Fundamentals of Medicinal Chemistry

CH 3

CH 3

CH 3

CH 3

CH 2 CH 3

CH 2 CH 3

CH 3

NH 2

CH 3

NHCOCH 2 N

CH 2 CH 3

NHCOCH 2 N

H

CH 3

CH 3

CH 2 CH 3

NHCOCH 2 N

HO

CH 3

CH 3

NHCOCH 2 NH 2

CH 3

CH 3

CH 2 CH 3

CH 2 CH 3

NHCOCH 2 N

H

HO

HO

COOH

NH 2

CH 3

HO NH 2

CH 3

CH 3

Lignocaine

4-Hydroxy-2,6-dimethylaniline

2,6-Dimethylaniline

Further

metabolites

Further

metabolites

Further

metabolites

Further

metabolites

Hydrolysis

Oxidation

Dealkylation

Oxidation

Oxidation

Oxidation

Hydrolysis

Dealkylation

4-Hydroxy-

2,6-xylidine

3-Hydroxymonoethyl-

glycylxylidide

3-Hydroxylignocaine Glycylxylidide

Monoethylglycylxylidide

Figure 2.5 An outline of the known metabolic pathways of the local anaesthetic lignocaine

its site of action. A slow elimination process can result in a build-up of the drug

concentration in the body. This may benefit the patient in that the dose required

to maintain the therapeutic effect can be reduced, which in turn reduces the

chances of unwanted side effects. Conversely, the rapid elimination of a drug

means that the patient has to receive either increased doses, with a greater risk of

toxic side effects, or more frequent doses, which carries more risk of under- or

over-dosing. The main excretion route for drugs and their metabolites is

through the kidney in solution in the urine. However, a significant number

of drugs and their metabolic products are also excreted via the bowel in the

faeces.

52 AN INTRODUCTION TO DRUGS AND THEIR ACTION