Phase I Reactions: Hydrolytic Reactions - Concept | Pharmacokinetics and Pharmacodynamics | JoVe

Hydrolysis is a chemical process where a compound is decomposed by reacting with water without altering its oxidation state.

This process plays a vital role in phase I biotransformation reactions, enhancing the hydrophilicity of xenobiotics.

Hydrolysis of esters involves enzymatic cleavage of the ester bonds to yield more soluble alcohols and acids. Aspirin, for instance, undergoes hydrolysis to form salicylic acid.

Amide drugs such as lidocaine also undergo hydrolytic reactions, where the amide bond is cleaved.

Hydrazide compounds like isocarboxazid are hydrolyzed to benzyl hydrazine.

Nonaromatic heterocycles containing amide groups or lactams undergo hydrolysis involving the disruption of the heterocyclic ring. An instance of this is the hydrolysis of chlordiazepoxide to an open-ring derivative.

Hydrolytic dehalogenation refers to the removal of a halogen atom from a compound. DDT, for example, is dehalogenated to DDE.

Hydrolysis, a cornerstone of phase I biotransformation reactions, uses water to cleave chemical bonds. This process is pivotal in drug metabolism, generating more polar metabolites that can be easily excreted.

An important hydrolytic reaction is ester hydrolysis. Ester bonds, often found in prodrugs, are broken down, increasing the solubility of drugs like aspirin and lidocaine for more straightforward elimination. Amide hydrolysis is another critical reaction, targeting amide bonds prevalent in numerous drugs. Secondary amides like acetaminophen and tertiary amides like lidocaine undergo hydrolysis, resulting in corresponding carboxylic acids and amines. Hydrazides like isoniazid also experience hydrolysis, yielding carboxylic acid and hydrazine.

Nonaromatic heterocycles, including imidazoles and pyrazoles, can also be hydrolyzed. For instance, metronidazole transforms into the respective carboxylic acid and alcohol through hydrolysis. Hydrolytic dehalogenation, removing a halogen atom from a molecule, represents another hydrolytic mechanism. Chloramphenicol, for example, can be hydrolyzed into its corresponding carboxylic acid and alcohol. Miscellaneous hydrolytic reactions extend to the hydrolysis of thioesters like captopril, which transforms into the respective carboxylic acid and thiol.

Hydrolysis significantly contributes to phase I biotransformation reactions in drug metabolism. The process enhances the polarity and solubility of metabolites, facilitating their excretion and playing an indispensable role in drug elimination.

Tags

Phase I Reactions Hydrolytic Reactions Hydrolysis Drug Metabolism Ester Hydrolysis Amide Hydrolysis Carboxylic Acids Acetaminophen Lidocaine Hydrazides Metronidazole Hydrolytic Dehalogenation Chloramphenicol Thioesters Drug Elimination

Dal capitolo 5:

article

Now Playing

5.6 : Phase I Reactions: Hydrolytic Reactions

Pharmacokinetics: Drug Biotransformation

49 Visualizzazioni

article

5.1 : Drug Biotransformation: Overview

Pharmacokinetics: Drug Biotransformation

184 Visualizzazioni

article

5.2 : Phase I Oxidative Reactions: Overview

Pharmacokinetics: Drug Biotransformation

213 Visualizzazioni

article

5.3 : Phase I Reactions: Oxidation of Aliphatic and Aromatic Carbon-Containing Systems

Pharmacokinetics: Drug Biotransformation

116 Visualizzazioni

article

5.4 : Phase I Reactions: Oxidation of Carbon-Heteroatom and Miscellaneous Systems

Pharmacokinetics: Drug Biotransformation

48 Visualizzazioni

article

5.5 : Phase I Reactions: Reductive Reactions

Pharmacokinetics: Drug Biotransformation

160 Visualizzazioni

article

5.7 : Phase II Conjugation Reactions: Overview

Pharmacokinetics: Drug Biotransformation

116 Visualizzazioni

article

5.8 : Phase II Reactions: Glucuronidation

Pharmacokinetics: Drug Biotransformation

177 Visualizzazioni

article

5.9 : Phase II Reactions: Sulfation and Conjugation with α-Amino Acids

Pharmacokinetics: Drug Biotransformation

129 Visualizzazioni

article

5.10 : Phase II Reactions: Glutathione Conjugation and Mercapturic Acid Formation

Pharmacokinetics: Drug Biotransformation

106 Visualizzazioni

article

5.11 : Phase II Reactions: Acetylation Reactions

Pharmacokinetics: Drug Biotransformation

137 Visualizzazioni

article

5.12 : Phase II Reactions: Methylation Reactions

Pharmacokinetics: Drug Biotransformation

83 Visualizzazioni

article

5.13 : Phase II Reactions: Miscellaneous Conjugation Reactions

Pharmacokinetics: Drug Biotransformation

28 Visualizzazioni

article

5.14 : Factors Affecting Drug Biotransformation: Physicochemical and Chemical Properties of Drugs

Pharmacokinetics: Drug Biotransformation

127 Visualizzazioni

article

5.15 : Factors Affecting Drug Biotransformation: Biological

Pharmacokinetics: Drug Biotransformation

79 Visualizzazioni

Copyright © 2025 MyJoVE Corporation. Tutti i diritti riservati