The goal of this study is to design a pilot trial evaluating the safety, feasibility, pharmacokinetic modeling, and physiological effects of a volatile anesthetic, sevoflurane, directly administered in extracorporeal membrane oxygenation machines.
Venovenous extracorporeal membrane oxygenation (VV-ECMO) is a life-saving therapy for catastrophic respiratory failure, including severe COVID-19. Optimal drug dosing in critically ill patients is challenging due to concomitant organ dysfunction, and with the addition of ECMO, the level of complexity significantly increases. ECMO PK interactions with intravenous (IV) sedatives are complex and therapeutic failures are often encountered, highlighting the need for alternative sedation strategies. To overcome these limitations, volatile anesthetics are a potential solution for sedation and analgesia. Nevertheless, their use has been limited during ECMO support due to the low respiratory volumes associated with the lung-protective strategies, and the concerns of bioavailability given the compromised native lung function. The overarching aim of this project is to evaluate a strategy to mitigate the influence of ECMO on sedatives pharmacokinetics, using volatile anesthetics directly vaporized into ECMO oxygenators. The study will consist of two phases: the ex-vivo trial an the in-vivo trial. For the ex-vivo trial, two ECMO circuits primed with Ringer's lactate will be used to design the dosing recommendations for the feasibility trial. Vaporized sevoflurane will be delivered directly into the membrane oxygenator with the ECMO gas and evacuated through the wall suction. Sevoflurane concentrations will be monitored with an infrared multi-gas analyzer sensor at the ECMO gas outlet. The test will be performed with different sweep flows and sevoflurane concentrations. Sevoflurane concentrations will be measured in the fluid to design a dosing model to conduct the in-vivo trial. The in-vivo trial will be a prospective, single-center, open-label, pilot feasibility/PK study of 10 patients receiving venovenous ECMO (VV ECMO) in the Medical-Surgical Intensive Care Unit (MSICU) at the Toronto General Hospital. Following informed consent, these patients will be enrolled and managed with sevoflurane-based anesthesia directly delivered into the ECMO machine. During their ECMO run, samples will be taken and sevoflurane concentrations analyzed with headspace gas chromatography and mass spectrometry. Sedation scales, surrogates of respiratory dynamics and effort, and biotrauma inflammatory cytokines levels will be obtained at the same time.
Study Type
INTERVENTIONAL
Allocation
NA
Purpose
TREATMENT
Masking
NONE
Enrollment
10
Sevoflurane will be directly vaporized into the ECMO machine through the sweep gas.
Sevoflurane plasma concentrations
Plasma concentrations of sevoflurane will be measured with gas chromatography and mass spectrometry
Time frame: 7 days
Percentage of sevoflurane in ECMO exhausted gas
The volume/volume percentage of sevoflurane will be measured with an infrared multi-gas analyzer sensor at the sweep gas outlet
Time frame: 7 days
Respiratory dynamics and respiratory effort
Driving pressure, occlusion pressure, and P0.1 pressures will be measured with the patients mechanical ventilator daily
Time frame: 7 days
Plasma levels of ventilator-induced lung injury biomarkers
As a surrogate for ventilator-induced lung injury, plasma levels of interleukins 6 and 8, and necrosis tumor factor will be measured daily
Time frame: 7 days
Required doses of sedative adjuvants
The doses of other sedatives and analgesics, including opioids, antipsychotics, benzodiazepines, ketamine and propofol will be recorded
Time frame: 7 days
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