1. Drug action and receptors Dave Hallsworth, StR2 SMH
2. “Tell me how drugs exert their action on the body.”
3. Simples! A drug is an exogenous agent administered to create a physiological effect dependant on:
Physicochemical properties of the drug,
Enzyme inhibition, or
Receptor interaction
4. Physicochemical properties Manitol – plasma tonicity
Antacids – e.g. Sodium citrate
Chelating agents – eg. Penicillamine in Wilson’s disease and mercury poisoning.
5. Enzyme inhibition Increase the concentration of substrates and decrease the level of products, e.g.
ACEi
AChE inhibitors
NSAIDs
6. Receptor binding “What is a receptor?”
A receptor is a protein molecule which is usually located in the cell membrane and contains a specific ligand binding site. Binding of a ligand initiates a conformation change in the receptor-ligand complex, leading to a physiological action.
In broad terms, ligand binding either opens an ion channel or activates a second messenger system.
There are also ‘intracellular receptors’ not bound to the membrane. Ligand binding opens a DNA / RNA binding domain and causes changes in gene transcription / translation.
7. When Vivas �go bad.... What can you tell me about drug-receptor interactions....?
8. Drug-receptor interaction The two properties of a drug that determine the nature of its interaction with the receptor are it’s:
AFFINITY
This is how avidly the ligand binds the receptor
At equilibrium
INTRINSIC ACTIVITY (IA)
Refers to the magnitude of effect the drug has when bound and takes a value between 0 and 1 (an inverse agonist may have a value of -1; more later.......)
9. What is an agonist? An agonist has significant receptor affinity and full intrinsic activity (IA=1) i.e. causes a maximal response
10. Dose-response curve
Hyperbolic
Dose for 50% receptor occupance = Ka or EC50
Log[dose]-response curve
Semi-logarithhmic
Sigmoidal
Allows comparison of drugs
How does potency affect the curve? What is it?
How does efficacy effect the curve? What is it?
11. Potency
Reciprocal of EC50
Increasing potency
shifts left
Efficacy
Analogous to
maximal effect
12. What is a partial agonist? A partial agonist has significant receptor affinity, but only partial intrinsic activity.
Maximum response not
never elicited despite
increasing concentration
and full receptor occupancy
e.g. Buprenorphine
acting at the OP3 receptor
13. So a partial agonist always acts as an ‘agonist’? True? NO!
Partial agonist alone = yes
Partial agonist + low dose
full agonist = yes
Partial agonist + high
dose of full agonist
= NO!!
15. What is an inverse agonist? Inverse agonists have a significant receptor affinity and IA, but their effect is OPPOSITE to the endogenous agonist.
-1 < IA < 0
Example: atropine, certain benzodiazepines
Muscarinic receptors have a constitutive activity. An agonist ‘activates’ the receptor (muscarinic effect). An inverse agonist ‘deactivates’ the receptor (anti-muscarinic effects)
16. What is an inverse agonist?
17. What is an antagonist? Define and classify. Antagonists can be:
Chemical, e.g. Dexferrioxamine and iron
Pharmacokinetic, e.g. Rifampicin and OCP
Pharmacodynamic, occurring at a:
Common receptor
Irreversible
Reversible
Competitive
Non-competitive
Allosteric modulators
Different receptor (e.g. physiological antagonism)
Common receptor antagonists have significant receptor affinity but an intrinsic activity of zero
18. Competitive reversible antagonism Antagonist competes with same receptor site, but their effect can be overcome by increasing the concentration of agonist
e.g. Non-depolarising muscle relaxants, beta-blockers and norad
Log[dose] vs response
curve is shifted to the
right
pA2 value = -log[conc]
of antagonist required to
produce dose ratio of 2
19. Rocuronium is 1/5th as potent as vecuronium but in our daily practice is faster acting. Why?
Because it is given in 5x the dose (0.5mg/kg versus 0.1mg/kg; an equipotent dose), therefore there is a higher concentration gradient driving molecules into the NMJ (Roc&Vec have a similar VD) and greater concentration at the synaptic cleft.
‘Bowman’s Principle’
20. Non-competitive reversible antagonists Bind at a different receptor site and cause a conformational change.
Action cannot be overcome
by increasing [agonist]
Example
ketamine antagonises glutamate
at the NMDAR
21. Allosteric modulators Not all drugs fit the categorisation!
Some bind at sites distant to the agonist but still modulate the agonist binding
These may have negative or positive effects
Example: benzodiazepines are positive allosteric modulators of GABA at the GABAA receptor
22. Irreversible antagonists May bind at the same or distant site but do not dissociate and cannot be overcome by increasing the agonist concentration.
Effect is terminated by synthesising a new receptor molecule.
Examples
Phenoxybenzamine at the alpha-receptor
Aspirin at the COX-1 receptor
23. Tachyphylaxis, desensitisation and tolerance They are not addiction!
Tachyphylaxis
Rapid decrease in response over a short period of time
Usually due to depletion of transmitter
Ephedrine (indirect sympathomimetic) depletes
noradrenaline stores
Desensitisation
Loss of response over a longer period
May be due to change in receptor numbers
or modulation of affinity
E.g. Loss of myocardial beta-receptors with
chronic exposure to adrenaline or dobutamine
24. Tolerance
Refers to the phenomenon whereby larger doses of the agonist is required to create the same response.
E.g. Chronic opioid use
