Management of post traumatic respiratory failure

Initial Experiences of Extracorporeal Membrane Oxygenation for Trauma Patients at a Single Regional Trauma Center in South Korea

Purpose For severe lung injuries or acute respiratory distress syndrome that occurs during critical care due to trauma, extracorporeal membrane oxygenation (ECMO) may be used as a salvage treatment. This study aimed to describe the experiences at a single center with the use of ECMO in trauma patients. Methods We enrolled a total of 25 trauma patients who were treated with ECMO between January 2015 and December 2019 at a regional trauma center. We analyzed and compared patients’ characteristics between survivors and non-survivors through a medical chart review. We also compared the characteristics of patients between direct and indirect lung injury groups. Results The mean age of the 25 patients was 45.9±19.5 years, and 19 patients (76.0%) were male. The mean Injury Severity Score was 26.1±10.1. Ten patients (40.0%) had an Abbreviated Injury Scale (AIS) 3 score of 4, and six patients (24.0%) had an AIS 3 score of 5. There were 19 cases (76.6%) of direct lung injury. The mortality rate was 60.0% (n=15). Sixteen patients (64.0%) received a loading dose of heparin for the initiation of ECMO. There was no significant difference in heparin use between the survivors and non-survivors (70% in survivors vs. 60% in non-survivors, p=0.691). When comparing the direct and indirect lung injury groups, there were no significant differences in variables other than age and ECMO onset time. Conclusions If more evidence is gathered, risk factors and indications will be identified and we expect that more trauma patients will receive appropriate treatment with ECMO.

48 h cessation of mechanical ventilation during venovenous extracorporeal membrane oxygenation in severe trauma: a case report

A 32-year-old motorcyclist who was hit by a tram subsequently presented with blunt force thoracic trauma, a pelvic fracture and a penetrating injury to the left lower extremity. Coagulopathy persisted following surgery of the leg and pelvic vascular intervention. Bedside thoracotomy was performed to treat pneumothorax and pneumopericardium. Severe hypoxemia secondary to lung failure ensued, which required venovenous extracorporeal membrane oxygenation (VV ECMO) support. On the third day after the trauma, ultra-protective mechanical ventilation was not possible due to non-existent lung compliance; thus, the ventilator was disconnected, and the T-piece was connected to the blocked tracheal tube left in the airway. Gas exchange occurred via VV ECMO separately. After 48 h of cessation of ventilator support, the patient was weaned from sedation. At this time, respiratory effort was observed, and assisted ventilation was initiated. The patient ultimately recovered and experienced an excellent outcome. The clinical significance of zero end-expiratory pressure (ZEEP) and the complete cessation of open lung strategy during ECMO remains controversial. In cases of reduced lung compliance, if VV ECMO can facilitate adequate gas exchange, the discontinuation of ventilation is an option that can be used to prevent ventilator-induced lung damage and to allow the lungs to rest. VV ECMO is feasible as lung support with no mechanical ventilation in case of severe lung failure after major trauma.

Respiratory management in the patient with spinal cord injury

Spinal cord injuries (SCIs) often lead to impairment of the respiratory system and, consequently, restrictive respiratory changes. Paresis or paralysis of the respiratory muscles can lead to respiratory insufficiency, which is dependent on the level and completeness of the injury. Respiratory complications include hypoventilation, a reduction in surfactant production, mucus plugging, atelectasis, and pneumonia. Vital capacity (VC) is an indicator of overall pulmonary function; patients with severely impaired VC may require assisted ventilation. It is best to proceed with intubation under controlled circumstances rather than waiting until the condition becomes an emergency. Mechanical ventilation can adversely affect the structure and function of the diaphragm. Early tracheostomy following short orotracheal intubation is probably beneficial in selected patients. Weaning should start as soon as possible, and the best modality is progressive ventilator-free breathing (PVFB). Appropriate candidates can sometimes be freed from mechanical ventilation by electrical stimulation. Respiratory muscle training regimens may improve patients' inspiratory function following a SCI.

Extracorporeal lung support in trauma patients with severe chest injury and acute lung failure: a 10-year institutional experience

Introduction

Severe trauma with concomitant chest injury is frequently associated with acute lung failure (ALF). This report summarizes our experience with extracorporeal lung support (ELS) in thoracic trauma patients treated at the University Medical Center Regensburg.

Methods

A retrospective, observational analysis of prospectively collected data (Regensburg ECMO Registry database) was performed for all consecutive trauma patients with acute pulmonary failure requiring ELS during a 10-year interval.

Results

Between April 2002 and April 2012, 52 patients (49 male, three female) with severe thoracic trauma and ALF refractory to conventional therapy required ELS. The mean age was 32 ± 14 years (range, 16 to 72 years). Major traffic accident (73%) was the most common trauma, followed by blast injury (17%), deep fall (8%) and blunt trauma (2%). The mean Injury Severity Score was 58.9 ± 10.5, the mean lung injury score was 3.3 ± 0.6 and the Sequential Organ Failure Assessment score was 10.5 ± 3. Twenty-six patients required pumpless extracorporeal lung assist (PECLA) and 26 patients required veno-venous extracorporeal membrane oxygenation (vv-ECMO) for primary post-traumatic respiratory failure. The mean time to ELS support was 5.2 ± 7.7 days (range, <24 hours to 38 days) and the mean ELS duration was 6.9 ± 3.6 days (range, <24 hours to 19 days). In 24 cases (48%) ELS implantation was performed in an external facility, and cannulation was done percutaneously by Seldinger's technique in 98% of patients. Cannula-related complications occurred in 15% of patients (PECLA, 19% (n = 5); vv-ECMO, 12% (n = 3)). Surgery was performed in 44 patients, with 16 patients under ELS prevention. Eight patients (15%) died during ELS support and three patients (6%) died after ELS weaning. The overall survival rate was 79% compared with the proposed Injury Severity Score-related mortality (59%).

Conclusion

Pumpless and pump-driven ELS systems are an excellent treatment option in severe thoracic trauma patients with ALF and facilitate survival in an experienced trauma center with an interdisciplinary treatment approach. We encourage the use of vv-ECMO due to reduced complication rates, better oxygenation and best short-term outcome.

Feasibility of a sedation wake-up trial and spontaneous breathing trial in critically ill trauma patients: a secondary analysis

OBJECTIVES

To determine the feasibility of conducting a sedation wake-up trial (SWT) plus a spontaneous breathing trial (SBT) in critically ill trauma patients based on the ability to implement the combined intervention; to measure and describe patients' physiological responses; and to maintain patient safety.

METHODS

A secondary analysis of the intervention group from a trial of 20 mechanically ventilated patients receiving SWT plus SBT in a trauma-intensive care unit.

RESULTS

Patients passed 67% of the 39 SWTs performed; those who failed presented RASS scores of +1 and +2 (70%), tachycardia (15%) or ventilator asynchrony (15%). Eighteen patients tolerated their first SBT, and after the second SBT, more than half of the patients were discontinued from the mechanical ventilator. A significant increase from the beginning to the end of the SWT was found in heart rate (p=.021), respiratory rate (p=.043) and systolic blood pressure (p=.04). Although these measures increased significantly, their overall mean did not increase by 20%.

CONCLUSION

SWT plus SBT was well tolerated and successfully implemented. Our data showed that it is not necessary to withhold continuous-infusion analgesia during the SWT.

The evolution of damage control surgery

The philosophy of damage control surgery has developed tremendously over the past 10 years. It has expanded outside the original boundaries of the abdomen and has been applied to all aspects of trauma care, ranging from resuscitation to limb-threatening vascular injuries. In recent years, the US military has taken the concept to a new level by initiating a damage control approach at the point of injury and continuing it through a transcontinental health care system. This article highlights many recent advances in damage control surgery and discusses proper patient selection and the risks associated with this management strategy.

A randomized prospective trial of airway pressure release ventilation and low tidal volume ventilation in adult trauma patients with acute respiratory failure

BACKGROUND

Airway pressure release ventilation (APRV) is a mode of mechanical ventilation, which has demonstrated potential benefits in trauma patients. We therefore sought to compare relevant pulmonary data and safety outcomes of this modality to the recommendations of the Adult Respiratory Distress Syndrome Network.

METHODS

Patients admitted after traumatic injury requiring mechanical ventilation were randomized under a 72-hour waiver of consent to a respiratory protocol for APRV or low tidal volume ventilation (LOVT). Data were collected regarding demographics, Injury Severity Score, oxygenation, ventilation, airway pressure, failure of modality, tracheostomy, ventilator-associated pneumonia, ventilator days, length of stay (LOS), pneumothorax, and mortality.

RESULTS

Sixty-three patients were enrolled during a 21-month period ending in February 2006. Thirty-one patients were assigned to APRV and 32 to LOVT. Patients were well matched for demographic variables with no differences between groups. Mean Acute Physiology and Chronic Health Evaluation II score was higher for APRV than LOVT (20.5 ± 5.35 vs. 16.9 ± 7.17) with a p value = 0.027. Outcome variables showed no differences between APRV and LOVT for ventilator days (10.49 days ± 7.23 days vs. 8.00 days ± 4.01 days), ICU LOS (16.47 days ± 12.83 days vs. 14.18 days ± 13.26 days), pneumothorax (0% vs. 3.1%), ventilator-associated pneumonia per patient (1.00 ± 0.86 vs. 0.56 ± 0.67), percent receiving tracheostomy (61.3% vs. 65.6%), percent failure of modality (12.9% vs. 15.6%), or percent mortality (6.45% vs. 6.25%).

CONCLUSIONS

For patients sustaining significant trauma requiring mechanical ventilation for greater than 72 hours, APRV seems to have a similar safety profile as the LOVT. Trends for APRV patients to have increased ventilator days, ICU LOS, and ventilator-associated pneumonia may be explained by initial worse physiologic derangement demonstrated by higher Acute Physiology and Chronic Health Evaluation II scores.

Low incidence of multiple organ failure after major trauma

BACKGROUND

In major trauma patients, multiple organ failure (MOF) is considered a leading cause of death. Acute lung injury is deemed a "pacemaker" of MOF. The purpose of this study was to determine if incidence of organ failure and mortality in multiple trauma patients can be reduced by implementation of lung-protective strategies.

METHODS

All critically ill multiple trauma patients admitted to the ICU of a major trauma center in Berlin, Germany from January 1999 to December 2002 were analyzed retrospectively. Patients were ventilated pressure controlled with low tidal volumes and adequate PEEP.

RESULTS

n=287 patients were included. The most frequent injuries were traumatic brain injury (TBI-68%), chest trauma (68%), and lung contusions (55%). Injury severity score (ISS) was 32+/-19 (mean+/-standard deviation), polytraumaschluessel (PTS) 34+/-19, and APACHE II 14+/-7. During their ICU-stay 16 patients died, 9 (56%) from TBI. Single-organ-failure occurred in n=69 patients (24%, mortality 5%), two-organ-failure in n=22 (8%, mortality 14%), and MOF in n=9 (3%, mortality 13%); one patient died from MOF 14 days after trauma. The number of days on mechanical ventilation increased depending on the number of organs failed (R=0.618, p<0.001). Seven patients (2%) fulfilled ARDS criteria for longer than 24h despite optimized ventilatory settings, one died of irreversible shock. Patients with MOF had a significantly increased ICU-LOS (35+/-15 days) compared to patients without organ failure (11+/-11 days; p<0.001).

CONCLUSION

The low incidence of MOF in our series of trauma patients suggests that MOF may be prevented in some patients by implementation of lung-protective strategies. The improved outcome was associated with an increased ICU-LOS.

A single ventilator for multiple simulated patients to meet disaster surge

Objectives

To determine if a ventilator available in an emergency department could quickly be modified to provide ventilation for four adults simultaneously.

Methods

Using lung simulators, readily available plastic tubing, and ventilators (840 Series Ventilator; Puritan‐Bennett), human lung simulators were added in parallel until the ventilator was ventilating the equivalent of four adults. Data collected included peak pressure, positive end‐expiratory pressure, total tidal volume, and total minute ventilation. Any obvious asymmetry in the delivery of gas to the lung simulators was also documented. The ventilator was run for almost 12 consecutive hours (5.5 hours of pressure control and more than six hours of volume control).

Results

Using readily available plastic tubing set up to minimize dead space volume, the four lung simulators were easily ventilated for 12 hours using one ventilator. In pressure control (set at 25 mm H₂O), the mean tidal volume was 1,884 mL (approximately 471 mL/lung simulator) with an average minute ventilation of 30.2 L/min (or 7.5 L/min/lung simulator). In volume control (set at 2 L), the mean peak pressure was 28 cm H₂O and the minute ventilation was 32.5 L/min total (8.1 L/min/lung simulator).

Conclusions

A single ventilator may be quickly modified to ventilate four simulated adults for a limited time. The volumes delivered in this simulation should be able to sustain four 70‐kg individuals. While further study is necessary, this pilot study suggests significant potential for the expanded use of a single ventilator during cases of disaster surge involving multiple casualties with respiratory failure.

ICF Core Set for patients with musculoskeletal conditions in early post-acute rehabilitation facilities

PURPOSE

The aim of this consensus process was to decide on a first version of the ICF Core Set for patients with musculoskeletal conditions in early post-acute rehabilitation facilities.

METHODS

The ICF Core Set development involved a formal decision-making and consensus process integrating evidence gathered from preliminary studies including focus groups of health professionals, a systematic review of the literature and empiric data collection from patients.

RESULTS

Fifteen experts selected a total of 70 second-level categories. The largest number of categories was selected from the ICF component Body Functions (23 categories or 33%). Seven (10%) of the categories were selected from the component Body Structures, 22 (31%) from the component Activities and Participation, and 18 (26%) from the component Environmental Factors.

CONCLUSION

The Post-acute ICF Core Set for patients with musculoskeletal conditions is a clinical framework to comprehensively assess patients in early post-acute rehabilitation facilities, particularly in an interdisciplinary setting. This first ICF Core Set will be further tested through empiric studies in German-speaking countries and internationally.