General Pharmacology: Adverse Drug Reactions and Drug Interactions PDF

Summary

This document provides an overview of adverse drug reactions and drug interactions in general pharmacology. It categorizes adverse effects into different types and discusses mechanisms and examples of various drug interactions. The document focuses on pharmacokinetic and pharmacodynamic aspects.

Full Transcript

Adverse effects of drugs
 Type A: augmented and dose dependent
 Type B: bizarre and unpredictable (not related to the normal
pharmacology of the drug)
 Type C (chronic): chronic effects after long use of the drugs
 Type D (delayed): delayed effects of the drugs
 Type E (end dose): end of use effects (effects of sudden
stoppage of drug use)
 Type F (failure of therapy): tolerance
 Adverse effects of drugs
Type A
 Side effect: unavoidable, undesirable normal action
produced by therapeutic dose of the drug. E.g. dry
mouth induced by atropine when used as antispasmodic
 Supersensitivity: exaggerated normal action in response
to small therapeutic dose of the drug. E.g.
supersensitivity to adrenaline in hyperthyroid patients
 Adverse effects of drugs
Type A
 Secondary effect: undesirable secondary to normal
action of the drug. E.g. broad spectrum antibiotics may
cause superinfection and diarrhea due to inhibition of
intestinal flora
 Over-dose: exaggerated normal response due to
increase of the drug dose
 Adverse effects of drugs
Type A
 Cytotoxicity: cardiotoxicity (halothane), hepatotoxicity
(halothane), nephrotoxicity (gentamicin), neurotoxicity
(streptomycin), bone marrow inhibition (chloramphenicol)
 Iatrogenic (drug-induced) disease: chlorpromazine (may
cause parkinsonism), cortisone (may cause cushing
syndrome)
 Drug –drug interactions
 Adverse effects of drugs
Type B
Allergy (hypersensitivity)
 Definition: Unpredictable abnormal response to drugs due
to antigen-antibody reaction
 Characters: not all patients, not all drugs, not dose-
dependent, not first exposure and not to reuse the drug
again, cross allergy between related drugs
 Manifestations: fever, rash, angioneurotic edema,
bronchial asthma and anaphylactic shock
 Adverse effects of drugs
Type B
Idiosyncrasy
 Definition: Unpredictable abnormal response to drugs due
to genetic abnormality
 Occurs on first exposure
 Examples: hemolytic anemia (aspirin, phenacetin,
primaquine,sulphonamides,chloramphenicol), malignant
hyperthermia (succinylcholine, halothane), succinylcholine
apnea and peripheral neuritis (isoniazid)
 Adverse effects of drugs
Type C
Drug dependence
 Habituation: psychic dependence, sudden stop of the drug
leads to psychic craving for the drug and examples include
smoking, tea and coffee
 Addiction: psychic and physical dependence, sudden stop of
the drug leads to withdrawal symptoms that may be fatal and
examples include morphine, barbiturates and ethanol
 Adverse effects of drugs
Type D
 Teratogenicity: ability of the drug to cause fetal malformations when
given to pregnant mothers, e.g. aspirin and thalidomide (FDA
:A,B,C,D,X)
 Carcinogenicity: tobacco smoking → bronchogenic carcinoma

Type E
 withdrawal symptoms: sudden stop of addicting drugs as morphine

 sudden stop of cortisone after long use → acute addisonian crisis
 Adverse effects of drugs
Type F
Tolerance
 Definition: failure of the responsiveness to the usual dose of the
drug
 Types: congenital (species, racial, individual) and acquired
(bacterial resistance to antibiotics, cross tolerance, tachyphylaxis)
 Mechanisms of acquired tolerance: decrease absorption, increase
metabolism or excretion, down-regulation of receptors (decrease in
number and sensitivity) and target cell adaptation
 DRUG INTERACTIONS
Pharmacokinetic drug interactions
 Drug interactions affecting absorption: Tetracyclines bind
metals as calcium, magnesium and aluminum →
decrease their absorption
 Drug interactions affecting distribution: Drugs with high
affinity binding to plasma proteins e.g. aspirin and
sulphonamides can displace other drugs e.g. warfarin
from their plasma proteins binding sites increasing their
action (changing from bound to free) and may lead to
toxicity of these drugs
 DRUG INTERACTIONS
Pharmacokinetic drug interactions
 Drug interactions affecting metabolism: some drugs
stimulates hepatic microsomal enzymes (hepatic
microsomal enzymes inducers) leading to increased
metabolism of other drugs e.g rifampicin while other
drugs inhibits hepatic microsomal enzymes(hepatic
microsomal enzymes inhibitors) leading to
decreased metabolism of other drugs e.g
chloramphenicol
 DRUG INTERACTIONS
Pharmacokinetic drug interactions
Drug interactions affecting excretion:
Alkalinization of urine by sodium
bicarbonate increases excretion of acidic
drugs e.g. aspirin while acidification of urine
by ascorbic acid increases excretion of
basic drugs e.g ephedrine
 DRUG INTERACTIONS
Results of drug interactions
 Addition or Summation (1+1=2): The resultant
action=sum of individual drug actions e.g. acetylcholine
+ histamine on intestinal contractility
 Synergism (1+1>2): the resultant action >sum of
individual drug actions. E.g. ethyl alcohol + barbiturates
causes severe CNS depression
 Potentiation (1+0>1): one drug has no action (0) but
increaes the effect of another drug(>1). E.g.
physostigmine + acetylcholine
 DRUG INTERACTIONS
Results of drug interactions
 Antagonism: antagonism may be chemical (neutralization of
heparin by protamine sulphate and chelation of Hg or As by BAL),
physiological or pharmacological (kinetic or dynamic)
 Reversal: adrenaline and phentolamine on blood pressure
 DRUG INTERACTIONS
Pharmacodynamic drug interactions
 Pharmacological Antagonism (2 drugs with opposite
actions operating on the same receptor): the antagonist
may be competitive or non-competitive. Non-competitive
antagonist may be reversible or irreversible
 Physiological Antagonism (2 drugs with opposite actions
operating on the different receptors): Caffeine
antagonizes CNS depressant effect of barbiturates
 Types of antagonists
 Competitive: the antagonist can be displaced from the receptor
by increasing agonist concentration. E.g. atropine

 Non-competitive: the antagonist cannot be displaced from the
receptor by increasing agonist concentration. It may be
reversible (the block ends by metabolism of the antagonist, e.g.
succinylcholine) or irreversible (the block ends by synthesis of
new receptors, e.g. phenoxybenzamine)