Dental Pharmacology PHT 350 Past Paper PDF

Summary

This document covers the topic of dental pharmacology, including pharmacokinetics and pharmacodynamics. It details the absorption, distribution, metabolism, and excretion (ADME) of drugs. The document also includes mechanisms of drug transport across cell membranes. It appears to be a set of lecture notes or study materials for a pharmacology course, but not a past paper.

Full Transcript

Pharmacology
1-Pharmacokinetics
Pharmacology deals with the knowledge of drugs, their sources,
2-Pharmacodynamics biochemical and physiological effects, mechanism of action, and
therapeutic uses of drug.
Pharmacology comprises two main branches:
3. Cholinergic ANS

4-Adrenergic ANS

5-Antihypertensives MY
Pharmacokinetics Pharmacodynamics
what body does
a to what drug does to
drug body
Dental Pharmacology
G
(B-→ D) (D-→ B)
PHT 350 Quiz 1
1443
1 2

ADMÉ
Pharmacokinetics Pharmacodynamics Pharmacokinetics of Drugs
of Drugs: of Drugs:

FI H
First, drug absorption from the site of
1 (Absorption) administration (Absorption) permits entry of
the therapeutic agent into plasma
Absorption Drug actions me
2 Second, the drug may then reversibly leave the
blood stream and distribute into the interstitial
Distribution Mechanism of It 6 (Distribution). and intracellular fluids (Distribution). fm.am
action active
Third, the drug may be metabolized by the liver,

Metabolism and Adverse 3 (Metabolism). kidney, or other tissues
effects of drugs
in in
side
e ffects
Finally, the drug and its metabolites are

Excretion 4 (Elimination). removed from the body in urine, bile, or feces
(Elimination).

3
Kidny sweat 4
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Absorption
em Absorption is the transfer of a drug
from

Schematic C
its site of administration
to the blood stream.
representation of
drug absorption,
distribution,
metabolism, and Commonly used routes of
elimination. drug administration.

IV = intravenous;
is IM = intramuscular;
SC = subcutaneous. 6

5

Mechanisms of transport of drugs across cell 1. Passive diffusion:
membranes: Characteristics
1- Along concentration gradient. ; the
drug moves from a region of high
Passive
concentration to one of lower

I
Facilitated Active concentration.
diffusion diffusion Endocytosis
transport
2- NO carrier.
3- NO energy.

The vast majority of drugs gain access to the
s body by this mechanism.
Schematic representation of
Lipid-soluble drugs readily move across most drugs crossing a cell
biologic membranes due to their solubility in membrane of an epithelial
cell of the
the membrane bilayers. gastrointestinal tract.

7 wishes TdHÉpid
8
 saturation

of it
2. Facilitated diffusion: 3. Active transport:
Through the protein channel in the cell Characteristics
membrane; facilitate the passage of large 1. Against concentration gradient;
molecules. from a region of low drug
Characteristics concentration to one of higher

If
drug concentration.
1. Along concentration gradient
2. Needs Carrier → Site for
44 2. Needs Carrier → Site for Saturation
3. No energy
Saturation & Competition
(Interaction)
3. Need Energy

A few drugs that closely resemble the

a
Schematic representation of structure of naturally occurring metabolites Schematic representation of
drugs crossing a cell drugs crossing a cell
membrane of an epithelial
are actively transported across cell membrane of an epithelial

i iI
cell of the membranes using these specific carrier cell of the
gastrointestinal tract. proteins. gastrointestinal tract.

The process shows saturation ATP = adenosine triphosphate;
kinetics for the carrier. ADP = adenosine diphosphate.
9 10

4. Endocytosis:
This type of drug delivery
transports drugs of
exceptionally large size
across the cell membrane.

Endocytosis involves
11 engulfment of a drug molecule protien
carrineyes
by the cell membrane and
transport into the cell by
pinching off the drug-filled 9to
vesicle.

waterf.li
Schematic representation of
For example, vitamin B is drugs crossing a cell
membrane of an epithelial
transported across the gut wall cell of the
by endocytosis. gastrointestinal tract.
12

11

wa f vescle si
 SIT A fraction of Most drugs binds Reversibly to
Drug Distribution Binding of
plasma proteins Mainly albumin.
a
Drugs To The Bound fraction of the drug →
Drug distribution is the process by
which a drug reversibly leaves the
1) Blood flow,
Pdistrition Plasma NOT Active NOT Filtered
bloodstream
interstitium
and enters
(extracellular
the
fluid) Proteins NOT Metabolized NOT Excreted →
and/or the cells of the tissues. Depot Form.
2) Capillary

The delivery of a drug from the plasma blood M permeability, More binding = More Depot = Longer
duration.
1 se
Ii capillaryPermiblity
to the interstitium primarily depends

fi
on:
3) The degree of binding

i iff
of the drug to plasma The Free fraction of the drug →
Edith

j
and tissue proteins, and Albumin
main Active, Metabolized
Excreted. There equilibrium between the
free makethebenititactive 4) The relative
hydrophobicity of the
bound & the free fractions of the drug.
fromAlbumn drug. Tstration
Yasmin storage notactive 13 14

Binding of Class I and Class II drugs to Clinical importance of drug
albumin when drugs are administered
alone (A and B) or together (C). displacement:
This assignment of drug classification assumes importance when a patient
taking a Class I drug, such as warfarin, is given a Class II drug, such as a
sulfonamide antibiotic.
A low aunt alotalbumin loweffect Warfarin is highly bound to albumin, and only a small fraction is free. This
means that most of the drug is sequestered on albumin and is inert in
highaiunt lowalbumin high
effect terms of exerting pharmacologic actions. is

together displacement.fm
f wm is
If a sulfonamide is administered, it displaces warfarin from albumin,
leading to a rapid increase in the concentration of free warfarin in in i
plasma, because almost 100 percent is now free, compared with the
initial small percentage.
[Note: The increase in warfarin concentration may lead to increased
therapeutic effects, as well as increased toxic effects, such as bleeding.]

15 16

class dk.it
 dasI umlfnmide
themain sideof metabolism liver
to

Metabolism a us
Chemical alteration of the drug AIMING to convert: Drugs (Active, an chemical
Non-ionized & Lipid soluble) → Metabolite (Inactive, Ionized &
water soluble) → Easily excreted in urine & bile.
Site Of Biotransformation metabolism
tw 11
a- Liver (Hepatic) is the main site for biotransformation inactive
b- Lung → Nicotine, Prostaglandins & Angiotensin (ACE).
ionized
nin iiized
c- Kidney → Vitamin D
lipidsoulble The biotransformation of drugs.
d- G.I.T. & Gut flora → Tyramine & Histamine
watersoulble
e- Skin → Vitamin D

tmetabolis inaoire
f- Plasma (Cholinesterase) → Succinylcholine

[Note: Some agents are initially administered as inactive 18
compounds (pro-drugs) and must be metabolized to their active
forms.]
activwwtwsdim.hu 17

Oxidation Factors Affecting Hepatic Microsomal
9911 Phase I reactions Reduction Phase
activitiative Enzymes
µ Hydrolysis I
A) Hepatic Microsomal Enzyme Inducers (Activators): db.ME
94
a tinswwsix Edf
Examples: Phenytoin, Testosterone, Cortisol & Tobacco smoking.
They  Metabolism of other drugs e.g. Oral anti-coagulants, Oral
PDose
Conjugation with sulfate, glycine, or
C c
hypoglycemics & Oral contraceptives →  Their duration of action.
glucuronic acid to increase drug w
They  Their own metabolism (Auto-induction) → Tolerance.
Pid Phase II polarity.
reactions The conjugates are ionized, and the as
charged molecules cannot back- B) Hepatic Microsomal Enzyme Inhibitors:
diffuse out of the kidney lumen. Specific: Grapefruit, Estrogen, Cimetidine, Chloramphenicol, Ciprofloxacin.
Non-specific (General):
toxic live.atworkliver 1
a- Hepato-toxic drugs: Carbon monoxide, Carbon tetrachloride & Ozone.
41 111
adf.ie b- Drugs  Hepatic blood flow: -Blockers (Propranolol) & H2-Blockers
(Cimetidine)
19
C) Age:
iii a
Elimination
H.M.E. Activity is inhibited in extremities of age.
soulble
Premature neonate can NOT conjugate chloramphenicol → Fatal Grey Baby Syndrome.
D) Liver disease & Cancer →  H.M.E. Activity inactiv Kissing
E) Genetic Abnormality (Idiosyncrasy): Favism & Abnormal Pseudo-Ch.E.
Removal of a drug from the body
F) Starvation vitamin, protein or calcium deficiency impairs drug metabolism occurs via a number of routes, the
decreased activity of the microsomal enzymes of the liver most important being through the
G) Pregnancy kidney into the urine.
I) Hormonal effects
Other routes include the bile,
Thyroidectomy reduces the metabolism of a number of drugs like barbiturate induced
sleeping time is prolonged in thyroidectomized animals. intestine, lung, or milk in nursing
mothers.
Alloxan or streptozotocin induced diabetes in rats also reduced the metabolism of
hexobarbitone thus prolonging the sleeping time.

22

Drug elimination by the kidney:
A drug passes through several processes
in the kidney before elimination:

Glomerular
filtration Renal elimination of a
drug
Active tubular
secretion, Effect of drug metabolism on
reabsorption in the distal
tubule.
Passive

i
tubular
reabsorption.

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THAT’S
THAT’SIT!!
IT!!