Pharmacology For The Third Year Dental Students 2024-2025 PDF

Summary

This document is a lecture on pharmacology for third-year dental students at Sphinx University. The lecture covers important topics such as drug absorption, distribution, metabolism, and excretion. It details various mechanisms and factors influencing these processes in the body.

Full Transcript

Pharmacology
For
The Third Year
Dental students
Sphinx University

BY
Assoc. Prof. Mohamed Mostafa Elbadr
2024-2025
 Introduction
What is Pharmacology ?
-Pharmacology is the drug science.
-It is the major body of information about drugs.
-This information includes knowledge about the mechanism
of action, pharmacological effects, therapeutic uses, adverse
effects and any other information about the drug.
What is the drug?
Drug is a chemical substance used for prevention, diagnosis
and treatment of diseases
What is general pharmacology?
-General pharmacology include
pharmacokinetics and pharmacodynamics
-Pharmacokinetics
-Pharmacokinetics deals with the processes that
undergo to the drug following its
administration.
-These processes include: absorption of the drug,
its distribution as well as its elimination
(biotransformation and excretion)
-Pharmacodynamics
-It deals with the relationship between the
concentration of drugs at the site of
action and the magnitude of the obtained
effects.
-Pharmacodynamics includes the
mechanism of action of drug and its
pharmacological effects.
A. Drug absorption
-Drug absorption occurs by one of the following
mechanisms:
1-Passive or lipid diffusion.
-It occurs with the lipid soluble drugs.
-The most important one
-The drug penetrates from high to low concentration after
their solubility in lipid membrane
-Passive process, so not need energy
-It depends on lipid solubility, ionization of the drug and
the concentration difference across the membrane
-Facilitated diffusion is a special type of passive diffusion
that is facilitated by a carrier
2-Filtration or aqueous diffusion:
-It occurs with water soluble drugs, where drugs
pass through aqueous channels or pores
between the cells.
-These pores are absent in the blood brain
barrier (BBB) and placental barrier so any water
soluble drug cannot cross BBB and placental
barrier
3-Active transport:
-It needs energy and carrier, so there are
selectivity, saturability and competition.
4-Pinocytosis (endocytosis):
-It occurs with high molecular weight drugs
as iron, hormones and vit.B12.
 Factors affecting drug absorption
(a) Factors related to the drug:
-Lipid solubility
-Ionization
-Molecular weight
-Dosage form
-Concentration
 (b) Factors related to the patient:
-Route of administration
-Blood supply
-Healthy state
-GIT motility
-Presence of other drugs
-Presence of food
B. Drug distribution
 The drugs are first rapidly distributed to blood
rich organs (heart, liver, kidney, brain) then to
the muscles, fat and skin which have poor
blood supply.
If the drug is unionized, high lipid soluble and
less bound to plasma protein; it is highly
distributed to different areas as it easily passes
to interstitial and cellular compartment.
 Some drugs have selective accumulation in
certain tissue as:
-Iodides in thyroid tissue.
-Tetracyclines in bone.
Some areas in the body are protected from
drugs by a special barrier as, for example, the
blood brain barrier through which drugs pass
to the brain.
 Factors affecting drug distribution
1- Lipid solubility
2-Ionization
3-Plasma protein binding
4-Tissue protein binding
5-Blood supply
6-Healthy state
7-Age and sex
C. Drug Biotransformation
(Drug metabolism)
Definition:
- Drug biotransformation is the chemical
transformation which occurs to the drug inside
the body in order to decrease its lipid solubility
and increase its water solubility to be excreted
by the kidney.
Types of alteration of biological activity of drugs:
a) An active drug changes to inactive
metabolite (as in most of drugs).
b) An active drug changes to another active
metabolite, e.g. codeine is metabolized to
morphine
c) An inactive drug (prodrug) changes to an
active metabolite as enalapril is
metabolized to enalaprilat.
Organs responsible for biotransformation include:
1- Liver (main site of biotransformation).
2- Others: kidney, gut mucosa, lung and skin.
 The most important enzymes responsible for
metabolism are mixed functional oxidases
(MFOs) and they form large family of isozymes
and called also cytochrome P450.
(N.B) cytochrome P45o- 3A4 is most important
enzyme and responsible for metabolism of
more than 60% of drugs.
Types of metabolic reactions (Phases):
(1) Phase I (Non- synthetic reaction)
Here; the drug is changed to a more polar
form and is prepared to undergo phase II. In
certain cases; the drug may be still active.
Phase I includes: oxidation, reduction or
hydrolysis reaction.
Oxidation is the most important one
(2) Phase II (Synthetic or conjugation reactions)
Drugs released from phase 1 are coupled with
an endogenous substance.
The coupled drugs are more polar and water
soluble and, thus, easily excreted by kidney.
However, some drugs are excreted in bile.
Decoupling may occur by gut bacteria, so
reabsorption of the uncoupled drug can occur
and this is called enterohepatic circulation as
with estrogen.
Factors affecting drug biotransformation:
(1) Genetic polymorphism:
-In some individuals, there is rapid
biotransformation (fast metabolizers). In
others there is slow biotransformation (slow
metabolizers).
 In fast metabolizers, the therapeutic
effective blood levels may not be reached
due to rapid metabolism of the drug.
In slow metabolizers, toxicity may occur
from the usual doses due to accumulation
of the drug.
 The cause of this condition is due to a genetic
difference in affinity of the enzyme to the drug
or difference in the amount of the enzymes
especially cytochrome P450.
Examples:
1-Acetylation of isoniazid: In slow acetylator
drug accumulation may occur causing
peripheral neuropathy
2- Succinylcholine apnea due to genetic
deficiency of the pseudocholinesterase enzyme
 (2) Age and sex:
Young age especially newborn are slow
metabolizers due to immaturity of the enzyme
system, as enzymes of phase 1 need several
months and enzymes of phase II need 2-3 years
to be as in adult enzymes.
-Males may be rapid metabolizers than females
due to androgen hormone.
(3) Environmental factors:
Cigarette smokers, persons exposed to
pesticides are rapid metabolizers due to
enzyme induction.
Charcoal –broiled foods, cruciferous
vegetables induce P450-1A while
grapefruit juice inhibits P450-3A
(4) Pathological factors:
Liver, heart and lung diseases as well as
malnutrition decrease drug metabolism
by reducing the amount and activity of
enzymes.
(5) Drug- drug interaction (enzyme inducers
and inhibitors):
Enzyme inducers:
-They induce liver enzymes by increasing the
amount or activity of these enzymes.
-There is rapid metabolism of the drugs which
are metabolized by the induced enzymes, so
the effect of these drugs is decreased.
-Examples: as phenobarbitone, phenytoin,
rifampicin and carbamazepine
Enzyme inhibitors:
-They inhibit metabolism of other drugs, so
potentiate their effects.
-Cimetidine and erythromycin are the most
important enzyme inhibitors.
D. Drug Excretion
 Drugs are excreted either unchanged or in the
form of metabolic products.
Drugs to be excreted must be water soluble
(ionized).
Lipid soluble drugs are not excreted (due to
their passive tubular reabsorption) until their
metabolism.
Sites of excretion:
-Kidney (main site)
-Bile
-Lung (more with inhalational anesthesia).
-Saliva
- Milk, sweat, skin, and hair are minor routes.
Factors affecting renal excretion:
1-Lipid solubility and ionization of the drug
-Increase in lipid solubility and in unionization
decrease drug excretion
2-Plasma protein binding of the drug
- Increase in binding leads to decrease in free
form so decreasing excretion
3-Presence of other drugs
- As competition between drugs with the same
transport mechanism may occur
Probenecid inhibits active tubular section of penicillins
due to competition for the same carrier system
- Some drugs may cause acidification of alkalinization of
urine, so may increase or decrease ionization of other
drugs so may increase or decrease excretion of these
drugs
Examples:
A- Na HCO3 and acetazolamide cause alkalinization of urine
-They increase ionization of weak acidic drugs as aspirin and
barbiturates, so they decrease passive tubular reabsorption
causing increase in their excretion
So used to treat toxicity of acidic drugs
-They decrease ionization of weak basic drugs as atropine,
morphine, benzodiazepines, so they increase passive
tubular reabsorption causing decrease in their excretion
B- NH4Cl and ascorbic acid (vitamin C) cause
acidification of urine
-They decrease ionization of weak acidic drugs
as aspirin and barbiturates, so they increase
passive tubular reabsorption causing decrease in
their excretion
-They increase ionization of weak basic drugs as
atropine, morphine, benzodiazepines, so they
decrease passive tubular reabsorption causing
increase in their excretion
So used to treat toxicity of basic drugs
4-Molecular weight of the drug
-increase in molecular weight of the drug causes
decrease in drug excretion
5-Renal blood flow
6-Healthy state of the kidney
Pharmacokinetic variables
(Parameters)
 They are variables which differ from one
individual to other according to certain
physiological factors (as age, sex,....), or
pathological factors (as liver, kidney
diseases......) and so need adjustment of the
dose.
They include:
a) Bioavailability (F)
b) Volume of distribution (Vd)
c) Clearance (Cl)
d) Biological half- life (t 1/2).
(a) Bioavailability (F)
- It is the fraction of a given dose that reaches systemic
circulation
- Bioavailability =
Plasma or systemic concentration
dose given
- It ranges from 0-1, in cases of I.V. injection equal to1
(or 100%). If no drug reach systemic circulation equal
to 0
- Causes of low oral bioavailability (factors
affecting it).
(a) Poor absorption as aminoglycosides which
are not absorbed at all.
(b) Extensive first pass- metabolism (metabolism
which occurs before the drug reach systemic
circulation , may occur in GIT or the liver as in
cases of insulin, lidocaine and epinephrine )
- Drugs with low oral bioavailability can be given
I.V., I.M., sublingual
(b) Clearance (CI)
- Clearance of a drug is the rate of elimination by
all routes relative to the concentration of drug
in any biologic fluid.
-Clearance of the drug from the body may
involve process occurring in the liver, kidney,
lung or other organs.
-Clearance may be constant or variable
-In cases of renal failure, we use drugs that
do not depend on the kidney for their
clearance
-In cases of hepatic failure, we use drugs
that do not depend on the liver for their
clearance
(c) Biological half- life (t ½ )
-The half-life is the time needed for the plasma
concentration or the amount of drug in the
body to be reduced by 50%.
-Measurement of the t ½:
So t ½ = Vd ×0.693 / Cl
-The half-life depends on the clearance and
volume of distribution, so it affected by
factors affect both.
- The half-life is important in the selection of
dosage interval for maintenance therapy
- Drugs reach to Css (steady state concentration)
after 4-5 t ½
-In cases of drugs with long t ½ , we may use the
loading dose (very high dose used at the start
of the therapy) to reach to Css rapidly.
Maintenance dose (dosing rate)
Definition:
Dose that is needed to maintain Css
Calculation:
Maintenance dose = Cl × Css
It depends on the clearance
Loading dose
Definition:
Dose that is used to reach Css
It is large dose that is given at the onset of
therapy to reach the Css rapidly
Calculation:
Loading dose = Vd× Css
It depends on Vd
Indication:
Loading dose is needed when the time required
to reach Css (target concentration) is long relative
to the condition which is treated