PROJECT SUMMARY/ABSTRACT Acute respiratory failure (ARF) requiring invasive ventilation occurs in one-third of intensive care unit (ICU) patients and is associated with a high risk of death. Ventilation-induced lung injury (VILI) is a modifiable determinant of ARF outcomes that develops when the at-risk lung experiences excessive global or regional stress/strain. VILI may result from excessive forces applied by the ventilator and/or respiratory muscles. Optimizing ventilator titration has been studied extensively, while far less is known about the contribution of spontaneous breathing effort to VILI in ARF. High respiratory drive can cause injuriously high tidal volumes, increasing global stress/strain either with synchronous effort or breath stacking dyssynchrony depending on ventilator mode. High drive also causes temporally heterogeneous insufflation, increasing intra-tidal regional strain for a given tidal volume. Both patterns of respiratory drive-related increase in stress/strain worsen lung injury in preclinical models and have been observed in patients with ARF, but whether they contribute clinically meaningful lung injury in patients is unclear. Extremes of drive, high or low, also may cause clinically relevant diaphragm injury. High drive risks load-induced injury, particularly in flow-limited ventilator modes or certain patient-ventilator dyssynchronies in which inspiratory support ends prematurely relative to patient effort. Low drive risks diaphragm disuse atrophy, proven to occur in some patients within a few days on the ventilator. Causes of drive heterogeneity in ARF are not well established. Chemoreceptor, mechanoreceptor, and cortical inputs (e.g. pain, anxiety) are well established modulators of respiratory drive, but they alone do not fully explain drive heterogeneity in ARF. Although deep sedation often suppresses respiratory drive in healthy individuals, we recently found that sedation depth and respiratory drive are not well correlated in ARF. Many patients exhibit high drive refractory to deep sedation, while in others even light sedation can completely eliminate drive. Our preliminary data suggest differences in systemic inflammation might explain this drive heterogeneity. This research will deepen understanding of mechanisms underlying drive heterogeneity and its relationship with clinical outcomes in patients with ARF. Our overall hypothesis is that systemic inflammation is a key determinant of respiratory drive, extremes of which cause clinically important lung and diaphragm injury. We will assemble a prospective two-hospital, multi-ICU cohort in whom respiratory mechanics and serum biomarkers are ascertained serially. Aim 1 evaluates circulating inflammatory markers as a potential contributor to drive heterogeneity. Aim 2 determines mechanisms by which extremes of respiratory drive may contribute to lung and diaphragm injury. Aim 3 evaluates the relationship between respiratory drive and time to extubation. Findings f...