technique on activities of daily living.

The finding of our meta-analysis of RCTs suggest that patients treated with ECTR returned to work or daily activities earlier than those treated with OCTR. Consistent with our results, Vasiliadis et al. (21) and Paryavi et al. (52) reported that patients who underwent ECTR experienced less surgical trauma than those who underwent an open technique, and this resulted in less time off work, faster recovery, and better performance of daily activities. However, regarding the RTW data, we noticed that divergences between the studies resulted in large between-study heterogeneity. A possible explanation for this large variability is that the flexibility required for the work and the nature of the work and daily activities may have been substantially different in the included studies. Furthermore, while Sanati et al. (53) demonstrated the superiority of minimally invasive techniques over conventional open release in terms of recovery time, they highlighted the remarkable inconsistencies in how RTW as an outcome measure was examined across studies. Nevertheless, the effects of such inconsistencies were rather small when only RCTs were considered, similar to that observed in our study. Compared with open release, patients undergoing endoscopic release can return to work and their daily activities sooner.

Our meta-analysis revealed that lower scar-related complication rates and better healing were achieved in the ECTR group than in the OCTR group. This may be because of the extended incision in the palm made during OCTR that may extend the immobilization time and increase postoperative pain and the risk for hypertrophic or hypersensitive scars (21). In contrast, ECTR uses a small incision and divides the transverse carpal ligament from below, thereby preserving the overlying skin and muscle and resulting in fewer minor complications (59,60), particularly those related to cutaneous scars. However, previous studies demonstrated that ECTR is associated with more nerve injury; therefore, the technique is less favorable owing to its higher risk of iatrogenic injury to the cutaneous branch of the median nerve (14,18,33). Contrary to expectations, our study did not find a significant difference in the occurrence of permanent nerve injury between the two surgical approaches; furthermore, most noted nerve injuries were transient, and patients still achieved full recovery after surgery (36,37,49,61). Moreover, Martin et al. (62) developed a novel endoscopic system which may avoid the transient nerve injury occurring with other ECTR methods.

4.1. Limitations

This study had two limitations. First, subgroup analyses of the various ECTR techniques (one-portal and two-portal techniques) and OCTR techniques (mini-incision and long incision) were not performed. Although the use of different techniques may be associated with different outcomes, we were unable to perform subgroup analyses because of the rather small number of studies and limited available data. Second, although we included only RCTs, all the trials had methodological flaws, including unblinded assessments of outcomes.

Nevertheless, our study is novel since it includes the largest number of RCTs to compare ECTR and OCTR techniques. Furthermore, this is the first study to group results into different follow-up times and assess different patient outcomes, thus making the data more comparable. We found that after careful manipulation during endoscopic surgery, ECTR can substitute OCTR, and this the first study to demonstrate that ECTR is associated with better patient outcomes.

5. Conclusions

The present meta-analysis determined that ECTR was superior to OCTR in terms of higher satisfaction rates, improved key pinch strengths, earlier RTW times, and fewer scar-related complications. Our findings suggest that patients with CTS can be effectively managed with ECTR; however, the possibility of transient nerve injury should be considered.

List Of Abbreviations

CTS: carpal tunnel syndrome

OCTR: open carpal tunnel release

ECTR: endoscopic carpal tunnel release

RCT: randomized controlled trial

PRISMA: Preferred Reporting Items for Systematic Reviews and Meta-Analyses

BCTQ-S: Boston Carpal Tunnel Questionnaire Symptom Severity Scale

BCTQ-F: Boston Carpal Tunnel Questionnaire Functional Status Scale

RTW: return to work

GRADE: Grading of Recommendations Assessment, Development, and Evaluation

MD: mean difference

CI: confidence interval

OR: odds ratio

Declarations

Ethics approval and consent to participate

This article does not contain any studies involving human participants conducted by any of the authors.

Consent for publication

Not applicable.

Availability of data and materials

The datasets used and/or analyzed during the current study are available from the corresponding author on reasonable request.

Competing interests

The authors declare that they have no competing interests.

Funding

This work was supported by the Jilin Scientific and Technological Development Program [grant number 20190905003SF]. The funding institution was responsible for the provision of literature database resources and literature purchase. The funding body had no role in the design of the study and collection, analysis, and interpretation of data and in writing the manuscript.

Authors' contribution

Conception and design: X.G. and Z.Z. Acquisition of data: Y.L., W.L., G.W., and S.C. Analysis and interpretation of data: Y.L., W.L., Z.Z., and X.G. Drafting the article: Y.L., W.L., and S.C. Critically revision of the article: Y.L., W.L., G.W., Z.Z., and X.G. Reviewed submitted version of manuscript: Y.L., W.L., G.W., and S.C. Study supervision: X.G., Z.Z., and Y.L. All authors read and approved the final manuscript.

Acknowledgments

Not applicable.

 

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Tables

Table 1. Study characteristics of the randomized controlled trials included in the meta-analysis

Author

Year

Region

Groups, sample sizes, and techniques

Follow-up interval

Outcomes

Agee et al. (38)

1992

US

OCTR (n=65): conventional release

ECTR (n=82): one-portal (2 cm)

1, 2, 3, 6, 9, 13, 26 week(s)

Return of hand use for ADL, time to RTW, grip strength, pinch strength, lateral/key and pulp strength, SW monofilament test, Phalen’s wrist flexion test, Tinel’s test, scar tenderness, radial and ulnar pillar tenderness, record of medication use, complications

Atroshi et al. (9) 

2006

Sweden

OCTR (n=65): 4 cm

ECTR (n=63): two-portal (1 cm) 

3, 6 weeks;

3, 12 months

Pain, time to RTW, BCTQ-S, BCTQ-F, SF-12, sensation, grip strength, key pinch strength, DL, quality of life, SW monofilament test, 2PD test, complications

Atroshi et al. (61)

2009

Sweden

OCTR (n=63): 4 cm

ECTR (n=63): two-portal (1 cm)

1, 5 year(s)

Operative time, satisfaction rating, symptom relief, BCTQ-S, BCTQ-F, pain score, complications

Atroshi et al. (24) 

2015

Sweden

OCTR (n=61): 4 cm

ECTR (n=63): two-portal (1 cm)

1, 11–16 year(s)

BCTQ-S, BCTQ-F, pain score, numbness and tingling, satisfaction score, quick DASH, pain scale, complications

Aslani et al. (35)

2012

Iran

OCTR (n=36): conventional release

OCTR (n=28): mini-incision

ECTR (n=32): two-portal (length NR)

4 weeks;

4 months

Numbness, nocturnal pain, wrist pain, weakness and stiffness, Tinel’s test, Phalen’s wrist flexion test, EMG, NCV, strength to grasp, time to RTW and ADL, satisfaction rating, operative time, complications

Brown et al. (31)

1993

US

OCTR (n=82): conventional release

ECTR (n=78): two-portal (2 cm)

3, 6, 12 weeks

2PD test, SW monofilament test, APB strength, thenar atrophy, grip strength, key pinch strength, pain, numbness, paresthesia, weakness, Tinel’s test, Phalen’s wrist flexion test, interstitial carpal tunnel pressure, satisfaction rating, time to RTW, rate of ADL impairment, ADL score, operative time, hospital cost, complications

Dumontier et al. (39)

1995

France

OCTR (n=40): conventional release

ECTR (n=56): two-portal (Chow (12))

2 weeks;

1, 3, 6 month(s)

Paresthesia, pain, time to RTW, grip strength, finger mobility, complications

Ejiri et al. (40)

2012

Japan

OCTR (n=50): 3 cm vertical incision

ECTR (n=50): one-portal (Okutsu et al. (50))

1, 3 month(s)

Paresthesia, nighttime pain, impairment of ADL, APB-DL, SW monofilament test, 2PD test, grip strength, pinch strength, key pinch strength, complications

Erdmann (41)

1994

UK

OCTR (n=52): NR (short length)

ECTR (n=53): two-portal (Chow (12))

1, 2 week(s);

1, 3, 6 month(s);

1 year

Grip and pinch strength, time to normal grip strength, time to normal pinch strength, time to RTW, ADL, time to relief of symptoms, median nerve motor and sensory DL, VAS pain score, complications

Ferdinand and MacLean (27)

2002

UK

OCTR (n=25): NR

ECTR (n=25): one-portal

6, 12, 26 weeks;

13 months

VAS scores (numbness, pain, and paresthesia), ADL, return to full activities, time to RTW, thenar muscle strength, lateral pinch strength, grip strength, wrist and finger movement, 2PD test, Jebson score, operative time, satisfaction rating, complications

Gümüştaş et al. (42)

2015

Turkey

OCTR (n=20): NR (Taleisnik (63))

ECTR (n=21): two-portal (Chow (12))

6 months

BCTQ-S, BCTQ-F, median nerve motor DL, CMAP, SCV, sensory nerve action potential, complications

Jacobson and Rahme (36)

1996

Sweden

OCTR (n=16): conventional release

ECTR (n=16): two-portal (Chow (12))

2, 6, 24 weeks

Symptom relief, total number of analgesics, 2PD test, time to RTW, nerve conduction test, complications

Kang et al. (28)

2013

South Korea

OCTR (n=52): mini-incision (1.5 cm)

ECTR (n=52): one-portal (Agee et al. (38))

3 months

BCTQ-S, BCTQ-F, DASH, complications

Larsen et al. (43)

2013

Denmark

OCTR (n=30): classic incision, 7 cm

OCTR (n=30): short incision, 3 cm

ECTR (n=30): one-portal (Menon (64))

1, 2, 3, 6, 12, 24 week(s)

VAS (pain), grip strength, range of motion, pillar pain, VAS (paresthesia), time to RTW, complications 

Macdermid et al. (44)

2003

Canada

OCTR (n=32): conventional release

ECTR (n=91): two-portal (Chow (12))

1, 6, 12 week(s)

Time to RTW, McGill pain questionnaire, key pinch strength, tripod pinch strength, grip strength, symptom severity score (Likert score), sensory threshold, self-report scale, SF-36, complications

Mackenzie et al. (45)

2000

US

OCTR (n=14): 2.5 cm palmar incision

ECTR (n=22): one-portal (Agee et al. (38))

1, 2, 4 week(s)

Grip strength, pinch strength, BCTQ-S, BCTQ-F, complications

Martínez et al. (23)

2019

Spain

OCTR (n=52): 1 cm mini-incision

ECTR (n=35): one-portal (Menon (64))

1 week;

1, 6, 12 month(s)

Grip strength, pinch strength, VAS pain score, satisfaction questionnaire, complications

Michelotti et al. (54)

2014

US

OCTR (n=25): 3 cm palmar incision

ECTR (n=25): one-portal (Agee et al. (38), 1.5 cm)

2, 4, 8, 12, 24 weeks

2PD test, SW monofilament test, thenar strength, grip strength, BCTQ-S, BCTQ-F, satisfaction rating, complications

Michelotti et al. (46)

2018

US

OCTR (n=30): 3 cm palmar incision

ECTR (n=30): one-portal (Agee et al. (38), 1.5 to 2 cm)

2, 4, 8, 12, 24 weeks

VAS pain score, 2PD test, SW monofilament test, thenar strength, grip strength, BCTQ-S, BCTQ-F, satisfaction rating, complications

Oh et al. (47)

2017

South Korea

OCTR (n=32): mini-incision (1.5 cm) 

ECTR (n=35): one-portal (Agee et al. (38), 1.5 cm)

24 weeks

BCTQ-S, BCTQ-F, DASH, CSA, CSA-I, CSA-M, CSA-O, flattening ratio, complications

Rab et al. (48)

2006

Austria

OCTR (n=10): two mini-incisions

ECTR (n=10): two-portal (Chow (12))

2, 4, 6, 12 weeks; 6, 12 months

VAS pain score, grip strength, pinch strength, key pinch strength, ADL, BCTQ-S, BCTQ-F, 2PD, DL, NCV, complications

Saw et al. (37)

2003

UK

OCTR (n=42): 2 cm palmar incision

ECTR (n=43): one-portal (Agee et al. (38))

1, 3, 6, 12 week(s)

BCTQ-S, BCTQ-F, grip strength, VAS pain score, time to RTW, operation time, complications

Sennwald and Benedetti (49)

1995

Switzerland

OCTR (n=22): Sennwald incision

ECTR (n=25): one-portal (Agee et al. (38), 2–3 cm)

4, 8, 12 weeks

Grip strength, key pinch strength, time to RTW, complications

Tian et al. (34)

2007

China

OCTR (n=36): S-shaped incision

ECTR (n=34): one-portal (Okutsu et al. (50), 1 cm)

2 years

Symptom improvement, operation time, hospital stay time, time to RTW, 2PD test, grip strength, scar tenderness, complications

Trumble et al. (32)

2002

US

OCTR (n=95): palmar incision (3~4 cm)

ECTR (n=97): one-portal (Agee et al. (38), 1 cm)

2, 4, 8, 12, 26, 52 weeks

BCTQ-S, BCTQ-F, 2PD test, satisfaction rating, grip strength, pinch strength (key pinch, three-jaw), hand dexterity, time to RTW, thenar atrophy, strength of APB, complications

Wong et al. (29)

2003

Hong Kong

OCTR (n=30): mini-incision

ECTR (n=30): two-portal (Chow (12))

2, 4, 8, 16 weeks; 6, 12 months

VAS pain score, grip strength, pinch strength, 2PD test, operation time, symptom relief, incision length, complications

Zhang et al. (33)

2016

China

OCTR (n=72): double small incision 

OCTR (n=65): standard incision (5–7 cm)

ECTR (n=69): two-portal (Chow (12))

3 years

BCTQ-S, BCTQ-F, patient satisfaction, VAS pain score, cylindrical strength, lateral strength, pinch strength, grip strength, time to RTW, 2PD test, SW monofilament test, hospital cost, complications

Zhao et al. (30)

2004

China

OCTR (n=21): S-shaped incision

ECTR (n=26): one-portal (Okutsu et al. (50), 1 cm)

2 years

EMG, operation time, hospital stay time, 2PD test, time to RTW, complications

2PD: Two-point Discrimination; ADL: activities of daily living; APB: abductor pollicis brevis; BCTQ-F: Boston Carpal Tunnel Questionnaire Functional Status Scale; BCTQ-S: Boston Carpal Tunnel Questionnaire Symptom Severity Scale; CMAP: compound muscle action potential; CSA: cross-sectional area; CSA-I: inlet at the distal wrist crease level; CSA-M: the middle of the tunnel at the level of the pisiform; CSA-O: the tunnel outlet at the level of the hamate hook; DASH: Disability of Arm, Shoulder, and Hand Questionnaire; DL: distal latency; ECTR: endoscopic carpal tunnel release; EMG: electromyography; NCV: nerve conduction velocity; NR: not reported; OCTR: open carpal tunnel release; RTW: return to work; SCV: sensory conduction velocity; SF-12: 12-Item Short Form Health Survey; SF-36: 36-Item Short Form Health Survey; SW: Semmes-Weinstein; UK: United Kingdom; US: United States; VAS: Visual Analog Scale.

 

Table 2. Summary estimates of outcome variables in the current study

Outcome

No. of studies

Heterogeneity I2* (%)

Pooled odds ratio

Mean difference

95% confidence interval (lower bound)

95% confidence interval (upper bound)

Operative time

4

99

NA

-5.81

-17.85

6.23

Grip strength

2

0

NA

1.99

-0.43

4.42

BCTQ-S score

3

92

NA

0.15

-0.04

0.35

BCTQ-F score

3

91

NA

0.17

-0.02

0.36

SW monofilament test score

2

0

NA

0.06

-0.09

0.21

2PD test score

3

35

NA

-0.16

-0.45

0.12

Satisfaction rate

2

0

NA

3.13

1.43

4.82

Key pinch strength

2

0

NA

0.79

0.27

1.32

Return to work

4

98

NA

-7.25

-14.31

-0.19

Transient nerve injury

25

0

4.87

NA

1.37

17.25

Permanent nerve injury

25

29

1.93

NA

0.58

6.4

Scar-related complications

25

0

0.2

NA

0.07

0.59

Hematoma

25

0

1.60

NA

0.36

7.16

Wound infection

25

0

0.53

NA

0.15

1.97

Superficial palmar arch injury

25

NA

3.07

NA

0.12

76.48

Persistent symptoms

25

0

2.17

NA

0.85

5.55

Pillar pain

25

35

0.95

NA

0.32

2.82

Reflex sympathetic dystrophy

25

0

0.40

NA

0.10

1.65

Tendon injury

25

NA

0.26

NA

0.01

6.50

2PD: Two-point Discrimination; BCTQ-F: Boston Carpal Tunnel Questionnaire Functional Status Scale; BCTQ-S: Boston Carpal Tunnel Questionnaire Symptom Severity Scale; ECTR: endoscopic carpal tunnel release; NA: not applicable; OCTR: open carpal tunnel release; SW: Semmes-Weinstein. 

*Heterogeneity test: I2 > 50%, random-effects analysis model; I2 < 50%, fixed-effects analysis model.

If odds ratio >1, favors ECTR; if odds ratio <1, favors OCTR.

If mean difference >0, favors ECTR; if mean difference <0, favors OCTR.