Is Adductor Canal Block Better Than Femoral Nerve Block in Primary Total Knee Arthroplasty? A GRADE Analysis of the Evidence Through a Systematic Review and Meta-Analysis

Accepted Manuscript Is adductor canal block better than femoral nerve block in primary total knee arthroplasty? A GRADE analysis of the evidence through a systematic review and meta-analysis Ming-jie Kuang, Jian-xiong Ma, Lin Fu, Wei-wei He, Jie Zhao, Xin-long Ma PII:

S0883-5403(17)30421-7

DOI:

10.1016/j.arth.2017.05.015

Reference:

YARTH 55882

To appear in:

The Journal of Arthroplasty

Received Date: 22 December 2016 Revised Date:

26 April 2017

Accepted Date: 8 May 2017

Please cite this article as: Kuang M-j, Ma J-x, Fu L, He W-w, Zhao J, Ma X-l, Is adductor canal block better than femoral nerve block in primary total knee arthroplasty? A GRADE analysis of the evidence through a systematic review and meta-analysis, The Journal of Arthroplasty (2017), doi: 10.1016/ j.arth.2017.05.015. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.

ACCEPTED MANUSCRIPT Is adductor canal block better than femoral nerve block in primary total knee arthroplasty? A GRADE analysis of the evidence through a systematic review and meta-analysis

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Ming-jie Kuanga,b, *, Jian-xiong Ma a, *, Lin Fu a,b,*, Wei-wei Hea,b, Jie Zhaoa, Xin-long Maa,b *These authors contributed equally to this work. a

Biomechanics Labs of Orthopaedics Institute, Tianjin Hospital, Tianjin 300050, People's

Department of Orthopedics, Tianjin Medical University General Hospital, Tianjin 300052,

People's Republic of China

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Republic of China

Corresponding author: Xin-long Ma, Tianjin Hospital, Tianjin 300211, China, e-mail ： [email protected], phone number: +86-13602179865. Email

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Name

[email protected]

Jian-xiong Ma

[email protected]

Jie Zhao

[email protected]

[email protected]

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Weiwei He

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Ming-jie Kuang

Lin Fu

[email protected]

Xin-long Ma

[email protected]

ACCEPTED MANUSCRIPT Abstract: Background: Total knee arthroplasty (TKA) is associated with intense postoperative pain with a need for early ambulation to gain function and prevent postoperative

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complications. Compared with femoral nerve block (FNB), adductor canal block (ACB) can relieve postoperative pain and preserve quadriceps muscle strength. This

pain relief and function recovery following TKA.

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meta-analysis was conducted to investigate which analgesic method provides better

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Method: We conducted a meta-analysis to identify relevant randomized controlled trials (RCTs) involving ACB and FNB after TKA in electronic databases, including Web of Science, Embase, PubMed, and the Cochrane Library, up to November 2016. Finally, nine RCTs involving 609 patients (668 knees) were included in our study.

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Review Manager Software and GRADE (Grading of Recommendations Assessment, Development and Evaluation) profiler were used to perform the meta-analysis. Results: Compared with FNB, ACB resulted in better quadriceps muscle strength and

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mobilization ability. There were no significant differences in the visual analogue scale

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(VAS) at rest, VAS with mobilization, rescue opioid consumption, patient satisfaction, and length of hospital stay. Conclusions: Compared with FNB, ACB shows similar pain control after TKA. However, ACB can better preserve quadriceps muscle strength and improve mobilization ability. In conclusion, ACB showed better functional recovery after TKA without compromising pain control. Therefore, ACB is recommended as an alternative analgesic method for early ambulation after TKA.

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Keywords: adductor canal block, femoral nerve block, total knee arthroplasty

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Is adductor canal block better than femoral nerve block in primary total knee

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arthroplasty? A GRADE analysis of the evidence through a systematic

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review and meta-analysis

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Abstract:

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Background: Total knee arthroplasty (TKA) is associated with intense

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postoperative pain with a need for early ambulation to gain function and

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prevent postoperative complications. Compared with femoral nerve block

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(FNB), adductor canal block (ACB) can relieve postoperative pain and

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preserve quadriceps muscle strength. This meta-analysis was conducted to

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investigate which analgesic method provides better pain relief and function

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recovery following TKA.

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Method: We conducted a meta-analysis to identify relevant randomized

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controlled trials (RCTs) involving ACB and FNB after TKA in electronic

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databases, including Web of Science, Embase, PubMed, and the Cochrane

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Library, up to November 2016. Finally, nine RCTs involving 609 patients

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(668 knees) were included in our study. Review Manager Software and

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GRADE (Grading of Recommendations Assessment, Development and

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Evaluation) profiler were used to perform the meta-analysis.

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Results: Compared with FNB, ACB resulted in better quadriceps muscle

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strength and mobilization ability. There were no significant differences in the

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visual analogue scale (VAS) at rest, VAS with mobilization, rescue opioid

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consumption, patient satisfaction, and length of hospital stay.

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Conclusions: Compared with FNB, ACB shows similar pain control after

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TKA. However, ACB can better preserve quadriceps muscle strength and

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improve mobilization ability. In conclusion, ACB showed better functional

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recovery after TKA without compromising pain control. Therefore, ACB is

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recommended as an alternative analgesic method for early ambulation after

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TKA.

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Keywords: adductor canal block, femoral nerve block, total knee

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arthroplasty

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Introduction

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An increasing number of total knee arthroplasties (TKAs) are performed

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because of end-stage knee osteoarthritis and rheumatoid arthritis [1]. Usually,

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TKA is associated with intense early postoperative pain and a need for early

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ambulation to regain function and prevent postoperative complications [2].

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Femoral nerve block (FNB) techniques are considered preferred methods to

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deliver post-operative analgesia and to minimize postoperative pain in TKA

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patients [3]. However, some recent studies reported that continuous blockade

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of the femoral nerve may result in weakness of the quadriceps muscle and

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therefore increases the risk of falling during early ambulation [4-6]. Thus far,

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the management of early postoperative pain following TKA has not been

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optimized to improve quadriceps muscle strength without compromising

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analgesia dosage [7].

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Adductor canal block (ACB) is a relatively new technique that has been

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successfully used for early postoperative pain control after TKA without

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weakening quadriceps muscle strength [8]. Recently, an anatomical study of

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the adductor canal showed that both the saphenous nerve and the nerve to the

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vastus medialis contribute to the innervation of the knee joint and are distal

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to the quadriceps motor branches [9]. Thus, ACB can relieve postoperative

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pain while preserving quadriceps muscle strength.

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double-blind randomized controlled trial (RCT) in healthy volunteers

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A prospective

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demonstrated that ACB reduced quadriceps strength by only 8% compared

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with 49% using FNB [8]. In addition, several studies reported that ACB

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preserved quadriceps muscle strength better than FNB in patients undergoing

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TKA [10-13]. However, there are no consistent conclusions on which of the

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two techniques leads to better function recovery after TKA. Some studies [12,

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14] showed that ACB improve postoperative motor function after TKA;

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however, others drew different conclusions and reported that ACB provides

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equivalent ambulation ability compared with FNB [15, 16]. A meta-analysis

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conducted by Li et al[17] showed that ACB provided better ambulation

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ability, faster functional recovery and better pain control at rest after TKA

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than FNB. However, the authors included a wide variety of studies that were

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not applicable to the meta-analysis. For example, the meta-analysis included

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reports by Kwofie et al [18] and Jaeger et al [19], which focus on the

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influences to the quadriceps strength of health volunteers without TKAs.

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Therefore, the results of meta-analysis were limited and inaccurate.

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To achieve a fast functional recovery and early ambulation after TKA, it is

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necessary to choose an optimal anesthetic technique. Therefore, to

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investigate which anesthetic technique provided better pain relief, we

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performed a meta-analysis to evaluate evidence from all available RCTs that

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compared ACB with FNB for patients undergoing primary TKA and to

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propose recommendations for clinicians using the GRADE (Grading of

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Recommendations, Assessment, Development and Evaluation) system.

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Materials and methods

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Search strategy

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This systematic review and meta-analysis was prospectively registered on

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PROSPERO (International prospective register of systematic reviews) and

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the registration number was CRD42016051316 (Supplemental PDF). The

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PRISMA guidelines[20], GRADE system[21] and Cochrane Handbook[22]

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were applied to assess the quality of the results published in all included

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studies to make sure the results of our meta-analysis reliable and veritable.

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We conducted a meta-analysis to identify relevant RCTs involving ACB and

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FNB after TKA in electronic databases including Web of Science, Embase,

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PubMed, the Cochrane Controlled Trials Register, and the Cochrane Library

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up to November 2016. Only RCTs performed on human beings is included.

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The search strategy was presented in Supplemental table 2. Flow chart of

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the trial selection process was presented in Fig 1. In addition, we also

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conducted other databases according to the Cochrane Collaboration

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guidelines.

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Inclusion criteria

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Included studies were considered eligible if they met the PICOS criteria as

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follows:

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Population: Patients were scheduled for primary TKA;

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Intervention: ACB;

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Comparator: FNB;

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Outcomes: The primary outcomes included the following: visual analogue

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scale [23] (VAS) pain score at rest and VAS pain score after mobilization (8

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h, 24 h, 48 h). VAS pain score, which consisted of a scale from 0 (no pain) to

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10 (worst imaginable pain), was used to evaluate pain control. Secondary

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outcomes contained the following: timed up and go (TUG) test [24], which is

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a method to evaluate mobilization ability; quadriceps muscle strength;

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adductor muscle strength; opioid consumption (all opioids given were

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converted to morphine equivalents at 8, 24 and 48 h); the length of the

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hospital stay (days) and patient satisfaction. Patient satisfaction was

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evaluated using a ten-point scale from 0 (completely unsatisfied) to 10

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(totally satisfied) [16]

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Study design: Interventional studies (RCTs);

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Only published clinical studies were included; the included studies were

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required to contain at least one outcome. Only studies published in English

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were included. The studies must have had a follow up rate of at least 80%,

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and at least two main patient-important outcomes had to be included. Two

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authors had to have assessed the eligible studies independently. In cases of

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disagreement, a consensus was reached through discussion between two

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authors.

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Exclusion criteria included observational studies, non-RCTs, review articles,

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studies with a sample size < 50 and studies with insufficient outcome data.

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Data extraction

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We used a standard data extraction form to retrieve the relevant data from

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eligible articles. The extracted data included authors, study location, sample

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size, study design, publishing date, gender, population, age, duration of

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follow-up, interventions, dosages and type of anaesthesia, and outcomes. If

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necessary, we contacted the corresponding authors of the included RCTs to

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make sure the information was integrated and to get any missing data. Two

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reviewers extracted the data independently. If there were disagreements

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between two authors, consensus were reached through discussion.

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Risk of bias and quality assessment

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According to the Cochrane Handbook for Systematic Reviews of

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Interventions, the methodological quality and basis of the included literature

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were assessed as follows: randomization, allocation concealment, blind

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method, selective reporting, group similarity at baseline, incomplete outcome

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data, compliance, timing of outcome assessments, and intention-to-treat

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analysis (Fig 2 and Fig 3).

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Assessment of reporting bias

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A funnel plot was used to assess the existence of reporting bias. We

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evaluated whether asymmetry was due to publication bias or to a relationship

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between trial size and effect size.

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Dealing with missing data

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In cases of incomplete and missing data, we contacted the corresponding

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authors of the included studies to make sure the information integrated. All

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the data was presented as the form of mean ± standard deviation (SD) in our

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meta-analysis. If the data were reported as median and interquartile range

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(IQR), we assumed that the median was equivalent to the mean and that the

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width of the IQR was equivalent to 1.35 times the SD. When data were

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reported in a graph, means ± SD was estimated by Get Data software. All the

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methods mentioned above to calculate the means ± SD on the basis of the

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Cochrane Handbook for Systematic Reviews.

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Statistical analysis and data synthesis

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Meta-analyses was performed with Review Manager Software for Windows

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(Version 5.3. Copenhagen: The Nordic Cochrane Centre, the Cochrane

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Collaboration, 2014). The mean difference (MD) or standard mean

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difference (SMD) was used to assess continuous outcomes such as VAS

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score, rescue opioid consumption, TUG test, and quadriceps muscle strength,

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with a 95% confidence interval [CI]. Relative risks (RR) with a 95% CI were

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used to assess dichotomous outcomes. The inverse variance and Mantel–

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Haenszel methods were used to combine separate statistics. If P values were

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less than 0.05, the results were considered statistically significant.

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GRADE the evidence

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GRADE system was used to evaluate the quality of the evidence for each

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outcome [21]. GRADE profiler (Version 3.6.1) was used to evaluate the

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evidence regarding included outcomes. Initially, RCTs were considered as

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being of high confidence in estimating an effect, and observational studies

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were considered as being of low confidence in estimating an effect. Reasons

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that may decrease the level of confidence include risk of bias, inconsistency,

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indirectness, imprecision, and publication bias. Reasons that may raise the

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level of confidence include large effect, dose response, and all plausible

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residual confounding and bias. The GRADE evidence was divided into the

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following categories: (1) High-quality evidence, which indicated that further

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research was unlikely to change the confidence in an estimate of effect; (2)

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Moderate-quality evidence, which indicated that further research was likely

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to have an important impact on confidence in an estimate of effect and may

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change the estimate; (3) Low-quality evidence, which indicated that further

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research was likely to have an important impact on confidence in an estimate

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of effect and was likely to change the estimate; (4) Very low-quality

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evidence, which indicated that we were very uncertain about the results. The

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results of the GRADE analysis are presented in Supplemental table 2.

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Investigation of heterogeneity

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Statistical heterogeneity of the included studies was evaluated using

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chi-square test in accordance with the values of P and I2. If the I2 < 50% and

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P > 0.1, the heterogeneity might not be important. A fixed-effects model was

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used to assess the outcomes. If I2 was between 50% to 100%, it may

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represent substantial heterogeneity. We used random-effects model to

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evaluate these outcomes. Thresholds for the interpretation of I2 can be

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misleading, since the importance of inconsistency depends on several factors.

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Therefore, subgroup analysis was performed to interpret the potential source

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of heterogeneity.

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Results

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Excluded studies and search results

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Initially, a total of 212 citations were identified from electronic journals

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databases, of which 137 records were removed by primary screening

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according to the title and abstract. After reading the full text of 75 remaining

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studies in detail, 63 studies that did not meet the inclusion criteria were

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excluded. Among 12 RCTs, two studies [18, 19] focused on the influences to

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the quadriceps strength of health volunteers rather than TKAs. The control

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group was placebo rather than FNB in another study [25]. Finally, 9 RCTs

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[10-13, 15, 16, 26-28] with 609 patients (668 knees) that compared ACB

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with FNB were included in our meta-analysis. All the included studies were

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published between 2013 and 2016. The characteristics of 9 included studies

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were summarised in Table 1.

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The sample size of each RCT ranged from 42 to 98. The American Society of

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Anesthesiologists grade[29] was presented in three studies[11, 12, 15]. The

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proportion and combination of anaesthetics were different in included studies

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(Table 1). Only two studies [11, 15] used bupivacaine as the study

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medication, and ropivacaine was used in other articles. Two studies [10, 26]

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reported that outcome assessors and clinical personnel were blinded. All

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articles except Zhang[27] reported the random sequence generation. All

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included studies reported outcomes of more than 95% of participants.

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Risk of bias in included studies

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Randomization

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Eight included studies[10-13, 15, 16, 26, 28] clearly reported the random

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sequence generation, which indicated that a low risk of selection bias in

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these studies. Only one study[27] did not describe the randomization process.

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Therefore, the selection bias in this study was unclear.

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Allocation concealment

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Allocation concealment was considered to be adequate in eight studies[10-13,

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15, 16, 26, 28], and unclear in the other study [27], given that authors did not

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provide the allocation information in this study.

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Blinding method

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The blinding method can be divided into two parts: blinding of outcome

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assessment (detection bias) and blinding of the participants and personnel

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(performance bias). Seven studies[10, 11, 13, 15, 16, 26, 28] were

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double-blinded and were rated as having low-risk detection and performance

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bias. One study[12] did not report the blinding method and was rated as

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having high-risk detection and performance bias. Zhang et al[27] reported

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that only blind outcome assessment was used but did not clearly describe the

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method used. Therefore, the study was rated as having unclear-risk detection

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bias and high-risk performance bias [27].

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Selective reporting

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All nine included studies[10-13, 15, 16, 26-28] showed that all main

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outcomes were presented in the protocol and were considered at low risk of

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reporting bias.

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Group similarity at baseline

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Results (e.g. age, weight, male/female etc.) of ACB and FNB were similar at

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baseline for each study.

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Intention-to-treat analysis (ITT)

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Only five included studies reported the ITT [10, 11, 15, 16, 28]. The

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remaining studies showed an unclear[12, 13, 26] and high[27] risk of bias.

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Incomplete outcome data

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All the studies presented complete data and was considered at a low risk bias

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for this criterion.

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Compliance

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Risk of bias was unclear in all included studies because compliance was not

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monitored in the control group.

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Timing of outcome assessments

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Risk of bias was low because all important outcome assessments for all

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intervention groups were measured at the same time.

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Publication bias

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Publication bias was also evaluated using a funnel plot diagram

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(Supplemental Fig 1). The diagram was symmetrical, indicating low risk of

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publication bias.

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Other bias

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Further risks of bias was found in included studies. However, we cannot

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ignore other potential risk of biases. Therefore, we rated as having

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unclear-risk of other bias.

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Results of meta-analysis

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Primary outcomes

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(1) VAS score at rest

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Five studies assessing 418 knees reported VAS scores at rest within 8 hours

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post-operatively. There was no significant difference between the ACB and

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FNB groups (MD=0.13, 95%CI: [-0.15, 0.41], P=0.35; Fig 4). VAS score at

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24 hours post-operatively was reported in seven studies, and a total of 521

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knees were involved in the meta-analysis. No significant differences were

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found between the two groups (MD=-0.01, 95%CI: [-0.55, 0.53], P=0.97;

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Fig 4). Six studies involving 473 knees reported the VAS score at 48 hours.

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Meta-analysis showed no significant differences between the ACB and FNB

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groups (MD=-0.06, 95%CI: [-0.15, 0.03], P=0.23; Fig 4).

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(2) VAS score with mobilization

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Data from three studies assessing 227 knees reported the VAS score with

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mobilization within 8 hours. The ACB group reported a similar pain score

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with mobilization within 8 hours compared to the FNB group (MD=-0.15,

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95%CI: [-0.39, -0.09], P=0.21; Fig 4). A meta-analysis was conducted of

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seven studies involving a total of 511 knees to evaluate the VAS score with

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mobilization at 24 and 48 hours post-operatively. However, the results of the

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meta-analysis revealed no significant differences between ACB and FNB

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groups at 24 hours (MD=0.23, 95%CI: [-0.20, 0.66], P=0.30; Fig 4) and 48

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hours (MD=-0.07, 95%CI: [-0.17, 0.03], P=0.18; Fig 4) post-operatively.

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Secondary outcomes

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Two methods were used to evaluate quadriceps muscle strength. Three

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authors[10, 13, 28] evaluated quadriceps muscle strength as maximum

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voluntary isometric contraction[30] (MVIC) using a handheld dynamometer.

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A manual muscle test[31] (MMT) with a standardised 0–5 motor strength

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scale was used in four studies[15, 16, 26, 27].

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(1) Quadriceps muscle strength (MMT)

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Four studies involving 282 knees reported the quadriceps muscle strength as

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measured by MMT at 8 hours, 24 hours and 48 hours. The pooled data

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showed significant differences at 8 hours (MD=0.71, 95%CI: [0.05, 1.37],

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P=0.04; Fig 5), at 24 hours (MD=0.68, 95%CI: [0.05, 1.31], P=0.03; Fig 5)

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and 48 hours (MD=0.67, 95%CI: [0.03, 1.31], P=0.04; Fig 5).

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(2) Quadriceps muscle strength (MVIC)

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Meta-analysis showed that the quadriceps muscle strength measured by

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MVIC at 24 hours in the ACB group was much greater than that in the FNB

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group (MD=75.65, 95%CI: [28.49, 122.81], P=0.002; Fig 5).

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(3) Adductors muscle strength (MVIC)

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MVIC was also used to evaluate adductor muscle strength. Two studies

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assessing 97 knees reported adductor muscle strength at 24 hours

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post-operatively. There was no significant difference between the ACB and

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FNB groups (MD=-19.2, 95%CI: [-44.67, 6.26], P=0.14; Fig 5).

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(4) TUG test

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The TUG test was conducted in four studies involving a total of 348 knees to

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evaluate mobilization ability. Significant differences were found between the

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ACB and FNB groups at 24 hours (MD=-11.63, 95%CI: [-21.72, -1.53],

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P=0.02; Fig 5) and 48 hours (MD=-9.63, 95%CI: [-18.3, -0.96], P=0.03; Fig

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5).

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(5) Opioid consumption

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Opioid consumption was reported in four of the included studies, and a total

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of 252 knees were involved in the meta-analysis. The pooled data showed no

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significant difference between ACB and FNB groups at 8 hours (MD=1.64,

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95%CI: [-2.66, 5.94], P=0.45; Fig 6), 24 hours (MD=0.13, 95%CI: [-5.32,

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5.57], P=0.96; Fig 6) and 48 hours (MD=5.19, 95%CI: [-1.94, 12.33],

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P=0.15; Fig 6).

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(6) Patient satisfaction

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A meta-analysis examined four studies (315 knees) to assess post-operative

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patient satisfaction. No significant differences were discovered between

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ACB and FNB groups at 8 hours (MD=0.17, 95%CI: [-0.09, 0.43], P=0.20;

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Fig 6), 24 hours (MD=-0.41, 95%CI: [-0.90, 0.08], P=0.10; Fig 6) and 48

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hours (MD=0.02, 95%CI: [-1.84, 1.88], P=0.98; Fig 6).

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(7) Length of hospital stay

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Two studies with 191 patients reported the length of hospital stay. There

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were no significant differences between the ACB and FNB groups

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(MD=-0.38, 95%CI: [-1.30, 0.54], P=0.42; Fig 6).

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Discussion

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TKA is one of the most commonly treated osteoarthritis in older adults, and

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the prevalence of this operation will continue to rise as the population ages.

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The pain following TKA may be a major concern despite the successful

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recovery of function in the patient. Yet, to date, no clear standard is known

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for pain control after TKA. An optimal analgesic technique for TKA should

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be based on early ambulation and lasting symptom improvement without

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severe complications, including muscle weakness, nerve damage, and

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infection. Both ACB and FNB have proven to be safe and effective technique

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for pain management after TKA. Some recent published studies have

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reported that FNB is associated with delayed ambulation [10] and risk of

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falling [32]. However, Elkassabany et al did not detect a significant reduction

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in fall risk when comparing ACB with FNB [26]. Therefore, the aim of the

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present systematic review and meta-analysis was to evaluate the efficacy of

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ACB and FNB in postoperative pain control and recovering ambulation

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ability. Our findings demonstrated that ACB presents similar pain control

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compared with FNB. However, ACB can better preserve quadriceps muscle

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strength and improve mobility. In conclusion, ACB showed better functional

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recovery after TKA without compromising pain control.

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A previous meta-analysis demonstrated that their ACB group had lower VAS

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at rest during the early post-operative period compared to their FNB group

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[17]. However, according to our meta-analysis, ACB groups present similar

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VAS scores at rest after TKA compared with FNB groups, at 8 hours, 24

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hours and 48 hours. Several RCTs [10, 13, 15] also reported that VAS scores

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at rest were similar between ACB and FNB groups. This result was

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consistent with our findings. In the included studies, statistical heterogeneity

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was found in VAS at 8 hours and 24 hours. Thus, a random-effects model

347

was performed to evaluate the results. Subgroup analysis was carried out for

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the VAS score at rest to determine the source of heterogeneity (Table 2).

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Factors such as local anesthetic volume, race, tourniquet use, age, and type

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of catheter caused significant heterogeneity. Because of the inconsistency

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caused by very serious heterogeneity, the quality of evidence regarding VAS

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at rest with 8 hours and 24 hours was low. However, the evidence regarding

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VAS at rest at 48 hours was of high quality. Furthermore, all the included

354

studies were RCTs of high quality. Therefore, the overall quality of evidence

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and effect estimate regarding VAS at rest was reliable.

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In addition, our meta-analysis failed to find any significant difference for

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VAS score with mobilization at 8 hours, 24 hours and 48 hours between the

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ACB and FNB groups. However, the VAS score with mobilization at 8 hours

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was found to be slightly lower in the ACB group than in the FNB group.

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Several recent published studies reported that the VAS score with

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mobilization was similar between both groups during post-operative days 0

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to 2 [13, 15, 16, 26]. These findings are consistent with our meta-analysis.

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Therefore, ACB provides equally effective pain relief for patients after TKA

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compared with FNB.

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Opioid analgesics are often used to relieve postoperative pain for patients

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who have undergone TKA. Usually, rescue opioids are used for breakthrough

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postoperative pain based on patients’ reported VAS scores (VAS>7 points)

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[33]. In our meta-analysis, rescue opioid consumption also did no differ

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between the two groups within 48 hours. A retrospective study showed that

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opioid consumption in patients with ACB was not significantly different

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from patients receiving FNB within 48 hours [34]. A study presented by

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Shah et al[12] also reported the same conclusions. Because of the small

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sample size, the validity of the results regarding rescue opioid use in the

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ACB and FNB groups is limited. However, the quality of evidence was

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moderate, and the conclusion was reasonable.

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Quadriceps muscle strength has a great impact on the ability to ambulate.

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The results of our meta-analysis showed that quadriceps muscle strength was

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much greater in the ACB group than in the FNB group. However, the quality

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of evidence was low according to the GRADE system, and we could not

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confidently draw conclusions about this result. Several prospective studies

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comparing ACB and FNB in healthy volunteers [8, 35] and TKA patients[16,

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26] have suggested that the loss of quadriceps muscle strength in ACB

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groups is significantly lower than placebo or that in FNB groups. Moreover,

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Grevstad et al[36] reported that no statistically significant differences were

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found between local anesthetic volume (ACB) and effects on quadriceps

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muscle strength in healthy volunteers. Together, these findings demonstrated

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that ACB can preserve quadriceps strength. More RCTs with larger sample

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sizes are needed to verify our conclusions. Our meta-analysis failed to find

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any significant difference between ACB and FNB groups regarding adductor

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muscle strength, indicating that ACB does not reduce adductor muscle

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strength. However, Jenstrup et al[37] reported that ACB may block the nerve

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to the vastus medialis and thereby affect muscle strength. Grevstad et al

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demonstrated a positive correlation between local anesthetic volume and

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effects on the vastus medialis muscle [36]. Meanwhile, because of the small

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sample size and heterogeneity, the quality of evidence was very low. The

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effect estimate was uncertain and had a lower GRADE recommendation

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strength. The TUG test evaluates ambulation ability by measuring the time a

398

patient takes to stand up from a chair, walk a distance of three meters without

399

any support, and return to the chair [12]. The results of our meta-analysis

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reported that the TUG test result in the ACB group was better than that in the

401

FNB group at 24 hours and 48 hours. Hanson et al [25] reported that ACB

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for TKA resulted in better ambulation ability than placebo during the first 48

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hours.

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significant differences were found in motor function between ACB and FNB

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groups. Therefore, we confirmed that ACB was better than FNB in terms of

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enhancing mobilization ability after TKA.

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According to the results of our meta-analysis, patient satisfaction score

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within 48 hours and length of the hospital stay in the two groups were similar.

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Similarly, a study presented by Memtsoudis[15] showed that

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Since patient satisfaction is a subjective scale, it can easily be affected by

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subjective factors. Length of hospital stay was affected by multiple factors,

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including sex, age, and the physiological status of the patients. Prolonged

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hospitalization may cause serious complications, including urinary system

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infection, muscle atrophy, and deep vein thrombosis. Furthermore, cost

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increases greatly with prolonged hospitalization. Kim et al[11] reported side

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effects of pain management, such as nausea, vomiting and pruritis; however,

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there were no significant differences between their ACB and FNB groups.

417

Our systematic review and meta-analysis has the following limitations: (1)

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Only nine studies were included in our meta-analysis; if more RCTs had

419

been included, the test power for our analysis would have been greater. (2)

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We evaluated only the immediate effects within 48 hours after TKA; the

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included studies tell us nothing about the duration of the effects or whether

422

these effects lead to better long-term functional outcomes. Therefore, a

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long-term follow-up study is needed to investigate functional outcomes. (3)

424

Only English publications were included in our meta-analysis. (4)

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Heterogeneity among the included studies was unavoidable because of racial

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differences, age differences, and differences in the tourniquet use, mode of

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anesthesia, and type of catheter used.

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Conclusions

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Compared with FNB, ACB shows similar pain control after TKA. ACB can

430

better preserve quadriceps muscle strength and improve mobilization ability.

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In conclusion, ACB resulted in better functional recovery after TKA without

432

compromising pain control. Therefore, concerning the early ambulation after

433

TKA, ACB is recommended as an alternative analgesic method.

434

Conflict of interest

435

No conflict of interest exits in the submission of the manuscript, and the

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manuscript has been approved for publication by all authors.

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Lund

J,

Jenstrup

MT,

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P,

Sorensen

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JB.

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Table 1 . The characteristics of included studies ACB group/FNB group

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(mean)

(% male)

63/65

71/61

ASA grade(cases) Ⅰ

Ⅱ

N/A

N/A

Ⅲ

Anesthesia

ACB group

11/14

Spinal or general anesthesia

revstad 2015

25/24

65/54

28/33

N/A

N/A

N/A

Spinal or general anesthesia

Jæger 2013

22/26

70/66

22/52

N/A

N/A

N/A

Spinal anesthesia

46/47

68/67.6

48/38

2/3

38/36

6/8

Spinal anesthesia

Memtsoudis 2015

30/29

64.4

26

7

52

0

Spinal anesthesia

Shah 2014

48/50

68/66

27/28

13/14

35/33

RCT

30 ml of 0.2% ropivacaine

30 ml of 0.2% ropivacaine

RCT

30ml of 0.5 % ropivacaine , 0.2 % ropivacaine 8ml/h

30ml of 0.5 % ropivacaine , 0.2 % ropivacaine 8ml/h

RCT

15ml of 0.5 % bupivacaine with 5 ug/ml epinephrine

30ml of 0.25 % bupivacaine with 5 ug/ml epinephrine

RCT

15 ml bupivacaine 0.25 %

30 ml of 0.25 % bupivacaine

RCT RCT RCT

Spinal anesthesia

20 ml of 0.75% ropivacaine

General anaesthesia

15 ml of 0.375 % ropivacaine

15 ml of 0.375 % ropivacaine

Spinal anesthesia General anaesthesia

20 ml of 0.33% ropivacaine 30mL, 100 mg of Bupivacaine hydrochloride

20 ml of 0.33% ropivacaine 30mL, 100 mg of Bupivacaine hydrochloride

43/43

N/A

N/A

N/A

Zhang 2014

30/30

64/62

20/26

N/A

N/A

N/A

Macrinici 2016

49/49

67/67

39/37

N/A

N/A

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72/66

N/A

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FNB: Femoral Nerve Block

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A bolus of 20 ml of 0.5% ropivacaine

0/3

21/21

ACB: Adductor Canal Block

A bolus of 20 ml of 0.5% ropivacaine

30ml of 0.25 % bupivacaine at an interval of 4 h

Wiesmann 2016

RCT: Randomized Controlled Trial

Reference type

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FNB group

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Elkassabany 2016

Cases

Gender

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Study(year)

Age

ASA: American Society of Anesthesiologists

N/A: not applicable

RCT RCT

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Table 2.

Subgroup analysis Effect estimate

Subgroup or Outcomes Studies χ MD and 95%CI I2 (%) P Spinal anesthesia 6 56.44 -0.09 (-0.65, 0.46) 91 0.74 Apply tourniquet 3 0.03 0.36 (-0.11, 0.82) 0 0.13 Ropivacaine usage 5 54.51 -0.13(-0.77, 0.52) 93 0.70 2 2 MD: Mean Difference, CI: Confidence Interval, χ : Chi-square test, I : Heterogeneity Test

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