Early Versus Late Tracheostomy in Trauma Patients: A Propensity-Matched Cohort Study of 5 Years’ Data at a Single Institution in Korea

Impact of Early Tracheostomy on Clinical Outcomes in Trauma Patients Admitted to the Intensive Care Unit: A Retrospective Causal Analysis

OBJECTIVES

To assess the indications, timing, and clinical outcomes that result from the early tracheostomy (ET) administration, by causal inference models.

DESIGN

A retrospective observational study.

SETTING

Multiinstitutional intensive care unit in the United States PARTICIPANTS: The study comprised 626 trauma patients.

INTERVENTIONS

An ET versus late tracheostomy (LT).

MEASUREMENTS AND MAIN RESULTS

Trauma patients with tracheostomy were identified from 2 public databases named Medical Information Mart for the Intensive Care-IV and eICU Collaborative Research Database. Tracheostomy was defined as early (≤7 days) or late (>7 days) from intensive care unit admission. A marginal structural Cox model (MSCM) with inverse probability weighting was employed. For comparison, the authors also used time-dependent propensity-score matching (PSM) to account for differences in the probability of receiving an ET or LT. A total of 626 eligible patients were enrolled in the study, of whom 321 (51%) received a ET. The MSCM and time-dependent PSM indicated that the ET group was associated with reduced ventilation-associated pneumonia (VAP) and a shorter mechanical ventilation (MV) duration than the LT group. Yet, mortality did not show any difference between the two groups.

CONCLUSIONS

The authors' study observed that ET was not associated with reduced mortality in trauma patients, but it was associated with reduced VAP risk and MV duration. The results warrant further validation in randomized controlled trials.

Tracheostomy versus prolonged intubation in moderate to severe traumatic brain injury: a multicentre retrospective cohort study

PURPOSE

Tracheostomy is a surgical procedure that is commonly performed in patients admitted to the intensive care unit (ICU). It is frequently required in patients with moderate to severe traumatic brain injury (TBI), a subset of patients with prolonged altered state of consciousness that may require a long period of mechanical respiratory assistance. While many clinicians favour the use of early tracheostomy in TBI patients, the evidence in favour of this practice remains scarce. The aims of our study were to evaluate the potential clinical benefits of tracheostomy versus prolonged endotracheal intubation, as well as whether the timing of the procedure may influence outcome in patients with moderate to severe TBI.

METHODS

We conducted a retrospective multicentre cohort study based on data from the provincial integrated trauma system of Quebec (Québec Trauma Registry). The study population was selected from adult trauma patients hospitalized between 2013 and 2019. We included patients 16 yr and older with moderate to severe TBI (Glasgow Coma Scale score < 13) who required mechanical ventilation for 96 hr or longer. Our primary outcome was 30-day mortality. Secondary outcomes included hospital and ICU mortality, six-month mortality, duration of mechanical ventilation, ventilator-associated pneumonia, ICU and hospital length of stay as well as orientation of patients upon discharge from the hospital. We used propensity score covariate adjustment. To overcome the effect of immortal time bias, an extended Cox shared frailty model was used to compare mortality between groups.

RESULTS

From 2013 to 2019, 26,923 patients with TBI were registered in the Québec Trauma Registry. A total of 983 patients who required prolonged endotracheal intubation for 96 hr or more were included in the study, 374 of whom underwent a tracheostomy and 609 of whom remained intubated. We observed a reduction in 30-day mortality (adjusted hazard ratio, 0.33; 95% confidence interval, 0.21 to 0.53) associated with tracheostomy compared with prolonged endotracheal intubation. This effect was also seen in the ICU as well as at six months. Tracheostomy, when compared with prolonged endotracheal intubation, was associated with an increase in the duration of mechanical respiratory assistance without any increase in the length of stay. No effect on mortality was observed when comparing early vs late tracheostomy procedures. An early procedure was associated with a reduction in the duration of mechanical respiratory support as well as hospital and ICU length of stay.

CONCLUSION

In this multicentre cohort study, tracheostomy was associated with decreased mortality when compared with prolonged endotracheal intubation in patients with moderate to severe TBI. This effect does not appear to be modified by the timing of the procedure. Nevertheless, the generalization and application of these results remains limited by potential residual time-dependent indication bias.

Impact of Early Tracheostomy Versus Late or No Tracheostomy in Nonneurologically Injured Adult Patients: A Systematic Review and Meta-Analysis

OBJECTIVE

The optimal timing of tracheostomy in nonneurologically injured mechanically ventilated critically ill adult patients is uncertain. We conducted a systematic review of randomized controlled trials to evaluate the effect of early versus late tracheostomy or prolonged intubation in this population.

DATA SOURCES

We searched MEDLINE, Embase, CENTRAL, CINAHL, and Web of science databases for randomized controlled trials comparing early tracheostomy (<10 d of intubation) with late tracheostomy or prolonged intubation in adults.

DATA SELECTION

We selected trials comparing early tracheostomy (defined as being performed less than 10 d after intubation) with late tracheostomy (performed on or after the 10th day of intubation) or prolonged intubation and no tracheostomy in nonneurologically injured patients. The primary outcome was overall mortality. Secondary outcomes included ventilator-associated pneumonia, duration of mechanical ventilation, ICU, and hospital length of stay.

DATA EXTRACTION

Two reviewers screened citations, extracted data, assessed the risk of bias, and classification of Grading of Recommendations, Assessment, Development, and Evaluation independently.

DATA SYNTHESIS

Our search strategy yielded 8,275 citations, from which nine trials (n = 2,457) were included. We did not observe an effect on the overall mortality of early tracheostomy compared with late tracheostomy or prolonged intubation (risk ratio, 0.91, 95% CI, 0.82-1.01; I2 = 18%). Our results were consistent in all subgroup analyses. No differences were observed in ICU and hospital length of stay, duration of mechanical ventilation, incidence of ventilator-acquired pneumonia, and complications. Our trial sequential analysis showed that our primary analysis on mortality was likely underpowered.

CONCLUSION

In our systematic review, we observed that early tracheostomy, as compared with late tracheostomy or prolonged intubation, was not associated with a reduction in overall mortality. However, we cannot exclude a clinically relevant reduction in mortality considering the level of certainty of the evidence. A well-designed trial is needed to answer this important clinical question.

Prediction of factors influencing the timing and prognosis of early tracheostomy in patients with multiple rib fractures: A propensity score matching analysis

Objective

To investigate the factors affecting the timing and prognosis of early tracheostomy in multiple rib fracture patients.

Methods

A retrospective case-control study was used to analyze the clinical data of 222 patients with multiple rib fractures who underwent tracheotomy in the Affiliated Hospital of Yangzhou University from February 2015 to October 2021. According to the time from tracheal intubation to tracheostomy after admission, the patients were divided into two groups: the early tracheostomy group (within 7 days after tracheal intubation, ET) and late tracheostomy group (after the 7th day, LT). Propensity score matching (PSM) was used to eliminate the differences in baseline characteristics Logistic regression was used to predict the independent risk factors for early tracheostomy. Kaplan–Meier and Cox survival analyses were used to analyze the influencing factors of the 28-day survival.

Results

According to the propensity score matching analysis, a total of 174 patients were finally included in the study. Among them, there were 87 patients in the ET group and 87 patients in the LT group. After propensity score matching, Number of total rib fractures (NTRF) (P < 0.001), Acute respiratory distress syndrome (ARDS) (P < 0.001) and Volume of pulmonary contusion(VPC) (P < 0.000) in the ET group were higher than those in the LT group. Univariate analysis showed that the patients who underwent ET had a higher survival rate than those who underwent LT (P = 0.021). Pearson's analysis showed that there was a significant correlation between NTRF and VPC (r = 0.369, P = 0.001). A receiver operating characteristic(ROC)curve analysis showed that the areas under the curves were 0.832 and 0.804. The best cutoff-value values of the VPC and NTRF were 23.9 and 8.5, respectively. The Cox survival analysis showed that the timing of tracheostomy (HR = 2.51 95% CI, 1.12–5.57, P = 0.004) and age (HR = 1.53 95% CI, 1.00–2.05, P = 0.042) of the patients had a significant impact on the 28-day survival of patients with multiple rib fractures. In addition, The Kaplan–Meier survival analysis showed that the 28-day survival of patients in the ET group was significantly better than that of the LT group, P = 0.01.

Conclusions

NTRF, ADRS and VPC are independent risk factors for the timing and prognosis of early tracheotomy. A VPC ≥ 23.9% and/or an NTRF ≥ 8.5 could be used as predictors of ET in patients with multiple rib fractures. Predicting the timing of early tracheostomy also need prediction models in the future.

Timing of Tracheostomy in Patients with Intracerebral Haemorrhage: A Propensity-Matched Analysis

AIMS

Although early tracheostomy (ET) is recommended for patients with severe stroke, the optimal timing of tracheostomy for patients with intracerebral haemorrhage (ICH) remains controversial. This study aimed to explore the clinical characteristics, risk factors and timing of tracheostomy in patients after tracheal intubation using a propensity-matched analysis.

METHODS

We conducted a retrospective database search and assessed 267 consecutive patients who underwent endotracheal intubation (175 of whom underwent tracheostomy) and ICH between July 2017 and June 2021. A logistic regression model was applied to identify the critical factors influencing the decision for tracheostomy by comparing factors in a tracheostomy group and a nontracheostomy group. Patients were divided into an early (≤5 days) or a late (>5 days) group according to the median time of tracheostomy. Propensity score matching was performed to adjust for possible confounders and investigate differences in outcomes between ET and late tracheostomy (LT).

RESULTS

Among the 267 enrolled patients with ICH and endotracheal intubation, 65.5% received tracheostomy during hospitalisation, and 52.6% received ET. The independent risk factors for tracheostomy included National Institute of Health Stroke Scale (NIHSS) (odds ratio [OR]: 1.179; 95% confidence interval [CI]: 1.028-1.351; P = 0.018), aspiration (OR: 2.171; 95% CI: 1.054-4.471; P = 0.035) and infiltrates (OR: 2.149; 95% CI: 1.088-4.242; P = 0.028). Using propensity matching, we found that ET was associated with fewer antibiotic-using days (15 vs. 18; P < 0.001) and sedativeusing days (6 vs. 8; P < 0.001), shorter intensive care unit (ICU) Length of Study (LOS) (9 vs. 12; P < 0.05) and reduced in-ICU costs (3.59 vs. 7.4; P < 0.001) and total hospital costs (8.26 vs. 11.28, respectively; P < 0.001). Muscle relaxants (31.8% vs. 60.6%) were used less frequently in patients with ET (P = 0.001). However, there were no differences between the ET and LT groups in terms of modified Rankin Scale (mRS) (4 vs. 4; P = 0.932), in-general-ward costs (4.74 vs. 4.37; P = 0.052), mechanical ventilation days (6 vs. 6; P = 0.961) and hospital LOS (23 vs. 23; P = 0.735) as well as the incidences of ventilator-associated pneumonia (28.8% vs. 37.9%; P = 0.268), tracheostomyrelated complications (16.7% vs. 19.7%; P = 0.652), respiratory failure (24.2% vs. 31.8%; P = 0.333), all-cause deaths (15.2% vs. 16.7%; P = 0.812) and pneumonia (77.3% vs. 87.9%; P = 0.108).

CONCLUSION

We recommend ET for high-risk patients with ICH. Although ET cannot reduce inhospital mortality or improve patient prognosis, it may help reduce hospital costs and ICU LOS as well as the use of antibiotics, sedatives and muscle relaxants.

Early Tracheostomy for Managing ICU Capacity During the COVID-19 Outbreak: A Propensity-Matched Cohort Study

BACKGROUND

During the first wave of the COVID-19 pandemic, shortages of ventilators and ICU beds overwhelmed health care systems. Whether early tracheostomy reduces the duration of mechanical ventilation and ICU stay is controversial.

RESEARCH QUESTION

Can failure-free day outcomes focused on ICU resources help to decide the optimal timing of tracheostomy in overburdened health care systems during viral epidemics?

STUDY DESIGN AND METHODS

This retrospective cohort study included consecutive patients with COVID-19 pneumonia who had undergone tracheostomy in 15 Spanish ICUs during the surge, when ICU occupancy modified clinician criteria to perform tracheostomy in Patients with COVID-19. We compared ventilator-free days at 28 and 60 days and ICU- and hospital bed-free days at 28 and 60 days in propensity score-matched cohorts who underwent tracheostomy at different timings (≤ 7 days, 8-10 days, and 11-14 days after intubation).

RESULTS

Of 1,939 patients admitted with COVID-19 pneumonia, 682 (35.2%) underwent tracheostomy, 382 (56%) within 14 days. Earlier tracheostomy was associated with more ventilator-free days at 28 days (≤ 7 days vs > 7 days [116 patients included in the analysis]: median, 9 days [interquartile range (IQR), 0-15 days] vs 3 days [IQR, 0-7 days]; difference between groups, 4.5 days; 95% CI, 2.3-6.7 days; 8-10 days vs > 10 days [222 patients analyzed]: 6 days [IQR, 0-10 days] vs 0 days [IQR, 0-6 days]; difference, 3.1 days; 95% CI, 1.7-4.5 days; 11-14 days vs > 14 days [318 patients analyzed]: 4 days [IQR, 0-9 days] vs 0 days [IQR, 0-2 days]; difference, 3 days; 95% CI, 2.1-3.9 days). Except hospital bed-free days at 28 days, all other end points were better with early tracheostomy.

INTERPRETATION

Optimal timing of tracheostomy may improve patient outcomes and may alleviate ICU capacity strain during the COVID-19 pandemic without increasing mortality. Tracheostomy within the first work on a ventilator in particular may improve ICU availability.

Timing of tracheostomy in acute traumatic spinal cord injury: A systematic review and meta-analysis

BACKGROUND

Patients with acute traumatic cervical or high thoracic level spinal cord injury (SCI) typically require mechanical ventilation (MV) during their acute admission. Placement of a tracheostomy is preferred when prolonged weaning from MV is anticipated. However, the optimal timing of tracheostomy placement in patients with acute traumatic SCI remains uncertain. We systematically reviewed the literature to determine the effects of early versus late tracheostomy or prolonged intubation in patients with acute traumatic SCI on important clinical outcomes.

METHODS

Six databases were searched from their inception to January 2020. Conference abstracts from relevant proceedings and the gray literature were searched to identify additional studies. Data were obtained by two independent reviewers to ensure accuracy and completeness. The quality of observational studies was evaluated using the Newcastle Ottawa Scale.

RESULTS

Seventeen studies (2,804 patients) met selection criteria, 14 of which were published after 2009. Meta-analysis showed that early tracheostomy was not associated with decreased short-term mortality (risk ratio [RR], 0.84; 95% confidence interval [CI], 0.39-1.79; p = 0.65; n = 2,072), but was associated with a reduction in MV duration (mean difference [MD], 13.1 days; 95% CI, -6.70 to -21.11; p = 0.0002; n = 855), intensive care unit length of stay (MD, -10.20 days; 95% CI, -4.66 to -15.74; p = 0.0003; n = 855), and hospital length of stay (MD, -7.39 days; 95% CI, -3.74 to -11.03; p < 0.0001; n = 423). Early tracheostomy was also associated with a decreased incidence of ventilator-associated pneumonia and tracheostomy-related complications (RR, 0.86; 95% CI, 0.75-0.98; p = 0.02; n = 2,043 and RR, 0.64; 95% CI, 0.48-0.84; p = 0.001; n = 812 respectively). The majority of studies ranked as good methodologic quality on the Newcastle Ottawa Scale.

CONCLUSION

Early tracheostomy in patients with acute traumatic SCI may reduce duration of mechanical entilation, length of intensive care unit stay, and length of hospital stay. Current studies highlight the lack of high-level evidence to guide the optimal timing of tracheostomy in acute traumatic SCI. Future research should seek to understand whether early tracheostomy improves patient comfort, decreases duration of sedation, and improves long-term outcomes.

LEVEL OF EVIDENCE

Systematic Review, level III.

Development of clinical tracheostomy score to identify cervical spinal cord injury patients requiring prolonged ventilator support

BACKGROUND

Cervical spinal cord injuries often necessitate ventilator support (VS). Prolonged endotracheal tube use has conveyed substantial morbidity in prospective study. Tracheostomy is recommended if VS is anticipated to be 7 days or longer, which defines prolonged ventilation (PV). Identifying these patients on arrival and before tracheostomy need is readily evident could prevent morbidity while lowering hospital costs. We aimed to create a tracheostomy score (trach score) to identify patients requiring PV and who could benefit from immediate tracheostomy.

METHODS

A review of patients with cervical spine fractures and cervical spinal cord injuries from 2005 to 2017 from the Pennsylvania Trauma Outcome Study database was performed. Patients were excluded for missing data, no use of VS or death in less than 7 days. Patients were selected for a training set or validation set by state identification number. We used automated forward stepwise selection to select a logistic model. Significant continuous variables were dichotomized to create a simplified screening score (trach score) and this was applied to the validation set.

RESULTS

Needing ventilation for 7 or more days was positively associated with higher Injury Severity Scores having a complete or anterior injury, and having a motor cord injury from C1 to C4. Application of the logistic model to the validation data produced a receiver operating characteristic curve with area under the curve of 0.7712, with 95% confidence limit (CL) of 0.6943 to 0.8481. The validation receiver operating characteristic curve was statistically better than chance using a contrast test with χ with p value less than 0.01. In the validation set, a trach score of 0 correlated to 33% needing PV, a score of 1 with 67% needing PV, 2 with 85%, and 3 with 98%.

CONCLUSION

Use of the trach score identified the majority of patients requiring prolonged VS in our study. An early tracheostomy protocol using predictive modeling could aid in reduction of intensive care unit length of stay and improving ventilator weaning in these patients. External verification of this predictive tool and of an early tracheostomy protocol is needed.

LEVEL OF EVIDENCE

This work is a retrospective prognostic cohort study and meets evidence Level III criteria.

The Impact of Tracheostomy Timing on the Duration and Complications of Mechanical Ventilation

Background:

Mechanical ventilation is a life support for ICU patients and is indicated in case of acute or chronic respiratory failure. 75% of patients admitted to ICU require this support and most of them stay on prolonged MV. Tracheostomy plays a fundamental role in airway management, facilitating ventilator weaning and reducing the duration of MV. Early tracheostomy is defined when the procedure is conducted up to 10 days after the beginning of MV and late tracheostomy when the procedure is performed after this period. Controversy still exists over the ideal timing and classification of early and late tracheostomy.

Objective:

Evaluate the impact of timing of tracheostomy on ventilator weaning.

Method:

Single-center retrospective study. Patients were divided into three groups: very early tracheostomy (VETrach), intermediate (ITrach) and late (LTrach): >10 days.

Results:

One hundred two patients were included: VETrach (n=21), ITrach (n=15), and LTrach (n=66). ITrach group had lower APACHE II (p=0.004) and SOFA (p≤0.001). Total ICU length of stay, and incidence of post-tracheostomy ventilator-associated pneumonia were significantly lower in the VETrach and ITrach groups. The GCS and RASS scores improved in all groups, while the maximal inspiratory pressure and rapid shallow breathing index showed a tendency towards improvement on discharge from the ICU.

Conclusion:

Very early tracheostomy did not reduce the duration of MV or length of ICU stay after the procedure when compared to late tracheostomy, but was associated with low rates of ventilatorassociated pneumonia. Neurological patients benefitted more from tracheostomy, particularly very early and intermediate tracheostomy.

Early Versus Late Tracheostomy in Trauma Patients With Rib Fractures

BACKGROUND

Patients with blunt chest trauma with multiple rib fractures (RF) may require tracheostomy. The goal was to compare early (≤7 d) versus late (>7 d) tracheostomy patients and to analyze clinical outcomes, to determine which timing is more beneficial.

METHODS

This retrospective review included 124 patients with RF admitted to trauma ICU at two level 1 trauma centers who underwent tracheostomy. Analyzed variables included age, gender, injury severity score, Glasgow Coma Scale, number of ribs fractured, total fractures of the ribs, prevalence of bilateral RF, flail chest, maxillofacial injuries, cervical vertebrae trauma, traumatic brain injuries (TBI), coinjuries, epidural analgesia, surgical stabilization of RF, failure to extubate, hospital LOS, intensive care unit LOS (ICULOS), duration of mechanical ventilation, mortality, and timing and type of tracheostomy.

RESULTS

Mean number of RF in all tracheostomized patients with blunt chest trauma was 5.2 and 85% of patients had pulmonary co-injuries. Mean tracheostomy timing was 9.9 d. Early tracheostomy (ET) was correlated with statistically significant reduction in ICULOS and duration of mechanical ventilation. The dominant cause of mortality in all groups was TBI and it was more pronounced in the ET patients. Most deaths were encountered between 3 and 5 wk after admission. ET was more often performed in the operating room with an open technique, whereas late tracheostomy was more often implemented with percutaneous technique at bedside.

CONCLUSIONS

ET could be beneficial in chest trauma patients with multiple RF as it reduces ICULOS and ventilation requirements. Mortality benefits are not correlated with tracheostomy timing.