Predicting the need for tracheostomy in patients with cervical spinal cord injury (original) (raw)
Related papers
Time to tracheostomy impacts overall outcomes in patients with cervical spinal cord injury
Journal of Trauma and Acute Care Surgery, 2020
BACKGROUND: The morbidity associated with cervical spine injury increases in the setting of concomitant cervical spinal cord injury (CSCI). A significant proportion of these patients require placement of a tracheostomy. However, it remains unclear if timing to tracheostomy following traumatic CSCI can impact outcomes. The aim of our study was to characterize outcomes associated with tracheostomy timing following traumatic CSCI. METHODS: We performed a 5-year (2010-2014) analysis of the American College of Surgeons Trauma Quality Improvement Program database and included all adult (age, ≥18 years) trauma patients who had traumatic CSCI and received tracheostomy. Patients were subdivided into two groups: early tracheostomy (ET) (≤4 days from initial intubation) and late tracheostomy (LT) (>4 days). Outcome measures included respiratory complications, ventilator-free days, intensive care unit-free days and hospital length of stay, and mortality. Multivariate logistic regression analysis was performed. RESULTS: A total of 5,980 patients were included in the study, of which 1,010 (17%) patients received ET, while 4,970 (83%) patients received LT. Mean age was 46 years, and 73% were men. In terms of CSCI location, 48% of the patients had high CSCI (C1-C4), while 52% had low CSCI (C5-C7). Patients in the ET group had lower rates of respiratory complications (30% vs. 46%, p = 0.01), higher ventilator-free days (13 days vs. 9 days; p = 0.02), intensive care unit-free days (11 days vs. 8 days; p = 0.01), and a shorter hospital length of stay (22 days vs. 29 days; p = 0.01) compared with those in the LT group. On regression analysis, ET was associated with lower rates of respiratory complications in patients with high CSCI (odds ratio, 0.55 [0.41-0.81]) and low CSCI (odds ratio, 0.93 [0.72-0.95]). However, no association was found between time to tracheostomy and in-hospital mortality. CONCLUSION: Early tracheostomy regardless of CSCI level may lead to improved outcomes. Quality improvement efforts should focus on defining the optimal time to tracheostomy and considering ET as a component of SCI management bundle.
2005
Background: Patients who sustain cervical spinal cord injury (C-SCI) with neurologic deficit may require a definitive airway and/or prolonged mechanical ventilation. The purpose of this study was to characterize factors associated with a high risk for respiratory failure and/or the need for mechanical ventilation in C-SCI patients. Methods: Patients with C-SCI and neurologic deficit admitted to a Level I Trauma Center between July 1, 2000 and June 30, 2002 were retrospectively reviewed for demographics, level and completeness of neurologic deficit, need for definitive airway, need for tracheostomy, need for mechanical ventilation at hospital discharge (MVDC), and outcomes. The level and completeness of injury were defined by American Spinal Injury Association standards. Results: One hundred nineteen patients with C-SCI and neurologic deficit were identified over this period. Of these, 45 were identified as complete C-SCI: 12 (27%) patients had levels of C1 to C4; 19 (42%) had a level of C5; and 14 (31%) had levels of C6 and below. There were 37 males and 8 females. There were 36 blunt and 9 penetrating injuries. The average age of these patients was 40؉/-21, and the average ISS was 45؉/-22. Eight of the patients with complete C-SCI died, for a mortality of 18%. Of the 37 survivors, 92% received a definitive airway, 81% received tracheostomy, and 51% required MVDC. All patients with complete injuries at the C5 level and above required a definitive airway and tracheostomy, and 71% of survivors required MVDC. Of the patients with complete injuries of C6 and below, 79% received a definitive airway, 50% required tracheostomy, and 15% of survivors required MVDC. Only 35% of incomplete injuries required a definitive airway, and only 7% required tracheostomy. Conclusions: The need for definitive airway control, tracheostomy, and ventilator dependence is significant, especially for patients with high complete C-SCI. Based on these results we recommend consideration of early intubation and tracheostomy for patients with complete C-SCI, especially for those with levels of C5 and above.
Spinal Cord, 2011
Study design: Systematic review. Objectives: Identify, evaluate, and synthesize evidence regarding the effectiveness of various treatment strategies for the respiratory management of acute tetraplegia. Setting: Melbourne, Australia. Methods: A search of multiple electronic databases (Medline, Cinahl, EMBASE, Cochrane Library, Web of Science, http://www.guideline.gov and http://www.icord.org/scire) was undertaken accompanied by the reference lists of all relevant articles identified. Methodological quality was assessed using the Newcastle-Ottawa Scale and the PEDro Scale. Descriptive analysis was performed. Results: Twenty-one studies including 1263 patients were identified. The majority of the studies were case series (n ¼ 13). A variety of interventions were used for the management of respiratory complications. Mortality (ARR ¼ 0.4, 95% confidence interval (CI) 0.18, 0.61), the incidence of respiratory complications (ARR ¼ 0.36, 95% CI (0.08, 0.58)), and requirement for a tracheostomy (ARR ¼ 0.18, 95% CI (À0.05, 0.4)) were significantly reduced by using a respiratory protocol. A clinical pathway reduced duration of mechanical ventilation by 6 days 95% CI (À0.56, 12.56), intensive care unit length of stay by 6.8 days 95% CI (0.17-13.77) and costs. Intubation, mechanical ventilation, and tracheostomy are the mainstay of respiratory management for complete injuries above the level of C5. Conclusion: This review showed a clinical pathway with a structured respiratory protocol that includes a combination of treatment techniques provided regularly is effective in reducing respiratory complications and cost. The overall study quality was moderate and further studies using specific interventions that target respiratory complications are associated with specific regions of the cervical spine using more methodologically rigorous designs are required.
Spinal Cord, 2010
Methods: Causes of death were ascertained from the Office of National Statistics. Kaplan-Meier analysis of survival was calculated according to ventilator-wean status at discharge. Risk factors were obtained by Cox regression analysis. Results: Over 50% of deaths in weaned and ventilated patients were respiratory in origin. The mean survival of weaned patients in the age group 31-45 was 19.3 compared with 10.5 years for ventilated patients (P ¼ 0.047). Those under 30 survived a further 22.1 and 18.4 years (P ¼ 0.31), while those over 45 lived for 11.0 and 8.3 years (P ¼ 0.50), values for weaned and ventilated patients, respectively. The survival advantage for weaned patients in the middle age group was less evident when the 1-year survivors were compared. The mean survival time of younger patients with diaphragm pacing was 1.8 years longer than those on mechanical ventilation (P ¼ 0.142). The variables with significant hazard ratios were any comorbidity (3.07); mechanical ventilation on discharge (2.26); and older age at injury, (3.1). Conclusions: The survival time for patients with high tetraplegia on long-term ventilation compares with other datasets and older patients have a proportionately greater loss in life expectancy. Selfventilating patients with tetraplegia remain at considerable risk from respiratory death and consideration needs to be given to more effective preventative measures.
Specialized Respiratory Management for Acute Cervical Spinal Cord Injury: A Retrospective Analysis
Topics in Spinal Cord Injury Rehabilitation, 2012
Background: In individuals with cervical spinal cord injury (SCI), respiratory complications arise within hours to days of injury. Paralysis of the respiratory muscles predisposes the patient toward respiratory failure. Respiratory complications after cervical SCI include hypoventilation, hypercapnea, reduction in surfactant production, mucus plugging, atelectasis, and pneumonia. Ultimately, the patient must use increased work to breathe, which results in respiratory fatigue and may eventually require intubation for mechanical ventilation. Without specialized respiratory management for individuals with tetraplegia, recurrent pneumonias, bronchoscopies, and difficulty in maintaining a stable respiratory status will persist. Objective: This retrospective analysis examined the effectiveness of specialized respiratory management utilized in a regional SCI center. Methods: Individuals with C1-C4 SCI (N = 24) were the focus of this study as these neurological levels present with the most complicated respiratory status. Results: All of the study patients' respiratory status improved with the specialized respiratory management administered in the SCI specialty unit. For a majority of these patients, respiratory improvements were noted within 1 week of admission to our SCI unit. Conclusion: Utilization of high tidal volume ventilation, high frequency percussive ventilation, and mechanical insufflationexsufflation have demonstrated efficacy in stabilizing the respiratory status of these individuals. Optimizing respiratory status enables the patients to participate in rehabilitation therapies, allows for the opportunity to vocalize, and results in fewer days on mechanical ventilation for patients who are weanable.
World Neurosurgery, 2018
Introduction: To determine the optimal moment to carry out a tracheostomy in a patient requiring anterior cervical fixation. Methods: A retrospective observational study was carried out over an 18-year period on 56 patients who had been admitted to the ICU with acute spinal cord injury (SCI), and who underwent a tracheostomy and surgical fixation. The sample was divided into two groups: An at-risk group (31 patients, who had undergone a tracheostomy prior to the cervical surgery or <4 days after the procedure), and a not at-risk group (25 patients, who had undergone a tracheostomy >4 day following the fixation surgery). Both a descriptive and a comparative study were carried out. The overall trend of the collected data was analysed using cubic splines (graphic methods). Results: The only infectious complications diagnosed as related to the surgical procedure were infection of the surgical wound in two patients of the not at-risk group (12%) and deep-tissue infection in one patient of the at-risk group (3.2%). During the study period, we identified a tendency towards the conduct of early tracheostomies.
Risks factors of mechanical ventilation in acute traumatic cervical spinal cord injured patients
Spinal Cord
Study design Descriptive retrospective study. Objectives To analyze risk factors associated with mechanical ventilation (MV) in cases of acute traumatic Cervical Spinal Cord Injury (tCSCI). Setting Unidad de Lesionados Medulares, Complejo Hospitalario Universitario A Coruña, in Galicia (Spain). Methods The study included patients with tCSCI who were hospitalized between January 2010 and December 2014. The following variables were analyzed: age, gender, etiology, neurological level, ASIA (American Spinal Injury Association) grade, associated injuries, injury severity score (ISS), ASIA motor score (AMS) at admission and mortality. Results A total of 146 patients met the study's inclusion criteria. The majority were men (74.7%) with mean age of 62.6 (s.d. ± 18.8) years. Sixty patients (41.1%) required MV. Mean age of ventilated vs. non-ventilated patients was 57.3 vs. 65.7. Men were more likely to require MV than women, ASIA grades A and B were also more likely to need MV than grades C and D, as well as patients with associated injuries. The AMS of patients receiving MV was lower than that of those who did not require MV (20.1 vs. 54.3). Moreover, the ISS was higher in patients receiving MV (31.2 vs. 13.4). An AMS ≤ 37 and an ISS ≥ 13 increased the risk of requiring MV by a factor of 11.98 and 7.28, respectively. Conclusions Isolated factors associated with a greater risk of MV in tCSCI were: age, gender, ASIA grade, ISS and AMS. However, the only factor with a significant discriminatory ability to determine the need for MV was the AMS at admission.