Combined effects of Drugs, Pharmacology
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Jul 27, 2014
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About This Presentation
Combined effects of Drug action, Pharmacology
Slide Content
COMBINED EFFECTS OF DRUGS
By:
Dr. Dhruva Kumar Sharma
Department of Pharmacology
Moderator:
Dr. Supratim Datta
Associate Professor
Department of Pharmacology
SMIMS
By:
Dr. Dhruva Kumar Sharma
Department of Pharmacology
Moderator:
Dr. Supratim Datta
Associate Professor
Department of Pharmacology
SMIMS
Protocol:
Summation
Additive effects
Synergism
Drug antagonism
2
Summation
Additive effects
Synergism
Drug antagonism
2
EFFECT OF COMBINATION OF DRUGS
Combinations of two/ more drugs, simultaneously or
in quick succession
1.No interference with each other’s effects.
2.May oppose each other’s actions (antagonism)
3.May produce similar actions on the same organ
(synergism)
Combinations of two/ more drugs, simultaneously or
in quick succession
1.No interference with each other’s effects.
2.May oppose each other’s actions (antagonism)
3.May produce similar actions on the same organ
(synergism)
Interaction
Pharmacokinetic Pharmacodynamic
Pharmacokinetic Pharmacodynamic
Drug Synergism
Syn- together ; ergon- work
Syn- together ; ergon- work
Drug Synergism:
This is facilitation of the effects of one drug
by another when given together
Types:
a.Additive (summation)
b.Supra-additive (Potentiation)
This is facilitation of the effects of one drug
by another when given together
Types:
a.Additive (summation)
b.Supra-additive (Potentiation)
Summation /Addition
Effect of drugs A + B = Effect of drug A + Effect of drug B
•Final effect is same as the algebraic sum of the
magnitude of individuals drugs
•Side effects do not add up
Examples of Summation: Different MOA
Aspirin : (-) PG synthesis analgesia +
Codeine : Opioid agonist analgesia +
Examples of Addition: Same MOA
Ibuprofen: (-) PG synth analgesia +
Paracetamol: (-) PG synth analgesia+
Analgesia
++
Analgesia
++
Effect of drugs A + B = Effect of drug A + Effect of drug B
•Final effect is same as the algebraic sum of the
magnitude of individuals drugs
•Side effects do not add up
Examples of Summation: Different MOA
Aspirin : (-) PG synthesis analgesia +
Codeine : Opioid agonist analgesia +
Examples of Addition: Same MOA
Ibuprofen: (-) PG synth analgesia +
Paracetamol: (-) PG synth analgesia+
Analgesia
++
Analgesia
++
Other Additive Drug Combinations
Drug
Combination
Effect
Amlodipine +
Atenolol
Antihypertensive
Glibenclamide +
Metformin
Hypoglycemic
Drug
Combination
Effect
Amlodipine +
Atenolol
Antihypertensive
Glibenclamide +
Metformin
Hypoglycemic
Supraadditive ( Potentiation)
Effect of drug A + B > Effect of drug A + Effect of drug B
When two drugs are given together the final effect is much
more than the simple algebraic sum of the magnitude of
individuals drugs.
Examples:
Sulphamethoxazole & Trimethoprim--- sequential blockade
of two steps in synthesis of folic acid in micro-organisms.
Effect of drug A + B > Effect of drug A + Effect of drug B
When two drugs are given together the final effect is much
more than the simple algebraic sum of the magnitude of
individuals drugs.
Examples:
Sulphamethoxazole & Trimethoprim--- sequential blockade
of two steps in synthesis of folic acid in micro-organisms.
Synergism by altering Pharmacokinetics
of the other:
•Levodopa + Carbidopa
of the other:
•Levodopa + Carbidopa
Other supraadditive drug
combinations
DRUG PAIR BASIS OF POTENTIATION
Ach + PhysostigmineInhibition of break
down
Adrenaline + CocaineInhibition of neuronal
uptake
Tyramine + MAO
inhibitors
Increasing
releaseable CAT
store
combinations
DRUG PAIR BASIS OF POTENTIATION
Ach + PhysostigmineInhibition of break
down
Adrenaline + CocaineInhibition of neuronal
uptake
Tyramine + MAO
inhibitors
Increasing
releaseable CAT
store
Drug Antagonism
Drug Antagonism
Definition:
Combined effect of two drugs is less than the sum of
the effects of the individual drugs
Effect of drugs A + B < Effect of drug
A + Effect of drug B
One drug decreases / opposes / reverses / counters
the effect of other drug by different mechanisms
Definition:
Combined effect of two drugs is less than the sum of
the effects of the individual drugs
Effect of drugs A + B < Effect of drug
A + Effect of drug B
One drug decreases / opposes / reverses / counters
the effect of other drug by different mechanisms
Types:
a.Pharmacological Antagonism :
i.Competitive (Reversible)
ii.Non-competitive (Irreversible)
b.Chemical Antagonism
c.Physiological Antagonism
d. Physical antagonism
a.Pharmacological Antagonism :
i.Competitive (Reversible)
ii.Non-competitive (Irreversible)
b.Chemical Antagonism
c.Physiological Antagonism
d. Physical antagonism
Pharmacological Antagonism:
Competitive Non Competitive
Irreversibly
competitive
Reversibly
competitive
Pseudo-
reversibly
competitive
Interfere “Down-stream events” Act on
“allosteric site”
PHARMACODYNAMIC ANTAGONISM
Competitive Non Competitive
Irreversibly
competitive
Reversibly
competitive
Pseudo-
reversibly
competitive
Interfere “Down-stream events” Act on
“allosteric site”
PHARMACODYNAMIC ANTAGONISM
Competitive
Antagonism
18
Antagonism
18
19
D-R interactions
R
BB
D
B
D-R interactions
R
BB
D
B
= Agonist = Antagonist
0
20
40
60
80
100
120
- 10.5 - 10 - 9.5 - 9 - 8.5 - 8 - 7.5 - 7 - 6.5 - 6
0
20
40
60
80
100
120
- 10.5 - 10 - 9.5 - 9 - 8.5 - 8 - 7.5 - 7 - 6.5 - 6
= Agonist = Antagonist
0
20
40
60
80
100
120
-11 -10 -9 -8 -7 -6
0
20
40
60
80
100
120
-11 -10 -9 -8 -7 -6
= Agonist = Antagonist
0
20
40
60
80
100
120
-11 -10 -9 -8 -7 -6
0
20
40
60
80
100
120
-11 -10 -9 -8 -7 -6
= Agonist = Antagonist
0
20
40
60
80
100
120
-11 -10 -9 -8 -7 -6
0
20
40
60
80
100
120
-11 -10 -9 -8 -7 -6
= Agonist = Antagonist
0
20
40
60
80
100
120
-11 -10 -9 -8 -7 -6
0
20
40
60
80
100
120
-11 -10 -9 -8 -7 -6
= Agonist = Antagonist
0
20
40
60
80
100
120
-11 -10 -9 -8 -7 -6
0
20
40
60
80
100
120
-11 -10 -9 -8 -7 -6
= Agonist = Antagonist
0
20
40
60
80
100
120
-11 -10 -9 -8 -7 -6
0
20
40
60
80
100
120
-11 -10 -9 -8 -7 -6
27
Reversible-Competitive
B
D
R
•Weak bond
•Same agonist
site
•Short duration
Reversible-Competitive
B
D
R
•Weak bond
•Same agonist
site
•Short duration
28
LDRC shift to R
B
R
D
D
D
D
D
Reversible-Competitive
Conc dependant Dynamic Equilibrium
LDRC shift to R
B
R
D
D
D
D
D
Reversible-Competitive
Conc dependant Dynamic Equilibrium
Competitive (Reversible) Antagonism /Competitive
(Equilibrium ) Antagonism
1.Same receptor by forming Weak bonds
2.Maximal response depends on concentration of
both agonist and antagonist
3.The effect of antagonist can be overcome by
increasing the concentration of agonist. The same
maximal response can be attained by increasing
dose of agonist---It is “surmountable antagonism”.
4. Parallel rightward shift of DRC
(Equilibrium ) Antagonism
1.Same receptor by forming Weak bonds
2.Maximal response depends on concentration of
both agonist and antagonist
3.The effect of antagonist can be overcome by
increasing the concentration of agonist. The same
maximal response can be attained by increasing
dose of agonist---It is “surmountable antagonism”.
4. Parallel rightward shift of DRC
= Agonist = Antagonist
0
20
40
60
80
100
120
-11 -10 -9 -8 -7 -6
0
20
40
60
80
100
120
-11 -10 -9 -8 -7 -6
= Agonist = Antagonist
Examples: Atropine and Acetylcholine at Muscarinic -R
Naloxone and Morphine at opioid-R
Propranolol and NE at β
2
- R
%
R
e
s
p
o
n
s
e
50
ED 50 ED 50 ED 50
Naloxone and Morphine at opioid-R
Propranolol and NE at β
2
- R
%
R
e
s
p
o
n
s
e
50
ED 50 ED 50 ED 50
Irreversibly Competitive or Non
Equilibrium Competitive Antagonism:
1.Have affinity for the same receptor sites and
bind in an irreversible manner by covalent
bond
2.Effects cannot be overcome even by
increasing the concentration of the agonist
(unsurmountable)
3.LDR curves of agonist (in presence of
antagonist) would show reduced efficacy but
unaltered potency
Equilibrium Competitive Antagonism:
1.Have affinity for the same receptor sites and
bind in an irreversible manner by covalent
bond
2.Effects cannot be overcome even by
increasing the concentration of the agonist
(unsurmountable)
3.LDR curves of agonist (in presence of
antagonist) would show reduced efficacy but
unaltered potency
34
Irreversibly- Competitive
B
D
R
•Same agonist site
•Strong bond
•LDRC efficacy
(flatten)
•Long duration
Irreversibly- Competitive
B
D
R
•Same agonist site
•Strong bond
•LDRC efficacy
(flatten)
•Long duration
35
36
Irreversible antagonist
+ Agonist
+ Agonist
Irreversible antagonist
+ Agonist
+ Agonist
•DOA of irreversible antagonist is longer
•Equilibrium between Antagonist - Agonist
cannot be established even after increasing
the dose of agonist hence the term “Non-
equilibrium competitive antagonism”
•E.g. Dibenamine and NE at α
1
adrenoceptors
•Equilibrium between Antagonist - Agonist
cannot be established even after increasing
the dose of agonist hence the term “Non-
equilibrium competitive antagonism”
•E.g. Dibenamine and NE at α
1
adrenoceptors
Pseudo-reversible Antagonism:
•Lesser degree of receptor occupancy by the
antagonist & availability of spare receptors
•Increasing conc. of agonist- shift LDR to right
•Increasing conc. of antagonist- reduction in
maximal response.
•Hence the term “Pseudo-reversible
Antagonism”
•Lesser degree of receptor occupancy by the
antagonist & availability of spare receptors
•Increasing conc. of agonist- shift LDR to right
•Increasing conc. of antagonist- reduction in
maximal response.
•Hence the term “Pseudo-reversible
Antagonism”
39
Pseudo-Reversible Competitive
B
D
R
R
R
R
D
D
•Strong bond
•Spare receptors
Agonist
overcomes
antagonist
•Same agonist
site
•LDRC
Pseudo-Reversible Competitive
B
D
R
R
R
R
D
D
•Strong bond
•Spare receptors
Agonist
overcomes
antagonist
•Same agonist
site
•LDRC
40
Pseudo reversible competitivePseudo - Reversible Competitive
Inc. dose of agonist
Pseudo reversible competitivePseudo - Reversible Competitive
Inc. dose of agonist
E.g.
Phenoxybenzamine - at α
1
adrenoceptor
Methysergide - at 5HT receptor
(5HT receptor blocker)
41
Pseudo-Reversible Competitive
Phenoxybenzamine - at α
1
adrenoceptor
Methysergide - at 5HT receptor
(5HT receptor blocker)
41
Pseudo-Reversible Competitive
Non Competitive
Antagonism
42
Antagonism
42
43
Non Competitive Antagonism
•Via Allosteric Modulation
•Receptor-Effector pathway
modulation
(Down-stream regulation)
NO Competition
for Agonist site
Non Competitive Antagonism
•Via Allosteric Modulation
•Receptor-Effector pathway
modulation
(Down-stream regulation)
NO Competition
for Agonist site
44
B
D
R
•Different
Receptor site
•DR interaction
ineffective
•No Reversal
•LDRCflatten
Antagonism through Allosteric
receptor site binding:
B
D
R
•Different
Receptor site
•DR interaction
ineffective
•No Reversal
•LDRCflatten
Antagonism through Allosteric
receptor site binding:
i.Binds to site other than the agonist site
ii.Prevent the receptor activation by the
agonist
E.g.
•Flumazenil by binding to BZD site
antagonises the effects of BZD by
preventing the binding of GABA to GABA
A
receptor
•Bicuculline and BZD
Antagonism through Allosteric
receptor site binding:
ii.Prevent the receptor activation by the
agonist
E.g.
•Flumazenil by binding to BZD site
antagonises the effects of BZD by
preventing the binding of GABA to GABA
A
receptor
•Bicuculline and BZD
Antagonism through Allosteric
receptor site binding:
46
GABA
GABA
binding site
Channel
blocker
(Picrotoxin)
Channel
modulators
(barbiturates)
Inverse
agonists
(β-carbolines)
Flumazenil
(antagonists)
Benzodiazepines Modulatory Site
Cl
-
Cl
-
Antagonism through Allosteric
receptor site binding:
GABA
GABA
binding site
Channel
blocker
(Picrotoxin)
Channel
modulators
(barbiturates)
Inverse
agonists
(β-carbolines)
Flumazenil
(antagonists)
Benzodiazepines Modulatory Site
Cl
-
Cl
-
Antagonism through Allosteric
receptor site binding:
47
Receptor-Effector pathway modulation
(Down-Stream Regulation)
RD
Receptor-Effector pathway modulation
(Down-Stream Regulation)
RD
Receptor-Effector pathway modulation
(Down-stream regulation)
48
AT
1
-R
NE
Ag II
Prazosin
Comp. Ant
Losartan
Comp. Ant
IP
3
,
DAG
α
1
-R
Ca
2+
channel Activation
Free Ca
2+
entry
Ca
2+
Channel blocker
(eg., Nifedipine,
non-competitive antagonist
Vasoconstriction
(Down-stream regulation)
48
AT
1
-R
NE
Ag II
Prazosin
Comp. Ant
Losartan
Comp. Ant
IP
3
,
DAG
α
1
-R
Ca
2+
channel Activation
Free Ca
2+
entry
Ca
2+
Channel blocker
(eg., Nifedipine,
non-competitive antagonist
Vasoconstriction
Effects on log DRC
•There is downward shift .The slope is reduced
and maximum response is diminished
•The parallelism is not maintained
•No shift of curve on dose axis
•There is downward shift .The slope is reduced
and maximum response is diminished
•The parallelism is not maintained
•No shift of curve on dose axis
50
•Competitive Antagonism
(equilibrium or reversible)
Action of agonist is blocked if
conc. of antagonist is
Antagonism can be overcome
by conc. of agonist
Agonist can produce max.
response in higher conc.
Competitive antagonist shifts
LDRC of agonist to right
ED
50
of agonist in presence
of antagonist, e.g., Ach &
atropine; Adr & Prop.;
Morphine & Naloxone
•Non-competitive
(non-surmountable
Antagonist)
Antagonist binds to another
site of receptor
LDRC is flattened + max.
response is
e.g. Diazepam and bicuculline
•Competitive Antagonism
(equilibrium or reversible)
Action of agonist is blocked if
conc. of antagonist is
Antagonism can be overcome
by conc. of agonist
Agonist can produce max.
response in higher conc.
Competitive antagonist shifts
LDRC of agonist to right
ED
50
of agonist in presence
of antagonist, e.g., Ach &
atropine; Adr & Prop.;
Morphine & Naloxone
•Non-competitive
(non-surmountable
Antagonist)
Antagonist binds to another
site of receptor
LDRC is flattened + max.
response is
e.g. Diazepam and bicuculline
Chemical Antagonism
A type of antagonism where a drug counters the effect
of another by simple chemical reaction / neutralization
(not binding to the receptor)
1.Protamine sulphate & Heparin
2.Calcium sodium edetate form insoluble complexes
with arsenic / lead
3.Neutralization of gastric acid by antacids like
Aluminium hydroxide, Magnesium hydroxide,
Sodium bicarbonate
A type of antagonism where a drug counters the effect
of another by simple chemical reaction / neutralization
(not binding to the receptor)
1.Protamine sulphate & Heparin
2.Calcium sodium edetate form insoluble complexes
with arsenic / lead
3.Neutralization of gastric acid by antacids like
Aluminium hydroxide, Magnesium hydroxide,
Sodium bicarbonate
Physiological Antagonism
Definition:
A type of antagonism in which one drug opposes
/ reverses the effect of another drug by binding
to a different receptor and producing opposite
physiological effects
Examples:
1.Histamine and adrenaline on bronchial
muscles and BP
2.Glucagon and insulin on blood sugar level
Definition:
A type of antagonism in which one drug opposes
/ reverses the effect of another drug by binding
to a different receptor and producing opposite
physiological effects
Examples:
1.Histamine and adrenaline on bronchial
muscles and BP
2.Glucagon and insulin on blood sugar level
Physical antagonism
•Based on the physical property of drugs e.g.
Charcoal adsorbs alkaloids and can prevent
their absorption- used in alkaloidal poisonings
53
•Based on the physical property of drugs e.g.
Charcoal adsorbs alkaloids and can prevent
their absorption- used in alkaloidal poisonings
53
REFERENCES
•Goodman Gilman - The Pharmacological Basis of
Therapeutics, 12
th
Edition
•Katzung – Basic & Clinical Pharmacology,
12
th
Edition
•Sharma – Priciples of Pharmacology,
2
nd
Edition
• K.D Tripathi – Essentials of Medical
Pharmacology, 7
th
edition
• R.S Satoskar – Pharmacology and
Pharmacotherapeutics, 18
th
Edition
• www.google .com
•Goodman Gilman - The Pharmacological Basis of
Therapeutics, 12
th
Edition
•Katzung – Basic & Clinical Pharmacology,
12
th
Edition
•Sharma – Priciples of Pharmacology,
2
nd
Edition
• K.D Tripathi – Essentials of Medical
Pharmacology, 7
th
edition
• R.S Satoskar – Pharmacology and
Pharmacotherapeutics, 18
th
Edition
• www.google .com
55
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