Robust control of burst suppression for medical coma

Abstract: Objective Medical coma is an anesthetic-induced state of brain inactivation, manifest in the electroencephalogram by burst suppression. Feedback control can be used to regulate burst suppression, however, previous designs have not been robust. Robust control design is critical under real-world operating conditions, subject to substantial pharmacokinetic and pharmacodynamic parameter uncertainty and unpredictable external disturbances. We sought to develop a robust closed-loop anesthesia delivery (CLAD) system … Show more

“…The algorithms used in our PCLC device are based on established frameworks for closed-loop control of medically-induced coma[10]–[13]. We use a threshold-based mechanism for EEG artifact reduction[19].…”

“…A previously validated recursive algorithm is used to identify periods of suppression based on EEG variance in real-time[14]. Finally, an algorithm infers BSPs from the binary observations of bursts and suppressions, based on a state-space model of propofol pharmacokinetics and pharmacodynamics (PK-PD)[13]. For control, the inferred BSP is compared with a target BSP provided by the operator of the system.…”

“…The difference between the inferred and target BSP is fed into a robust proportional-integral (PI) controller, which adjusts the infusion rate of propofol. The robust PI controller is tuned for individual patients to optimize performance and minimize sensitivity to disturbances[13]. Patient-specific parameters used for controller design and BSP inference are obtained from the Schnider model of propofol PK and a ramp-drop procedure designed to capture PD characteristics of individuals[13].…”

“…The robust PI controller is tuned for individual patients to optimize performance and minimize sensitivity to disturbances[13]. Patient-specific parameters used for controller design and BSP inference are obtained from the Schnider model of propofol PK and a ramp-drop procedure designed to capture PD characteristics of individuals[13]. Specifically, the Schnider model produces customized PK parameters based on patients’ mass, age, sex and height; and PD modeling uses an iterative least-squares algorithm to find the parameters of a sigmoidal PD curve that describes the BSPs as a function of the steady state propofol concentration in the brain[20].…”

Design, implementation, and evaluation of a physiological closed-loop control device for medically-induced coma

“…The algorithms used in our PCLC device are based on established frameworks for closed-loop control of medically-induced coma[10]–[13]. We use a threshold-based mechanism for EEG artifact reduction[19].…”

“…A previously validated recursive algorithm is used to identify periods of suppression based on EEG variance in real-time[14]. Finally, an algorithm infers BSPs from the binary observations of bursts and suppressions, based on a state-space model of propofol pharmacokinetics and pharmacodynamics (PK-PD)[13]. For control, the inferred BSP is compared with a target BSP provided by the operator of the system.…”

“…The difference between the inferred and target BSP is fed into a robust proportional-integral (PI) controller, which adjusts the infusion rate of propofol. The robust PI controller is tuned for individual patients to optimize performance and minimize sensitivity to disturbances[13]. Patient-specific parameters used for controller design and BSP inference are obtained from the Schnider model of propofol PK and a ramp-drop procedure designed to capture PD characteristics of individuals[13].…”

“…The robust PI controller is tuned for individual patients to optimize performance and minimize sensitivity to disturbances[13]. Patient-specific parameters used for controller design and BSP inference are obtained from the Schnider model of propofol PK and a ramp-drop procedure designed to capture PD characteristics of individuals[13]. Specifically, the Schnider model produces customized PK parameters based on patients’ mass, age, sex and height; and PD modeling uses an iterative least-squares algorithm to find the parameters of a sigmoidal PD curve that describes the BSPs as a function of the steady state propofol concentration in the brain[20].…”

Design, implementation, and evaluation of a physiological closed-loop control device for medically-induced coma

“…Additionally, automated titration of hypnotics and analgesics might decrease the clinician's workload during anaesthesia [54]. Closed-loop administration of propofol was also tested in a rodent animal model to induce coma using burst suppression of the EEG as a controlled variable [55,56].…”

Model-based drug administration

Controlling Level of Unconsciousness by Titrating Propofol with Deep Reinforcement Learning