The main challenge of anesthesia is the maintenance of the desired sedation level before, during, and after the induction. We developed an in-silico model-based control loop for the administration of an analgesic opioid, remifentanil, and of an anesthetic, propofol. The patients’ response (i.e. the real process) is predicted in-silico by a physiologically-based pharmacokinetic model, conjugated with suitable pharmacodynamic models that simulate the dynamic response of heart rate, arterial pressure, and bispectral index. We simulated the induction phase of anesthesia and obtained a fast and safe patient's response by setting the arterial pressure and bispectral index as controlled variables, and implementing proper bounds on both the plasma concentration and the controlled variables.
Model predictive control for automated anesthesia
Savoca A.;Barazzetta J.;Pesenti G.;Manca D.
2018-01-01
Abstract
The main challenge of anesthesia is the maintenance of the desired sedation level before, during, and after the induction. We developed an in-silico model-based control loop for the administration of an analgesic opioid, remifentanil, and of an anesthetic, propofol. The patients’ response (i.e. the real process) is predicted in-silico by a physiologically-based pharmacokinetic model, conjugated with suitable pharmacodynamic models that simulate the dynamic response of heart rate, arterial pressure, and bispectral index. We simulated the induction phase of anesthesia and obtained a fast and safe patient's response by setting the arterial pressure and bispectral index as controlled variables, and implementing proper bounds on both the plasma concentration and the controlled variables.| File | Dimensione | Formato | |
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