Buried or exposed Kirschner wire for the management of hand and forearm fractures: A systematic review, meta-analysis, and meta-regression

Nucki Nursjamsi Hidajat; R. M. Satrio Nugroho Magetsari; Gregorius Thomas Prasetiyo; Danendra Rakha Putra Respati; Kevin Christian Tjandra

doi:10.1371/journal.pone.0296149

Abstract

Background

The recommendation on whether to bury or expose the Kirschner wire (K-wire) for the management of fractures has still been controversial with inconsistent results in the published studies due to the potential issue associated with exposed K-wire is the heightened risk of infection, as it comes into direct contact with the external environment and air. This study aims to summarize the specific outcomes between buried and exposed K-wire for the management of hand and forearm fractures.

Methods

We conducted relevant literature searches on Europe PMC, Medline, Scopus, and Cochrane Library databases using specific keywords. This investigation focuses on individuals of any age diagnosed with hand or forearm fractures who underwent surgery involving Kirschner wire (K-wire) fixation. It examines the comparison between buried and exposed K-wire fixation, emphasizing primary outcome pin infection, along with secondary outcomes such as early pin removal, days to pin removal, and surgical duration. The study includes observational studies (cohort/case-control) or randomized clinical trials (RCTs). The results of continuous variables were pooled into the standardized mean difference (SMD), while dichotomous variables were pooled into odds ratio (OR) along with 95% confidence intervals using random-effect models. The quality of included studies was assessed with Cochrane Collaborations, Risk of Bias version 2 (RoB v2).

Results

A total of 11 studies were included. Our pooled analysis revealed that buried K-wire was associated with a lower risk of pin site infection [RR 0.49 (95% CI 0.36–0.67), p < 0.00001, I² = 0%] and 33.85 days longer duration until pin removal [MD 33.85 days (95% CI 18.68–49.02), p < 0.0001, I² = 99%] when compared with exposed K-wire. However, the duration of surgery was 9.98 minutes significantly longer in the buried K-wire [MD 6.98 minutes (95% CI 2.19–11.76), p = 0.004, I² = 42%] with no significant difference in the early pin removal rate [RR 0.73 (95% CI 0.36–1.45), p = 0.37, I² = 0%]. Further regression analysis revealed that sample size, age, sex, and duration of follow-up did not affect those relationships.

Conclusion

Buried K-wire may offer benefits in reducing the infection rate with a longer duration until pin removal. However, further RCTs with larger sample sizes are still needed to confirm the results of our study.

Citation: Hidajat NN, Magetsari RMSN, Prasetiyo GT, Respati DRP, Tjandra KC (2024) Buried or exposed Kirschner wire for the management of hand and forearm fractures: A systematic review, meta-analysis, and meta-regression. PLoS ONE 19(5): e0296149. https://doi.org/10.1371/journal.pone.0296149

Editor: Ismail Tawfeek Abdelaziz Badr, Menoufia University, EGYPT

Received: December 4, 2023; Accepted: April 13, 2024; Published: May 15, 2024

Copyright: © 2024 Hidajat 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: Mendeley Data: Buried or Exposed Kirschner Wire for the Management of Hand and Forearm Fractures: A Systematic Review, Meta-Analysis, and Meta-Regression. DOI: 10.17632/cxjd9nmx8r.1.

Funding: The author(s) received no specific funding for this work.

Competing interests: The authors have declared that no competing interests exist.

Introduction

Hand and forearm fractures present substantial challenges in orthopedic surgery, impacting infection prevention and postoperative quality of life. The choice of whether to bury or expose Kirschner wires (K-wires), commonly used for fixation, is a critical decision in surgical management of hand and forearm fractures. This decision can influence infection risk, timing of pin removal, and overall surgical outcomes.

Forearm fractures involving the radius and ulna are the most common fracture of the upper limb with an annual incidence of 16.2 fractures per 10,000 individuals, followed by hand fractures involving the metacarpals and phalanx with an annual incidence of 12.5 and 6.4 fractures per 10,000 individuals, respectively [1, 2]. Both forearms and hands are essential in carrying out daily activities so these two types of fractures often result in the disruption of a person’s quality of life [2].

Kirschner wire (K-wire) is often used by orthopedic surgeons, especially those specializing in the field of hand and upper extremity surgery to provide fixation for unstable hand or forearm fractures because it is associated with good outcomes at a relatively low cost [3, 4]. Results from several previous studies have demonstrated the non-inferiority of K-wire when compared to plate-screw fixation in the management of unstable metacarpal and phalangeal fractures [5, 6]. A meta-analysis study involving 5 randomized clinical trials (RCTs) and 9 cohort studies showed similar clinical, functional, and radiological outcomes between percutaneous K-wires when compared with volar locking plates (VLPs) for distal radius fixation, but with lower re-operation risk in the K-wire group [7]. These wires can be implanted under the skin or left exposed. A national survey conducted in the United Kingdom (UK) showed that the majority of orthopedic surgeons, plastic surgeons, and junior surgical trainees chose to leave K-wire exposed because it was easier to remove [8]. The concern that may arise from exposed K-wire is the potentially greater risk of infection because it has direct contact with the outside air and environmental exposure [8].

Several studies have been conducted to compare buried and exposed K-wires in the management of hand and forearm fractures but have yielded inconsistent results due to high risk of infection [9, 10]. The gap in existing reviews becomes apparent as these studies do not offer a cohesive and thorough comprehension of the effectiveness and risks associated with exposed versus buried K-wires. Furthermore, the current reviews lack a comparison regarding pin removal, surgery duration, and regression analysis concerning sample size, age, sex, and duration of follow-up regarding the management of hand and forearm fractures using buried versus exposed Kirschner wires. The reported inconsistencies stem from variations in the types of fractures studied, the populations involved, or the specific outcomes considered. This systematic review and meta-analysis aim to fill this gap by encompassing a broad spectrum of studies that explore the specific outcome of exposed and buried K-wires in the management of hand and forearm fractures.

The significance of this review lies in its commitment to summarizing the latest evidence and offering an up-to-date and thorough analysis. By addressing the existing inconsistencies in the literature, the review strives to bring clarity and consensus to the comparative effectiveness and risks associated with exposed and buried K-wires. Furthermore, the review seeks to inform clinical practice by providing valuable insights that can guide orthopedic surgeons and practitioners in making informed decisions regarding the optimal approach for managing hand and forearm fractures.

Material and method

Eligibility criteria

This review was written according to the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) statement and Cochrane Handbook guidelines [11, 12]. We included the following studies: (1) studies on patients of any age with the diagnosis of hand (phalangeal or metacarpal) or forearm (radius or ulna) fractures who have undergone surgery with Kirschner wire (K-wire) fixation (Population); (2) compare between buried and exposed K-wire fixation (Intervention and Control); (3) have data on the primary outcome (pin infection) with/without secondary outcomes (early pin removal, days to pin removal, and duration of surgery) (Outcome); (4) presented in the form of observational studies (cohort/case-control) or randomized clinical trials (RCTs) (Study Design).

Meanwhile, the studies (1) conducted in patients with humeral, shoulder, or lower extremity fractures; (2) using another method of fixation besides K-wire for the patients; (3) presented in the form of case reports, case series, and review articles were excluded from our analysis.

Literature search and study selection

The search of English literature on 4 international databases: Medline, Scopus, Europe PMC, and Cochrane Library was performed by five independent authors from April 28^th, 2023 until March 7^th,2023. We used the following combined keywords to capture all potentially eligible literature: “(buried OR implanted OR concealed OR embedded) AND (exposed OR uncovered) AND (Kirschner wire OR K-wire) AND (hand fractures OR phalangeal fractures OR metacarpal fractures OR forearm fractures OR radius fractures OR ulna fractures)” as shown in Table 1. At first, the identified articles from those databases were removed for duplicates and then screened based on their titles/abstracts. These articles that passed the initial screening process underwent the second step of evaluation in the form of full-text to see their compatibility with our inclusion/exclusion criteria. All of these processes for article selection were conducted by the same five authors who performed the literature searching process. All discrepancies were resolved through discussion with all of the authors. If the decision did not happen, the corresponding author took the final decision based on the determination of the eligibility and desired outcomes of the studies.

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Table 1. Literature search strategy.

https://doi.org/10.1371/journal.pone.0296149.t001

Data extraction

We extracted the following data for analytical purposes: study ID, publication year, country, study design, sample size, baseline characteristics of participants (mean age and sex distribution), follow-up duration, the number of participants in the buried and exposed K-wire groups, and the outcomes of interest. These data extracted by five independent authors were tabulated into Microsoft Excel 2019.

The outcomes of interest in this study were divided into primary and secondary outcomes. The primary outcome was pin site infection which encompassed both superficial and deep infection at or around the site of K-wire placement. The secondary outcomes consisted of early pin removal rate, days to pin removal, and duration of surgery. Early pin removal was defined as the removal of K-wire before the initially planned date due to complications.

Risk of bias assessment

The risk of bias assessment was conducted by five independent authors using validated tools. For analyzing the quality of included RCTs, we used a tool from Cochrane Collaborations, namely Risk of Bias version 2 (RoB v2), which includes a methodological assessment of 5 domains: (a) randomization process; (b) deviations from intended interventions; (c) missing outcome data; (d) measurement of the outcome; and (e) selection of the reported results [13]. The result is shown in Fig 2. The authors’ evaluations were categorized as "low risk," "high risk," or "some concerns" of bias [13]. For analyzing the quality of included cohort/case-control studies, we used Newcastle-Ottawa Scale (NOS) from the Ottawa Hospital Research Institute (OHRI) which includes 3 domains of assessment: (1) selection of participants; (2) comparability between exposed and non-exposed cohort; and (3) outcome ascertainment [14]. The total score that can be achieved ranged from 0 to 9 where articles with ≥7 scores were considered as having "good" qualities [14].

Statistical analysis

We used mean difference (SMD) along with 95% confidence intervals (95% CI) for the analytical pooling of continuous variables outcomes by using the Inverse-Variance formula. We also pooled dichotomous variable outcomes into risk ratio (RR) along with 95% CI by using the Mantel-Haenszel formula. Random-effect models were chosen in this review because of the consideration that significant heterogeneity was expected due to differences in the population characteristics and differences in the duration of follow-up. In this review, we used the I-squared (I²) statistic to assess the heterogeneity between studies where I² values of >50% were categorized as significant heterogeneity. We used a combined formula from Luo D et al. [15] and Wan X et al. [16] to change the data expressed in the form of the median and interquartile range (IQR) or data expressed as median, minimum, and maximum into mean and standard deviations (SD) for pooled analysis purposes. A publication bias analysis was performed when there were more than 10 studies on each outcome of interest. If an asymmetry in the funnel plot was found, we intended to review the PICO and outcomes characteristics to determine whether the observed asymmetry could be attributed to publication bias or alternative factors such as methodological heterogeneity among the studies. All of these statistical analyses were carried out using an application from the Cochrane Collaboration, namely Review Manager 5.4. The robustness of the outcomes was scrutinized through sensitivity meta-analysis, wherein only studies with overall low risk of bias included.

The statistical methodology of regression analysis is frequently employed for data analysis to elucidate the association between a dependent variable and one or more independent variables. Utilizing linear regression, the model centers on the dependent variable, such as sample size, age, sex, and follow-up duration, and whether they exhibited influence the observed associations or not. The choice of these variables is guided by theoretical considerations and their relevance to the analytical objectives. The regression analysis is conducted using STATA 17 for robust data interpretation.

Results

Study selection and characteristics

A literature search on 4 international databases yielded a total of 166 studies. After removing duplicates and screening studies based on their titles and abstracts, 140 studies were removed, leaving 26 studies. These 26 studies were assessed in a full-text form where 15 studies did not meet our eligibility criteria as follows: 8 studies were conducted on patients with humeral fractures, 2 studies did not have any control group, 2 studies did not have data on the outcome of interest, 1 study was only review article, 1 study did not use K-wire for all of the participants, and 1 study was not published in the English language, thus only 11 studies [9, 10, 17–25] were included in the final analysis Fig 1. Of these 11 studies, 5 were prospective RCTs and 6 were retrospective cohort studies. The number of samples ranged from 52 to 695 with the duration of follow-up varying from 6 weeks to 1 year. A summary of the baseline characteristics of the included studies can be found in Table 2.

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Fig 1. PRISMA diagram of the detailed process of selection of studies for inclusion in the systematic review and meta-analysis.

https://doi.org/10.1371/journal.pone.0296149.g001

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Table 2. Characteristics of included studies.

https://doi.org/10.1371/journal.pone.0296149.t002

Quality of study assessment

The risk of bias assessment by using the RoB v2 tool revealed that only 1 RCT [9] had a "low risk" of bias in all five assessment domains. The remaining four RCTs [10, 17–19] were judged to have “some concern” risk of bias. One RCT [18] used consecutive non-random sampling for the selection of participants which was deemed an inappropriate method for randomization, but there was no significant difference in the baseline characteristics of participants in the two groups of intervention, suggesting no serious problems during randomization, therefore was judged to have “some concern” risk of bias in the randomization process. Two RCTs [10, 17] did not mention in detail the blinding of the outcome assessors, therefore were judged to have “some concern” risk of bias in the measurement of the outcome. Lastly, one remaining RCT [19] did not mention in detail regarding both the randomization method and "blinding" of the outcome assessors, therefore were also judged to have "some concern" risk of bias in the randomization process and measurement of the outcome. The evaluation of all included cohort studies by using the NOS tool revealed "good quality" studies with total scores ranging from 7 to 8. The summary of the risk of bias assessment for all included studies in this review can be found in Fig 2 and Table 3.

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Fig 2. Risk of bias assessment of the included studies using RoB v2 tool.

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Table 3. Newcastle-Ottawa quality assessment of observational studies.

https://doi.org/10.1371/journal.pone.0296149.t003

Data synthesis

Primary outcome.

Pin site infection. Based on our pooled analysis of 11 studies (n = 2,022), it has been shown that buried K-wire was associated with a lower risk of pin site infection when compared with exposed K-wire in patients with hand and forearm fractures [RR 0.49 (95% CI 0.36–0.67), p < 0.00001, I² = 0%, random-effect models] as shown in Fig 3. Subgroup analysis based on the study design revealed consistent and significant results for both RCTs [RR 0.38 (95% CI 0.21–0.68), p = 0.001, I² = 0%, random-effect models] and observational studies [RR 0.54 (95% CI 0.37–0.79), p = 0.001, I² = 0%, random-effect models] with a lower RR was found in the RCTs studies.

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Fig 3. Forest plot that demonstrates the comparison between buried and exposed K-wire for the pin site infection outcome in both randomized clinical trials (RCTs) and observational studies.

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Secondary outcome.

Early pin removal. Pooled analysis from 6 studies (n = 1,200) showed a non-significant difference in the rate of early pin removal between buried and exposed K-wire for patients with hand and forearm fractures [RR 0.73 (95% CI 0.36–1.45), p = 0.37, I² = 0%, random-effect models] as in Fig 4. Subgroup analysis based on the study design revealed that the results remained non-significant for both RCT [RR 0.65 (95% CI 0.10–4.03), p = 0.64, I² = 31%, random-effect models] and observational studies [RR 0.74 (95% CI 0.34–1.61), p = 0.44, I² = 0%, random-effect models].

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Fig 4. Forest plot that demonstrates the comparison between buried and exposed K-wire for the early pin removal outcome in both randomized clinical trials (RCTs) and observational studies.

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Days to pin removal. Pooled analysis from 4 studies (n = 1,493) showed that buried K-wire was associated with significantly longer days to pin removal when compared to exposed K-wire in patients with hand and forearm fractures [MD 33.85 days (95% CI 18.68–49.02), p < 0.0001, I² = 99%, random-effect models]. The forest plot is available in Fig 5 Subgroup analysis based on the study design revealed significant results for both RCT [MD 29.00 (95% CI 24.04–33.96), p < 0.00001, random-effect models] and observational studies [MD 32.53 (95% CI 16.89–48.18), p < 0.0001, I² = 99%, random-effect models] with the MD was found to be higher in the observational studies.

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Fig 5. Forest plot that demonstrates the comparison between buried and exposed K-wire for the days to pin removal outcome in both randomized clinical trials (RCTs) and observational studies.

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Duration of surgery. Pooled analysis from 3 studies (n = 325) showed that the duration of surgery was significantly longer for the buried K-wire when compared to exposed K-wire in patients with hand and forearm fractures [MD 6.98 minutes (95% CI 2.19–11.76), p = 0.004, I² = 42%, random-effect models] as shown in Fig 6. Subgroup analysis based on the study design revealed that a significant difference in the duration of surgery was only seen in the RCTs studies [MD 7.53 (95% CI 0.74–14.31), p = 0.03, I² = 70%, random-effect models] but not in the observational studies [MD 5.45 minutes (95% CI -5.14–16.04), p = 0.31, random-effect models].

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Fig 6. Forest plot that demonstrates the comparison between buried and exposed K-wire for the duration (minutes) of surgery outcome in both randomized clinical trials (RCTs) and observational studies.

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Meta-regression. Identification of risk factors that influence the relationship of buried and exposed K-wire with all of the outcomes of interest was done with meta-regression. Our meta-regression revealed that variability in those outcomes in hand and forearm fractures patients receiving buried or exposed K-wire fixation cannot be explained by known patient factors associated with predictors of treatment outcomes (Table 4). From our meta-regression analysis, it was revealed that pin site infection in hand or forearm fractures patients treated with either buried or exposed K-wire was not significantly influenced by sample size (p = 0.3469) (Fig 7A), age (p = 0.5300) (Fig 7B), sex (p = 0.1105) (Fig 7C), or follow-up duration (p = 0.2895) (Fig 7D).

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Fig 7. Bubble-plot for meta-regression.

Meta-regression analysis showed that the comparison between buried and exposed K-wire with the pin site infection outcome was not significantly affected by sample size (A), age (B), sex (C), nor follow-up duration (D).

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Table 4. Result for the meta-regression models for each outcome of interest.

https://doi.org/10.1371/journal.pone.0296149.t004

The association between either buried or exposed K-wire with early pin removal was not significantly influenced by sample size (p = 0.8827) (Fig 8A), age (p = 0.4780) (Fig 8B), sex (p = 0.5103) (Fig 8C), or follow-up duration (p = 0.2063) (Fig 8D).

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Fig 8. Bubble-plot for meta-regression.

Meta-regression analysis showed that the comparison between buried and exposed K- wire with the early pin removal outcome was not significantly affected by sample size (A), age (B), sex (C), nor follow-up duration (D).

https://doi.org/10.1371/journal.pone.0296149.g008

Our meta-regression analysis also revealed that the days to pin removal in patients with hand or forearm fractures receiving either buried or exposed K-wire were not significantly influenced by sample size (p = 0.1839) (Fig 9A), age (p = 0.0514) (Fig 9B), or sex (p = 0.8928) (Fig 9C). Variable "follow-up duration" was not possible to be included in the meta-regression analysis for this outcome because of the insufficient number of data in the included studies.

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Fig 9. Bubble-plot for meta-regression.

Meta-regression analysis showed that the comparison between buried and exposed K- wire with the days to pin removal outcome was not significantly affected by sample size (A), age (B), sex (C).

https://doi.org/10.1371/journal.pone.0296149.g009

Finally, the outcome "duration of surgery" was also not possible to be analyzed in the meta-regression analysis due to the insufficient number of included studies for this outcome.

All the meta-regression results for each outcome of interest is summarized in this below Table 4.

Publication bias.

The Funnel-plot analysis shown in Fig 10 for the pin site infection outcome revealed a relatively symmetrical inverted plot, suggesting no indication of publication bias. Meanwhile, the publication bias analysis was not performed for the early pin removal, days to pin removal, and duration of surgery outcomes due to less than 10 studies included in these outcomes where funnel plots and statistical tests to detect publication bias are less reliable [26, 27].

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Fig 10. Funnel plot analysis that showed a relatively symmetrical inverted plot for the pin site infection outcome, indicating no publication bias.

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Discussion

In a randomized controlled trial conducted by Maradei-Pereira JAR et al., the prevailing literature concerning forearm fractures, particularly those implicating the radius and ulna, has underscored their prevalence and consequential implications on routine activities. Kirschner wires (K-wires) have arisen as a prevalent fixation modality, notably within the domain of hand and upper extremity surgery, attributed to their favorable outcomes and cost-effectiveness [9]. Nonetheless, previous investigations comparing K-wires against alternative fixation techniques have yielded disparate results, with specific scrutiny directed towards the potential risk of infection posed by exposed K-wires [9, 10].

Based on the results of our meta-analysis, it has been shown that buried K-wire was associated with a lower risk of pin site infection and longer duration of pin removal when compared with exposed K-wire in patients with hand and forearm fractures, although the early pin removal rate did not differ significantly between two groups and the duration of surgery was significantly longer in the buried K-wire group. Importantly, to provide a comprehensive assessment of the practical implications, we scrutinized that re-surgical intervention was required for the removal of buried K-wires. This additional consideration is crucial for understanding the postoperative management and potential complications associated with buried K-wire fixation. Despite the longer duration of surgery observed in the buried K-wire group, the lack of a significant difference in the early pin removal rate suggests that the benefits associated with buried K-wire placement outweigh the potential drawbacks. Further regression analysis also revealed that the study’s variables, such as sample size, age, sex, and follow-up duration did not significantly influence these relationships.

The results of our meta-analysis were in line with the results of the previous study by Chen L et al. [28] which also showed that buried K-wires had a lower risk of infection compared to exposed K-wires even though early pin removal did not differ significantly between groups. However, there were some differences between our current meta-analysis and the previous study by Chen L et al. [28].

First, the previous study by Chen L et al. [28]. only included a total of 7 studies consisting of 2 RCTs and 5 observational studies. Meanwhile, our current meta-analysis has included more studies, a total of 11 studies (5 RCTs and 6 observational studies) with an additional 3 RCTs and 1 observational study when compared to the previous study which will certainly produce more solid evidence.

Second, the previous study by Chen L et al. [28]. combined the results from RCT studies with results from observational studies. This action was inappropriate and not recommended when we referred to the guidelines from the Cochrane Handbook of Systematic Reviews of Intervention [12]. Observational studies tend to be susceptible to several biases such as selection bias and information bias which can have an impact on the research results [29, 30]. Selection bias can lead to differences in the baseline characteristics of the two groups of participants which will also influence the results of the analysis [29, 30]. Information bias can lead to inaccuracies of data and the results of outcome measurement obtained [29, 30]. In addition, observational studies are often unable to anticipate the existence of several confounders which can also have an impact on research results [29, 30]. Meanwhile, RCTs can avoid the presence of confounders through a process of randomizing the participants [31, 32]. The existence of bias such as selection bias and information bias can also be minimized by allocation concealment and blinding methods, both for the participants and the outcome assessors [31, 32]. Therefore, it is advisable to separate the results from RCTs and the results from observational studies. In our current meta-analysis, we have followed the recommendations of the Cochrane guidelines by separating the results from the RCTs and observational studies that can be seen in all of our forest plots, although there were no significant differences in results between those two study designs.

Third, our current meta-analysis had an additional outcome in the form of "days to pin removal" which was not analyzed in the previous study by Chen L et al. [28] From this new outcome, it was found that buried K-wire was able to provide a longer time for pin removal when compared to exposed K-wire. In addition, our current meta-analysis was also equipped with a meta-regression analysis to see the effect of several study variables, such as sample size, age, sex, and follow-up duration. From the results of our regression analysis, we have found no significant effect of these variables on the outcomes of interest.

The results of our meta-analysis align with the findings of previous studies, specifically those conducted by Maradei-Pereira JAR et al. [9] and Khaled M et al. [10]. In our analysis, buried K-wires demonstrated a lower risk of pin site infection, consistent with the study on distal radial fractures by Maradei-Pereira JAR et al. [9], which observed a greater risk of infection when K-wires were left exposed. The contrast in infection risk between exposed and buried K-wires was further supported by our meta-analysis.

Conversely, our results also correspond with the study by Khaled M et al. [10], which showed no significant difference in the complication rate, including pin infection incidence, between exposed and buried K-wires. The lack of a significant difference in the early pin removal rate between the two groups in our meta-analysis echoes the findings of Khaled M et al. [10]. The existing literature, combined with our meta-analysis results, suggests a consistent trend in favor of buried K-wires for reducing the risk of pin site infection, while not significantly impacting the early pin removal rate.

Despite having several advantages above, our current meta-analysis is not without limitations. The majority of included studies have small sample sizes, under 100 participants. Some of these studies, especially the RCTs, also have "some concern" risk of bias caused by a lack of detailed information regarding the randomization method and the blinding of the outcome assessors. Two of our outcomes of interest, namely days to pin removal and duration of surgery, have relatively high heterogeneities (above 50%) which may be due to differences in the surgeon’s experience and length of follow-up duration. Finally, data regarding the cost-effectiveness analysis of the two K-wire methods were lacking in the included studies, therefore cannot be analyzed further. Further RCTs with larger sample sizes are still needed to confirm the results of our meta-analysis.

Conclusion

Our systematic review and meta-analysis suggests that buried K-wire may be more beneficial than exposed K-wire to provide a lower risk of infection and longer duration until pin removal in patients with hand and forearm fractures. However, the duration of surgery was relatively longer in the buried K-wire groups with no significant difference in the rate of early pin removal. The final decision on whether to bury or expose the K-wire fixation should still be based on the surgeon’s judgment with the consideration of the patient’s clinical condition as well as the benefits and risks for each patient. Further RCTs with larger sample sizes are still needed to confirm the results of our study.

Supporting information

S1 Checklist. PRISMA 2020 checklist.

https://doi.org/10.1371/journal.pone.0296149.s001

(DOCX)

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Figures

Abstract

Background

Methods

Results

Conclusion

Introduction

Material and method

Eligibility criteria

Literature search and study selection

Data extraction

Risk of bias assessment

Statistical analysis

Results

Study selection and characteristics

Quality of study assessment

Data synthesis

Primary outcome.

Secondary outcome.

Publication bias.

Discussion

Conclusion

Supporting information

S1 Checklist. PRISMA 2020 checklist.

References