Abstract
Population pharmacokinetic (PK) modeling has become a cornerstone of drug development and optimal patient dosing. This approach offers great benefits for datasets with sparse sampling, such as in pediatric patients, and can describe between-patient variability. While most current algorithms assume normal or log-normal distributions for PK parameters, we present a mathematically consistent nonparametric maximum likelihood (NPML) method for estimating multivariate mixing distributions without any assumption about the shape of the distribution. This approach can handle distributions with any shape for all PK parameters. It is shown in convexity theory that the NPML estimator is discrete, meaning that it has finite number of points with nonzero probability. In fact, there are at most N points where N is the number of observed subjects. The original infinite NPML problem then becomes the finite dimensional problem of finding the location and probability of the support points. In the simplest case, each point essentially represents the set of PK parameters for one patient. The probability of the points is found by a primal-dual interior-point method; the location of the support points is found by an adaptive grid method. Our method is able to handle high-dimensional and complex multivariate mixture models. An important application is discussed for the problem of population pharmacokinetics and a nontrivial example is treated. Our algorithm has been successfully applied in hundreds of published pharmacometric studies. In addition to population pharmacokinetics, this research also applies to empirical Bayes estimation and many other areas of applied mathematics. Thereby, this approach presents an important addition to the pharmacometric toolbox for drug development and optimal patient dosing.
Highlights
Pharmacokinetic studies in healthy volunteers commonly collect multiple observations in each subject
We have provided the first comprehensive description of the Nonparametric adaptive grid (NPAG) algorithm for estimating multivariate mixing distributions
This algorithm can describe between subject variability without assuming any shape for the distribution of PK parameters and is excellently suited for optimizing patient dosing [33,34,35]; NPAG is based on an iterative algorithm employing the Primal-Dual Interior-Point method and an Adaptive Grid method
Summary
Pharmacokinetic studies in healthy volunteers commonly collect multiple observations in each subject. Parametric population modeling algorithms are commonly used and assume typically either normal or log-normal distributions for the between subject variability of PK parameters. Most published algorithms require the {Yi } to be identically distributed and assume that the population model { p(Yi |θi )} is rather simple, such as p(Yi |θi ) is a multivariate normal density with mean vector θi and covariance matrix Σ. We describe the details of our algorithm It was proved by Lindsay [7] and Mallet [8] , under simple hypotheses on the population model { p(Yi |θi )}, that the global maximizer F ML of L( F ) could be represented by a discrete distribution with support on at most N points, i.e., a distribution with nonzero probability located on at most N points.
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