Pharmacology DEFINITIONS: Pharmacology is the study of how drugs exert
their effects on living systems.Pharmacologists work to identify drug targets in order to learn how drugs work. Pharmacologists also study the ways in which drugs are modified within organisms. In most of the pharmacologic specialties, drugs are also used today as tools to gain insight into both normal and abnormal function.
Pharmacology
Divisions of Pharmacology• Pharmacokinetics• Pharmacodynamics• Pharmacogenomics
Pharmacokinetics
Is what the body does to the drug. The magnitude of the pharmacological effect of a drug depends on its concentration at the site of action.
• Absorption• Distribution• Metabolism• Elimination
Pharmacodynamics
Is what the drug does to the body. Interaction of drugs with cellular proteins, such as receptors or enzymes, to control changes in physiological function of particular organs.
• Drug-Receptor Interactions– Binding
• Dose-Response– Effect
• Signal Transduction– Mechanism of action, Pathways
Pharmacogenetics
Area of pharmacology concerned with unusual responses to drugs caused by genetic differences between individuals. Responses that are not found in the general population, such as general toxic effects, allergies, or side effects, but due to an inherited trait that produces a diminished or enhanced response to a drug.
• Differences in Enzyme Activity– Acetylation polymorphism– Butylcholinesterase alterations– Cytochrome P450 aberration
Drugs
Drugs can be defined as chemical agents that uniquely interact with specific target molecules in the body, thereby producing a biological effect.
Drugs can be stimulatory or inhibitory
Drugs
• Drugs, as well as hormones, neurotransmitter, autocoids and toxins can make possible the transfer of information to cells by interaction with specific receptive molecules called “receptors”.
Receptor
DRUG
Drugs
• Drugs interact with biological systems in ways that mimic, resemble or otherwise affect the natural chemicals of the body.
• Drugs can produce effects by virtue of their acidic or basic properties (e.g. antacids, protamine), surfactant properties (amphotericin), ability to denature proteins (astringents), osmotic properties (laxatives, diuretics), or physicochemical interactions with membrane lipids (general and local anesthetics).
ReceptorsMost drugs combine (bind) with specific receptorsto produce a particular response. This association or binding takes place by precise physicochemical and steric interactions between specific groups of the drug and the receptor.
1. Proteins a. Carriersb. Receptors
i. G protein-linked ii. Ligand gated channelsiii. Intracellular
c. Enzymes2. DNA
Endogenous compounds act on their Receptors
Neurotransmitter
Neuropeptides
Hormones
Ions
Receptor
1) PharmacologicalMediator (i.e. Insulin, Norepinephrine, estrogen)
2) Biophysical and BiochemicalSecond messenger system (i,.e. cAMP, PLC, PLA)
3) Molecular or StructuralSubunit composition (i.e. 5HT1A )
4) AnatomicalTissue (i.e muscle vs ganglionic nAChRs)Cellular (i.e. Membrane bound vs Intracellular)
Classification of Receptors
Types of ReceptorsMEMBRANE BOUND RECEPTORS• G-Protein-linked receptors
Serotonin, Muscarinic, Dopaminergic, Noradrenergic• Enzyme receptors
Tyrosine kinase• Ligand-gated ion channel receptors
Nicotinic, GABA, glutamate
INTRACELLULAR AND NUCLEAR RECEPTORS• Hormone receptors • Autocoid receptors• Growth factors receptors• Insulin receptors
G Protein–linked Receptors
Enzyme-like Receptors
Ligand-gated Ion-Channel Receptors
Nuclear Receptors
Drug-Receptor Interactions
1) Lipophilic2) Hydrophilic3) Ionic4) Hydrogen bonds5) Steric (stereospecificity) effects6) Electronic effect7) pK effects
Physicochemical and steric interactions
Drug-Receptor InteractionsChemical Bonds
Van der Waals Interactions
Hydrophobic Interactions
Drug-Receptor Interactions•Drug-receptor interactions serve as signals to trigger a cascade of events. This cascade or signaling pathway, is a collection of many cellular responses which serve to amplify the signal and produce a final effect.
•Effectors are thus the molecules that translate the drug-receptor interaction into changes in cellular activity.
+ EFFECT DRUG DRUG + RECEPTOR DRUG + RECEPTOR EFFECTOR EFFECTOR INTERACTION COMPLEX SYSTEM
STIMULUS BINDING ACTIVATION TRANSDUCTION AMPLIFICATION RESPONSE
SIGNALLING PATHWAY
Receptor Signaling Pathways
Second Messengers:1. Ions (Ca2+, Na+, K+, Cl-)2. cAMP, cGMP, IP3, Diacylglycerol3. DNA binding – Transcriptional regulation.4. Phosphorylated proteins and enzymes via
tyrosine kinase receptors.
Third Messengers:5. Enzymes (PKC, PKA)6. Ions (Ca2+, K+)
Receptor Signaling Pathways
Adenylate Cyclase (AC)
Guadenylyl Cyclase (GC)
Phospholipase C (PLC)
Phospholipase A (PLA2)
Nitric oxide Synthase
Ions
cAMP
cGMP
DAG and IP3
Arachidonic acid
NO and CO
Na+, Ca2+
, K+
, Cl-
EFFECTORSSECOND
MESSENGER
Receptor Signaling Pathways
R R R R
Receptor Signaling Pathways
Drug-Receptor InteractionsTheory and assumptions of drug-receptor interactions.• Drug Receptor interaction follows simple mass-action
relationships, i.e. only one drug molecule occupies each receptor and binding is reversible (We know now there are some exceptions).
• For a given drug the magnitude of the response is proportional to the fraction of total receptor sites occupied by drug molecules.
• Combination or binding to receptor causes some event which leads to a response.
• Response to a drug is graded or dose-dependent.
Law of Mass Action
When a drug (D) combines with a receptor (R), it does so at a rate which is dependent on the concentration of the drug and the concentration of the receptor.
D = drugR = receptorDR = drug-receptor complexk1 = rate for associationk2 = rate for dissociationKD = Dissociation ConstantKA = Affinity Constant
k2
[D] + [R] [DR] k1
k1 = KD = [DR]
k2 [D][R]
1 = KA = k2 = [D][R] KD k1 [DR]