XPOP - 2016 - Annual activity report

XPOP

XPOP - 2016

Team Xpop

Members

Overall Objectives

Research Program

Application Domains

Highlights of the Year

New Software and Platforms

New Results

Bilateral Contracts and Grants with Industry

Bilateral Contract with Industry

Partnerships and Cooperations

Dissemination

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Publications of the year

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Section: Research Program

The mixed-effects models

Mixed-effects models are statistical models with both fixed effects and random effects. They are well-adapted to situations where repeated measurements are made on the same individual/statistical unit.

Consider first a single subject $i$ of the population. Let $y_{i} = (y_{i j}, 1 \leq j \leq n_{i})$ be the vector of observations for this subject. The model that describes the observations $y_{i}$ is assumed to be a parametric probabilistic model: let $p_{Y} (y_{i}; ψ_{i})$ be the probability distribution of $y_{i}$ , where $ψ_{i}$ is a vector of parameters.

In a population framework, the vector of parameters $ψ_{i}$ is assumed to be drawn from a population distribution $p_{Ψ} (ψ_{i}; θ)$ where $θ$ is a vector of population parameters.

Then, the probabilistic model is the joint probability distribution

p (y_{i}, ψ_{i}; θ) = p_{Y} (y_{i} | ψ_{i}) p_{Ψ} (ψ_{i}; θ)

(1)

To define a model thus consists in defining precisely these two terms.

In most applications, the observed data $y_{i}$ are continuous longitudinal data. We then assume the following representation for $y_{i}$ :

y_{i j} = f (t_{i j}, ψ_{i}) + g (t_{i j}, ψ_{i}) ε_{i j}, 1 \leq i \leq N, 1 \leq j \leq n_{i} .

(2)

Here, $y_{i j}$ is the observation obtained from subject $i$ at time $t_{i j}$ . The residual errors $(ε_{i j})$ are assumed to be standardized random variables (mean zero and variance 1). The residual error model is represented by function $g$ in model (2).

Function $f$ is usually the solution to a system of ordinary differential equations (pharmacokinetic/pharmacodynamic models, etc.) or a system of partial differential equations (tumor growth, respiratory system, etc.). This component is a fundamental component of the model since it defines the prediction of the observed kinetics for a given set of parameters.

The vector of individual parameters $ψ_{i}$ is usually function of a vector of population parameters $ψ_{pop}$ , a vector of random effects $η_{i} \sim 𝒩 (0, Ω)$ , a vector of individual covariates $c_{i}$ (weight, age, gender, ...) and some fixed effects $β$ .

The joint model of $y$ and $ψ$ depends then on a vector of parameters $θ = (ψ_{pop}, β, Ω)$ .

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