General Pharmacology PDF

Summary

This document provides an overview of general pharmacology, including the history and sources of drugs, along with details about drug nomenclature. The document also discusses factors that influence drug absorption and action.

Full Transcript

General Pharmacology
By;
Abebe E. (B.pharm, Msc)

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 BRIEF HISTORY OF PHARMACOLOGY
 Medicaments have, since time immemorial, been
used for treating diseases in humans and animals.
 Belief in the curative powers of plants and certain
substances rested exclusively upon traditional
knowledge (empirical information not subjected
to critical examination)
 Claudius Galen (AD 129–200): First attempted to consider
the theoretical background of pharmacology.

“The empiricists say that all is found by
experience. We, however, maintain that
it is found in part by experience, in part
by theory. Neither experience nor theory
alone is apt to discover all.”
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 Theophrastus von Hohenheim (1493–1541), aka Paracelsus: Rejected the irrational concoctions and mixtures of medieval medicine.

 Johann Jakob Wepfer (1620–1695): Was the first to verify by animal experimentation assertions about pharmacological or toxicological actions

“If you want to explain any poison properly,
what then is not a poison? All things are
poison, nothing is without poison; the dose
alone causes a thing not to be poison.”

“I pondered at length. Finally I resolved
to clarify the matter by experiments.”

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 Rudolf Buchheim (1820–1879), Estonia: Founded the
first institute of pharmacology
 T. Frazer (1840–1920), Scotland: Structure–activity
relationships
 J. Langley (1852–1925), England: Drug receptors
 P. Ehrlich (1854–1915), Germany: Selective toxicity
 Alexander J. Clarke (1885–1941), England: first
formalized receptor theory by applying the Law of
Mass Action to drug–receptor interactions.

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 General Pharmacology
 Pharmacology came from the Greek words
“Pharmacon” meaning drug and “logos” meaning
discourse in.
 Pharmacology is the science that deals with properties
and effects of drugs in relation to their interaction with
living systems.
 Drugs are chemical substances that interact with human
and/or animal body to exert their effects, and intended
for prophylactic, diagnostic and treatment purposes.

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 It also includes history,sourse,physicochemical
properties,dosage forms,methods of administration,
absorbtion, distribution, mechanism of action,
biotransformation, excretion,clinical uses and adverse
effects of drugs.
 Pharmacodynamics: - is the study of the biological and
therapeutic effects of drugs.i.e ”what the drug does to the
body”.
Pharmacokinetics: - is the study of the absorbtion,
distribution, metabolism and excretion (ADME) of drugs.i.e
“what the body does to the drug”.
Pharmacotherapeutics: deals with the proper selection &
use of drugs for the prevention and treatment of disease.
Toxicology: is a science of poisons. Many drugs in large
doses can act as poison. Poisons are substances that cause
harmful, dangerous or fatal sympthoms in living organisms.
SOURCES OF DRUGS

1. Minerals: Liquid parafine, Magnesium sulphate,
Magnesium trisilcate, etc.

2. Animals: Insuline, thyroid extract, heparine, antitoxine
sera, etc.

3. Plants: Morphine, digoxine, atropine, castor oil etc.

4. Synthetic sources: Asprine, sulphonamides, paracetamol
etc.

5. Micro organisms: Penicilline, streptomycine etc.

6. Genetic engineering: Human insuline, human growth
hormone etc.
DRUG NOMENCLATURE

A drug generally has three categories of names:

1. Chemical name: - describes the substance chemically.
E.g. 1-(Isopropyl amino)-3-(1-naphthyloxy) propane-2-ol.

This is cumbersome and not suitable for use in prescribing.

2. Non-proprietary (generic) name: - It is the name
accepted by a competent scientific body.e.g Mebendazole.

3. Proprietary (Brand) name:-It is the name assigned by
the manufacture(s) and its property or trade mark.One drug
may have a multiple proprietary names.
 Pharmacokinetics
 Pharmacokinetics deals with absorption, distribution,
metabolism and excretion of drugs.
 To produce its characteristic effects, a drug must be
present in appropriate concentration at its site of action.
 Concentration at the site of action depends on
absorption, distribution, binding or localization in
tissues, biotransformation, and excretion.
 All the pharmacokinetic processes involve passage of
drug through membranes.

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THE MOVEMENT OF DRUG MOLECULES ACROSS
CELL BARRIERS
Cell membranes: barriers between aqueous
compartments in the body
Gastrointestinal mucosa or renal tubule: a layer of
cells tightly connected to each other
 Molecules must traverse at least two cell membranes to
pass from one side to the other
 Vascular endothelium: more complicated
 Gaps between endothelial cells are packed with a loose
matrix of proteins that act as filters, retaining large
molecules and letting smaller ones through.

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 Contd….
 Some organs (e.g. CNS and the placenta), have tight
junctions between the cells
 Prevent potentially harmful molecules from leaking from the
blood into these organs
 Have major pharmacokinetic consequences for drug distribution
 Other organs (e.g. the liver and spleen) have endothelium
which is discontinuous, allowing free passage between
cells.
 Fenestrated endothelium occurs in endocrine glands, facilitating
transfer of hormones or other molecules through pores in the
endothelium

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 There are four main ways by which small molecules
cross cell membranes:
 diffusing directly through the lipid
 diffusing through aqueous pores
 transmembrane carrier proteins that bind a molecule on one
side of the membrane then changes conformation and
releases it on the other
 by endocytosis

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 Passive diffusion
The major mechanism for absorption of drugs.

The driving force for this process is the concentration
gradient or electrochemical gradient

Fick’s first law of diffusion: drug molecules diffuse
from a region of higher concentration to one of lower
concentration until equilibrium is attained

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Influence of pH on passive diffusion: The pH partition
hypothesis states that the process of absorption is governed by:
 The dissociation constant (pKa) of the drug
 The lipid solubility of the unionized drug
 The pH of the absorption site
Most drugs are either weak acids or weak bases that are
present, as both nonionized and ionized species.
The nonionized molecules are usually more lipid soluble &
diffuse more easily than the ionized species
The transmembrane distribution of a weak electrolyte usually
is determined by its pKa and the pH gradient across the
membrane.

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 For weak acids
HA H+ + A  ,
 For weak bases
BH+ H+ + B,
 Very weak acids (pKa  8) are essentially unionized at all
pH values and therefore their absorption is rapid and
independent of GI pH.
 Acids in the pKa range 2.5 to 7.5 are better absorbed from
acidic conditions of stomach (where pH  pKa) where
they largely exist in unionized form.
 Stronger acids with pKa  2.5 are ionized in the entire pH
range of GIT and remain poorly absorbed.

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 Very weak bases (pKa  5) are essentially unionized
at all pH values and therefore have a rapid absorption
which is independent of pH.
 Bases in the pKa range of 5 to 11 are better absorbed
from the relatively alkaline conditions of the intestine
where they largely exist in unionized form.
 Stronger bases with pKa  11 are ionized in the entire
pH range of the GIT and therefore are poorly
absorbed.

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18
 Carrier Mediated Transport
Involves binding of the drug to specific receptors on the
membrane for translocation into the cytoplasm
Characteristics of carrier mediated transport
 Selectivity
 Competitive inhibition by chemical congeners
 Requires energy
 Saturability
 Movement against electrochemical gradient
Active transport: when movement is against
concentration gradient
Facilitated diffusion: movement of drugs is along
concentration gradient but in a much faster rate than
simple diffusion.
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Filtration or Pore Transport
Is passage through the water filled pores in
membranes
It is accelerated by the hydrodynamic flow of water
occurring under hydrostatic or osmotic pressure
gradient
Drug should be water soluble and of smaller
molecular size than the diameter of the pores.

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Drug Absorption

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Drug Absorption: Describes the rate at which a drug leaves
its site of administration and the extent to which this occurs.

Bioavaillability is a term used to indicate the extent to
which a drug reaches its site of action or a biological fluid
from which the drug has access to its site of action.

Absorption takes place through one or combination of the
process described earlier

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Factors That Modify Absorption
Drug solubility at the site of absorption

Dosage form

Local condition at the site of action

Drug concentration at the site of absorption

Circulation to the site of absorption

Area of the absorbing surface

The route of administration

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 The main mechanism of most drug absorption in GI tract is:
A. Active transport (carrier-mediated diffusion)
B. Filtration (aqueous diffusion)
C. Endocytosis and exocytosis
D. Passive diffusion (lipid diffusion)
What kind of substances can’t permeate membranes by
passive diffusion?
A. Lipid-soluble
B. Non-ionized substances
C. Hydrophobic substances
D. Hydrophilic substances

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DRUG DISTRIBUTION

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 Drug distribution is the process by which absorbed
drug or drug directly introduced into the circulation
is carried to various interstitial and cellular fluids.
 Possible Modes of Drug Distribution:
 Following its uptake into the
body, the drug is distributed in
the blood (1)
 and through it, the drug may be
restricted to the extracellular
space (plasma volume plus
interstitial space) (2)
 or it may also extend into the
intracellular space (3).
 certain drugs may bind strongly
to tissue structures (4).

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 Apparent volume of distribution: The concentration
(c) of a solution corresponds to the amount (D) of
substance dissolved in a volume (V); thus, c = D/V

If the dose of drug (D) and its plasma concentration (c)
are known, a volume of distribution (V) can be
calculated from

However, this represents an apparent (notional) volume
of distribution (Vapp), because an even distribution in
the body is assumed in its calculation.

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 Homogeneous distribution will not occur if drugs are bound to
membranes of cell or intracellular organelles; or are stored
within organelles.
In these cases, plasma concentration, cp, becomes small and V
can exceed the actual size of the available fluid volume
Clinical prediction:
– If Vd = 2L, you can assume drug is distributed in plasma only

– If Vd = 18L, you can assume drug is distributed in plasma and tissues

– If Vd > 46L, the drug is likely stored in a depot because the body only contains 40-
46L of fluid

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 Tissue Distribution
is determined by the partitioning of drug between blood
and the specific tissue, which in turn depends on
 Lipid solubility of drugs
 pH gradient between plasma and the tissue (ion trapping)
 The relative binding of drug to plasma proteins and tissue
macromolecules
Some tissues act as storage sites by accumulating the
drug and releasing it slowly over a period of time

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 WHAT IS THE EFFECT OF ION TRAPPING
ON DRUG DISTRIBUTION?

Compartment Compartment
with Low pH with High pH

Unionized Unionized
Weak Acid Weak Acid
Higher total
concentration
of weak acid
Ionized Ionized
Weak Acid
Weak Acid

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 Factors Affecting Distribution of Drugs
Physico-chemical properties of drugs
 Lipid solubility of the drug
 pKa of the drug
 Degree of plasma protein binding (Albumin-vs- α-1 acid
gp)
Physiological factors
 Rate of blood flow
 Tissue uptake
Presence of barriers
 BBB
 Placental barrier
 Testicular barrier

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 Redistribution
Termination of drug effect usually is by
biotransformation and excretion, but it may also result
from redistribution of the drug from its site of action
into other tissues or sites.

E.g. Redistribution
of thiopental after
an intravenous
bolus
administration.

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What do you think is the clinical
significance of drug distribution?
DRUG BIOTRANSFORMATION
(METABOLISM)

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 Drug biotransformation is a process by which drugs are
chemically changed in the body to facilitate excretion of drugs
by rendering them more polar or by conjugating them with
highly polar molecules.
 Every tissue has some ability to metabolize drugs (i.e. GI
tract, lungs, skin, kidneys); however, the liver is the
principal organ for drug metabolism
Biotransformation may lead to one of the following:
 Inactive or less active metabolite
 Metabolite with same activity as the parent drug
 More active compounds (prodrugs are employed to improve bioavailability
(e.g. enalapril), mask unpleasant odor/taste, alter drug solubility and/or
provide site specific delivery)
 Toxic compounds (e.g. acetaminophen overdose)

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 Pattern of Biotransformation
Biotransformation reactions are classified as phase I
and phase II reactions
Phase I (functionalization or non-synthetic) reactions
 Introduce or expose a functional group on the parent drug.
 Generally result in the loss of pharmacological activity,
although there are examples of retention, enhancement or
alteration of activity.
 If not excreted rapidly, the products of phase I
biotransformation undergo phase II conjugation reaction.
 Prominent reactions in this category include oxidation,
reduction and hydrolysis

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Phase II (conjugation or synthetic) reactions
 Lead to the formation of a covalent linkage between a
functional group on the parent compound with endogenous
substrates (glucuronic acid, sulfate, amino acids, glutathione
or acetate).
 Form highly polar conjugates which are generally inactive and
are rapidly excreted in the urine or feces
 Is a saturable process
 Higher molecular weight conjugated metabolites are mostly
excreted in the bile

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The two phases of drug metabolism

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39
 Drug Metabolizing Systems
Biotransformations are enzymatic in nature

The cytochrome P450 enzyme system is the major in
terms of catalytic versatility and the number of drugs it
metabolizes to inactive or active metabolites.
CYP450 is found highly concentrated in liver
endoplasmic reticulum (microsomes)

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 Extrahepatic microsomal enzymes
(oxidation, conjugation)

Hepatic microsomal enzymes
(oxidation, conjugation)

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42
NADP+ Drug
CYP Fe+3
CYP e -

R-Ase Drug
PC DrugOH
NADPH

CO CYP Fe+3
C
CYP-Fe+2 O CYP Fe+2 Drug OH
Drug h
Drug
e-
O2
CYP Fe+2 H2O
O2 Drug
2H+

Electron flow in microsomal drug oxidizing system
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 Enzyme Induction
 Exposure to certain drugs and environmental
pollutants is associated with an increased synthesis of
CYP450 and hence increased rate of
biotransformation.
 Induction brings about decreased bioavailability of
parent drug and increased concentration of metabolite
which depending on the pharmacological activity can
result in either decreased activity or toxicity.
 Induction of metabolism of ethinylestradiol by
rifampicin and phenobarbitone and the associated loss
in contraceptive potency of ethinylestradiol.

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45
 Enzyme Inhibition
 Competition between two or more drugs for the active
site of the same metabolizing enzyme may lead to a
decrease in the metabolism of one of these agents,
depending on the relative concentration of each substrate
and their affinities for the enzyme.
 Some drugs bind tightly to the Cytochrome P450 heme
iron and reduce the metabolizing activity of the enzymes.
 It results in elevated levels of the parent drug and hence
prolonged pharmacological effect and an increased
incidence of drug-induced toxicity.

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 Factors Affecting Drug Biotransformation
 Genetic polymorphism
 Disease conditions especially of the major drug
metabolizing sites.
 Age
 Predisposing factors to enzyme induction or
inhibition.

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 Clinical Significance:
– First-pass (PRESYSTEMIC) metabolism
– Altered pharmacological action (Asprin vs salicylic acid)
– Toxic metabolites (paracetamol, safe but not too safe when…!)
– Use of ethanol in methanol and ethylene glycol Poisoning (the better
of two evils!)
– Terfenadine vs fexofenadine (offsetting the loss!)
– Alcoholism: (Why are Orientals less into it?)
– CYP 2D6, beta blockers and…in Ethiopians: (Why we, in Ethiopia,
need more clinical pharmacists/clinical researchers!)
– CYP 2C19 (Why do Asian physicians prescribe lower doses of
Diazepam than those of the West?)
– INH toxicity: fast vs slow metabolisers (a double edged sword!)

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Acetominophen Metabolism

~60%
~35%

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Drug Excretion

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 Drug excretion is the elimination (passage out) of a
systemically absorbed drug from the body in the form
of metabolites or unchanged drug.
 The kidneys are the main organ of excretion of drugs
and their metabolites.
 Other routes of drug elimination:
 lungs: for volatile substances
 Sweat: for volatile oils
 Bile and colon (for conjugated large molecular weight drug
or metabolite)
 Saliva
 tears

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 Renal Excretion (water soluble substances)
 The amount of drug or its metabolites ultimately present in urine is the
cumulative effect of glomerular filtration, tubular reabsorption and
tubular secretion.
 Glomerular filtration: depends on
 Plasma protein binding: for a drug to be filtered through the glomerulas, it
should not bind to plasma proteins.
 Rate of blood flow
 Passive tubular reabsorption
 Drugs should be in their non-ionized form to undergo passive reabsorption.
Hence, polar drugs are more readily excreted through the kidneys.
 Active tubular secretion
 An active process which can be inhibited by drugs which use the same
transport mechanism. E.g. probenecid prolongs the t½ of penicillins.

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 Biliary Excretion
 The liver secretes about 1 L of bile daily

 Drugs with mol wt lower than those of most protein
reach the hepatic extracellular fluid from where they are
transported into hepatocytes by carrier-mediated
systems and passive diffusion (more lipophilic drugs).
 Drugs Pass into bile through selective systems with only
few drugs crossing by diffusion.

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 Most drugs secreted by the liver into the bile are not
reabsorbed
 Once in the intestine, most are usually passively
reabsorbed that the drugs will reenter the blood that
perfuse the intestine and again be carried to the liver
(enterohepatic recirculation)
 Conjugation (esp. glucuronidation) generally enhances
biliary excretion since it both
 Introduces a strong polar (i.e., anionic) center
 Increases its molecular weight
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 Conjugated drugs are hydrolyzed by gut enzymes such
as -glucuronidase for reabsorption.
 Liver disease or injury usually impairs bile secretion and
hepatic drug metabolism
 Antibiotics may alter the intestinal flora which diminish
the presence of sulfatase and glucuronidase-containing
bacteria decreasing enterohepatic recirculation.

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 Pulmonary excretion
 Any volatile material, irrespective of its route of
administration, has the potential for pulmonary excretion
 The rate of loss of gases depends on the rate of respiration
and pulmonary blood flow, degree of solubility of the gas
in blood

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 Sweat and Saliva
 Excretion depends on the diffusion of un-ionized lipid-
soluble form across the epithelial cells of the glands.
 Quantity excreted is determined by the pKa of the drug and
the pH of the secretions formed in the glands
 Excretion into sweat may be responsible for the skin
reactions caused by some therapeutic agents
 Substances excreted into saliva are usually swallowed
 Excretion of drugs into saliva accounts for the drug
taste of certain compounds given by IV.

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 Excretion in Milk
 Concentration of drugs in milk depends on many
factors, including
 amount of drug in the maternal blood

 lipid solubility of the drug

 Drug’s degree of ionization

 The extent of its active excretion

 Milk is more acidic (pH 6.5) than plasma, hence basic
drugs are more concentrated in this fluid.

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 What do you think is the clinical
significance of drug excretion?
Routes of Drug Administration

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 Drugs are administered for either their action
in the locality of their administration or for
general systemic purpose.

 Many factors such as the nature of the target
tissue, physico-chemical properties of the
drug, the disease state etc.. dictate the route the
drug should be administered

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1. Systemic routes of administration

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 1.1. Oral ingestion
 Refers to the administration of drugs though the mouth,
mostly, for systemic effect. It is the most common method
of drug administration

 Advantages
 Safe, more convenient and economical

 Often painless, need no assistance for administration

 Both solid dosage forms and liquid dosage forms can be
administered

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 Disadvantages
Action slower and thus not suitable for emergencies
Unpalatable drugs difficult to administer
Not suitable for uncooperative /unconscious/
vomiting patients
Certain drugs are not absorbed sufficiently
Some drugs are destroyed by digestive juice or liver
enzymes (first pass metabolism)

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 1.2. Parenteral route
 Par = beyond and enteral = intestine
 Drug directly introduced into tissue fluids or blood
without having to cross the intestinal mucosa.
 Routes include
 Intravenous
 Intramuscular Major parenteral routes
 subcutaneous
 Other parenteral routes include
 Intraarterial
 Intrathecal
 Intraarticular

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 Advantages
 Action faster (hence valuable in emergencies)

 Employed in unconscious/uncooperative/vomiting patients

 No interference of food or digestive juice and first pass effect
is bypassed to a certain extent.

 Disadvantages
 Preparation is costlier
 Need of assistance by others during administration

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 Intravenous administration

 Drug injected as a bolus or infused slowly over hours in
one of the superficial veins, the drug directly reaches into
the blood stream and effects are produced immediately
 Only aqueous solutions can be injected

 Dose required is smallest as bioavailability is 100%

 Even large volumes can be infused through this route

 It is the most risky route

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 Intramuscular administration
 Drug is injected in one of the large skeletal muscles:
deltoid, triceps, gluteus maximus, rectus femoris etc.
 Muscle is less richly supplied with sensory nerves and
(mild irritants can be applied) and is more vascular
(absorption is faster)

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 Subcutaneous administration
 The drug is deposited in the loose subcutaneous tissue

 Is richly supplied by nerves (unsuitable for irritant drug
administration) but is less vascularized (slow absorption)
 Self injection is simple

 Oily solution or aqueous suspensions can be injected for
prolonged action

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 1.3. Sublingual administration
 Tablets are placed under the tongue or crushed in the
mouth and spread over the buccal mucosa
 Non polar and hence lipid soluble drugs are rapidly
absorbed
 Drug is protected from first pass metabolism as there is
direct drainage into the superior vena cava.

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 1.4. Rectal administration

 Certain irritant and unpleasant drugs can be put into the
rectum as suppositories or enema for systemic effect.
 This is often useful when oral ingestion is precluded by
vomiting or when the patient is unconscious.
 It is rather inconvenient and embarrassing

 Absorption is slower, irregular and often unpredictable

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 1.5. Pulmonary administration
 Suitable for gaseous and volatile drugs

 Rapid absorption due to large surface area

 Solutions can be atomized and the fine droplets in air
(aerosol) inhaled
 Advantage: Rapid absorption, avoidance of hepatic first
pass loss, local application to the pulmonary system.
 Disadvantage: Poor ability to regulate the dose and
irritation of the pulmonary mucosa

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73
2. Topical administration

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 Application could be on mucous membranes, skin or
the eye.
 Mucous membranes
 Drugs are applied on the mucous membranes of the
conjunctiva, nasopharynx, oropharynx, vagina and colon
usually for their local effects.
 Absorption through mucous membranes occur readily to
cause systemic effects

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 Skin
 Absorption is proportional to the surface area and lipid
solubility of the drug.
 Conditions that increase cutaneous blood flow enhance
absorption.
 Systemic absorption from skin is sometimes a reason of
toxicity.
 Eye
 Ophthalmic preparations are meant for their local action
 Systemic absorption that results from drainage thought the
nasolacrimal canal is usually undesirable
 Very little is lost through drainage; hence, systemic side effects
are minimized.

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77
Dosage forms
of
drugs

78
 A dosage form of a drug is the form of preparation
designed for administration to the body for the purpose
of diagnosis, prophylaxis and treatment.
After development of a specific chemical entity for its
pharmacological effects, it is formulated in a form that
is suitable for administration and even efficacy and for
the stability of the drug itself.
There are different dosage form designs intended for
the various routes of administration.
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 Solid dosage forms
 Tablets:
 tablets are solid dosage forms containing the active
ingredient with or without suitable diluents
 They may be coated or uncoated.

 Coating is intended to mask the contents of the tablet
 Enteric coated: intended for intestinal medications without getting
disintegrated in the stomach.
 Non-enteric coated: intended to mask the unpleasant odour and
taste of a drug.
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 Capsules
 Are solid dosage forms which the solid or liquid drug is
enclosed in a hard or soft soluble gelatin shell to mask its bad
taste and odour. They are intended for internal use.

 Suppositories
 Are solid dosage forms with various sizes and shape for
administration into body cavities (rectum, vagina, and
urethra)
 Rectal suppositories are conical or bullet shaped, vaginal
suppositories spherical, and urethral suppositories pencil
shaped.
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 Semi-solid dosage forms
 Syrups
 Syrups are semi-solid, viscous, sticky preparations containing
medicinal substance dissolved in a concentrated sugar solution.
 Ointments
 Are semi-solid preparations containing the medicinal agent
intended for use for application on skin or mucous membranes
 Creams
 Creams are emulsions for external use as protective or
emollients to soften and sooth.
 Pastes
 Are semi-solid dosage forms of heavy consistency.

82
 Liquid dosage forms
 Solutions
 Are liquid preparations prepared by dissolving active medicinal
substance in a solvent. It can be for internal or external use.
 For internal use solutions
 Tinctures: hydroalcoholic or alcoholic solution of vegetable material or
chemical substance. They can also be used for external purpose.
 Elixirs: hydroalcoholic preparations flavoured and sweetened with or
without active substance.
 Injectables

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 Injectables are sterile preparations for parenteral route.
They may be labeled as
 “for injection”: a sterile powder prepacked in a vial which on the
addition of a suitable vehicle forms a clear solution.
 “injection”: a ready made sterile liquid preparation in an ampoule
or vial.
 “sterile suspension”: a ready made suspension for parenteral uses,
but not for intravenous or intrathecal injection.
 “sterile for suspension”: a sterile powder prepacked in a vial which
on addition of a sterile vehicle is made into a suspension for
parenteral uses, but not for intravenous or intrathecal injection.
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 For external use solutions
 Drops: are aqueous preparations intended for topical
administration to the nose, throat, eye or ear. Eye drops should be
clear and sterile aqueous solutions, adjusted to a suitable pH and
osmotic pressure.
 Gargles: are aqueous solution used to treat disease of the pharynx
or nasopharynx and as deodorant or antiseptic.
 Enemas: are aqueous solutions to be placed in the rectum to
evacuate the bowel or to bring about local or systemic
therapeutic action.
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 Suspensions
 Suspensions are preparations containing drugs,
uniformly dispersed with the help of a dispersing agent.
Every suspension should have a label “shake well before
use”
 Suspensions include
 Emulsions: preparations consisting of two non-miscible liquids,
with an emulsifying agent. They may be used for both internal
and external use.
 Mixtures: preparation of any solid material suspended in a
liquid, and intended for internal use.
 Lotion: an aqueous suspension to be applied without friction,
for soothing, cleansing or antiseptic action on the skin.

86
Dosage regimen

87
 Dosage regimen is a systematic way of drug administration.
There are two types: constant and variant dosing
 Constant dosing is employed only for safe and affordable
drugs
 Variant dosing includes
 A loading dose in one or a series of doses that may be given at the
onset of therapy with the aim of achieving the target concentration
rapidly. It is desirable if the time required to attain steady state by the
administration of drug at a constant rate (four elimination half lives)
is long relative to the temporal demands of the condition being
treated.

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 Use of loading dose has significant disadvantages
I. Sensitive individuals may be exposed abruptly to a toxic
concentration of a drug.

II. If the drug has long half-life. It takes long time for the
concentration to fall if the level achieved was excessive

III. Loading doses tend to be large, and they are often given
parenterally and rapidly; this can be particularly dangerous
if toxic effects occur as a result of action of the drug at sites
that are in rapid equilibrium with plasma.

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 Maintenace dose: is a dose administered to maintain the
target concentratin of a drug. The amount is equivalent
to dailly excreted dose.

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Pharmacodynamics

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 Pharmacodynamics studies the physiological and
biochemical effects of drugs and their mechanism of
action
 Drugs interact with receptors to produce their
characteristic effects. Receptors are functional
macromolecular components of the organism
 Drugs potentially are capable of altering both the extent
and rate at which any bodily function proceeds
 Drugs do not create effects but instead modulate intrinsic
physiological functions.

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 Mechanism of Drug Action
 Physical action
 Mass of the drug (in bulk laxatives), adsorptive property (activated
charcoal), osmotic activity (mannitol)
 Chemical action
 Antacids, chelating agents (BAL, calcium disodium edetate)
 Through protein targets:
(Ion channels, carrier molecules, enzymes, receptors)
 Through enzymes
 Drugs alter rate of enzyme catalyzed reactions
 Actions could be
 Stimulation: increased substrate affinity to enzyme
 Inhibition: is a common mode of drug action and could be
 Competitive: drug binds to catalytic site (mostly non-covalently);
reversed by increasing concentration of substrate.
 Noncompetitive: drug binds to a site adjacent to catalytic site and as a
result the catalytic property of the enzyme is lost.

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 Through receptors
 Receptors in pharmacology denote to a class of macromolecules that
are concerned specifically and directly in chemical signaling between
and within cells.
 Affinity: ability of a ligand to bind to receptors
 Intrinsic activity (efficacy): ability of a ligand to cause change in
receptor conformation upon binding.
 In view of binding, ligands can be
 Agonists: have affinity and intrinsic activity (A=1, IA=1)
 Antagonist: have affinity but no intrinsic activity (A=1, IA=0)
 Partial agonist/antagonist: have affinity but with submaximal
intrinsic activity (A=1, 0