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Mechanism-based pharmacodynamic model for propofol haemodynamic effects in healthy volunteers☆

Hong Su, Douglas J. Eleveld, Michel Struys, Pieter Colin

2022British Journal of Anaesthesia30 citationsDOIOpen Access PDF

Abstract

Background: The adverse haemodynamic effects of the intravenous anaesthetic propofol are well known, yet few empirical models have explored the doseeresponse relationship. Evidence suggests that hypotension during general anaesthesia is associated with postoperative mortality. We developed a mechanism-based model that quantitatively characterises the magnitude of propofol-induced haemodynamic effects during general anaesthesia. Methods: Mean arterial pressure (MAP), heart rate (HR) and pulse pressure (PP) measurements were available from 36 healthy volunteers who received propofol in a step-up and step-down fashion by target-controlled infusion using the Schnider pharmacokinetic model. A mechanistic pharmacodynamic model was explored based on the Snelder model. To benchmark the performance of this model, we developed empirical models for MAP, HR, and PP. Results: The mechanistic model consisted of three turnover equations representing total peripheral resistance (TPR), stroke volume (SV), and HR. Propofol-induced changes were implemented by E max models on the zero-order production rates of the turnover equations for TPR and SV. The estimated 50% effective concentrations for propofol-induced changes in TPR and SV were 2.96 and 0.34 mg ml 1 , respectively. The goodness-of-fit for the mechanism-based model was indistinguishable from the empirical models. Simulations showed that predictions from the mechanism-based model were similar to previously published MAP and HR observations. Conclusions: We developed a mechanism-based pharmacodynamic model for propofol-induced changes in MAP, TPR, SV, and HR as a potential approach for predicting haemodynamic alterations.

Topics & Concepts

PropofolHemodynamicsPharmacodynamicsAnesthesiaMedicineMean arterial pressureStroke volumeHeart ratePharmacokineticsBlood pressurePharmacologyInternal medicineAnesthesia and Sedative AgentsHemodynamic Monitoring and TherapyAnesthesia and Neurotoxicity Research