Multicompartment Models: Overview - Concept | Pharmacokinetics and Pharmacodynamics | JoVe

Multicompartment models illustrate how drugs are distributed and eliminated within the body. They offer a more accurate depiction than one-compartment models, which assume instantaneous distribution equilibrium.

These models assume that the body has multiple distinct compartments, each housing its drug concentration.

Highly perfused organs comprise the central compartment, while organs with similar distribution are pooled together to constitute the peripheral compartments.

The distribution between compartments is reversible, and equilibrium is achieved over a finite time.

Drug movement between these compartments and drug input and output rates in every compartment is theorized to follow first-order kinetics.

Multicompartment models facilitate accurate prediction of drug concentrations across different tissues and organs.

They also help understand the impact of disease states or physiological changes on drug distribution and elimination.

In summary, these models offer a comprehensive understanding of how drugs behave within the body.

Multicompartment models are mathematical constructs that depict how drugs are distributed and eliminated within the body. They segment the body into several compartments, symbolizing various physiological or anatomical areas connected through drug transfer processes such as absorption, metabolism, distribution, and elimination.

These models offer a more comprehensive representation of drug behavior in the body than one-compartment models. They accommodate the complexity of drug distribution, consider multiple elimination routes, and can describe drug behavior across different tissues or organs.

Certain assumptions underpin multicompartment models. These include immediate equilibrium in drug distribution between compartments, first-order elimination processes, and plasma drug concentration, which indicates drug concentration across all body tissues.

Multicompartment models have several applications in pharmacokinetics. They help predict drug concentration-time profiles, estimate parameters like clearance and volume of distribution and aid in formulating optimized drug dosing schedules. They prove especially useful for drugs exhibiting complex pharmacokinetics, such as those with wide tissue distribution or multiple elimination pathways.

In summary, multicompartment models offer a detailed and precise depiction of drug behavior within the body, enhancing our understanding and prediction of drug pharmacokinetics.

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Multicompartment Models Drug Distribution Drug Elimination Pharmacokinetics Absorption Metabolism Drug Behavior Tissue Distribution Drug Dosing Clearance Volume Of Distribution Concentration time Profiles First order Elimination Plasma Drug Concentration

From Chapter 7:

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7.11 : Multicompartment Models: Overview

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7.1 : Analysis Methods of Pharmacokinetic Data: Model and Model-Independent Approaches

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7.2 : Model Approaches for Pharmacokinetic Data: Compartment Models

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7.3 : One-Compartment Open Model for IV Bolus Administration: General Considerations

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7.4 : One-Compartment Open Model for IV Bolus Administration: Estimation of Elimination Rate Constant, Half-Life and Volume of Distribution

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7.5 : One-Compartment Open Model for IV Bolus Administration: Estimation of Clearance

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7.6 : One-Compartment Model: IV Infusion

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7.7 : One-Compartment Open Model for Extravascular Administration: Zero-Order Absorption Model

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7.8 : One-Compartment Open Model for Extravascular Administration: First-Order Absorption Model

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7.9 : One-Compartment Open Model: Wagner-Nelson and Loo Riegelman Method for ka Estimation

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7.10 : One-Compartment Open Model: Urinary Excretion Data and Determination of k

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7.12 : Two-Compartment Open Model: Overview

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7.13 : Two-Compartment Open Model: IV Bolus Administration

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7.14 : Two-Compartment Open Model: IV Infusion

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7.15 : Two-Compartment Open Model: Extravascular Administration

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