How early should VATS be performed for retained haemothorax in blunt chest trauma?

Pleural Space Management in Thoracic Trauma

SUMMARY

Thoracic injuries are common, occurring in up to 60% of polytrauma patients and represent 25% of trauma deaths. Thoracic trauma frequently involves injury to the pleural space resulting in hemothorax and pneumothorax-effective management of the pleural space is essential. Reviewed in this article is management of the pleural space in chest wall trauma (including pneumothorax and hemothorax), and chest tube placement, indications for video-assisted thoracoscopic surgery, management, and complications.

Intrapleural Fibrinolytic Interventions for Retained Hemothoraces in Rabbits

Bleeding within the pleural space may result in persistent clot formation called retained hemothorax (RH). RH is prone to organization, which compromises effective drainage, leading to lung restriction and dyspnea. Intrapleural fibrinolytic therapy is used to clear the persistent organizing clot in lieu of surgery, but fibrinolysin selection, delivery strategies, and dosing have yet to be identified. We used a recently established rabbit model of RH to test whether intrapleural delivery of single-chain urokinase (scuPA) can most effectively clear RH. scuPA, or single-chain tissue plasminogen activator (sctPA), was delivered via thoracostomy tube on day 7 as either one or two doses 8 h apart. Pleural clot dissolution was assessed using transthoracic ultrasonography, chest computed tomography, two-dimensional and clot displacement measurements, and gross analysis. Two doses of scuPA (1 mg/kg) were more effective than a bolus dose of 2 mg/kg in resolving RH and facilitating drainage of pleural fluids (PF). Red blood cell counts in the PF of scuPA, or sctPA-treated rabbits were comparable, and no gross intrapleural hemorrhage was observed. Both fibrinolysins were equally effective in clearing clots and promoting pleural drainage. Biomarkers of inflammation and organization were likewise comparable in PF from both groups. The findings suggest that single-agent therapy may be effective in clearing RH; however, the clinical advantage of intrapleural scuPA remains to be established by future clinical trials.

Thoracic cavity irrigation prevents retained hemothorax and decreases surgical intervention in trauma patients

INTRODUCTION

Retained hemothorax (HTX) is a common complication following thoracic trauma. Small studies demonstrate the benefit of thoracic cavity irrigation at the time of tube thoracostomy (TT) for the prevention of retained HTX. We sought to assess the effectiveness of chest irrigation in preventing retained HTX leading to a secondary surgical intervention.

METHODS

We performed a single-center retrospective study from 2017 to 2021 at a Level I trauma center, comparing bedside thoracic cavity irrigation via TT versus no irrigation. Using the trauma registry, patients with traumatic HTX were identified. Exclusion criteria were TT placement at an outside hospital, no TT within 24 hours of admission, thoracotomy or video-assisted thoracoscopic surgery (VATS) prior to or within 6 hours after TT placement, VATS as part of rib fixation or diaphragmatic repair, and death within 96 hours of admission. Bivariate and multivariable analyses were conducted.

RESULTS

A total of 370 patients met the inclusion criteria, of whom 225 (61%) were irrigated. Patients who were irrigated were more likely to suffer a penetrating injury (41% vs. 30%, p = 0.03) and less likely to have a flail chest (10% vs. 21%, p = 0.01). On bivariate analysis, irrigation was associated with lower rates of VATS (6% vs. 19%, p < 0.001) and retained HTX (10% vs. 21%, p < 0.001). The irrigated cohort had a shorter TT duration (4 vs. 6 days, p < 0.001) and hospital length of stay (7 vs. 9 days, p = 0.04). On multivariable analysis, thoracic cavity irrigation had lower odds of VATS (adjusted odds ratio, 0.37; 95% confidence interval [CI], 0.30-0.54), retained HTX (adjusted odds ratio, 0.42; 95% CI, 0.25-0.74), and a shorter TT duration ( β = -1.58; 95% CI, -2.52 to -0.75).

CONCLUSION

Our 5-year experience with thoracic irrigation confirms findings from smaller studies that irrigation prevents retained HTX and decreases the need for surgical intervention.

LEVEL OF EVIDENCE

Therapeutic/Care Management; Level III.

Late video-assisted thoracoscopic surgery versus thoracostomy tube reinsertion for retained hemothorax after penetrating trauma, a prospective randomized control study

BACKGROUND

Early video-assisted thoracoscopic surgery (VATS) is the recommended treatment of choice for retained hemothorax (RH). A prospective single-center randomized control study was conducted to compare outcomes between VATS and thoracostomy tube (TT) reinsertion for patients with RH after penetrating trauma in a resource constrained unit. Our hypothesis was that patients with a RH receiving VATS instead of TT reinsertion would have a shorter hospital stay and lesser complications.

MATERIALS AND METHODS

From January 2014 to November 2019, stable patients with thoracic penetrating trauma complicated with retained hemothoraces were randomized to either VATS or TT reinsertion. The outcomes were length of hospital stay (LOS) and complications.

RESULTS

Out of the 77 patients assessed for eligibility, 65 patients were randomized and 62 analyzed: 30 in the VATS arm and 32 in the TT reinsertion arm. Demographics and mechanisms of injury were comparable between the two arms. Length of hospital stay was: preprocedure: VATS 6.8 (+/-2.8) days and TT 6.6 (+/- 2.4) days (p = 0.932) and postprocedure: VATS 5.1 (+/-2.3) days, TT 7.1 (+/-6.3) days (p = 0.459), total LOS VATS 12 (+/- 3.9) days, and TT 14.4 (+/-7) days (p = 0.224). The TT arm had 15 complications compared to the VATS arm of four (p = 0.004). There were two additional procedures in the VATS arm and 10 in the TT arm (p = 0.014).

CONCLUSION

VATS proved to be the better treatment modality for RH with fewer complications and less need of additional procedures, while the LOS between the two groups was not statistically different.

Outcomes of Video-assisted Thoracic Surgery-guided Early Evacuation of Traumatic Hemothorax: A Randomized Pilot Study at Level I Trauma Center

Introduction

Traumatic hemothorax is accounted for about 20% of traumatic chest injuries. Although majority can be managed with the timely placement of intercostal tube (ICT) drainage, the remaining pose a challenge owing to high complication rates associated with retained hemothorax. Although various treatment modalities including intrapleural instillation of fibrinolytics, radioimage guided drainage, VATS guided evacuation and thoractomy do exist to address the retained hemothorax, but indications along with timing to employ a specific treatment option is still unclear and ambiguous.

Methods

Patient with residual hemothorax (>200 mL) on ultrasonography after 48 h of indwelling ICT was randomized into either early video-assisted thoracic surgery (VATS) or conventional approach cohort. Early VATS cohort was subjected to video-assisted thoracoscopic evacuation of undrained blood along with normal saline irrigation and ICT placement. The conventional cohort underwent intrapleural thrombolytic instillation for 3 consecutive days. The outcome measures were the duration of indwelling ICT, removal rate of tube thoracostomy, length of hospital stay, duration of intensive care unit (ICU) monitoring, need for mechanical ventilation, incidence of pulmonary and pleural complications, and requirement of additional intervention to address undrained hemothorax and mortality rate.

Results

The early VATS cohort had shorter length of hospital stay (7.50 ± 0.85 vs. 9.50 ± 3.03, P = 0.060), reduced duration of indwelling ICT (6.70 ± 1.25 vs. 8.30 ± 2.91, P = 0.127) with higher rate of tube thoracostomy removal (70% vs. 30%, P = 0.003) and lesser need of additional interventions (0% vs. 30%, P = 0.105). Thoracotomy (3 patients) and image-guided drainage (4 patients) were additional interventions to address retained hemothorax in the conventional cohort. However, similar length of ventilator assistance (0.7 ± 0.48 vs. 0.60 ± 1.08, P = 0.791) and prolonged ICU monitoring (1.30 ± 1.06 vs. 0.90 ± 1.45, P = 0.490) was observed in early VATS cohort. Both the cohorts had no mortality.

Conclusion

VATS-guided early evacuation of traumatic hemothorax is associated with shorter length of hospital stay along with abbreviated indwelling ICT duration, reduced incidence of complications, lesser readmissions, and improved rate of tube thoracostomy removal. However, the duration of ventilator requirement, ICU stay, and mortality remain unchanged.

Video-Assisted Thoracic Surgery Evacuation of Retained Hemothorax; Timing May Not Increase Thoracoscopic Failure

INTRODUCTION

Current guidelines for retained hemothorax (rHTX) in trauma patients recommend video-assisted thoracic surgery (VATS) within 4 days. However, this recommendation is currently based upon evidence from small observational studies. The aim of this study is to further evaluate the association between timing of VATS and clinical outcomes in rHTX following trauma.

METHODS

Using the 2017-2019 Trauma Quality Improvement Program database, adult (≥15 years-old) trauma patients with rHTX who underwent evacuation of rHTX through VATS were included. Multivariable linear and logistic regression were used to evaluate the association between the timing of VATS and clinical outcomes. Postponing/delaying evacuation through VATS was defined in our analysis as performing the surgery 1 day later in time.

RESULTS

793 patients were included. VATS was performed at a median 4.5 days (Interquartile range = 2.4, 8.4). A 1.17 day increase in hospital length of stay (P = <0.001), a 0.17 day increase in postoperative hospital length of stay (P = 0.007), a 0.48 day increase in ventilation days (P = <0.001), and a 0.66 day increase in intensive care unit length of stay (P = <0.001) was found for each day that VATS was delayed. Additionally, a 1.10 odds ratio for infectious complications (P = <0.001) and a 0.96 odds ratio for discharge to home (P = 0.006) was seen for each day VATS was delayed. There was no significant association between the timing of VATS failure of VATS (defined as requiring additional procedures such as a secondary VATS or progressed to thoracotomy after initial VATS) and mortality (P > 0.05).

CONCLUSIONS

While delaying VATS was statistically associated with increased hospital length of stay, and other secondary outcomes, the clinical significance of the increase in these variables were less dramatic compared to the results of other studies, thus tempering the urgency of evacuation. Additionally, there was no association found between the timing of VATS and mortality, discharge disposition, or the need for additional VATS and/or thoracotomy. Therefore, in the appropriate clinical context, the evacuation of rHTX through VATS can be delayed if clinically necessary, without an associated increase in mortality or the requirement for additional procedures.

[Occult and Retained Haemothorax - Recommendations of the Interdisciplinary Thoracic Trauma Task Group of the German Trauma Society (DGU - Section NIS) and the German Society for Thoracic Surgery (DGT)]

The management of occult and retained haemothorax is challenging for all involved in the care of polytrauma patients in terms of diagnosis and treatment. The focus of decision making is preventing sequelae such as pleural empyema and avoiding a trapped lung. An interdisciplinary task force of the German Society for Thoracic Surgery (DGT) and the German Trauma Society (DGU) on thoracic trauma offers recommendations for post-trauma care of patients with occult and/or retained haemothorax, as based on a comprehensive literature review.

Factors Associated With Successful Video-Assisted Thoracoscopic Surgery for Traumatic Hemothorax in Children: A Cross-Sectional Study

INTRODUCTION

Due to the rarity of traumatic hemothorax in children, no studies have evaluated factors associated with successful video-assisted thoracoscopic surgery (VATS) as definitive management.

METHODS

We conducted an exploratory cross-sectional analysis of pediatric patients in the Trauma Quality Programs database from 2008 to 2017 with traumatic hemothorax managed with primary VATS. Those with early resuscitative thoracotomy for cardiac arrest were excluded. We stratified patients by blunt or penetrating mechanism and estimated absolute differences (ADs) and 95% confidence intervals (CIs) to identify factors associated with successful VATS without conversion to thoracotomy or reoperation.

RESULTS

A total of 293 patients were eligible. Among 184 penetrating injuries, 150 (82%) underwent successful VATS, 6 (3%) required reoperation, and 28 (15%) converted to thoracotomy. Diaphragmatic injuries (AD = -28, 95% CI = -46 to -10) and rib fractures (AD = 12, 95% CI = 1 to 23) had the strongest negative and positive associations (respectively) with successful VATS. There were 109 blunt injuries: 86 (79%) underwent successful VATS, 6 (6%) required reoperation, and 17 (16%) converted to thoracotomy. Moderate or severe head injury (AD = -15, 95% CI = -32 to 2), injury severity score >15 (AD = -19, 95% CI = -33 to -5), and the presence of diaphragmatic injury (AD = -38, 95% CI = -71 to -4) had the strongest negative associations with successful VATS.

CONCLUSIONS

Some children with traumatic hemothorax can be successfully managed with VATS. For penetrating mechanism, diaphragmatic injuries were associated with less success, while rib fractures were associated with more success. For blunt mechanism, diaphragmatic injuries, injury severity score >15, or moderate or severe head injury were associated with less success.

Optimal time to thoracoscopy for trauma patients with retained hemothorax

BACKGROUND

Retained hemothorax remains a common problem after thoracic trauma with associated morbidity and prolonged hospitalizations. The goal of this study was to examine the impact of time to video assisted thoracoscopic surgery (VATS) on pulmonary morbidity using a large, national data set.

METHODS

Patients undergoing VATS for retained hemothorax within the first 14 days postinjury were identified from the Trauma Quality Improvement Program database over 5 years, ending in 2016. Demographics, mechanism, severity of injury, severity of shock, time to VATS, pulmonary morbidity, and mortality were recorded. Multivariable logistic regression analysis was performed to determine independent predictors of pulmonary morbidity. Youden's index was then used to identify the optimal time to VATS.

RESULTS

From the Trauma Quality Improvement Program database, 3,546 patients were identified. Of these, 2,355 (66%) suffered blunt injury. The majority were male (81%) with a median age and Injury Severity Score of 46 and 16, respectively. The median time to VATS was 134 hours. Both pulmonary morbidity (13 vs 17%, P = .004) and hospital length of stay (9 vs 12 days, P < .0001) were significantly reduced in patients undergoing VATS before 3.9 days. Multivariable logistic regression identified VATS during the first 7 days as the only modifiable risk factor significantly associated with reduced pulmonary morbidity (odds ratio 0.52; 95% confidence interval 0.43-0.63, P < .0001).

CONCLUSION

Patients undergoing VATS for retained hemothorax have significant morbidity and prolonged length of stay. VATS within the first week of admission results in fewer pulmonary complications and shorter length of stay. In fact, the optimal time to VATS was identified as 3.9 days and was the only modifiable risk factor associated with decreased pulmonary morbidity.

Early video-assisted thoracoscopic surgery (VATS) for non-emergent thoracic trauma remains underutilized in trauma accredited centers despite evidence of improved patient outcomes

PURPOSE

Thoracic injury is a major contributor to morbidity in trauma patients. There is limited data regarding practice patterns of video-assisted thoracoscopic surgery (VATS) across trauma-accredited hospitals in the United States. We hypothesized that early VATS remains underutilized affecting patient outcomes.

METHOD

We evaluated a cohort of patients who underwent non-urgent thoracic surgical intervention for trauma from the ACS-TQIP database in 2017 excluding patients who were discharged within 48-h or died within 72-h. We selected patients who underwent partial lung resection and decortication to assess the effect of early (day 2-5) versus late VATS. Univariate followed by multivariate regression analyses were utilized to evaluate the independent impact of timing.

RESULTS

Over 12 months, 997,970 patients were admitted to 850 trauma-accredited centers. Thoracic injury occurred in 23.5% of patients, 1% of whom had non-urgent thoracic procedures. A total of 406 patients underwent VATS for pulmonary decortication with/out partial resection, 39% were Early VATS (N = 159) compared to 61% late VATS (N = 247). Both groups had comparable demographics and comorbidities with exception of a higher ISS score in the late surgical group (17.9 ± 9.8 vs 14.9 ± 7.6, p < 0.01). The late VATS patients' group had higher rates of superficial site infection, unplanned intubation, and pneumonia. Early VATS was associated with shorter ICU stay and HLOS. Multivariate analysis confirmed the independent effect of surgical timing on postoperative complications and LOS. The conversion rate from VATS to thoracotomy was 1.9% in early group compared to 6.5%, p = 0.03. There was no difference in surgical pattern among participating facilities.

CONCLUSION

Despite established practice guidelines supporting early VATS for thoracic trauma management, there is underutilization with less than half of patients undergoing early VATS. Early VATS is associated with improved patient outcomes.

Scoping review of traumatic hemothorax: Evidence and knowledge gaps, from diagnosis to chest tube removal

BACKGROUND

Traumatic hemothorax is a common injury that invites diagnostic and management strategy debates. Evidence-based management has been associated with improved care efficiency. However, the literature abounds with long-debated, re-emerging, and new questions. We aimed to consolidate up-to-date evidence on traumatic hemothoraces, focusing on clinical conundra debated in literature.

METHODS

We conducted a scoping review of 21 clinical conundra in traumatic hemothorax diagnosis and management according to PRISMA-ScR guidelines. Experimental and observational studies evaluating patients (aged ≥18 years) with traumatic hemothoraces were identified through database searches (PubMed, EMBASE, Web of Science, Cochrane Library; database inception to Sep, 26 2020) and bibliography reviews of selected articles. Three reviewers screened and selected articles using standardized forms.

RESULTS

We screened 1,440 articles for eligibility, of which 71 met criteria for synthesis. The review comprises 6 sections: (1) Presumptive antibiotics before tube thoracostomy; (2) Initial diagnostic and intervention decisions; (3) Chest tubes; (4) Retained hemothoraces; (5) Delayed hemothoraces; and (6) Chest tube removal). The 21 conundra across these sections follow the format of a question, our recommendation based on interpretation of available evidence, and succinct rationale. Rationale sections detail knowledge gaps and opportunities for future research.

CONCLUSION

Even practices engrained into surgical dogma, such as obtaining chest x-rays after inserting or removing chest tubes and mandating operation for patients who develop chest tube output above a certain threshold, deserve re-evaluation. Some knowledge gaps require rigorous future investigation; sound clinical judgment can likely supplement others.

Factors Associated with Successful Video-Assisted Thoracoscopic Surgery and Thoracotomy in the Management of Traumatic Hemothorax

BACKGROUND

Few studies have identified factors associated with successful VATS or thoracotomy as the initial operative strategy among patients with traumatic hemothorax.

MATERIAL AND METHODS

We performed an exploratory analysis using the 2008 to 2017 TQP database. We identified all patients aged 18 to 89 years with traumatic hemothorax who were treated with tube thoracostomy alone in the first 24-hours of admission, followed by VATS or thoracotomy. Logistic regression was used to identify factors associated with successful VATS (no conversion or reoperation) or thoracotomy (no reoperation) as the initial operative strategy.

RESULTS

Among 2052 patients managed with initial VATS after chest tube drainage, 1710 (83%) were successful, while 263 (13%) were converted to thoracotomy and 79 (4%) required reoperation. On multivariable analysis, poor GCS (OR = 0.96 [95% CI = 0.94-0.99]), major injury (OR = 0.69 [95% CI = 0.53-0.90]), and diaphragmatic injury (OR = 0.42 [95% CI = 0.30-0.60]) were associated with lower odds of successful VATS, while rib fractures (OR=1.29 [95% CI=1.01-1.66]) were associated with higher odds of success of the initial operative plan. Among 3486 patients initially managed with thoracotomy after drainage with tube thoracostomy, 3118 (89.4%) were successful, while 11% (n = 368) required reoperation. Multivariable analysis revealed that major injury (OR = 0.68 [95% CI = 0.50-0.92]), blunt mechanism (OR = 0.63 [95% CI = 0.50-0.78]), and diaphragmatic injury (OR = 0.67, 95% CI = 0.53-0.84]) were associated with lower odds of successful thoracotomy as the initial operative plan.

CONCLUSIONS

More severe injuries and diaphragmatic injuries have lower odds of successful of VATS or thoracotomy as the initial operative management strategy among patients with traumatic hemothorax. Rib fractures may be associated with higher odds of success of VATS as the initial management strategy.

Outcomes in Delayed Drainage of Hemothorax

BACKGROUND

Prompt drainage of traumatic hemothorax is recommended to prevent empyema and trapped lung. Some patients do not present the day of their trauma, leading to their delayed treatment. Delayed drainage could be challenging as clotted blood may not evacuate through a standard chest tube. We hypothesized that such delays would increase the need for surgery or secondary interventions.

METHODS

Our trauma registry was reviewed for patients with a hemothorax admitted to our level 1 trauma center from 1/1/00 to 4/30/19. Patients were included in the delayed group if they received a drainage procedure >24 hours after injury. These patients were matched 1:1 by chest abbreviated injury score to patients who received drainage <24 hours from injury.

RESULTS

A total of 19 patients with 22 hemothoraces received delayed drainage. All but 3 patients had a chest tube placed as initial treatment. Four patients received surgery, including 3 who initially had chest tubes placed. Longer time to drainage increased the odds of requiring intrathoracic thrombolytics or surgery. In comparison, 2 patients who received prompt drainage received thrombolytics (P = .11) and none required surgery (P = .02). Patients needed surgery when initial drainage was on or after post-injury day 5, but pigtail catheter drainage was effective 26 days after injury.

DISCUSSION

Longer times from injury to intervention are associated with increased likelihood of needing surgery for hemothorax evacuation, but outcomes were not uniform. A larger, multicenter study will be necessary to provide better characterization of treatment outcomes for these patients.

Blunt trauma related chest wall and pulmonary injuries: An overview

Physical traumas are tragic and multifaceted injuries that suddenly threaten life. Although it is the third most common cause of death in all age groups, one out of four trauma patients die due to thoracic injury or its complications. Blunt injuries constitute the majority of chest trauma. This indicates the importance of chest trauma among all traumas. Blunt chest trauma is usually caused by motor vehicle accident, falling from height, blunt instrument injury and physical assault. As a result of chest trauma, many injuries may occur, such as pulmonary injuries, and these require urgent intervention. Chest wall and pulmonary injuries range from rib fractures to flail chest, pneumothorax to hemothorax and pulmonary contusion to tracheobronchial injuries. Following these injuries, patients may present with a simple dyspnea or even respiratory arrest. For such patient, it is important to understand the treatment logic and to take a multidisciplinary approach to treat the pulmonary and chest wall injuries. This is because only 10% of thoracic trauma patients require surgical operation and the remaining 90% can be treated with simple methods such as appropriate airway, oxygen support, maneuvers, volume support and tube thoracostomy. Adequate pain control in chest trauma is sometimes the most basic and best treatment. With definite diagnosis, the morbidity and mortality can be significantly reduced by simple treatment methods.

Facilitating ventilator weaning through rib fixation combined with video-assisted thoracoscopic surgery in severe blunt chest injury with acute respiratory failure

Background

Severe blunt chest injury sometimes induces acute respiratory failure (ARF), requiring ventilator use. We aimed to evaluate the effect of performing rib fixation with the addition of video-assisted thoracoscopic surgery (VATS) on patients with ARF caused by blunt thoracic injury with ventilator dependence.

Methods

This observational study prospectively enrolled patients with multiple bicortical rib fractures with hemothorax caused by severe blunt chest trauma. All patients received positive pressure mechanical ventilation within 24 h after trauma because of ARF. Some patients who received rib fixation with VATS were enrolled as group 1, and the others who received only VATS were designated as group 2. The length of ventilator use was the primary clinical outcome. Rates of pneumonia and length of hospital stay constituted secondary outcomes.

Results

A total of 61 patients were included in this study. The basic demographic characteristics between the two groups exhibited no statistical differences. All patients received operations within 6 days after trauma. The length of ventilator use was shorter in group 1 (3.19 ± 3.37 days vs. 8.05 ± 8.23, P = 0.002). The rate of pneumonia was higher in group 2 (38.1% vs. 75.0%, P = 0.005). The length of hospital stay was much shorter in group 1 (17.76 ± 8.38 days vs. 24.13 ± 9.80, P = 0.011).

Conclusion

Rib fixation combined with VATS could shorten the length of ventilator use and reduce the pneumonia rate in patients with severe chest blunt injury with ARF. Therefore, this operation could shorten the overall length of hospital stay.

Hemothorax: A Review of the Literature

Hemothorax is a collection of blood in the pleural cavity usually from traumatic injury. Chest X-ray has historically been the imaging modality of choice upon arrival to the hospital. The sensitivity and specificity of point-of-care ultrasound, specifically through the Extended Focal Assessment with Sonography in Trauma (eFAST) protocol has been significant enough to warrant inclusion in most Level 1 trauma centers as an adjunct to radiographs.^1,2 If the size or severity of a hemothorax warrants intervention, tube thoracostomy has been and still remains the treatment of choice. Most cases of hemothorax will resolve with tube thoracostomy. If residual blood remains within the pleural cavity after tube thoracostomy, it is then considered to be a retained hemothorax, with significant risks for developing late complications such as empyema and fibrothorax. Once late complications occur, morbidity and mortality increase dramatically and the only definitive treatment is surgery. In order to avoid surgery, research has been focused on removing a retained hemothorax before it progresses pathologically. The most promising therapy consists of fibrinolytics which are infused into the pleural space, disrupting the hemothorax, allowing for further drainage. While significant progress has been made, additional trials are needed to further define the dosing and pharmacokinetics of fibrinolytics in this setting. If medical therapy and early procedures fail to resolve the retained hemothorax, surgery is usually indicated. Surgery historically consisted solely of thoracotomy, but has been largely replaced in non-emergent situations by video-assisted thoracoscopy (VATS), a minimally invasive technique that shows considerable improvement in the patients' recovery and pain post-operatively. Should all prior attempts to resolve the hemothorax fail, then open thoracotomy may be indicated.

Timing to perform VATS for traumatic-retained hemothorax (a systematic review and meta-analysis)

PURPOSE

In this systematic review, we analyzed the optimal time range to evacuate traumatic-retained hemothorax using video-assisted thoracoscopic surgery (VATS).

METHODS

We searched PubMed, EMBASE, the Cochrane Register of Controlled Trials, Google Scholar, and the U.S. National Library of Medicine clinical trials database up to February 2019. Randomized controlled trials (RCTs) and observational studies with relevant data were included. Data were extracted from studies that reported the success, mortality, or length of hospital stay (LOS) after using VATS during at least two out of three of our time-ranges of interest: days 1-3 (group A), days 4-6 (group B), and day 7 or later (group C).

RESULTS

Six cohort studies with 476 total participants were included in the meta-analysis. The patients in group A had a significantly higher success rate than those in group C (RR = 0.42; 95% CI = 0.21-0.84, p = 0.01). The total LOS for patients whose retained hemothorax was evacuated in group A was 4.7 days shorter than that for those in group B (95% CI =  - 5.6 to  - 3.8, p = 0.006). Likewise, group B patients were discharged 18.1 days earlier than group C patients (95% CI =  - 22.3 to  - 14, p < 0.001). Short-term mortality was not decreased by early VATS.

CONCLUSIONS

Our results indicate that VATS should be considered within the first three days of admission if this intervention is the clinician's choice to evacuate a traumatic-retained hemothorax. Protocol registration number in PROSPERO: CRD42017046856.

A new instrument for surgical stabilization of multiple rib fractures

Objective

Rib fixation is an effective treatment for patients with multiple rib fractures. We retrospectively evaluated the application of a four-claw titanium plate in patients with rib fractures.

Methods

Fifty-four patients treated for multiple rib fractures in our hospital from 2012 to 2016 were divided into a surgery group (n = 27) and conservative treatment group (n = 27). The patients’ age, sex, cause of fracture, Injury Severity Score, chest Abbreviated Injury Scale score, number of ventilator days, and length of hospitalization were recorded.

Results

The mean duration of mechanical ventilation was 4.5 ± 0.7 and 7.9 ± 1.7 days in the surgery and control group, respectively, with a significant difference. The length of intensive care unit stay was also significantly different between the groups (5.9 ± 0.6 vs. 10.6 ± 1.9 days, respectively). The length of hospital stay and recovery time to regular life in the surgery and control group were 11.5 ± 1.9 and 3.9 ± 4.0 days and 38.2 ± 8.3 and 60.8 ± 12.1 days, respectively, both with significant differences.

Conclusion

A four-claw titanium plate is valuable for patients with multiple rib fractures, allowing easy fixation of broken ribs beneath the scapula, even the second rib.

Video-assisted thoracoscopic surgery in trauma: pros and cons

Thoracic injuries account for 60% of all trauma presentations. These patients often have extra-thoracic injuries adding to the complexity of their management. Morbidity and the associated mortality are significantly increased in the elderly. The majority of cases will comprise of simple rib fractures, requiring adequate analgesia. In those that require surgical intervention, the use of video-assisted thoracoscopic surgery (VATS) is becoming increasingly more popular. VATS can often provide greater visualisation of the intra-thoracic structures, whilst limiting the burden of injury to smaller non-rib spreading incisions. It is therefore becoming increasingly used as a diagnostic tool to identify the extend of the injuries whilst also allowing for therapeutic intervention. These benefits translate into decreased rate of post-operative complications and a shorter length of inpatient stay. We also discuss the relative contra-indications and cautions to the use of VATS in the setting of trauma.

The advantages of adding rib fixations during VATS for retained hemothorax in serious blunt chest trauma - A prospective cohort study

BACKGROUND

Serious blunt chest trauma usually induces hemothorax, pneumothorax, and rib fracture. Early video-assisted thoracoscopic surgery (VATS) to evacuate retained hemothorax is one commonly used treatment. In this study, a new strategy was implemented to combine VATS with fractured rib fixation simultaneously.

METHODS

This prospective observational study was performed from January 2013 to April 2018. All patients were aged 18 years or older and had blunt chest trauma with displaced fractures in more than three ribs. No patients had acute respiratory failure within 24 h after trauma. Patients with retained hemothorax who received VATS constituted the study cohort. Subsequently, patients who received rib fixation during VATS procedures were compared with those who did not. Clinical outcomes such as dose of analgesics, and length of hospital stay were recorded.

RESULTS

During the study period, 128 patients were enrolled. Available demographic characteristics of the 2 groups were compared, and no statistical differences were observed. The rates of shorter temporary ventilator dependence after operations were lower in the rib fixation group (0% vs. 24.7%, P = 0.017). Persistent air leakage more than 5 days after operations were also lower in the rib fixation group (0% vs. 10.4%, P = 0.001). The length of stay in overall hospital stay were longer for patients who received VATS without rib fixation (9.29 ± 2.51 days vs. 12.39 ± 4.65, P = 0.001). Furthermore, the rib fixation group were administered much lower doses of opiates during their hospital stays (52.45 ± 15.67 mg vs. 77.24 ± 50.42 mg, P = 0.001).

CONCLUSION

Adding rib fixation during VATS in the management of retained hemothorax can contribute to shorten whole treatment courses. Rib fixation can also reduce pain, thus reducing dependence on analgesics.

Early Management of Retained Hemothorax in Blunt Head and Chest Trauma

Background

Major blunt chest injury usually leads to the development of retained hemothorax and pneumothorax, and needs further intervention. However, since blunt chest injury may be combined with blunt head injury that typically requires patient observation for 3–4 days, other critical surgical interventions may be delayed. The purpose of this study is to analyze the outcomes of head injury patients who received early, versus delayed thoracic surgeries.

Materials and methods

From May 2005 to February 2012, 61 patients with major blunt injuries to the chest and head were prospectively enrolled. These patients had an intracranial hemorrhage without indications of craniotomy. All the patients received video-assisted thoracoscopic surgery (VATS) due to retained hemothorax or pneumothorax. Patients were divided into two groups according to the time from trauma to operation, this being within 4 days for Group 1 and more than 4 days for Group 2. The clinical outcomes included hospital length of stay (LOS), intensive care unit (ICU) LOS, infection rates, and the time period of ventilator use and chest tube intubation.

Result

All demographics, including age, gender, and trauma severity between the two groups showed no statistical differences. The average time from trauma to operation was 5.8 days. The ventilator usage period, the hospital and ICU length of stay were longer in Group 2 (6.77 vs. 18.55, p = 0.016; 20.63 vs. 35.13, p = 0.003; 8.97 vs. 17.65, p = 0.035). The rates of positive microbial cultures in pleural effusion collected during VATS were higher in Group 2 (6.7 vs. 29.0%, p = 0.043). The Glasgow Coma Scale score for all patients improved when patients were discharged (11.74 vs. 14.10, p < 0.05).

Discussion

In this study, early VATS could be performed safely in brain hemorrhage patients without indication of surgical decompression. The clinical outcomes were much better in patients receiving early intervention within 4 days after trauma.

Tube Thoracostomy Management in the Combat Wounded

The intent of this study was to characterize the management and subsequent complications of combat injury tube thoracostomies and to determine risk factors for the development of pneumonia (PNA) and retained hemothorax (RH). One hundred fifteen patients with 173 tube thoracostomies met the inclusion criteria and were analyzed. The mean injury severity score was 30.8 1 11.6, 23.5 per cent had traumatic amputations, 49.7 per cent had a hemothorax, and 50.3 per cent had a pneumothorax as indications for tube thoracostomy (TT) placement. Within 24 hours of injury, 89.6 per cent were intubated, the majority (54%) were injured by improvised explosive devices, 35.6 per cent sustained rib fractures, and 12.2 per cent had a diaphragm injury. A mean of 1.5 1 0.7(range 1–4) tube thoracostomies were placed, 18.3 per cent of patients had bilateral tube thoracostomies, and the average TT duration was 6.7 1 3.9 days. The incidence of PNA was 27 per cent (n = 31), RH was 9.6 per cent (n = 11), and empyema was 1.7 per cent (n = 2). Multivariable analysis identified the duration of ventilation [OR 1.2, 95% confidence interval (CI): 1.097–1.313, P < 0.001] as independently associated with the development of PNA. Bilateral TT placement (OR 3.848, 95% CI: 1.219–12.143, P = 0.0216) and injury severity score (OR 1.050, 95% CI: 1.001–1.102, P = 0.0443) were independently associated with PNA development when a patient was intubated for eight days or less. The number of tube thoracostomies placed (OR 3.08, 95% CI: 1.03–9.18, P = 0.0439) was independently associated with the development of RH. Further research is warranted to identify modifiable risk factors to reduce the incidence of PNA and RH in patients with TT placed for traumatic injuries.

Management of post-traumatic retained hemothorax

Introduction

Chest injuries occur in a significant portion of trauma patients and hemothorax is a common result. While the initial management of traumatic hemothorax is most commonly treated with tube thoracostomy, the management of retained hemothorax is a subject of debate. Recent literature has proposed different methods for treating or preventing retained hemothorax, yet the approach to this pathology is not straightforward.

Methods

The literature was reviewed for relevant studies regarding the prevention and management of post-traumatic retained hemothorax. What follows is a review of the recent literature and an algorithm for the approach to treating a traumatic retained hemothorax.

Results

Identifying a traumatic retained hemothorax and preventing subsequent complications such as pneumonia, empyema, and fibrothorax are significant issues faced by surgeons. Studies for preventing retained hemothorax have focused on initial chest tube size, location, and peri-procedural placement conditions, as well as thoracic lavage. Several treatment modalities exist, including second drainage procedure and intra-pleural fibrinolytic drug instillation, but video-assisted thoracoscopic surgery is the most common and successful approach. Regardless of the approach to evacuation, early intervention is paramount.

Conclusion

Further studies will help characterize appropriate candidates, timing, treatment modalities, and guide therapy for retained hemothorax.

[Chest trauma from a surgical perspective]

Patients with multiple injuries in particular frequently also suffer from chest trauma. During the initial phase the identification and treatment of life-threatening injuries is essential and tension pneumothorax is of particular importance during this phase. The Advanced Trauma Life Support (ATLS) algorithm should be followed for structured treatment. In most cases treatment by insertion of a chest tube is sufficient but for some injuries an emergency thoracotomy is unavoidable as a life-saving intervention. In the further treatment especially a flail chest and retained hemothorax are responsible for complications, such as acute lung failure and thoracic empyema. Early operative interventions in the sense of rib fracture stabilization and thoracoscopy-assisted evacuation of hematomas can help to prevent such complications.

Efficiency Analysis of Direct Video-Assisted Thoracoscopic Surgery in Elderly Patients with Blunt Traumatic Hemothorax without an Initial Thoracostomy

Hemothorax is common in elderly patients following blunt chest trauma. Traditionally, tube thoracostomy is the first choice for managing this complication. The goal of this study was to determine the benefits of this approach in elderly patients with and without an initial tube thoracostomy. Seventy-eight patients aged >65 years with blunt chest trauma and stable vital signs were included. All of them had more than 300 mL of hemothorax, indicating that a tube thoracostomy was necessary. The basic demographic data and clinical outcomes of patients with hemothorax who underwent direct video-assisted thoracoscopic surgery without a tube thoracostomy were compared with those who received an initial tube thoracostomy. Patients who did not receive a thoracostomy had lower posttrauma infection rates (28.6% versus 56.3%, P = 0.061) and a significantly shorter length of stay in the intensive care unit (3.13 versus 8.27, P = 0.029) and in the hospital (15.93 versus 23.17, P = 0.01) compared with those who received a thoracostomy. The clinical outcomes in the patients who received direct VATS were more favorable compared with those of the patients who did not receive direct VATS.

Video-assisted thoracoscopic surgery for retained hemothorax in blunt chest trauma

Purpose of review

In the last decade, video-assisted thoracoscopic surgery (VATS) has become a popular method in diagnosis and treatment of acute chest injuries. Except for patients with unstable vital signs who require larger surgical incisions to check bleeding, this endoscopic surgery could be employed in the majority of thoracic injury patients with stable vital signs.

Recent findings

In the past, VATS was used to evacuate traumatic-retained hemothorax. Recent study has revealed further that lung repair during VATS could decrease complications after trauma. Management of fractured ribs could also be assisted by VATS. Early VATS intervention within 7 days after injury can decrease the rate of posttraumatic infection and length of hospital stay. In studies of the pathophysiology of animal models, N-acetylcysteine and methylene blue were used in animals with blunt chest trauma and found to improve clinical outcomes.

Summary

Retained hemothorax derived from blunt chest trauma should be managed carefully and rapidly. Early VATS intervention is a well tolerated and reliable procedure that can be applied to manage this complication cost effectively.

Surgical stabilization of severe rib fractures decreases incidence of retained hemothorax and empyema

BACKGROUND

Retained hemothorax (RH) is relatively common after chest trauma and can lead to empyema. We hypothesized that patients who have surgical fixation of rib fractures (SSRF) have less RH and empyema than those who have medical management of rib fractures (MMRF).

METHODS

Admitted rib fracture patients from January 2009 to June 2013 were identified. A 2:1 propensity score model identified MMRF patients who were similar to SSRF. RH, and empyema and readmissions, were recorded. Variables were compared using Fisher exact test and Wilcoxon rank-sum tests.

RESULTS

One hundred thirty-seven SSRF and 274 MMRF were analyzed; 31 (7.5%) had RH requiring 35 interventions; 3 (2.2%) SSRF patients had RH compared with 28 (10.2%) MMRF (P = .003). Four (14.3%) MMRF subjects with RH developed empyema versus zero in the SSRF group (P = .008); 6 (19.3%) RH patients required readmission versus 14 (3.7%) in the non-RH group (P = .002).

CONCLUSIONS

Patients with rib fractures who have SSRF have less RH compared with similar MMRF patients. Although not a singular reason to perform SSRF, this clinical benefit should not be overlooked.

A case of delayed hemothorax with an inferior phrenic artery injury detected and treated endovascularly

We report the rare case of delayed hemothorax (DHX) with an inferior phrenic artery (IPA) injury due to blunt thoracic trauma. Our case suggests that DHX almost always occurs early after injury, and endovascular treatment is an effective procedure for traumatic hemothorax including DHX.

The surgical stabilization of multiple rib fractures using titanium elastic nail in blunt chest trauma with acute respiratory failure

BACKGROUND

Blunt chest injuries are usually combined with multiple rib fractures and severe lung contusions. This can occasionally induce acute respiratory failure and prolong ventilations. In order to reduce the periods of ventilator dependency, we propose a less invasive method of fixing multiple rib fractures.

METHODS

Since October 2009, we have developed a new method to fix fractured ribs caused by blunt trauma. Rib fixations were performed using 2.0- or 2.5-mm intramedullary titanium elastic nails (TEN), with the help of video-assisted thoracoscopic surgery (VATS) and minimal thoracic incisions. All the patients' demographics and postoperative data were collected.

RESULTS

From January 2010 to December 2012, a total of 65 patients presenting with multiple rib fractures resulting in acute respiratory failure were included in the study. Twelve patients received the new surgical fixation. Rib fixations were performed at an average of 4 days after trauma. Patients were successfully weaned off ventilators after an average of 3 days. The average length of stay in the hospital and the intensive care unit (ICU) was shorter for the patients with fixation than for nonsurgical patients. All twelve patients returned to normal daily activities and work.

CONCLUSIONS

In the reconstruction of an injured chest wall, the VATS with TENs fixation in multiple rib fractures is feasible. This method is also effective in decreasing the length of the surgical wound. Because the structure of the chest cage is protected, the period of mechanical ventilation is shortened and the length of stay in the hospital and the ICU can be reduced.