Benefits of early tracheostomy in severely burned children

Outcomes After Tracheostomy in Patients Undergoing Congenital Heart Surgery

BACKGROUND

Early tracheostomy improves outcomes in the adult population, but there is little evidence of benefit in the pediatric population. We investigated hospital and late survival of tracheostomy placement in patients who also underwent congenital cardiac surgery.

METHODS

A single-center review of 65 consecutive patients who underwent tracheostomy placement and cardiac surgery in a pediatric hospital between 2011 and 2022 was performed. Multivariable logistic regression analysis was performed to assess predictors of mortality, and a Kaplan-Meier estimate was performed to evaluate mortality.

RESULTS

Final analysis included 62 patients. Median birth weight and age at tracheostomy admission was 2.7 (interquartile range [IQR], 2-3) kg and 175 (IQR, 107-266) days, respectively. Patients failed extubation a median of 3 (IQR, 1-4) times. Duration of ventilation before tracheostomy was 85 (IQR, 49-106) days. Thirty-nine patients (63%) were discharged from the hospital. Thirty-eight patients (61%) died overall, of which 21 (55%) died in hospital. Median survival was 328 (IQR, 94-1711) days. Independent predictors of mortality were longer length of stay (odds ratio [OR], 4.66; 95% CI, 1.6-13.8; P < .01), tracheomalacia (OR, 0.31; 95% CI, 0.1-0.93; P = .04), sepsis (OR 3.4; 95% CI, 1.18-10; P = .02), pneumonia before or after tracheostomy (OR, 3.3; 95% CI, 1.1-10.2; P = .04), and acute kidney injury requiring dialysis (OR, 8; 95% CI, 1.96-54.5; P = .01).

CONCLUSIONS

With 61% mortality after tracheostomy in patients undergoing cardiac surgery in a pediatric hospital, one can wonder whether this practice improves survival in these patients. Families should be warned that, in the sickest patients, tracheostomy may only offer increased survival for a limited time.

Delayed Presentation of Thermal Epiglottitis in a Toddler: A Case Report

A minor insult to the pediatric airway can have a devastating result. Unfortunately, the signs and symptoms of obstruction might not be present immediately and take some time to develop. Therefore, physicians should have a higher index of suspicion for airway obstruction in children that present with a history of ingestion of scalding liquid. Signs and symptoms of infectious vs noninfectious epiglottis do overlap and the key to differentiate is by careful history and physical exam, especially in nonverbal children. A secondary bacterial infection might complicate thermal epiglottis and make the picture a bit confusing. Therefore, a coordinated approach through a multidisciplinary team is indicated from the start and these cases should be managed and referred to a higher center.

Retrospective outcomes analysis of tracheostomy in a paediatric burn population

INTRODUCTION

Previous analyses of tracheostomy in paediatric burns was hindered by a lack of multi-institution or nationwide analysis. This study aims to explore the effects of tracheostomy in paediatric burn patients in such an analysis. De-identified data was obtained from the TriNetX Research Network database.

METHODS

Two cohorts were identified using ICD and CPT codes: paediatric burn patients with tracheostomy (cohort 1) and paediatric burn patients without tracheostomy (cohort 2). Cohorts were matched according to age at diagnosis and pulmonary condition, specifically influenza and pneumonia, respiratory failure, acute upper respiratory infection, and pulmonary collapse. Cohorts were also matched for age at burn diagnosis and surface area burned. Several parameters including infection following a procedure, sepsis, volume depletion, respiratory disorders, laryngeal disorders, pneumonia, and other metrics were also compared.

RESULTS

A total of 152 patients were matched according to age and pulmonary condition. Cohort 1 and cohort 2 had a mean age of 4.45 ± 4.06 and 4.39 ± 3.99 years, respectively. Matched patients with tracheostomy had a higher risk for pneumonia, respiratory failure, other respiratory disorders, diseases of the vocal cord and larynx, sepsis, volume depletion, pulmonary edema, and respiratory arrest. The risk ratios for these outcomes were 2.96, 3.5, 3.13, 3.9, 2.5, 2.5, 3.3, and not applicable. Analysis of longitudinal outcomes of paediatric burn patients with tracheostomy vs. those without demonstrated the tracheostomy cohort suffered much worse morbidity and experienced higher health burden across several metrics.

CONCLUSION

The potential benefits of tracheostomy in paediatric burn patients should be weighed against these outcomes.

Tracheostomy Following Anterior Cervical Discectomy and Fusion With Plating in Trauma Patients: Is It Safe?

Objective

This study aimed to evaluate the safety and necessity of tracheostomy after anterior cervical discectomy and fusion (ACDF) with plating, despite the close proximity of the two surgical skin incisions.

Methods

Sixty-three patients with traumatic cervical fractures or spinal cord injury (SCI) who underwent single-level ACDF and plating between January 2014 and June 2019 were included in this study. The patients included 45 men and 18 women, with a mean age of 48.5 years. A retrospective analysis of the patients’ demographic data, level of injury, radiological findings, and neurological status was performed based on the American Spinal Injury Association (ASIA), open tracheostomy, and decannulation rate. Additionally, risk factors necessitating tracheostomy were statistically analyzed.

Results

Eighteen patients (28.5%) required subsequent open tracheostomy. Among them, 11 patients were successfully decannulated, four patients could not be decannulated during the follow-up period, and three patients died of unrelated complications. The median interval from ACDF with plating to open tracheostomy was 9.6 days (range, 5–23 days). On the basis of neurological status, ASIA A and B patients (p<0.001), high signal intensity on T2-weighted-magnetic resonance (MR) images (p=0.001), and major cervical fracture and dislocation were significant risk factors for tracheostomy (p=0.02). No patient showed evidence of significant soft tissue, bony infection, or nonunion during the follow-up period.

Conclusion

Independent tracheostomy did not increase the risk of infection or nonunion despite the close proximity of the two surgical skin incisions.

Optimal Timing of Tracheostomy in Injured Adolescents

OBJECTIVES

To evaluate the optimal timing of tracheostomy for injured adolescents.

DESIGN

Retrospective cohort study.

SETTING

Trauma facilities in the United States.

PATIENTS

Adolescents (age 12-17 yr) in the National Trauma Data Bank (2007-2016) who were ventilated for greater than 24 hours and survived to discharge.

INTERVENTIONS

None.

MEASUREMENTS AND MAIN RESULTS

After stratifying by traumatic brain injury diagnosis, we compared ICU and hospital length of stay, pneumonia, and discharge disposition of patients with tracheostomy prior to three cut points (3, 7, and 14 d after admission) to 1) patients intubated at least as long as each cut point and 2) patients with tracheostomy on or after each cut point. Of 11,045 patients, 1,391 (12.6%) underwent tracheostomy. Median time to tracheostomy was 9 days (interquartile range, 6-13 d) for traumatic brain injury and 7 days (interquartile range, 3-12 d) for nontraumatic brain injury patients. Nontraumatic brain injury patients with tracheostomy prior to 7 days had 5.6 fewer ICU days (-7.8 to -3.5 d) and 5.7 fewer hospital days (-8.8 to -2.7 d) than patients intubated greater than or equal to 7 days and had 14.8 fewer ICU days (-19.6 to -10.0 d) and 15.3 fewer hospital days (-21.7 to -8.9 d) than patients with tracheostomy greater than or equal to 7 days. Similar differences were observed at 14 days but not at 3 days for both traumatic brain injury and nontraumatic brain injury patients. At the 3- and 7-day cut points, both traumatic brain injury and nontraumatic brain injury patients with tracheostomy prior to the cut point had lower risk of pneumonia and risk of discharge to a facility than those with tracheostomy after the cut point.

CONCLUSIONS

For injured adolescents, tracheostomy less than 7 days after admission was associated with improved in-hospital outcomes compared with those who remained intubated greater than or equal to 7 days and with those with tracheostomy greater than or equal to 7 days. Tracheostomy between 3 and 7 days may be the optimal time point when prolonged need for mechanical ventilation is anticipated; however, unmeasured consequences of tracheostomy such as long-term complications and care needs must also be considered.

Hospital outcomes for pediatric heart transplant recipients undergoing tracheostomy: A multi-institutional analysis

Tracheostomy is associated with increased mortality and resource utilization in children with CHD. However, the prevalence and hospital outcomes of tracheostomy in children with HTx are not known. We describe the prevalence and compare the post-HTx hospital outcomes of pediatric patients with Pre-TT and Post-TT to those without tracheostomy. A multi-institutional retrospective cohort study was performed using the Pediatric Health Information System database. Hospital mortality, mediastinitis, LOS, and costs were compared among patients with Pre-TT, Post-TT, and no tracheostomy. Pre-TT was identified in 29 (1.1%) and Post-TT was identified in 41 (1.6%) of 2603 index HTx hospitalizations. Patients with Pre-TT were younger and more likely to have CHD, a non-cardiac birth defect, or an airway anomaly compared to those without Pre-TT. Pre-TT was not independently associated with increased post-HTx in-hospital mortality. Age at HTx < 1 year, CHD, and Post-TT were associated with increased in-hospital mortality. Pre-TT that occurred during the HTx hospitalization and Post-TT were associated with increased resource utilization. Tracheostomy was not associated with mediastinitis.

Factors Impacting Survival in Patients With Major Burn-Induced Acute Kidney Injury Postrenal Replacement Therapy: A Nationwide Study With 15 Years Follow-Up in Taiwan

BACKGROUND

Major burn-induced acute kidney injury (AKI) causes extremely high mortality, even though renal replacement therapy (RRT) was thought of as the most efficient treatment. There was scanty research for investigating the characteristic of burn-AKI-RRT patients during intensive care. This study aims to investigate the factors impacting the survival outcomes in those burn-AKI-RRT cases.

METHODS

Using the Taiwan National Health Insurance Research Database and its affiliated database, the Registry for Catastrophic Illness Patients, we defined a cohort composed of 171 patients encountering major burn-induced AKI and receiving RRT during burn care for a 15-year observation period. Demographic characteristic, comorbidities, total body surface area (TBSA), major procedures, and complications were analyzed to explore the factors affecting the survival outcomes during acute burn care and 1 year after discharge.

RESULTS

Patients who underwent tracheostomy and skin grafting had higher survival rates during acute burn care (tracheostomy: mortality vs survival, 15.7% vs 30.2%; P = 0.0257; skin grafting: mortality vs survival, 57.4% vs 76.2%; P = 0.0134). Multivariate regression analysis showed that tracheostomy group significantly presented with lower mortality risk by 65% (odds ratio [OR], 0.35; P = 0.0372), and subgroup analysis of delaminating follow-up duration showed that patients with tracheostomy had higher overall survival by 22% (90-day postburn mortality: nontracheostomy vs tracheostomy, 58.3% vs 36.3%; adjusted hazards ratio, 0.39; 95% confidence interval, 0.22-0.69; P = 0.0011), especially during postburn first 30 days (adjusted hazards ratio, 0.15; 95% confidence interval, 0.05-0.49; P = 0.0016). Total body surface area did not significantly affect survival; however, mortality risk was significantly higher in those with a larger TBSA (TBSA, ≥80%; OR, 6.48; P = 0.0022; TBSA, 60-79%; OR, 3.12; P = 0.0518; TBSA, 40-59%; OR, 1.88; P = 0.2402; TBSA, 30-39% as reference).

CONCLUSIONS

For patients with major burn-induced AKI receiving RRT, tracheostomy and skin grafting may improve survival in the cases living through acute burn stage.

The Pediatric Burn: Current Trends and Future Directions

Management of the pediatric burn patient presents a variety of clinical challenges for the pediatric anesthesiologist. Despite the high incidence of burn injuries, standard management strategies are far from universal. The complex physiologic changes presented by burn injuries present airway management and resuscitation challenges and mandate careful consideration of adequate nutritional support. Long hospital stays with frequent operations and dressing changes necessitate creative approaches to anxiolysis and pain control. Underutilized modalities warranting further research include regional anesthesia and nonpharmacologic approaches, such as virtual reality. Further research and collaboration between burn centers are needed to standardize care for this population.

Changes in ventilator settings and ventilation-induced lung injury in burn patients-A systematic review

OBJECTIVE

Ventilation strategies aiming at prevention of ventilator-induced lung injury (VILI), including low tidal volumes (V_T) and use of positive end-expiratory pressures (PEEP) are increasingly used in critically ill patients. It is uncertain whether ventilation practices changed in a similar way in burn patients. Our objective was to describe applied ventilator settings and their relation to development of VILI in burn patients.

DATA SOURCES

Systematic search of the literature in PubMed and EMBASE using MeSH, EMTREE terms and keywords referring to burn or inhalation injury and mechanical ventilation.

STUDY SELECTION

Studies reporting ventilator settings in adult or pediatric burn or inhalation injury patients receiving mechanical ventilation during the ICU stay.

DATA EXTRACTION

Two authors independently screened abstracts of identified studies for eligibility and performed data extraction.

DATA SYNTHESIS

The search identified 35 eligible studies. V_T declined from 14 ml/kg in studies performed before to around 8 ml/kg predicted body weight in studies performed after 2006. Low-PEEP levels (<10 cmH₂O) were reported in 70% of studies, with no changes over time. Peak inspiratory pressure (PIP) values above 35 cmH₂O were frequently reported. Nevertheless, 75% of the studies conducted in the last decade used limited maximum airway pressures (≤35 cmH₂O) compared to 45% of studies conducted prior to 2006. Occurrence of barotrauma, reported in 45% of the studies, ranged from 0 to 29%, and was more frequent in patients ventilated with higher compared to lower airway pressures.

CONCLUSION

This systematic review shows noticeable trends of ventilatory management in burn patients that mirrors those in critically ill non-burn patients. Variability in available ventilator data precluded us from drawing firm conclusions on the association between ventilator settings and the occurrence of VILI in burn patients.

Tracheostomy and mortality in patients with severe burns: A nationwide observational study

BACKGROUND

Tracheostomy is often performed in patients with severe burns who are undergoing prolonged mechanical ventilation. However, the appropriate timing of tracheostomy and its effect on mortality remain unknown. The aim of this study was to determine whether tracheostomy can reduce mortality in patients with severe burns.

METHODS

Using the Japanese Diagnosis Procedure Combination database from April 2010 to March 2014, we extracted data on adult patients with severe burns (burn index score of ≥15) who started mechanical ventilation within 3days of admission. We estimated the hazard ratio for 28-day in-hospital mortality associated with tracheotomy performed from day 5 to 28. We adjusted for baseline and time-dependent confounders using inverse probability of treatment weighting methods and fitted a marginal structural Cox proportional hazard model.

RESULTS

We identified 680 eligible patients (94 in the tracheostomy group, 2289 person-days; 586 in the non-tracheostomy group, 11,197 person-days). Patients who underwent a tracheostomy had worse prognostic factors for mortality. After adjustment for these factors, the hazard ratio for 28-day mortality associated with tracheostomy compared with non-tracheostomy was 0.73 (95% confidence interval, 0.39-1.34).

CONCLUSIONS

There was no significant association between 28-day in-hospital mortality and early tracheostomy in adult patients with severe burns.

The Need for Early Tracheostomy in Patients with Traumatic Cervical Cord Injury

Background

In patients who need sustained endotracheal intubation and mechanical ventilation due to respiratory failure after traumatic cervical spinal cord injury, tracheostomy can be performed to reduce the duration of mechanical ventilation and respiratory complications. The purpose of this study was to determine criteria and timing of tracheostomy in patients with severe traumatic cervical spinal cord injury accompanied by motor weakness.

Methods

We reviewed 22 patients who underwent tracheostomy (study group) and 27 patients who did not (control group) from January 2005 to March 2016. We assessed the American Spinal Injury Association (ASIA) impairment scale score and investigated accompanying thoracic injury, paradoxical respiration, postoperative endotracheal intubation and other clinical parameters. The study group was also subdivided into the early tracheostomy group and late tracheostomy group depending on whether the tracheostomy was performed within or later than 7 days after surgery.

Results

Twenty-two patients in the study group had a mean ASIA impairment scale score of 14.1 points, which was lower than the control group's 23.4 points. Paradoxical respiration was observed in 77% of the patients in the study group compared to 18% in the control group. Postoperative intubation was maintained in 68% in the study group; 32% underwent endotracheal intubation due to respiratory failure within 4 days after surgery and had a tracheostomy. In the control group, postoperative intubation was maintained in 22%, and all of them were weaned off intubation within 4 days after surgery. The duration of intensive care unit hospitalization was 11.4 days for the early tracheostomy group, which was shorter than the late tracheostomy group's 19.7 days.

Conclusions

In patients with severe traumatic cervical spinal cord injury, tracheostomy may be needed when the motor grade of the ASIA scale is low, above the C4 segment is injured, or paradoxical respiration occurs after injuries. In addition, if endotracheal extubation is not feasible within 4 days after surgery, an early tracheostomy should be considered.

Tracheostomy Among Infants With Hypoplastic Left Heart Syndrome Undergoing Cardiac Operations: A Multicenter Analysis

BACKGROUND

Less than 2.7% of infants undergoing congenital heart disease operations have difficulty weaning from invasive mechanical ventilation. In such instances, clinicians may choose to perform tracheostomy. Limited literature has examined tracheostomy placement specifically in infants with hypoplastic left heart syndrome (HLHS). This study evaluated the risk factors for tracheostomy placement in infants with HLHS and examined the outcomes of these infants before their first hospital discharge.

METHODS

This retrospective analysis of the Pediatric Heath Information System data set included infants with HLHS who underwent stage 1 Norwood operation, a hybrid procedure, or heart transplant from 2004 through 2013.

RESULTS

We identified 5721 infants with HLHS, and 126 underwent tracheostomy placement. Infants in the tracheostomy group had more morbidities and a higher mortality rate across the study period. Diagnosis of chromosomal abnormalities, anomalies of the trachea and esophagus, larynx, diaphragm and nervous system, bilateral vocal cord paralysis, and necrotizing enterocolitis, and procedures including extracorporeal membrane oxygenation support, cardiac catheterization, and gastrostomy tube were independently associated with tracheostomy placement in the study population. Despite an overall increase in rates of tracheostomy performed in infants with HLHS during the study period, the mortality rate did not improve among tracheostomy patients.

CONCLUSIONS

Several risk factors were identified in infants with HLHS in whom a tracheostomy was placed during their first hospitalization. Despite an overall increase in rates of tracheostomies during the study period, the mortality rate did not improve among these patients. Appropriate family counseling and thorough preoperative case selection is suggested when discussing possible tracheostomy placement in infants with HLHS.

Percutaneous Dilational Tracheotomy in Solid-Organ Transplant Recipients

OBJECTIVES

Solid-organ transplant recipients may require percutaneous dilational tracheotomy because of prolonged mechanical ventilation or airway issues, but data regarding its safety and effectiveness in solid-organ transplant recipients are scarce. Here, we evaluated the safety, effectiveness, and benefits in terms of lung mechanics, complications, and patient comfort of percutaneous dilational tracheotomy in solid-organ transplant recipients.

MATERIALS AND METHODS

Medical records from 31 solid-organ transplant recipients (median age of 41.0 years [interquartile range, 18.0-53.0 y]) who underwent percutaneous dilational tracheotomy at our hospital between January 2010 and March 2015 were analyzed, including primary diagnosis, comorbidities, duration of orotracheal intubation and mechanical ventilation, length of intensive care unit and hospital stays, the time interval between transplant to percutaneous dilational tracheotomy, Acute Physiology and Chronic Health Evaluation II score, tracheotomy-related complications, and pulmonary compliance and ratio of partial pressure of arterial oxygen to fraction of inspired oxygen.

RESULTS

The median Acute Physiology and Chronic Health Evaluation II score on admission was 24.0 (interquartile range, 18.0-29.0). The median interval from transplant to percutaneous dilational tracheotomy was 105.5 days (interquartile range, 13.0-2165.0 d). The only major complication noted was left-sided pneumothorax in 1 patient. There were no significant differences in ratio of partial pressure of arterial oxygen to fraction of inspired oxygen before and after procedure (170.0 [interquartile range, 102.2-302.0] vs 210.0 [interquartile range, 178.5-345.5]; P = .052). However, pulmonary compliance results preprocedure and postprocedure were significantly different (0.020 L/cm H2O [interquartile range, 0.015-0.030 L/cm H2O] vs 0.030 L/cm H2O [interquartile range, 0.020-0.041 L/cm H2O); P = .001]). Need for sedation significantly decreased after tracheotomy (from 17 patients [54.8%] to 8 patients [25.8%]; P = .004]).

CONCLUSIONS

Percutaneous dilational tracheotomy with bronchoscopic guidance is an efficacious and safe technique for maintaining airways in solidorgan transplant recipients who require prolonged mechanical ventilation, resulting in possible improvements in ventilatory mechanics and patient comfort.

Tracheostomy in pediatric burn patients

BACKGROUND

Tracheostomy is often performed in the pediatric burn population to establish secure airways. Tracheostomy is safe in this population, but the duration of tracheostomy may be related to age and extent and severity of burn. We hypothesized that burn related factors and not age determine the time to removal of a tracheostomy in pediatric burn patients.

METHODS

A 5-year retrospective review was performed for pediatric burn patients (age ≤18 years) who underwent tracheostomy. Patients were divided into three groups by age (group 1: 0 to ≤2 years, group 2: >2 to ≤12 years, group 3: >12 to ≤18 years). Data collected included: age, total body surface area burn injured (TBSA), gender, mechanism of injury, diagnosis of inhalation injury, mortality, time from injury to admission, time from admission to placement of tracheostomy, time of injury to placement of tracheostomy, duration of tracheostomy, days of mechanical ventilation, and tracheostomy related complications.

RESULTS

45 patients were reviewed. There were no differences in TBSA, length of ICU stay, length of hospital stay, and mortality between the three groups. Additionally, there were no differences in ventilator days and duration of tracheostomy. Multivariate linear regression analysis indicated that TBSA and not age independently increased the duration of tracheostomy.

CONCLUSION

Tracheostomy duration is dependent on the extent of burn in pediatric burn patients.

Tracheostomy in children with congenital heart disease: a national analysis of the Kids' Inpatient Database

Background. While single-institution studies reported the indications and outcomes of tracheostomy in children with congenital heart disease (CHD), no national analyses have been performed. We sought to examine the indications, performance, outcomes, and resource utilization of tracheostomy in children with CHD using a nationally representative database. Methods. We identified all children undergoing tracheostomy in the Kids' Inpatient Database 1997 through 2009, and we compared children with CHD to children without CHD. Within the CHD group, we compared children whose tracheostomy occurred in the same hospital admission as a cardiac operation to those whose tracheostomy occurred without a cardiac operation in the same admission. Results. Tracheostomy was performed in n = 2,495 children with CHD, which represents 9.6% of all tracheostomies performed in children (n = 25,928), and 3.5% of all admissions for children with CHD (n = 355,460). Over the study period, there was an increasing trend in the proportion of all tracheostomies that were done in children with CHD (p < 0.0001) and an increasing trend in the proportion of admissions for children with CHD that involved a tracheostomy (p < 0.0001). The population of children with CHD undergoing tracheostomy differed markedly in baseline characteristics, outcomes, and resource utilization. Similarly, the subgroup of children whose tracheostomy was performed in the same admission as a cardiac operation differed significantly from those whose tracheostomy was not. Conclusions. Tracheostomy is an increasingly common procedure in children with CHD despite being associated with significantly greater resource utilization and in-hospital mortality. The population of children with CHD who undergo tracheostomy differs markedly from that of children without CHD who undergo tracheostomy, and important differences are observed between children who undergo tracheostomy in the same admission as a cardiac surgical procedure and those who undergo tracheostomy in a nonsurgical admission, as well as between children with single-ventricle physiology and children with two-ventricle physiology.

Burn intensive care

As a result of continuous development in the treatment of burns, the LD50 (the burn size lethal to 50% of the population) for thermal injuries has risen from 42% total body surface area (TBSA) during the 1940s and 1950s to more than 90% TBSA for young thermally injured patients. This vast improvement in survival is due to simultaneous developments in critical care, advancements in resuscitation, control of infection through early excision, and pharmacologic support of the hypermetabolic response to burns. This article reviews these recent advances and how they influence modern intensive care of burns.

Clinical review: the critical care management of the burn patient

Between 4 and 22% of burn patients presenting to the emergency department are admitted to critical care. Burn injury is characterised by a hypermetabolic response with physiologic, catabolic and immune effects. Burn care has seen renewed interest in colloid resuscitation, a change in transfusion practice and the development of anti-catabolic therapies. A literature search was conducted with priority given to review articles, meta-analyses and well-designed large trials; paediatric studies were included where adult studies were lacking with the aim to review the advances in adult intensive care burn management and place them in the general context of day-to-day practical burn management.

Characterizing the need for tracheostomy placement and decannulation after cervical spinal cord injury

PURPOSE

There have been few reports on the risk factors for tracheostomy and the possibility of patients for decannulation. The purpose of this study was to identify factors necessitating tracheostomy after cervical spinal cord injury (SCI) and detect features predictive of successful decannulation in tracheostomy patients.

METHODS

One hundred and sixty four patients with cervical fracture/dislocation were retrospectively reviewed. The patients comprised 142 men and 22 women with a mean age of 44.9 years. The clinical records were reviewed for patients' demographic data, smoking history, level of cervical spine injury, injury patterns, neurological status, evidence of direct thoracic trauma and head injury, tracheostomy placement, and decannulation. Risk factors necessitating tracheostomy and factors predicting decannulation were statistically analysed.

RESULTS

Twenty-five patients (15.2%) required tracheostomy. Twenty-one patients were successfully decannulated. Smoking history (relative risk [RR], 3.05; p = 0.03) and complete SCI irrespective of injury level (C1-4 complete SCI: RR, 67.55; p < 0.001, C5-7 complete SCI: RR, 57.88; p < 0.001) were significant risk factors necessitating tracheostomy. C1-4 complete SCI was more frequent among those who could not be decannulated. However, even in patients with high cervical complete SCI at the time of injury, patients regaining sufficient movement to shrug their shoulders within 3 weeks after injury could later be decannulated.

CONCLUSIONS

The risk factors for tracheostomy after complete SCI were a history of smoking and complete paralysis irrespective of the level of injury. High cervical level complete SCI was found to be a risk factor for the failure of decannulation in patients without shoulder shrug within 3 weeks after injury.

Ventilator-associated pneumonia in burn patients: a cause or consequence of critical illness?

Infectious complications are a constant threat to thermally injured patients during hospitalizations and are a predominant cause of death. Most of the infections that develop in burn patients are nosocomial and of a pulmonary etiology. The bacteria that cause ventilator associated pneumonia (VAP) take advantage of the fact that uniquely among intensive care unit patients endotracheal intubation allows them a 'free' passage to the sterile lower airways; however, the combination of severe thermal injury (systemic immunosuppression) and inhalation injury (local immunosuppression and tissue injury) create an ideal environment for development of VAP. Thus, strategies directed at preventing and treating VAP in burn patients must address not only rapid extubation and VAP prevention bundles known to work in other intensive care unit populations, but therapies directed to more rapid wound healing and restoration of pulmonary patency.

[Inhalation injury--epidemiology, diagnosis and therapy]

OBJECTIVE

Inhalation injury is a vitally threatening medical syndrome, which might appear in patients with or without burn injuries. Thus, knowledge about development, diagnosis and treatment of inhalation injury should be available for each physician working in an intensive care unit.

METHODS

This review starts with the causal and formal pathogenesis of inhalation injuries. Furthermore, diagnosis and treatment in the critical care setting are presented, followed by the discussion of possible complications. Specific intoxications such as carbon monoxide are due to their importance separately discussed.

CONCLUSIONS

Inhalation injury present with an attributable excess mortality and thus worsen the prognosis of burned patients. New insights into the pathogenesis of inhalation injury, however, have led to improved therapeutic possibilities with improved outcome. Necessary prerequisites are a timely diagnosis and restrictive volume management, especially in patients with extensive burns. Prospective studies are needed to be able to answer the many emerging questions.

Airway management and smoke inhalation injury in the burn patient

Smoke inhalation injury, a unique form of acute lung injury, greatly increases the occurrence of postburn morbidity and mortality. In addition to early intubation for upper-airway protection, subsequent critical care of patients who have this injury should be directed at maintaining distal airway patency. High-frequency ventilation, inhaled heparin, and aggressive pulmonary toilet are among the therapies available. Even so, immunosuppression, intubation, and airway damage predispose these patients to pneumonia and other complications.

Tracheostomy in burns patients revisited

OBJECTIVE

The use of tracheostomy in burns patients has been controversial. A retrospective study was conducted to assess the use, complications and outcome of tracheostomy in ventilated adult burns patients.

METHODS

Data was collected retrospectively regarding the extent of injury in each patient, the indication for tracheostomy, and outcome in terms of length of stay, days of mechanical ventilation, airway and pulmonary complications and survival. Patients were followed until discharge from the unit or death.

RESULTS

Comparing patients who received tracheostomy to those who had translaryngeal intubation showed similar age distribution and no significant difference in the total burn surface area (TBSA). The use of tracheostomy was significantly higher in patients with TBSA >60%. Inhalation injury was significantly higher and mean probability of survival (ABSI), significantly lower in patients receiving tracheostomy. Duration of mechanical ventilation, length of stay in HDU/ITU and the incidence of pulmonary sepsis were significantly higher in tracheostomy group patients. However, there was no significant difference in mortality between the two groups.

CONCLUSION

Burn survivors with TBSA >60% are more likely to undergo repeated surgery and have burns to the head and neck region, therefore increasing the requirement for tracheostomy. Tracheostomy is a safe procedure with minimal perioperative complications. Late complications in this patient group may be related to duration of intubation and mechanical ventilation and the presence of an airway burn. Tracheostomy was associated with a higher prevalence of chest infection. We suspect that the cause of this is multifactorial, possibly due to a higher incidence of inhalation injury, greater burn size and prolonged mechanical ventilation in this group.

Elective tracheostomy in mechanically ventilated children in Canada

OBJECTIVE

To determine the current practice and opinions of paediatric intensivists in Canada regarding tracheostomy in children with potentially reversible conditions which are anticipated to require prolonged mechanical ventilation.

DESIGN AND SETTING

Self-administered survey among paediatric intensivists within paediatrics critical care units (PCCU) across Canada.

MEASUREMENTS AND RESULTS

All 16 PCCUs participated in the survey with a response rate of 81% (63 physicians). In 14 of 16 centres one to five tracheostomies were performed during 2006. Two centres did not perform any tracheostomies. The overall rate of tracheostomy is less than 1.5%. Percutaneous technique is used in 3/16 (19%) of centres. Readiness to undertake tracheostomy during the first 21[Symbol: see text]days of illness is influenced by patient diagnosis; severe traumatic brain injury 66% vs. 42% in a 2-year-old with Guillain-Barré syndrome, 48% in a 9-year-old with Guillain-Barré syndrome, and 12% in a child with isolated ARDS. In a child with ARDS 25% of respondents would never consider tracheostomy. Age does not affect timing nor keenness for tracheostomy. The majority, 81%, believe that the risks associated with the procedure do not outweigh the potential benefits. Finally, 51% believe that tracheostomy is underutilized in children.

CONCLUSIONS

Elective tracheostomy is rarely performed among ventilated children in Canada. However, 51% of physicians believe it is underutilized. The role of elective tracheostomy and the percutaneous technique in children requires further investigation.

Thermal and electrical injuries

Through progress in wound management, resuscitation, intensive care treatment, and a coordinated rehabilitation process, modern burn care has been able to deliver substantial increases in survival and improvement in functional outcomes for burn victims. The development of regionalized burn centers has contributed greatly to this progress. As the field of burns matures, burn centers are preparing to meet future challenges through collaborative efforts in disaster management and outcomes research.

Advances in burn critical care

BACKGROUND

Management of burn patients requires a complex interaction of surgical, medical, critical care, and rehabilitation approaches. Severe burn patients are some of the most challenging critically ill patients who may have multiple-system organ failure with life-threatening complications.

OBJECTIVE

To review and highlight some of the recent advances in burn critical care. We focused on some of the new treatment modalities in the management of respiratory complications, advances in burn resuscitation, management of the metabolic response to burns, and recent ideas in burn immunotherapy.

DATA SOURCE

A search of the MEDLINE database and manual review of published articles and abstracts from national and international meetings. DATA SYNTHESES AND CONCLUSIONS: The respiratory management of burn patients includes strategies to minimize iatrogenic injury with low tidal volume ventilation, to improve ventilation/perfusion mismatch, and to diagnosis pneumonia. Many aspects of burn resuscitation remain controversial, and the best form of fluid resuscitation has yet to be identified. Recent research in the metabolic response to thermal injury has identified many potentially beneficial treatments. Although immunomodulation therapy is promising, currently most of these treatments are not clinically viable, and further clinical and translational research is warranted.

Indications for tracheostomy in children

Vaccination programs, improvements in material engineering and anaesthetic skills have dramatically reduced the number of emergency tracheostomies performed for acute upper airway obstruction. Today, the indication to tracheotomise a child is generally ruled by the anticipation of long-term (cardio)respiratory compromise due to chronic ventilatory or, more rarely, cardiac insufficiency, or by the presence of a fixed upper airway obstruction that is unlikely to resolve for a significant period of time. As many of the younger candidates for tracheostomy have complex medical conditions, the indication for this intervention is often complicated by ethical, funding and socio-economic concerns that necessitate a multidisciplinary approach. Unfortunately, these considerations are frequently not made until the first catastrophe has occurred, even in those patients in whom imminent cardiorespiratory failure has been foreseeable. Non-invasive ventilation via a face mask and newer developments such as the in-exsufflator device have gained importance as an alternative to tracheostomy in selected patients.

Predicting the Need for Early Tracheostomy: A Multifactorial Analysis of 992 Intubated Trauma Patients

BACKGROUND

Tracheostomy has few, severe risks, while prolonged endotracheal intubation causes morbidity. The need for tracheostomy was assessed, based on early clinical parameters.

METHODS

Adult trauma patients (January 1994-August 2004), intubated for resuscitation, ventilated >24 hours, were retrospectively evaluated for demographics, physiology, brain, and pulmonary injury. Tracheostomy patients were compared with those without. Chi-square, Mann-Whitney, and multivariate logistic regression were used with statistical significance at p < 0.05.*

RESULTS

Of 992 patients, 430 (43%) underwent tracheostomy at 9.22 +/- 5.7 days. Risk factors were age (45.6* +/- 18.8 vs. 36.7 +/- 15.9, OR: 2.1 (18 years increments), ISS (30.3* +/- 12.5 vs. 22.0 +/- 10.3, OR: 2.1 (12u increments), damage control (DC) [68%*(n = 51) vs. 32%*(n = 51), OR: 3.8], craniotomy [70%*(n = 21) versus 30%(n = 9), OR: 2.6], and intracranial pressure monitor (ICP) [65.4%*(n = 87) vs. 34.6%(n = 46), OR: 2.1]. A 100% tracheostomy rate (n = 30, 3.0%) occurred with ISS (injury severity score) = 75, ISS >or=50, and age >or=55, admit/24 hour GCS (Glasgow Coma Scale) = 3 and age >or=70, AIS abdomen, chest or extremities >or=5 and age >or=60, bilateral pulmonary contusions (BPC) and >or=8 rib fractures, craniotomy and age >or=50, craniotomy with intracranial pressure (ICP) and age >or=40, or craniotomy and GCS <or=4 at 24 hour.A tracheostomy rate of >or=90% (n = 105, 10.6%) was found with ISS >or=54, ISS >or=40, and age >or=40, admit/24 hour GCS = 3 and age >or=55, paralysis and age >or=40, BPC and age >or=55.A tracheostomy rate >or=80% (n = 248, 25.0%) occurred with ISS >or=38, age >or=80, admit/24 hour GCS = 3 and age >or=45, DC and age >or=50, BPC and age >or=50, aspiration and age >or=55, craniotomy with ICP, craniotomy with GCS <or=9 at 24 hour.

CONCLUSION

Discrete risk factors predict the need for tracheostomy for trauma patients. We recommend that patients with >or=90% risk undergo early tracheostomy and that it is considered in the >or=80% risk group to potentially decreased morbidity, increased patient comfort, and optimize resource utilization.

Outcome of patients requiring tracheostomy in a pediatric intensive care unit

BACKGROUND

Although tracheostomy is a commonly performed procedure, there is a lack of studies in the pediatric intensive care unit (PICU) setting that describe its association with patient outcome and especially hospital mortality. Our goal was to evaluate the outcome of patients receiving a tracheostomy, while on mechanical ventilation (MV), in a PICU.

METHODS

Records of 260 children were reviewed retrospectively regarding PICU mortality, PICU length of stay (PICU LOS), duration of MV and a cost indicator (weighted hospital days; WHD).

RESULTS

Nineteen patients received tracheostomy (7.3%). The mortality of patients submitted to tracheostomy in the longer term was significantly higher compared to patients who were not (52.6%vs. 27.6%; P = 0.04) despite having a significantly lower severity of illness at admission (Pediatric Risk of Mortality score--PRISM) (10.9 vs. 13.7; P < 0.001). The mortality of patients without tracheostomy, however, was significantly higher within 30 days (24.8%vs. 5.2%, P < 0.001). Tracheostomized patients had significantly higher mean PICU LOS (68 days vs. 8 days; P < 0.001), duration of MV (62 days vs. 4 days; P < 0.001) and higher WHD (171.5 vs. 21.5; P < 0.001).

CONCLUSION

Contrary to findings in critically ill adult patients, ventilated children receiving a tracheostomy had less favorable outcomes compared with non-tracheostomized patients. In view of the greater use of resources, further studies are needed to confirm and to identify the subgroups of mechanically ventilated patients who will benefit most from this procedure.

Lésions respiratoires et brûlures

INTRODUCTION

Smoke inhalation and respiratory complications are still the major causes of mortality in severely burned patients.

STATE OF THE ART

The diagnosis is suspected clinically on the basis of history and physical examination and can be confirmed bronchoscopically. Respiratory failure in burned patients occurs through a number of associated mechanisms. Pneumonitis and adult respiratory distress syndrome (ARDS) are common early complications. New pulmonary treatments and advances in ventilation have reduced the incidence of both barotrauma and infectious complications. Tracheal stenosis can occur as a late complication of prolonged mechanical ventilation.

PERSPECTIVES

Clinical and experimental studies have shown that damage to the mucosal barrier and the release of inflammatory mediators are the most important pathophysiological events following smoke inhalation. Manipulation of the inflammatory response following inhalation may be a treatment option in the distant future.

CONCLUSION

Inhalation injury occurring in burned patients can produce severe respiratory and systemic complications.

Tracheostomy in Thermally Injured Patients: Does Diagnosis-Related Group 483 Adequately Estimate Resource Use and Hospital Costs?

BACKGROUND

This study compares burn and nonburn patients undergoing tracheostomy, all of whom were assigned to diagnosis-related group 483 to determine hospital reimbursement.

METHODS

We reviewed the records of all inpatients admitted to our hospital from January 2000 through December 2001 who underwent tracheostomy and who were assigned to diagnosis-related group 483. In addition, we compared our burn patient data with that from three other burn centers and the National Burn Repository.

RESULTS

We identified 357 inpatients who had tracheostomies during their hospitalization, only 12 of whom (3.4%) had acute burn injuries. The mean extent of burn in these patients was 43.4% total body surface area. The most frequent primary diagnoses for nonburn patients were injury and poisoning, and circulatory and respiratory disorders. Patients with burn injuries had 39.6 ventilator days, 40.7 intensive care unit days, and 49.2 hospital days compared with 19.8, 17.4, and 29.5 days, respectively, for nonburn patients (p <0.0001). Demographic, resource, and financial data for burn patients treated at the three other burn centers and those reported to the National Burn Repository were not significantly different from burn patients treated at our hospital. Total costs and charges for the care of burn patients were $186,830 and $343,904, respectively, compared with $82,176 and $160,498 for the nonburn patients (p <0.0005).

CONCLUSION

Burn patients requiring tracheostomies during their acute hospitalization consume significantly more resources than patients without burn injuries. More appropriate resource-based reimbursement for the care of these patients appears warranted.

Damage limitation in burn surgery

Burn injury differs from other types of trauma in the apparent lack of urgency for treatment. We argue that in order to limit physiological damage and the development of multi-organ failure, management of the burn wound must be immediate and aggressive. Supportive fluid treatment should be judicious in order to prevent excessive oedema causing wound extension. Some potential strategies utilising oral fluid resuscitation are discussed, and potential pharmacological interventions. When associated with other trauma, major burn injury has a detrimental effect on morbidity and mortality, and surgical management of both aspects of a patient's injuries are altered.