Physiological agonism and antagonism

Physiological agonism describes the action of a substance which ultimately produces the same effects in the body as another substance—as if they were both agonists at the same receptor—without actually binding to the same receptor. Physiological antagonism describes the behavior of a substance that produces effects counteracting those of another substance (a result similar to that produced by an antagonist blocking the action of an agonist at the same receptor) using a mechanism that does not involve binding to the same receptor.

Examples

Physiological agonists

Epinephrine induces platelet aggregation, and so does hepatocyte growth factor (HGF). Thus, they are physiological agonists to each other.

Physiological antagonists

There are several substances that have antihistaminergic action despite not being ligands for the histamine receptor. For instance, epinephrine raises arterial pressure through vasoconstriction mediated by A1-adrenergic receptor activation, in contrast to histamine, which lowers arterial pressure. Thus, despite not being true antihistamines because they do not bind to and block the histamine receptor, epinephrine and other such substances are physiological antagonists to histamine.

References

Pietrapiana, D; Sala, M; Prat, M; Sinigaglia, F (Aug 15, 2005). "Met identification on human platelets: role of hepatocyte growth factor in the modulation of platelet activation". FEBS Letters. 579 (20): 4550–4. doi:10.1016/j.febslet.2005.06.072. PMID 16083876. S2CID 39722975.

Pharmacology

Ligand (biochemistry)

Excitatory	Agonist Endogenous agonist Irreversible agonist Partial agonist Superagonist Physiological agonist

Inhibitory	Antagonist Competitive antagonist Irreversible antagonist Physiological antagonist Inverse agonist Enzyme inhibitor

Pharmacodynamics

Activity at receptor	Mechanism of action Mode of action Binding Receptor (biochemistry) Desensitization (medicine)

Other effects of ligand	Selectivity (Binding, Functional) Pleiotropy (drugs) Non-specific effect of vaccines Adverse effect Toxicity (Neurotoxicity)

Analysis	Dose–response relationship Hill equation (biochemistry) Schild plot Del Castillo Katz model Cheng-Prussoff Equation Methods (Organ bath, Ligand binding assay, Patch clamp)

Metrics	Efficacy Intrinsic activity Potency (EC50, IC50, ED50, LD50, TD50) Therapeutic index Affinity

Pharmacokinetics

Metrics	Loading dose Volume of distribution (Initial) Rate of infusion Onset of action Biological half-life Plasma protein binding Bioavailability

LADME	(L)ADME: (Liberation) Absorption Distribution Metabolism Excretion (Clearance)

Related
fields

Neuroscience and psychology	Neuropsychopharmacology Neuropharmacology Psychopharmacology Electrophysiology

Medicine	Clinical pharmacology Pharmacy Medicinal chemistry Pharmacoepidemiology

Biochemistry and genetics	Pharmacoinformatics Pharmacogenetics Pharmacogenomics

Toxicology	Pharmacotoxicology Neurotoxicology

Drug discovery	Classical pharmacology Reverse pharmacology

Other

Coinduction (anesthetics)

Combination therapy

Functional analog (chemistry)

Polypharmacology

Chemotherapy

Lists of drugs

WHO list of essential medicines

Tolerance and resistance	Drug tolerance Tachyphylaxis Drug resistance Antibiotic resistance Multiple drug resistance

Antimicrobial pharmacology	Antimicrobial pharmacodynamics Minimum inhibitory concentration Bacteriostatic Minimum bactericidal concentration Bactericide

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