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This study aims to better understand how short periods of exposure to high oxygen levels affect blood flow in the brain of patients who are intubated and mechanically ventilated in the Intensive Care Unit (ICU). Many ICU patients receive more oxygen than strictly necessary, and high blood oxygen levels (hyperoxemia) are very common. However, the immediate effects of short hyperoxic exposures on cerebral circulation and autoregulation remain poorly understood.
In this study, patients who already require mechanical ventilation for medical reasons will undergo a brief and controlled increase in the oxygen delivered through the ventilator (FiO₂). During this time, we will continuously monitor blood flow in one of the main brain arteries using a non-invasive ultrasound technique called transcranial Doppler (TCD). The goal is to evaluate how cerebral blood flow, pulsatility, and autoregulatory capacity change during and after a short hyperoxic stimulus.
No additional invasive procedures are required beyond standard ICU monitoring, except for the temporary adjustment of the ventilator's oxygen settings and arterial blood gas sampling, which are part of usual care in critically ill patients. Participation does not provide direct clinical benefit but may help improve future oxygen management in ICU patients. The study involves minimal risk, as short hyperoxic exposures are already common in routine care and will be interrupted immediately in case of any adverse event.
Full description
Patients will be studied under controlled mechanical ventilation with stable ventilatory, hemodynamic, and sedative settings. Continuous transcranial Doppler (TCD) monitoring will be performed using a 2-MHz probe insonating the middle cerebral artery through the temporal bone window. Cerebral blood flow velocity signals and arterial blood pressure waveforms will be recorded continuously for offline analysis.
The experimental protocol consists of stepwise increases in the fraction of inspired oxygen (FiO₂), according to baseline oxygen requirements. Patients with a baseline FiO₂ < 0.5 will undergo two consecutive hyperoxic steps (FiO₂ 0.5 followed by FiO₂ 1.0), whereas patients with a baseline FiO₂ ≥ 0.5 will undergo a single hyperoxic step (FiO₂ 1.0). Each hyperoxic step will include a stabilization period of approximately 5 minutes to allow attainment of a physiological steady state, followed by a 10-minute recording period dedicated to cerebral hemodynamic and autoregulation assessment. After completion of the hyperoxic exposure(s), FiO₂ will be returned to baseline values. In total, there will be 3 or 4 steps, depending on the baseline FiO₂.
Arterial blood gas samples will be obtained at baseline, at the end of each hyperoxic step, and after return to baseline oxygen settings to document changes in arterial oxygen and carbon dioxide tensions. Ventilation parameters, sedation, vasoactive drug infusion rates, and fluid therapy will be kept constant throughout the protocol whenever clinically feasible.
Cerebral hemodynamic assessment will include mean flow velocity, pulsatility index, and resistive index derived from TCD signals. Dynamic cerebral autoregulation will be evaluated using established indices (the mean flow index (Mxa), transfer function analysis (TFA) parameters, autoregulation index (ARI)), and metrics derived from spontaneous fluctuations in arterial blood pressure and cerebral blood flow velocity.
Analyses will primarily rely on paired statistical methods. Exploratory subgroup analyses according to baseline oxygen requirements, illness severity, or relevant comorbidities may be conducted.
Patient safety will be continuously monitored throughout the protocol, and the procedure will be immediately discontinued in case of any clinical instability, including hemodynamic deterioration, arrhythmias, or oxygenation abnormalities.
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80 participants in 1 patient group
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Michele Salvagno, MD
Data sourced from clinicaltrials.gov
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