Introduction
Approximately 10–15% of patients who are extubated from mechanical ventilation for acute respiratory failure require reintubation. Compared with patients who are successfully extubated, patients who are reintubated have worse clinical outcomes, including prolonged lengths of stay (LOSs) in the intensive care unit (ICU) and hospital, and increased mortality [
1‐
4]. The cause for the increased mortality is not known but has been hypothesized to be either a delay in reintubation or a complication of the endotracheal intubation itself. Alternatively, extubation failure may simply be a marker of disease severity, comorbidities, or an unrecognized underlying disease process. When controlling for disease severity using multivariate analysis, recent studies [
5,
6] found extubation failure to be independently associated with hospital death, although this is not a uniform finding [
7,
8].
To date, the impact of extubation failure on patient outcomes has been studied exclusively in tertiary care, academic hospitals [
1‐
9]. Because most inpatient care occurs in private, community medical centers, the true scope of the importance of extubation failure to patient outcome remains unknown. Moreover, the hospital costs associated with extubation failure have not been fully explored, having only been reported in postoperative vascular surgery patients [
4]. The purpose of the present study was to determine the impact of extubation failure on ICU and hospital mortality, LOS, and total costs in a community hospital ICU.
Methods
Study population
The study was performed by reviewing medical records. The source population included all mechanically ventilated patients admitted to the medical/surgical ICU of a community hospital in Baltimore, Maryland, USA between January 1997 and June 1999 who met the following inclusion criteria: acute respiratory failure as a primary diagnosis; and mechanical ventilation for more than 12 hours. Patients were excluded if they were ventilated noninvasively by mask or via tracheostomy, if extubation occurred inadvertently (unplanned), or if they died or were transferred before extubation. All ICU patients were enrolled in the standardized hospital weaning protocol. Of those in the source population, all patients who failed extubation were included in the study cohort. Of those patients who were successfully extubated, an administrator blinded to the study hypothesis or patient data other than medical record number chose 100 unmatched patients to comprise the control cohort.
Standardized weaning protocol
Mechanical ventilation was discontinued under the direction of one of three board certified critical care physicians, respiratory therapists, and nursing staff. There was no pulmonary or critical care fellowship program in this ICU, and attending physicians provided off-site coverage at night from home.
A previously established hospital protocol to initiate the weaning process included requirements for hemodynamic stability, improvement in underlying medical conditions, reaching a threshold in three respiratory parameters (i.e. arterial oxygen tension/fractional inspired oxygen ratio >200, positive end-expiratory pressure ≤5 cmH2O, minute ventilation ≤12 l), and having a satisfactory cough. Patients were evaluated for these criteria as part of a daily screen performed by respiratory therapists. Spontaneous breathing trials were performed using a T-piece and were continued for up to 2 hours if patients maintained a heart rate under 120 beats/min, pulse oximetry greater than 93% and respiratory rate under 35 breaths/min, and had no dysrhythmia, paradoxic breathing, or use of accessory muscles. If spontaneous breathing trials were not tolerated after 2 days, then patients underwent weaning by gradual decrease in pressure support. Patients were considered for extubation if they tolerated T-piece or ventilatory support of no more than 5 cmH2O continuous positive airway pressure and pressure support of 8 cmH2O for 2 hours on fractional inspired oxygen under 50%. The decision to extubate was made by the intensivist on duty. Criteria for considering reintubation included, but were not limited to, the same criteria used to evaluate weaning trial tolerance.
Definition of variables
The primary exposure in this study was extubation failure, which was defined as reinstitution of mechanical ventilation within 72 hours of extubation. Successful extubation was defined as freedom from mechanical ventilation for 72 hours after extubation. The primary outcome was total ICU LOS (in days) after the initial extubation. Secondary outcomes were total hospital LOS (in days) after the initial extubation, ICU mortality, hospital mortality, and total hospital costs and costs per hospital day, which were estimated by abstracting total hospital charges from electronic billing records on all patients, including both direct and indirect charges. Total charges were divided by the institutional charge/cost ratio during the time period of review (1.21): hospital costs per day = (total hospital charges/total hospital length of stay)/1.21 Other outcome data recorded included ICU discharge disposition (step-down unit, floor, or died) and need for tracheostomy during hospitalization.
Demographic data
Demographic variables were also collected from existing medical records to describe patient groups further. Data obtained included age, sex, and severity of illness by Acute Physiology and Chronic Health Evaluation II score. Etiology of acute respiratory failure was classified as shown in Table
1. The surgical service was recorded as vascular, thoracic, gastrointestinal, orthopedic, or obstetric/gynecologic. Ventilator weaning data obtained included ICU days before the first weaning attempt, and total ventilator days before the first extubation attempt.
Table 1
Classification of etiology of acute respiratory failure
Pulmonary | Upper airway obstruction, acute respiratory distress syndrome, chronic obstructuve pulmonary disease, lobar pneumonia, malignant effusion, aspergilloma, aspiration pneumonitis, lobar collapse, asthma exacerbation, noncardiogenic pulmonary edema |
Cardiac | Congestive heart failure, pericarditis, primary cardiomyopathy, acute myocardial infarction, bacterial endocarditis |
Neurologic | Status epilepticus, cerebral vascular accident, intracranial hemorrhage, convulsion/seizure disorder |
Renal | Acute renal failure |
Other | Liver failure, drug overdose, upper/lower gastrointestinal bleed, diabetic ketoacidosis, sepsis, blood transfusion reaction, vasculitis |
Statistical analysis
Patients who were successfully extubated were compared with the group who failed extubation. Normality of outcome variables was assessed using the Shapiro Wilk test, and results are expressed as mean ± standard deviation or as median (interquartile range), as appropriate. Either the Student's two-tailed t-test or Wilcoxon rank sum test was used to compare the two groups, depending on normality. Odds ratios (ORs) were calculated using unadjusted logistic regression. Multivariate analysis was not performed because of the limited sample size. P < 0.05 was considered statistically significant. Statistical analyses were performed using NCSS, version 2000 (NCSS, Kaysville, UT, USA).
Discussion
This study demonstrates that failed extubation had an adverse impact on clinical outcomes in patients recovering from acute respiratory failure in a community hospital ICU. We found that reintubation increased ICU and hospital LOSs, as well as total hospital costs and cost per hospital day.
In the whole cohort and both medical and surgical subgroups, failed extubation was associated with increased LOS in both the ICU and hospital after the initial extubation (Tables
3 and
4). These findings corroborate data obtained in ICUs at tertiary care centers, and contribute to the available literature by demonstrating the importance of reintubation in the community hospital setting. In an exclusively medical ICU, Epstein and coworkers [
6] found that extubation failure prolonged ICU stay by 17 days after initial extubation, which is greater than the additional 9 days identified in the present study. Similar to our data, Dupont and coworkers [
8] showed that reintubation increased ICU LOS by 9 days in an exclusively surgical population. Variations in postextubation failure LOS between populations are known to correlate with the etiology of extubation failure [
9], with worse outcomes associated with nonairway etiologies. In addition, complications associated with the process of reintubation, such as ventilator-associated pneumonia, may contribute to the need for prolonged intensive care [
10]. These factors were not documented during our review and this is a limitation of our analysis. Failed extubation did not increase post-ICU discharge LOS in this study, despite the increased frequency of transfer to a step-down unit (Table
3); this may be explained by the increased ICU mortality found in reintubated patients.
We found that the increased duration of patient care after failed extubation doubled the total hospital costs and costs per day, as compared with patients who did not require reintubation (Table
3). An analysis of the specific constituents that account for this increase in total costs, such as pharmacy, staff, laboratory, or facility expenses, was beyond the scope of the present study. Our findings in a medical/surgical ICU, however, extend the data presented by Pronovost and coworkers [
4] from a cohort of vascular surgery patients who failed extubation. They found that reintubation resulted in a 20% increase in hospital charges. Both reports present hospital charges as a surrogate for hospital costs, which may not be an accurate reflection of actual cost [
11].
ICU mortality was significantly higher in patients who failed extubation. This is consistent with the findings of Epstein and Ciubotaru [
9], who also reported that sepsis and multiorgan failure were the more common causes of mortality following reintubation. We did not find an association between extubation failure and hospital mortality in our community hospital setting, probably because of limited sample size. This contrasts with findings reported in prior studies performed in some tertiary care centers [
5,
6], but is similar to the findings of others [
7,
8]. In addition, our hospital mortality rates (Table
3) are substantially lower than those reported by Epstein [
6] and Esteban [
5], which may account for the lack of association between extubation failure and hospital death. The reason for the comparatively higher survival rate of medical patients in our hospital is not clear, but it may be due differences in the etiology or timing of reintubation, because these factors have been shown to have an important influence on patient outcomes [
6,
9]. Alternatively, severity of illness or perhaps some unrecognized aspect of the delivery of patient care, which may differ in the community hospital setting, may also account for these findings.
Conclusion
We have demonstrated that extubation failure may be an important ICU complication because of its association with adverse patient outcomes and cost in a community hospital. Through univariate analysis, we corroborated the unfavorable consequences of reintubation, such as increased ICU and hospital LOSs, that were previously reported in tertiary care academic hospitals. Our findings underscore the need for further study of predictive indices of extubation outcome that may help to prevent the substantial morbidity associated with reintubation.
Acknowledgements
We would like to thank Christina Gaughan, MS, of the University of Pennsylvania Center for Clinical Epidemiology and Biostatistics for her advice and expertise, and Donna Casella and Diane Alberter for their assistance with manuscript preparation.
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