A meta-analysis and trial sequential analysis of randomised controlled trials comparing nonoperative and operative management of chest trauma with multiple rib fractures

Hisamune, Ryo; Kobayashi, Mako; Nakasato, Karin; Yamazaki, Taiga; Ushio, Noritaka; Mochizuki, Katsunori; Takasu, Akira; Yamakawa, Kazuma

doi:10.1186/s13017-024-00540-z

Review
Open access
Published: 19 March 2024

A meta-analysis and trial sequential analysis of randomised controlled trials comparing nonoperative and operative management of chest trauma with multiple rib fractures

Ryo Hisamune¹,
Mako Kobayashi²,
Karin Nakasato²,
Taiga Yamazaki²,
Noritaka Ushio¹,
Katsunori Mochizuki¹,
Akira Takasu¹ &
…
Kazuma Yamakawa¹

World Journal of Emergency Surgery volume 19, Article number: 11 (2024) Cite this article

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Abstract

Background

Operative treatment of traumatic rib fractures for better outcomes remains under debate. Surgical stabilization of rib fractures has dramatically increased in the last decade. This study aimed to perform a systematic review and meta-analysis of randomised controlled trials (RCTs) to assess the effectiveness and safety of operative treatment compared to conservative treatment in adult patients with traumatic multiple rib fractures.

Methods

A systematic literature review was performed according to the preferred reporting items for systematic reviews and meta-analyses guidelines. We searched MEDLINE, Scopus, and Cochrane Central Register of Controlled Trials and used the Cochrane Risk-of-Bias 2 tool to evaluate methodological quality. Relative risks with 95% confidence interval (CI) were calculated for outcomes: all-cause mortality, pneumonia incidence, and number of mechanical ventilation days. Overall certainty of evidence was evaluated with the Grading of Recommendations Assessment, Development and Evaluation (GRADE) approach, with trial sequential analysis performed to establish implications for further research.

Results

From 719 records, we included nine RCTs, which recruited 862 patients. Patients were assigned to the operative group (received surgical stabilization of chest wall injury, n = 423) or control group (n = 439). All-cause mortality was not significantly different (RR = 0.53; 95% CI 0.21 to 1.38, P = 0.35, I² = 11%) between the two groups. However, in the operative group, duration of mechanical ventilation (mean difference -4.62; 95% CI -7.64 to -1.60, P < 0.00001, I² = 94%) and length of intensive care unit stay (mean difference -3.05; 95% CI -5.87 to -0.22; P < 0.00001, I² = 96%) were significantly shorter, and pneumonia incidence (RR = 0.57; 95% CI 0.35 to 0.92; P = 0.02, I² = 57%) was significantly lower. Trial sequential analysis for mortality indicated insufficient sample size for a definitive judgment. GRADE showed this meta-analysis to have very low to low confidence.

Conclusion

Meta-analysis of large-scale trials showed that surgical stabilization of multiple rib fractures shortened the duration of mechanical ventilation and reduced the incidence of pneumonia but lacked clear evidence for improvement of mortality compared to conservative treatment. Trial sequential analysis suggested the need for more cases, and GRADE highlighted low certainty, emphasizing the necessity for further targeted RCTs, especially in mechanically ventilated patients.

Systematic review registration: UMIN Clinical Trials Registry UMIN000049365.

Background

Traumatic deaths account for approximately 10% of all deaths worldwide [1]. Especially, chest trauma comprises up to 25% of the annual trauma cases [2], and rib fractures are the most common type of blunt trauma, accounting for 43% [3]. The common causes of trauma include road traffic accidents, high falls, crush forces, and direct violence. Rib fractures resulting from these causes can range from simple to a flail segment [4]. One of the characteristic clinical symptoms is a flail chest, which is defined as three or more sequential rib fractures at more than one site that result in paradoxical movement of the chest wall, alteration of respiratory mechanics, and, frequently, respiratory failure. Generally, it has been difficult to control pain in these injuries, which show a high incidence of complications, including chest wall instability, severe pulmonary restriction owing to paradoxical movement of the flail segment, and loss of lung volume [5]. The combination of chest wall instability, decreased lung capacity, and pain can result in decreased lung function and the need for prolonged ventilation.

Prolonged mechanical ventilation is associated with high rates of pneumonia, tracheostomy, barotrauma, long-term intensive care unit (ICU) stays, and high medical costs [6]. Rib fractures also represent a significant loss of working days and may reduce a patient’s quality of life for several months after injury [7]. The treatment strategy for rib fractures can be divided into two main categories: conservative treatment and surgical treatment. Although conservative treatment used to be the main strategy, surgical treatment to stabilize rib fractures (SSRF) has dramatically increased in the last decade [8], with rates of SSRF having risen from less than 1% to over 10% [9]. Conceptually, SSRF applies the basic orthopaedic principles of reduction and fixation to rib fractures, restoring chest wall stability, relieving pain, and improving respiratory failure. The most prevalent treatment of severe chest wall injuries consists of non-operative management via intubation and intermittent positive-pressure ventilation as needed, analgesia, pulmonary toilet, chest tube drainage, and chest physiotherapy. Recently, retrospective studies and multiple randomised controlled trials (RCTs) have reported that surgical treatment improved clinical outcomes compared to conservative treatment.

As mentioned above, the optimal strategy for traumatic multiple rib fractures is controversial due to limited available evidence. However, novel large-scale RCTs performed by Dehghan et al. [10] and Meyer et al. [11] were recently published. Here, we describe our systematic review and meta-analysis of RCTs performed to assess the certainty of evidence for determining the optimal strategy for patients with traumatic rib fractures.

Methods and designs

Protocol registration

This study protocol was registered in the University Hospital Medical Information Network (UMIN) Clinical Trials Registry (https://www.umin.ac.jp/ctr/index-j.htm) (Registration No. UMIN000049365). The protocol follows the Preferred Reporting Items for Systematic Reviews and Meta-Analyses Protocols (PRISMA-P) statements [12], and this systematic review and meta-analysis followed the PRISMA statement [13].

Focused review questions

The purpose of this review was to explore the effectiveness and safety of operative management for traumatic chest wall injury.

Types of studies

We included only RCTs that compared operative management in adults with multiple rib fractures to non-operative management. We excluded the following article types: cohort studies, case–control studies, experimental animal studies, narrative reviews, correspondence, case reports, expert opinions, and editorials from the study.

Participants

We included RCTs that enrolled adult patients aged 16 years or older suffering traumatic rib fractures with or without flail chest in which three or more adjacent ribs were fractured in at least two places and who required surgery.

Interventions and comparators

We included RCTs that describe an operative management group versus a non-operative management group for traumatic multiple rib fractures. Studies were included if surgery was performed within one week of patient enrolment. The number of rib fractures requiring repair varied across the studies, and rib fracture stabilization was primarily achieved using screws and plates, and wires. Also, the choice of surgical specialists, such as trauma surgeons, orthopaedic surgeons, or thoracic surgeons, depended on the studies. All patients in each group received standard-of-care treatment, including mechanical ventilation as needed, pain control management, chest drainage as needed, antibiotics administration, and pulmonary physiotherapy.

Outcome assessments

The primary outcome parameter was all-cause mortality. The secondary outcome parameters of duration of mechanical ventilation, incidence of pneumonia, length of ICU stay, length of hospital stay, and need for tracheostomy were also assessed.

Search strategy

We searched the following databases for relevant studies: MEDLINE (via PubMed), Scopus, and the Cochrane Central Register of Controlled Trials. We developed a search strategy in MEDLINE using a combination of keywords and Medical Subject Headings (MeSH) terms as listed in Additional file 4. We also screened the reference lists of all relevant papers for additional studies. Our MEDLINE search strategy was adapted appropriately for searches in the other two databases. No language or time restrictions were applied to the electronic searches. Our systematic search was conducted in September 2023.

Citation management and screening

Citations were stored, and duplicates were removed using EndNote software ver. 20.4 (Thomson Reuters, Toronto, Ontario, Canada). Studies were screened initially according to title and abstract by two authors (KN and TY) independently, and those not meeting the criteria were discarded. Disagreements were resolved by discussion and referral to a third author (KY) if necessary. After this initial stage, the full text of all remaining studies was reviewed, and disagreements were resolved in the same way as in the initial screening. We used the Rayyan QCRI website (http://rayyan.qcri.org) [14] in this screening process. We documented the study selection process in a PRISMA flow diagram.

Data extraction

Two authors (KN and TY) independently extracted the study characteristics from each included study and transferred the information into a study-specific format. The following information was extracted from the included studies: the number of patients in the intervention and control groups, type of surgery, number of patients who were on mechanical ventilation at the time of enrolment, number of fractured ribs, reported outcomes, and the respective mean and standard deviation or frequency data. Outcome data were double-checked, consolidated, and included in the meta-analysis software. Adjudication by a third author (KY) was used if necessary.

Assessment of risk of bias within studies

Independent reviewers (KN, TY, and RH) assessed the risk of bias in the individual trials as the methodological quality of the articles. Disagreements were resolved by discussion and consultation with a third author (KY). To evaluate the risk of bias in the individual RCTs, we followed the recommendations of the Cochrane Handbook for Systematic Reviews of Interventions and used the Cochrane Collaboration’s tool for assessing the risk of bias in randomised trials (Rob 2) [15]. For each domain, we assigned a judgment regarding the risk of bias as “high risk”, “low risk”, or “some concerns”. We attempted to contact a trial’s corresponding author for clarification when insufficient detail was reported to assess the risk of bias.

Statistical analysis

Statistical analyses were performed using Review Manager 5.4 software (Nordic Cochrane Centre, Cochrane Collaboration) and R software version 4.2.3. For each included trial, we calculated the relative risk with 95% confidence interval (CI) for all outcome measures. Continuous variables are reported as a mean difference (MD) with 95% CI using a random effects inverse variance model. Dichotomous variables were analysed using the Mantel–Haenszel model and were reported as a risk ratio (RR) with the random effects model.

Trial sequential analysis

Trial sequential analysis (TSA) was performed using Trial Sequential Analysis software ver. 0.9.5.10 beta [Computer program] (The Copenhagen Trial Unit, Centre for Clinical Intervention Research, The Capital Region, Copenhagen University Hospital-Rigshospitalet 2021). We assessed the adequacy of the available number of patients and performed TSA to establish the implication for further research. We calculated the required diversity-adjusted information size. Diversity, which indicates the percentage of variability between trials, is calculated as the sum of the between-trial variability and a sampling error estimate based on the required information size. We performed TSA with the goal of maintaining an overall 5% risk of type I error, which is considered the standard for most meta-analyses and systematic reviews. The required information size was also calculated (α error of 5%, β error of 20%) [16, 17]. In theory, firm evidence is likely established if the trial sequential monitoring boundary is crossed before reaching the required information size, but if this boundary is not crossed, it is highly likely that trials will need to be continued.

Assessment of heterogeneity

We investigated heterogeneity initially by visual examination of forest plots. Statistical heterogeneity was evaluated informally from forest plots of the study estimates and more formally using the χ² test (P-value < 0.1 = significant heterogeneity) and I² statistic (I² > 50% = significant high heterogeneity). We performed sensitivity analyses using low-risk-of-bias trials and trials of flail segments of rib fractures.

Assessment of publication biases

Funnel plots were conducted to evaluate potential publication bias in the current literature. We did not conduct a quantitative assessment of small studies or evaluate the presence of publication bias due to the inclusion of fewer than 10 studies in this meta-analysis [18].

Rating certainty of evidence with the grading of recommendations assessment, development, and evaluation (GRADE) approach

The risks of systematic errors (bias) and random errors were assessed, and the overall certainty of evidence was evaluated using the GRADE guidelines [19]. We labeled studies as having very low-, low-, moderate-, or high-quality evidence based on the presence of risk of bias, inconsistency of results, imprecision, publication bias, and magnitude of treatment effects.

Results

Study identification and selection

In total, 719 articles were retrieved, including 223 from PubMed, 414 from Scopus, and 82 from Cochrane Central Register of Controlled Trials by the search strategy, as shown in Fig. 1. Excluding duplicates, 580 articles underwent primary screening and 20 underwent secondary screening. Ultimately, 9 articles were included in the final analysis [10, 11, 20,21,22,23,24,25,26]. Of the total of 862 patients included in the articles under review, 423 were treated with operative treatment, and 439 were treated with conservation treatment. Seven RCTs [10, 20,21,22,23,24, 26] involved patients with flail segment and clinical flail chest, one study [11] involved patients with flail segment but no clinical flail chest, one study [25] involved patients with simple rib fractures without clinical or radiological flail chest, and one study included only men [23]. The characteristics of the included studies are summarised in Table 1.

Table 1 Characteristics of the included studies

Full size table

Assessment of bias

The identified studies exhibited heterogeneity in their inclusion criteria, surgical techniques, time to surgery, definition of flail chest, assessed outcomes, and length of follow-up. Therefore, we used random effect models for the analysis. The risk of individual within-study bias is represented in the Rob 2 traffic-light diagram shown in Additional file 1: Fig. S1. All of the Rob 2 assessment domains excluding the measurement of outcome domain had at least one or some concerns. One RCT raised high risk in its deviation from the intended intervention domain. Two RCTs were assigned a low risk of bias.

Outcomes

Mortality

All of the studies reported mortality. Complete data were extracted from all studies, with no statistical heterogeneity noted between groups (I² = 11%, P = 0.35). There was no significant difference in the mortality rate between the groups (RR = 0.53; 95% CI 0.21 to 1.38; P = 0.19) (Fig. 2A).

Incidence of pneumonia

Complete data were shown in 8 studies [10, 11, 20,21,22,23,24,25], with statistical heterogeneity noted between groups (I² = 57%, P = 0.02). A combined 144 events occurred in the 738 patients. There was a significant difference favouring the operative group (RR = 0.57; 95% CI 0.35 to 0.92; P = 0.02) (Fig. 2B).

Need for tracheostomy

Complete data were shown in 6 studies [10, 11, 20, 22,23,24], with statistical heterogeneity noted between groups (I² = 63%, P = 0.02). A combined 105 events occurred in the 588 patients. There was no significant difference between the groups (RR = 0.70; 95% CI 0.38 to 1.30; P = 0.26) (Fig. 2C).

Duration of mechanical ventilation

Complete data were shown in 7 studies [10, 11, 20,21,22,23,24], with statistical heterogeneity noted between groups (I² = 94%, P < 0.001). There was a significant difference favouring the operative group (MD -4.62; 95% CI -7.64 to -1.60; P = 0.003) (Fig. 2D).

ICU length of stay

Complete data were shown in 8 studies [10, 11, 20,21,22,23,24, 26], with statistical heterogeneity noted between groups (I² = 96%, P < 0.01). There was a significant difference favouring the operative group (MD -3.05; 95% CI -5.87 to -0.22; P = 0.03) (Fig. 2E).

Hospital length of stay

Complete data were shown in 7 studies [10, 11, 21,22,23,24, 26], with statistical heterogeneity noted between groups (I² = 97%, P < 0.001). There was no significant difference between the groups (MD -3.79; 95% CI -9.33 to 1.75; P = 0.18) (Fig. 2F).