Module 1: Basic Principles of Pharmacology PDF

Summary

This document provides a comprehensive overview of basic pharmacology principles. It covers topics including drug names, classification, routes of administration, drug distribution and metabolism, as well as drug-receptor interactions.

Full Transcript

PHARMACOLOGY 1
1st Tri, A.Y 24-25
TF: 12:30-5:00 PM
  Introduction
 Principles of Drug action
 Pharmacodynamic and Pharmacokinetic Phase
 Autacoids
 Autonomic Drugs
COURSE  Sedative Hypnotics
OUTLINE  Anesthetics
 Antiseizure
 Drugs for Mood Disorders
 Antipsychotic Drugs
 Analgesic
 NSAIDS
Introduction to
Pharmacology
 Pharmacology

 From the Greek pharmakon (drug) + logos
(to study)

Introduction  It is the study of drugs

 It the science of drugs including their origin,
composition, pharmacokinetics, therapeutic
use, and toxicology
 Pharmacology

 a medical science that forms a backbone of the
medical profession as drugs form the corner stone of
therapy in human diseases.

 is the science that deals with drugs and their action
Introduction on living organisms

 the study of interaction of drugs with living
organisms. It also includes history, source,
physicochemical properties, dosage forms, methods
of administration, absorption, distribution mechanism
of action, biotransformation, excretion, clinical uses
and adverse effects of drugs.
 1. Pharmacodynamics – what does the drug
do to the body

2. Pharmacokinetics – what does the body do
BRANCHES OF to the drug
PHARMACOLOGY
3. Pharmaceutics – study of the rational drug
use in the management of disease
  Clinical Pharmacology: It evaluate the
pharmacological action of drug preferred route
of administration and safe dosage range in
human by clinical trails.

 Drugs: Drugs are chemicals that alter functions
of living organisms. Drugs are generally given
DEFINITIONS for the diagnosis, prevention, control or cure of
disease.

 Pharmacy: It is the science of identification,
selection, preservation, standardization,
compounding and dispensing of medical
substances.
  Toxicology: It’s the science of poisons. Many drugs
in larger doses may act as poisons. Poisons are
substances that cause harmful, dangerous or fatal
symptoms in living substances.

 Chemotherapy: It’s the effect of drugs upon
microorganisms, parasites and neoplastic cells living
and multiplying in living organisms.
DEFINITIONS
 Pharmacopoeia: An official code containing a
selected list of the established drugs and medical
preparations with descriptions of their physical
properties and tests for their identity, purity and
potency e.g. Indian Pharmacopoeia (I.P), British
Pharmacopoeia (B.P).
  A drug is a chemical substance, typically
of known structure, which, when
administered to a living organism,
produces a biological effect.

What is a
DRUG?  A pharmaceutical drug, also called a
medication or medicine, is a chemical
substance used to treat, cure, prevent, or
diagnose a disease or to promote well-being.
 1. Minerals: Liquid paraffin, magnesium sulfate,
magnesium trisilicate, kaolin, etc.
2. Animals: Insulin, thyroid extract, heparin and
antitoxin sera, etc.

Drugs are 3. Plants: Morphine, digoxin, atropine, castor oil, etc.
4. Synthetic source: Aspirin, sulfonamides,
obtained paracetamol, zidovudine, etc.
5. Micro organisms: Penicillin, streptomycin and many
from: other antibiotics.
6. Genetic engineering: Human insulin, human growth
hormone etc.

 Out of all the above sources, majority of the drugs
currently used in therapeutics are from synthetic source.
  Most drugs have four names:
 1. Chemical name, which is used by chemists and
researchers—e.g., 1–(2S)-3–mercopto-methyl propionyl L-
proline, MW = 217.29— and gives the chemical formula of
the drug;

 2. Generic or nonproprietary name, e.g., captopril,
which gives the biochemistry of the drug. This name is not
DRUG NAMES capitalized and is used in formularies;

 3. Trade name or proprietary name, e.g., Capoten®,
which is created by the manufacturer for commercial and
marketing purposes, capitalized with the trademark symbol;
and,

 4. Official name, which is usually the generic name as
listed in the official compendia, the United States
Pharmacopoeia (USP) and the National Formulary (NF),
e.g., captopril, USP-NF.
 Example 1
 Chemical name: acetyl salicylic acid
 Generic name: aspirin
 Brand name: Aspilet®
 Official name: Aspilet or baby aspirin

DRUG NAMES
EXAMPLE Example 2
 Chemical name: 1— [(25) —3-mercapto-methyl
propionyl]- proline
 Generic name: Captopril
 Brand name: Capoten®
 Official name: Captopril USP-NF
 Example 3

 Chemical name: 4-thio-1-azabicyclo [3,2,0] heptane-
2-carboxylic acid, 6-Raminophenyacetypamino-3,3-
DRUG NAMES dimethyl-7-oxo-, [2 S{2a,-5a,613 (5*)}]
EXAMPLE  Generic name: Ampicillin
 Brand name: Polycillin®
 Official name: Ampicillin®, USP
 Drugs may be classified as or according to
their:

 Therapeutic or clinical indication

CLASSIFICATION  Physiological or chemical action
OF  Target on the body systems
DRUGS  Prototype drugs
 Prescription & non-prescription drugs
 Health orphan drugs
 Illegal or recreational drugs
  Therapeutic or clinical indication

 Therapeutic Indication
 the primary information on the use of a
medicine. It should clearly state the
CLASSIFICATION disease/condition and population that a medicine
is intended to treat.
OF
DRUGS
 Clinical Indication
 a combination of three or four words that can be
used on a prescription to describe the effect on
the patient of a particular drug.
  Therapeutic or clinical indication

 Examples:
 antihypertensives or hypotensive, which tower blood
pressure;
CLASSIFICATION  antiemetics, which control nausea and vomiting;
OF  diuretics, which induce urination;
DRUGS  antacids, which are used for hyperacidity; and,
 antibiotics, which inhibit growth of microorganisms.
  Physiological or chemical action

 Physiological Action
 Pertaining to the action of a drug when introduced
to a healthy person (to contrast from the
CLASSIFICATION therapeutic action).

OF
DRUGS  Chemical Action
 Actions of drugs are the biochemical physiological
mechanisms by which the chemical produces a
response in living organisms.
  Physiological or chemical action

 Examples:

CLASSIFICATION  Beta-adrenergic blockers,
OF  Calcium channel blockers, and
DRUGS  Anticholinergics
 Antiadrenergics
  Target on the body system

 A drug target is a molecule in the body,
usually a protein, that is intrinsically
associated with a particular disease process
CLASSIFICATION and that could be addressed by a drug to
OF produce a desired therapeutic effect.
DRUGS
 Such as drugs affecting the central nervous
system (CNS), cardiovascular system, and
the gastrointestinal system.
  Prototype drugs

 It's the blue print and first form of
a drug that is used to make other and
alternate forms of the drug.
CLASSIFICATION
OF
 Those whose profile of pharmacologic
DRUGS research information is representative of
many drugs or is the most commonly used
drug in its class in the chemical setting

 is the 'lead agent' in a drug class (family).
  Prototype drugs

 Example:

CLASSIFICATION  imipramine, the prototype of tricyclic
OF depressants;
DRUGS
 diazepam, the prototype of benzodiazepines,
sedative and hypnotic agents, and anti-
anxiety agents.
  Prescription drugs

 a drug that can be obtained only by means
of a physician's prescription.

CLASSIFICATION  The most commonly used prescription
OF drugs fall into three classes:
 Opioids. Examples: oxycodone (OxyContin),
DRUGS hydrocodone (Vicodin), and meperidine (Demerol)

 Central Nervous System (CNS) Depressants
Examples: phenobarbital (Luminal), diazepam
(Valium), and alprazolam (Xanax)

 Stimulants.
  Non-prescription drugs or OTC drugs

 defined as drugs that are safe and effective for use by
the general public without advice from a health
professional.

CLASSIFICATION  Most commonly abused over-the-counter drugs
OF  Dextromethorphan (DXM) DXM is used for temporary relief
of cough caused by the common cold
DRUGS  Loperamide
 Pseudoephedrine/phenylephrine
 Diphenhydramine (DPH)
 Acetaminophen
 Oxybutynin transdermal system
 Antacids
 Other regularly abused OTC products
  Health orphan drugs

 Drugs that are not developed by the pharmaceutical
industry for economic reasons but which respond to
public health need.
CLASSIFICATION
OF  Example of which are used to treat rare health
conditions like cystic fibrosis, Hansen's disease
DRUGS (leprosy), sickle cell anemia, blepharospasm, and
infant botulism.
  Illegal or recreational drugs

 Illegal drugs

CLASSIFICATION  drugs which a person is not allowed to own or
use. A drug is any chemical that affects the human
OF body or mind when taken in any way.
DRUGS
 a substance that affects the way the body functions.
If a drug is classified as 'illegal', this means that it is
forbidden by law.
  Illegal or recreational drugs

 Recreational drugs

 a loose term that refers to legal and illegal drugs that are
used without medical supervision.

CLASSIFICATION
 There are four categories of recreational drugs:
OF
DRUGS  Analgesics - include narcotics like heroin, morphine, fentanyl, and
codeine.
 Depressants - include alcohol, barbiturates, tranquilizers, and
nicotine.
 Stimulants - include cocaine, methamphetamine, and ecstasy (MDMA).
 Hallucinogens - include LSD (acid), peyote (mescaline), psilocybin
(magic mushrooms), marijuana, ketamine, phencyclidine (PCP), and salvia
divinorum (diviner's sage).
 About 80% of drugs are taken orally and
undergo four phases, namely the:

GENERAL  1. Pharmaceutic phase or dissolution
- which refers to the reduction of drugs in solid form
PRINCIPLES (e.g., tablets and capsules) into smaller particles and
OF their dissolution into a liquid to facilitate absorption;

DRUG ACTION
 2. Pharmacokinetic phase
- which refers to the process of drug movement—its
absorption, distribution, metabolism (or
biotransformation), and excretion (or elimination)
  3. Pharmacodynamic phase,
- or the mechanism of drug action and its effects on the
body;

GENERAL  4. Pharmacotherapeutic phase
PRINCIPLES - includes the different approaches to treating diseases.
Most successful treatments require a combination of any
OF of the following:
DRUG ACTION
 Drug therapy, or treatment using drugs;
 Diet therapy, or diet restrictions, such as low salt diet for
patients with cardiovascular disease and hypertension;
 Physiotherapy, which refers to treatment with natural
physical forces, such as light, water, and heat; and
 Psychological therapy, which identifies stressors and
devise to minimize stress and/or the use of illegal drugs.
  PHARMACKINETIC PHASE
PHARMACOKINETIC  Pharmacokinetics deals with the absorption,
distribution, metabolism and excretion drugs in the
PHASE body.

A. Bio transport of Drug
B. Drug Absorption
C. Distribution of Drugs
D. Metabolism of Drugs
E. Excretion of Drugs
  It is translocation of a solute from one side of the
biological barrier to the other.

1. Structure of biological membrane: The outer
surface of the cell covered by a very thin structure
known as plasma membrane. It is composed of lipid
Bio- and protein molecules.
transport of The membrane proteins have many functions like:
(a) contributing structure to the membrane
drug (b) acting as enzyme
(c) acting as carrier for transport of substances
(d) acting as receptors.

 The plasma membrane is a semipermeable membrane
allowing certain chemical substances to pass freely e.g. it
allows water, glucose, etc. but it won’t allow sucrose until
it is converted into glucose and fructose.
 2. Passage of drug across membrane
Membrane transport—movement of substances
into and out of the cell

Bio- Two types of basic mechanisms are involved
transport of in the transport of substances across the cell
membrane:
drug
1. Passive transport mechanism

2. Active transport mechanism
 2. Passage of drug across membrane

Movements Into and Out of the Cell

Bio- Passive (Physical) Transport
Require no cellular energy
Active (Physiological) Transport
Require cellular energy and
transport of and include: include:
drug Simple diffusion Active transport
Facilitated diffusion Endocytosis
Osmosis Exocytosis
Filtration Transcytosis
  PASSIVE TRANSPORT
1. SIMPLE DIFFUSION
Movement of substances from regions of higher
concentration to regions of lower concentration
Solutes are lipid-soluble materials or small enough to
pass through membrane pores
Transport
Oxygen, carbon dioxide and lipid-soluble substances
System
2. FACILITATED DIFFUSION
 Diffusion across a membrane with the help of a channel
or carrier molecule
 Transports lipid-insoluble and large subs
 Glucose and amino acids
  PASSIVE TRANSPORT
 3. OSMOSIS
Movement of water through a selectively permeable
membrane from regions of higher concentration to
regions of lower concentration
Water moves toward a higher concentration of solutes
Transport
 4. FILTRATION
System Smaller molecules are forced through porous
membranes
Water and solutes are forced through a membrane by
fluid, or hydrostatic pressure
A pressure gradient must exist
Solute-containing fluid is pushed from a high-
pressure area to a lower pressure area
Ex. Molecules leaving blood capillaries
  ACTIVE TRANSPORT
1. ACTIVE TRANSPORT (SOLUTE PUMPING)

Carrier molecules transport substances across a
membrane from regions of lower concentration to
regions of higher concentration
Transport Amino acids, some sugars, and ions are transported
by protein carriers called solute pumps
System ATP energizes protein carriers
In most cases, substances are moved against
concentration gradients
 EXAMPLE:
 Sodium-Potassium Pump - Creates balance by “pumping”
three (3) sodium (Na+) OUT and two (2) potassium (K+)
INTO the cell
  ACTIVE TRANSPORT
2. ENDOCYTOSIS
 Cell engulfs a substance by forming a vesicle
around the substance
 Defined as a transport mechanism by which
Transport the macromolecules enter the cell.
System
 Three types:
Pinocytosis –”cell drinking”
Phagocytosis –“cell eating”
Receptor-mediated endocytosis – requires
the substance to bind to a membrane-bound
receptor
  ACTIVE TRANSPORT
3. EXOCYTOSIS
Moves materials out of the cell
Material is carried in a membranous vesicle
Vesicle migrates to plasma membrane
Vesicle combines with plasma membrane
Transport
System 4. TRANSCYTOSIS
 Endocytosis followed by exocytosis
 Transports a substance rapidly through a cell
 HIV crossing a cell layer
Material is emptied to the outside
 Absorption is the process by which the drug enters in to
the systemic circulation from the site of administration
through biological barrier.
 In case of intravenous or intra-arterial administration the
drug bypasses absorption processes and it enters into the
circulation directly.

Drug I. ROUTES OF ADMINISTRATION
Absorption a) Enteral routes - those in which the drug is absorbed
from the gastrointestinal tract

i. Oral; e.g. paracetamol tablet, omeprazole capsule
ii. Buccal cavity: e.g. fentanyl, naloxone
iii. Sublingual; e.g. loratadine, nitroglycerin
iv. Stomach: e.g. aspirin, alcohol
v. Intestine: e.g. most of non ionized and ionized drugs.
vi. Rectum: e.g. rectal suppositories, bisacodyl laxatives.
 I. ROUTES OF ADMINISTRATION (cont..)
a) Enteral routes

Advantages of oral route: This route is safe,
convenient and economical.
Drug
Absorption Disadvantages of oral route: Onset of drug action is
slow, irritant drugs cannot be administered and it is not
useful in vomiting and severe diarrhea, gastric acid and
digestive enzymes may destroy some drugs, and water
soluble drugs are absorbed poorly.
 I. ROUTES OF ADMINISTRATION (cont..)
b) Parenteral routes - the term parenteral is usually
used for drugs given by injection or infusion.

i. Intradermal: This is given into the layers of the skin
Drug e.g. B.C.G. vaccine

Absorption ii. Subcutaneous: Non-irritant substances are given into
subcutaneous tissue e.g. insulin

iii. Intramuscular: Soluble substances, mild irritants,
suspensions and colloids can be injected by this route.
These injections can be given to deltoid or gluteal
muscle. This route is one of the more common routes
e.g. multivitamins, streptomycin, etc.
 I. ROUTES OF ADMINISTRATION (cont..)
b) Parenteral routes
iv. Intravenous: Drugs directly given into a vein, produce rapid action,
no need of absorption as they enter directly into blood, can be given as
bolus e.g. furosemide, morphine, dopamine or as continuous infusion
e.g. fluids during shock or dehydration.
 Advantages: It can be given in large volumes, production of desired
Drug blood concentration can be obtained with a well designed dose.
 Disadvantages: Drug effect cannot be halted if once the drug is injected,
Absorption expertise is needed to give injection.

v. Intrathecal: Injected into subarachnoid space of spinal cord e.g.
spinal anesthetics.

vi. Intraperitoneal: Injections given into the abdominal cavity e.g.
infant saline, glucose.

vii. Intra-articular: Injected directly into a joint e.g. hydrocortisone.
 I. ROUTES OF ADMINISTRATION (cont..)
c) Transcutaneous routes - passing, entering, or made
by penetration through the skin transcutaneous infection.

i. Iontophoresis: Galvanic current is used for bringing
Drug about the penetration of drugs into the deeper tissue
e.g. salicylates.
Absorption ii. Inunctions: Absorbed when rubbed in to the skin e.g.
nitroglycerin ointment in angina pectoris.
iii. Jet injection: With help of high velocity jet produced
through a micro fine orifice; No need of needle and
therefore painless. e.g. mass inoculation programs.

iv. Adhesive units: A transdermal therapeutic system
produce prolonged systemic effect e.g. scopolamine for
motion sickness.
 I. ROUTES OF ADMINISTRATION (cont..)
d) Topical/Local route
- refers to the application of medication to the surface of
the skin or mucous membrane of the eye, ear, nose,
mouth, vagina, etc. with the intent of containing the
Drug pharmacological effect of the drug only to the surface or
within the layers of skin or mucous membrane.
Absorption
- e.g. dusting powder, paste, lotion, drops, ointment,
suppository for vagina and rectum.
 I. ROUTES OF ADMINISTRATION (cont..)
e) Inhalation route
- Administration of a substance in the form of a gas,
aerosol, or fine powder via the respiratory tract, usually
by oral or nasal inhalation, for local or systemic effect.
Drug
Absorption  e.g. salbutamol spray used in bronchial asthma and
volatile general anaesthetics.
 II. BIOAVAILABILITY
 It is the rate and amount of drug that is absorbed from a
given dosage form and reaches the systemic circulation
following non-vascular administration. When the drug is
given IV, the bioavailability is 100%
 it is important to know the manner in which a drug is
Drug absorbed. The route of administration largely determines
the latent period between administration and onset of
action.
Absorption  Drugs given by mouth may be inactive for the following
reasons:
a) Enzymatic degradation of polypeptides within the lumen
of the gastrointestinal tract e.g. insulin, ACTH.
b) Poor absorption through gastrointestinal tract e.g.
aminoglycoside antibiotic.

c) Inactivation by liver e.g. testosterone during first passage
through the liver before it reaches systemic circulation.
 III. FACTORS AFFECTING DRUG ABSORPTION AND
BIOAVAILABILITY

Seven factors affect absorption and bioavailability, namely:
 1. Form and solubility — Drugs given in aqueous
solution are more rapidly absorbed than those in oily
Drug solutions because they mix more readily with the aqueous
phase at the absorptive site. The rate at which the drug
Absorption dissolves may be a limiting factor if the drug is solid.
Local conditions at the site of absorption, like pH, can
alter solubility. This is especially true in the
gastrointestinal tract; e.g., aspirin is relatively insoluble in
acidic gastric contents.

 2. Concentration — More concentrated solutions of a
drug are more extensively absorbed.
 III. FACTORS AFFECTING DRUG ABSORPTION AND
BIOAVAILABILITY (cont..)

 3. Route of administration — Parenteral (especially
intravenous injections) are more actively absorbed than
orally administered drugs.
Drug  4. Blood circulation at the site of absorption —
Vasoconstrictors decrease blood flow. Shock and some
Absorption diseases decrease the rate of absorption while local
application of heat and massage increase blood flow and
enhance absorption.
 5. Surface area available for absorption — Drugs are
rapidly absorbed at sites where epithelial membranes
have large surface areas; e.g.. drugs are rapidly absorbed
in the pulmonary alveolar epithelium, the intestinal
mucosa and, in cases of extensive application, the skin.
Absorption in the stomach is not as rapid or extensive.
 III. FACTORS AFFECTING DRUG ABSORPTION AND
BIOAVAILABILITY (cont..)

 6. Presence of food and other drugs

Drug
 7. Changes in liver metabolism caused by dysfunction
Absorption and inadequate blood supply.
  Definition: Penetration of a drug to the sites of action
through the walls of blood vessels from the administered
site after absorption is called drug distribution. Drugs
distribute through various body fluid compartments such
as:
(a) Plasma
(b) Interstitial fluid compartment
Drug (c) Trans-cellular compartment.

Distribution
 Apparent Volume of distribution (VD): The volume
into which the total amount of a drug in the body would
have to be uniformly distributed to provide the
concentration of the drug actually measured in the
plasma. It is an apparent rather than real volume.
 Factors Determining the Rate of Distribution Of Drugs:

1. Protein Binding Of Drug:
 A Variable And Other Significant Portion Of Absorbed Drug
May Become Reversibly Bound To Plasma Proteins. The
Active Concentration Of The Drug Is That Part Which Is Not
Drug Bound, Because It Is Only This Fraction Which Is Free To
Leave The Plasma And Site Of Action.
Distribution
(A) Free Drug Leave Plasma To Site Of Action
(B) Binding Of Drugs To Plasma Proteins Assists Absorption
(C) Protein Binding Acts As A Temporary Store Of A Drug And
Tends To Prevent Large Fluctuations In Concentration Of
Unbound Drug In The Body Fluids
(D) Protein Binding Reduces Diffusion Of Drug Into The Cell And
There By Delays Its Metabolic Degradation E.G. High
Protein Bound Drug Like Phenylbutazone Is Long Acting.
 Factors Determining the Rate of Distribution Of
Drugs:

2. Plasma Concentration Of Drug (Pc)
 It represents the drug that is bound to the plasma
proteins (albumins and globulins) and the drug in free
form.
Drug  It Is The Free Form Of Drug That Is Distributed To The
Tissues And Fluids And Takes Part In Producing
Distribution Pharmacological Effects.
 The Concentration Of Free Drug In Plasma Does Not
Always Remain In The Same Level E.G.

i. After I.V. Administration Plasma Concentration Falls
Sharply

ii. After Oral Administration Plasma Concentration Rises And
Falls Gradually.

iii. After Sublingual Administration Plasma Concentration
Rise Sharply And Falls Gradually.
 Factors Determining the Rate of Distribution Of Drugs:

5. Affinity Of Drugs To Certain Organs
 The concentration of A drug in certain tissues after A single
dose may persist even when its plasma concentration is
reduced to low. Thus the hepatic concentration of
Drug mepacrine is more than 200 times that of plasma level.

Distribution  Their concentration may reach a very high level on chronic
administration. Iodine is similarly concentrated in the
thyroid tissue.
 Definition:
 Drug metabolism is the process by which the body
breaks down and converts medication into active
chemical substances.
 The process by which the body brings about changes in
drug molecule is referred as drug metabolism or
biotransformation.
Drug
Enzymes responsible for metabolism of drugs:
Metabolism
 a) Microsomal enzymes: Present in the smooth
endoplasmic reticulum of the liver, kidney and GIT e.g.
glucuronyl transferase, dehydrogenase , hydroxylase and
cytochrome P450

 b) Non-microsomal enzymes: Present in the cytoplasm,
mitochondria of different organs. e.g. esterases, amidase,
hydrolase.
 Types of biotransformation
 The chemical reactions involved in
biotransformation are classified as phase-I and
phase – II (conjugation) reactions.

Drug  In phase-I reaction the drug is converted to more
polar metabolite. If this metabolite is sufficiently
Metabolism polar, then it will be excreted in urine.

 Some metabolites may not be excreted and
further metabolized by phase –II reactions.
 Phase-I: Oxidation, reduction and hydrolysis.
 Phase-II: Glucuronidation, sulfate conjugation,
acetylation, glycine conjugation and methylation
reactions.
  Definition: Excretion of drugs means the
transportation of unaltered or altered form of drug out
of the body.

 The major processes of excretion include renal
excretion, hepatobiliary excretion and
Drug pulmonary excretion.
Excretion
 The minor routes of excretion are saliva, sweat,
tears, breast milk, vaginal fluid, nails and hair.

 The rate of excretion influences the duration of action
of drug. The drug that is excreted slowly, the
concentration of drug in the body is maintained and
the effects of the drug will continue for longer period.
 DIFFERENT ROUTES OF DRUG EXCRETION

a) Renal excretion: A major part of excretion of chemicals
is metabolically unchanged or changed. The excretion of
drug by the kidney involves.

Drug  i) Glomerular filtration
Excretion
 ii) Active tubular secretion

 iii) Passive tubular reabsorption
 DIFFERENT ROUTES OF DRUG EXCRETION

The function of glomerular filtration and active
tubular secretion is to remove drug out of the
body, while tubular reabsorption tends to retain
the drug.
Drug
Excretion i) Glomerular filtration: It is a process, which
depends on
 (1) the concentration of drug in the plasma
 (2) molecular size, shape and charge of drug
 (3) glomerular filtration rate. Only the drug which is not
bound with the plasma proteins can pass through
glomerulus. All the drugs which have low molecular
weight can pass through glomerulus e.g. digoxin,
ethambutol, etc.
 DIFFERENT ROUTES OF DRUG EXCRETION

 ii) Active tubular secretion
 The cells of the proximal convoluted tubule actively
transport drugs from the plasma into the lumen of the
tubule e.g. acetazolamide, benzyl penicillin, dopamine,
Drug pethidine, thiazides, histamine.

Excretion
 iii) Tubular reabsorption
 The reabsorption of drug from the lumen of the distal
convoluted tubules into plasma occurs either by simple
diffusion or by active transport. When the urine is
acidic, the degree of ionization of basic drug increase
and their reabsorption decreases. Conversely, when the
urine is more alkaline, the degree of ionization of acidic
drug increases and the reabsorption decreases.
 DIFFERENT ROUTES OF DRUG EXCRETION

 c) Gastrointestinal excretion: When a drug is
administered orally, a part of the drug is not absorbed and
excreted in the feces. The drugs which do not undergo
enterohepatic cycle after excretion into the bile are
subsequently passed with stool e.g. aluminum hydroxide
Drug changes the stool into white color, ferrous sulfate changes
the stool into black and rifampicin into orange red.
Excretion
 d) Pulmonary excretion: Drugs that are readily
vaporized, such as many inhalation anesthetics and
alcohols are excreted through lungs. The rate of drug
excretion through lung depends on the volume of air
exchange, depth of respiration, rate of pulmonary blood
flow and the drug concentration gradient.
 DIFFERENT ROUTES OF DRUG EXCRETION

 e) Sweat: A number of drugs are excreted into the sweat
either by simple diffusion or active secretion e.g. rifampicin,
metalloids like arsenic and other heavy metals.

Drug  f) Mammary excretion: Many drugs mostly weak basic
Excretion drugs are accumulated into the milk. Therefore lactating
mothers should be cautious about the intake of these drugs
because they may enter into baby through breast milk and
produce harmful effects in the baby e.g. ampicillin, aspirin,
chlordiazepoxide, coffee, diazepam, furosemide, morphine,
streptomycin etc.
  PHARMACDYNAMIC PHASE
PHARMACODYNAMIC  Pharmacodynamics is the study of the biochemical
and physiological effects of drugs and their
PHASE mechanisms of action.

A. Receptor and non-receptor mechanisms
B. Site of drug action
C. Dose Response relationship
D. Structural Activity Relationship
  Most of the drugs act by interacting with a cellular
component called receptor. Some drugs act through
simple physical or chemical reactions without interacting
with any receptor.
Receptor  Receptors are protein molecules present either on the cell
surface or with in the cell e.g. adrenergic receptors,
and Non-
cholinoceptors, insulin receptors, etc.
receptor
 The endogenous neurotransmitters, hormones, autacoids
Mechanisms and most of the drugs produce their effects by binding with
their specific receptors.

 Aluminum hydroxide and magnesium trisilicate, which are
used in the treatment of peptic ulcer disease act by non-
receptor mechanism by neutralizing the gastric acid.
  A drug, which is able to fit onto a receptor, is said to
have affinity for that receptor. Efficacy is the ability
of a drug to produce an effect at a receptor. An
agonist has both an affinity and efficacy whereas
antagonist has affinity but not efficacy or intrinsic
activity.

DRUG-  When a drug is able to stimulate a receptor, it is known
as an agonist and therefore mimics the endogenous
RECEPTOR transmitter.
 When the drug blocks a receptor, it is known as
INTERACTION antagonist and therefore blocks the action of the
endogenous transmitter (i.e. it will prevent the natural
chemical from acting on the receptor).
 However, as most drug binding is reversible, there will
be competition between the drug and the natural
stimulus to the receptor.
 A drug may act:

i. Extracellularly e.g: osmotic diuretics,
plasma expanders.
Site of
Drug Action ii. On the cell surface e.g.: digitalis,
penicillin, catecholamines

iii. Inside the cell e.g.: anti-cancer drugs,
steroid hormones.
  The exact relationship between the dose and the
response depends on the biological object under
observation and the drug employed.

Dose  When a logarithm of dose as abscissa and responses
as ordinate are constructed graphically, the “S”
Response shaped or sigmoid type curve is obtained.
Relationship
 The lowest concentration of a drug that elicits a
response is minimal dose, and the largest
concentration after which further increase in
concentration will not change the response is the
maximal dose.
 Dose
Response
Relationship
  1. Graded dose effect: As the dose administered to a single
subject or tissue increases, the pharmacological response also
increases in graded fashion up to ceiling effect.
- It is used for characterization of the action of drugs. The concentration
that is required to produce 50 % of the maximum effect is termed as
EC50 or ED50.

 2. Quantal dose effect: It is all or none response, the sensitive
Dose objects give response to small doses of a drug while some will be
resistant and need very large doses. The quantal dose- effect curve
Response is often characterized by stating the median effective dose and the
Relationship median lethal dose.
 Median lethal dose or LD50: This is the dose (mg/kg), which would
be expected to kill one half of a population of the same species and
strain.

 Median effective dose or ED50: This is the dose (mg/kg), which
produces a desired response in 50 per cent of test population.

 Therapeutic index: It is an approximate assessment of the safety of
the drug. It is the ratio of the median lethal dose and the median
effective dose. Also called as therapeutic window or safety.
 The activity of a drug is intimately related to its
chemical structure. Knowledge about the chemical
structure of a drug is useful for:

 (i) Synthesis of new compounds with more specific
actions and fewer adverse reactions
Structural
Activity  (ii) Synthesis of competitive antagonist and
Relationship
 (iii) Understanding the mechanism of drug action.
 Slight modification of structure of the compound can
change the effect completely.