Video: One-Compartment Model: IV Infusion

IV infusion is suitable when maintenance of constant and stable drug concentration in the body is desired or when the drug poses toxicity risks.

For instance, IV infusion is used for antibiotics, where dosage control is critical.

In a one-compartment model, the rate of change in the amount of drug in the body equals the difference between the infusion and elimination rates, mathematically represented by the given equations.

The steady-state or infusion equilibrium is achieved when the rate of drug infusion equals its elimination rate.

The elimination rate constant, a crucial pharmacokinetic parameter, can be determined from the semilog plasma concentration-time plot, by calculating the slope of the line.

The apparent volume of distribution and total systemic clearance, two critical pharmacokinetic metrics, can be estimated using the steady-state concentration and the infusion rate.

They can also be computed from the total area under the curve until the end of infusion.

Intravenous (IV) infusion is often utilized when continuous and controlled drug delivery is necessary, such as during surgery or in the treatment of chronic diseases. This method offers numerous advantages, including immediate drug action, precise control over dosage, and bypassing the first-pass metabolism.

The one-compartment model for IV infusion uses mathematical equations to describe the rate of change in drug quantity in the body. At steady-state or infusion equilibrium, the drug input equals the drug output, leading to a constant concentration in the body. A semi-logarithmic plot of plasma concentration versus time helps determine the elimination rate constant, k.

In cases where rapid therapeutic concentration is needed, an initial loading dose is administered along with the infusion. The impact of both can be calculated using specific equations. Pharmacokinetic parameters such as volume of distribution (V_d) and half-life (t_1/2) can be determined from k, the elimination rate constant, and clearance. These calculations are crucial in dosage regimen design, ensuring effective and safe drug therapy.

From Chapter 7:

article

Now Playing

7.6 : One-Compartment Model: IV Infusion

Pharmacokinetic Models

92 Views

article

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

Pharmacokinetic Models

44 Views

article

7.2 : Model Approaches for Pharmacokinetic Data: Compartment Models

Pharmacokinetic Models

43 Views

article

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

Pharmacokinetic Models

85 Views

article

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

Pharmacokinetic Models

52 Views

article

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

Pharmacokinetic Models

29 Views

article

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

Pharmacokinetic Models

29 Views

article

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

Pharmacokinetic Models

116 Views

article

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

Pharmacokinetic Models

148 Views

article

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

Pharmacokinetic Models

48 Views

article

7.11 : Multicompartment Models: Overview

Pharmacokinetic Models

48 Views

article

7.12 : Two-Compartment Open Model: Overview

Pharmacokinetic Models

60 Views

article

7.13 : Two-Compartment Open Model: IV Bolus Administration

Pharmacokinetic Models

107 Views

article

7.14 : Two-Compartment Open Model: IV Infusion

Pharmacokinetic Models

123 Views

article

7.15 : Two-Compartment Open Model: Extravascular Administration

Pharmacokinetic Models

86 Views

See More

Copyright © 2025 MyJoVE Corporation. All rights reserved