Titration of the plasma effect site equilibrium rate constant of propofol; a link method of 'Concentration-Probability-Time'

The plasma effect-site equilibrium rate constant (k(e0)) of propofol has been reported in various pharmacodynamic studies; however, it is not desirable to apply k(e0) for the link with pharmacokinetic models that were separately investigated. Thus, we titrated k(e0) for the pharmacokinetic model, wh...

Full description

Saved in:
Bibliographic Details
Published in:Korean journal of anesthesiology 2010, 58(3), , pp.231-238
Main Authors: Kim, Jong-Yeop, Park, Sung-Yong, Park, Sun-Kyung, Kim, Jin-Soo, Min, Sang-Kee
Format: Article
Language:English
Subjects:
anesthesia
Clinical
pharmacodynamics
pharmacokinetics
propofol
target-controlled infusion
마취과학
Citations: Items that this one cites
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The plasma effect-site equilibrium rate constant (k(e0)) of propofol has been reported in various pharmacodynamic studies; however, it is not desirable to apply k(e0) for the link with pharmacokinetic models that were separately investigated. Thus, we titrated k(e0) for the pharmacokinetic model, which is known as the multiple covariates adjusted model of propofol. Ninety female patients scheduled for gynecologic surgery were randomly assigned to three groups targeting different plasma concentrations of 5.4, 8.1, and 10.8 microg/ml. Target-controlled infusions (TCI) were provided by a computer-assisted continuous infusion system. Time to loss of responsiveness (LOR) was measured by a blind investigator; effect-site concentrations (C(e)) for LOR were then calculated with simulation of TCI using different k(e0)s. We determined the k(e0) minimizing total discrepancy (TD) between the inputted and calculated k(e0) from the t(1/2)k(e0)s for a given probability of LOR of the C(e), and also obtained the k(e0) for the minimal TD between the median C(e), which were compared to the known k(e0). K(e0)s from these two methods were 0.3692 and 0.3788/min. C(e)s for LOR with these k(e0)s were significantly different from those with Schnider's k(e0). We proposed a method for titration of the k(e0) of propofol. The k(e0)s of propofol was lower than Schnider's k(e0). An adequate k(e0) for the specific pharmacokinetic model and a certain population would be useful for prediction of an accurate C(e), and could be used for calculation of accurate dosing during targeting of the effect site.
ISSN:2005-6419
2005-7563
DOI:10.4097/kjae.2010.58.3.231