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Drug interaction
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Drug interaction
In pharmaceutical sciences, drug interactions occur when a drug's mechanism of action is affected by the concomitant administration of substances such as foods, beverages, or other drugs. A popular example of drug–food interaction is the effect of grapefruit on the metabolism of drugs.
Interactions may occur by simultaneous targeting of receptors, directly or indirectly. For example, both Zolpidem and alcohol affect GABAA receptors, and their simultaneous consumption results in the overstimulation of the receptor, which can lead to loss of consciousness. When two drugs affect each other, it is a drug–drug interaction (DDI). The risk of a DDI increases with the number of drugs used.
A large share of elderly people regularly use five or more medications or supplements, with a significant risk of side-effects from drug–drug interactions.
Drug interactions can be of three kinds:
It may be difficult to distinguish between synergistic or additive interactions, as individual effects of drugs may vary.
Direct interactions between drugs are also possible and may occur when two drugs are mixed before intravenous injection. For example, mixing thiopentone and suxamethonium can lead to the precipitation of thiopentone.
Pharmacodynamic interactions are the drug–drug interactions that occur at a biochemical level and depend mainly on the biological processes of organisms. These interactions occur due to action on the same targets; for example, the same receptor or signaling pathway.
Pharmacodynamic interactions can occur on protein receptors. Two drugs can be considered to be homodynamic, if they act on the same receptor. Homodynamic effects include drugs that act as (1) pure agonists, if they bind to the main locus of the receptor, causing a similar effect to that of the main drug, (2) partial agonists if, on binding to a secondary site, they have the same effect as the main drug, but with a lower intensity and (3) antagonists, if they bind directly to the receptor's main locus but their effect is opposite to that of the main drug. These may be competitive antagonists, if they compete with the main drug to bind with the receptor. or uncompetitive antagonists, when the antagonist binds to the receptor irreversibly. The drugs can be considered heterodynamic competitors, if they act on distinct receptor with similar downstream pathways.
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Drug interaction
In pharmaceutical sciences, drug interactions occur when a drug's mechanism of action is affected by the concomitant administration of substances such as foods, beverages, or other drugs. A popular example of drug–food interaction is the effect of grapefruit on the metabolism of drugs.
Interactions may occur by simultaneous targeting of receptors, directly or indirectly. For example, both Zolpidem and alcohol affect GABAA receptors, and their simultaneous consumption results in the overstimulation of the receptor, which can lead to loss of consciousness. When two drugs affect each other, it is a drug–drug interaction (DDI). The risk of a DDI increases with the number of drugs used.
A large share of elderly people regularly use five or more medications or supplements, with a significant risk of side-effects from drug–drug interactions.
Drug interactions can be of three kinds:
It may be difficult to distinguish between synergistic or additive interactions, as individual effects of drugs may vary.
Direct interactions between drugs are also possible and may occur when two drugs are mixed before intravenous injection. For example, mixing thiopentone and suxamethonium can lead to the precipitation of thiopentone.
Pharmacodynamic interactions are the drug–drug interactions that occur at a biochemical level and depend mainly on the biological processes of organisms. These interactions occur due to action on the same targets; for example, the same receptor or signaling pathway.
Pharmacodynamic interactions can occur on protein receptors. Two drugs can be considered to be homodynamic, if they act on the same receptor. Homodynamic effects include drugs that act as (1) pure agonists, if they bind to the main locus of the receptor, causing a similar effect to that of the main drug, (2) partial agonists if, on binding to a secondary site, they have the same effect as the main drug, but with a lower intensity and (3) antagonists, if they bind directly to the receptor's main locus but their effect is opposite to that of the main drug. These may be competitive antagonists, if they compete with the main drug to bind with the receptor. or uncompetitive antagonists, when the antagonist binds to the receptor irreversibly. The drugs can be considered heterodynamic competitors, if they act on distinct receptor with similar downstream pathways.
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