Prof. Dr. Basavaraj K. Nanjwade M. Pharm., Ph. D

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Prof. Dr. Basavaraj K. Nanjwade M. Pharm., Ph. D

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Title: Prof. Dr. Basavaraj K. Nanjwade M. Pharm., Ph. D

1
ABSORPTION OF DRUGS

Prof. Dr. Basavaraj K. Nanjwade M. Pharm., Ph. D
Department of Pharmaceutics
KLE Universitys College of Pharmacy
BELGAUm 590010, Karnataka, India
Cell No 00919742431000
E-mail bknanjwade_at_yahoo.co.in

2
CONTENTS

Introduction of absorption.
Structure of the Cell Membrane.
Gastro intestinal absorption of drugs.
Mechanism of Drug absorption.
Factors affecting drug absorption
Absorption of drugs from non-per oral routes
Methods of determining absorption
References.

3
Introduction of Absorption

Definition
The process of movement of unchanged drug from
the site of administration to systemic
circulation.
There always exist a correlation between the
plasma concentration of a drug the therapeutic
response thus, absorption can also be defined
as the process of movement of unchanged drug from
the site of administration to the site of
measurement.
i.e., plasma.

4
Therapeutic success of a rapidly completely
absorbed drug.
?Not only the magnitude of drug that comes into
the systemic circulation but also the rate at
which it is absorbed is important this is clear
from the figure.
Minimum effective conc.
Plasma Drug Conc.
Therapeutic failure of a slowly absorbed drug.
Subtherapeutic level
Time
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CELL MEMBRANE

Also called the plasma membrane, plasmalemma or
phospholipid bilayer.
The plasma membrane is a flexible yet sturdy
barrier that surrounds contains the cytoplasm
of a cell.
Cell membrane mainly consists of
1. Lipid bilayer-
-phospholipid
-Cholesterol
-Glycolipids.
2. Proitens-
-Integral membrane proteins
-Lipid anchored proteins
-Peripheral Proteins

7
LIPID BILAYER
8
LIPID BILAYER

The basic structural framework of the plasma
membrane is the lipid bilayer.
Consists primarily of a thin layer of amphipathic
phospholipids which spontaneously arrange so that
the hydrophobic tail regions are shielded from
the surrounding polar fluid, causing the more
hydrophilic head regions to associate with the
cytosolic extracellular faces of the resulting
bilayer.
This forms a continuous, spherical lipid bilayer
app. 7nm thick.

It consists of two back to back layers
made up of three types Phospholipid,
Cholesterol, Glycolipids.
Phospholipids

?Principal type of lipid in membrane about 75
. Contains polar and non polar region. ?Polar
region is hydrophilic and non polar region is
hydrophobic. Non polar head contain two fatty
acid chain. ?One chain is straight fatty acid
chain.( Saturated ) Another tail have cis double
bond and have kink in tail. ( Unsaturated )
10
CHOLESTEROL

Amount in membrane is 20 .
Insert in membrane with same orientation as
phospholipids molecules.
Polar head of cholesterol is aligned with polar
head of phospholipids.
?FUNCTION
Immobilize first few hydrocarbons groups
phospholipids molecules.
Prevents crystallization of hydrocarbons
phase shift in membrane

11
NON - POLAR HYDROCARBON CHAIN
OH
RIGID STEROID REGION
POLAR REGION
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GLYCOLIPIDS

Another component of membrane lipids present
about 5 .
Carbohydrate groups form polar head.
Fatty acids tails are non polar.
Present in membrane layer that faces the
extracellular fluid.
This is one reason due to which bilayer is
asymmetric.
FUNCTIONS
Protective
Insulator
Site of receptor
binding

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COMPOSITION OF PROTEINS
16
INTEGRAL PROTEINS

Also known as Transmembrane protein.
Have hydrophilic and hydrophobic domain.
Hydrophobic domain anchore within the cell
membrane and hydrophilic domain interacts with
external molecules.
Hydrophobic domain consists of one, multiple or
combination of a helices and ß sheets protein
mofits.
Ex. Ion Channels, Proton pump, GPCR.

17
LIPID ANCHORED PROTEIN

Covalently bound to single or multiple lipid
molecules.
Hydrophobically inert into cell membrane anchor
the protein.
The protein itself is not in contact with
membrane.
Ex. G Proteins.

18
PERIPHERAL PROTEINS

Attached to integral membrane proteins OR
associated with peripheral regions of lipid
bilayer.
Have only temporary interaction with biological
membrane.
Once reacted with molecule, dissociates to carry
on its work in cytoplasm.
Ex. Some Enzyme, Some Hormone

19
GASTRO INTESTINAL ABSORPTION OF DRUGS
20

Stomach
The surface area for absorption of drugs is
relatively small in the stomach due to the
absence of macrovilli microvilli.
Extent of drug absorption is affected by
variation in the time it takes the stomach to
empty, i.e., how long the dosage form is able to
reside in stomach.
Drugs which are acid labile must not be in
contact with the acidic environment of the
stomach.
Stomach emptying applies more to the solid dosage
forms because the drug has to dissolve in the GI
fluid before it is available for absorption.
Since solubility dissolution rate of most drugs
is a function of pH, it follows that, a delivery
system carrying a drug that is predominantly
absorbed from the stomach, must stay in the
stomach for an extended period of time in order
to assure maximum dissolution therefore to
extent of absorption.

Small Intestine
The drugs which are predominantly absorbed
through the small intestine, the transit time of
a dosage form is the major determinant of extent
of absorption.
Various studies to determine transit time
Early studies using indirect methods placed the
average normal transit time through the small
intestine at about 7 hours.
These studies were based on the detection of
hydrogen after an oral dose of lactulose.
(Fermentation of lactulose by colon bacteria
yields hydrogen in the breath).

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Small Intestine

Newer studies suggest the transit time to be
about 3 to 4 hours.
Use gamma scintigraphy.
Thus, if the transit time in small intestine for
most healthy adults is between 3 to 4 hours, a
drug may take about 4 to 8 hours to pass through
the stomach small intestine during fasting
state.
During the fed state, the small intestine transit
time may take about 8 to 12 hours.

Large intestine
The major function of large intestine is to
absorb water from ingestible food residues which
are delivered to the large intestine in a fluid
state, eliminate them from the body as semi
solid feces.
Only a few drugs are absorbed in this region.

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MECHANISM OF DRUG ABSORPTION

Passive diffusion
Pore transport
Carrier- mediated transport
a) Facilitated diffusion
b) Active transport
Ionic or Electrochemical diffusion
Ion-pair transport
Endocytosis

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PASSIVE DIFFUSION

Also known as non-ionic diffusion.
It is defined as the difference in the drug
concentration on either side of the membrane.
Absorption of 90 of drugs.
The driving force for this process is the
concentration or electrochemical gradient.

Passive diffusion is best expressed by Ficks
first law of diffusion which states that the drug
molecules diffuse from a region of higher
concentration to one of lower concentration
until equilibrium is attained the rate of
diffusion is directly proportional to the
concentration gradient across the membrane.
dQ D A Km/w (CGIT C)
dt
h
Certain characteristic of passive diffusion can
be generalized.
Down hill transport

Greater the surface area lesser the thickness
of the membrane, faster the diffusion.
Equilibrium is attained when the concentration on
either side of the membrane become equal.
Greater the membrane/ water partition coefficient
of drug, faster the absorption.
Passive diffusion process is energy independent
but depends more or less on the square root of
the molecular size of the drugs.
The mol. Wt. of the most drugs lie between 100 to
400 Daltons which can be effectively absorbed
passively.

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Pore transport

Also known as convective transport, bulk flow or
filtration.
Important in the absorption of low mol. Wt. (less
than 100). Low molecular size (smaller than the
diameter of the pore) generally water-soluble
drugs through narrow, aqueous filled channels or
pores in the membrane structure.
e.g. urea, water sugars.
The driving force for the passage of the drugs is
the hydrostatic or the osmotic pressure
difference across the membrane.

The rate of absorption via pore transport depends
on the number size of the pores, given as
follows
dc N. R2. A . ?C
dt (?) (h)
where,
dc rate of the absorption.
dt
N number of pores
R radius of pores
?C concentration gradient
? viscosity of fluid in the pores

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CARRIER MEDIATED TRANSPORT MECHANISM

Involves a carrier (a component of the membrane)
which binds reversibly with the solute molecules
to be transported to yield the carrier solute
complex which transverses across the membrane to
the other side where it dissociates to yield the
solute molecule
The carrier then returns to its original site to
accept a fresh molecule of solute.
There are two types of carrier mediated transport
system
a) facilitated diffusion
b) active transport

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a) Facilitated diffusion

This mechanism involves the driving force is
concentration gradient.
In this system, no expenditure of energy is
involved (down-hill transport), therefore the
process is not inhibited by metabolic poisons
that interfere with energy production.

Limited importance in the absorption of drugs.
e.g. Such a transport system include entry of
glucose into RBCs intestinal absorption of
vitamins B1 B2.
A classical example of passive facilitated
diffusion is the gastro-intestinal absorption of
vitamin B12.
An intrinsic factor (IF), a glycoprotein produced
by the gastric parietal cells, forms a complex
with vitamin B12 which is then transported across
the intestinal membrane by a carrier system.

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b) Active transport

More important process than facilitated
diffusion.
The driving force is against the concentration
gradient or uphill transport.
Since the process is uphill, energy is required
in the work done by the barrier.
As the process requires expenditure of energy, it
can be inhibited by metabolic poisons that
interfere with energy production.

If drugs (especially used in cancer) have
structural similarities to such agents, they are
absorbed actively.
A good example of competitive inhibition of drug
absorption via active transport is the impaired
absorption of levodopa when ingested with meals
rich in proteins.
The rate of absorption by active transport can be
determined by applying the equation used for
Michalies-menten kinetics
dc C.(dc/dt)max
dt Km C
Where,
(dc/dt)max maximal rate of drug absorption at
high drug
concentration.
C concentration of drug available
for absorption
Km affinity constant of drug for the
barrier.

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IONIC OR ELECTROCHEMICAL DIFFUSION

This charge influences the permeation of drugs.
Molecular forms of solutes are unaffected by the
membrane charge permeate faster than ionic
forms.
The permeation of anions cations is also
influenced by pH.
Thus, at a given pH, the rate of permeation may
be as follows
Unionized molecule gt anions gt cations

The permeation of ionized drugs, particularly the
cationic drugs, depend on the potential
difference or electrical gradient as the driving
force across the membrane.
Once inside the membrane, the cations are
attached to negatively charged intracellular
membrane, thus giving rise to an electrical
gradient.
If the same drug is moving from a higher to lower
concentration, i.e., moving down the electrical
gradient , the phenomenon is known as
electrochemical diffusion.

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ION PAIR TRANSPORT

It is another mechanism is able to explain the
absorption of such drugs which ionize at all pH
condition.

Transport of charged molecules due to the
formation of a neutral complex with another
charged molecule carrying an opposite charge.
Drugs have low o/w partition coefficient values,
yet these penetrate the membrane by forming
reversible neutral complexes with endogenous
ions.
e.g. mucin of GIT.
Such neutral complexes have both the required
lipophilicity as well as aqueous solubility for
passive diffusion.
This phenomenon is known as ion-pair transport.

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ENDOCYTOSIS

It involves engulfing extracellular materials
within a segment of the cell membrane to form a
saccule or a vesicle (hence also called as
corpuscular or vesicular transport) which is then
pinched off intracellularly.

In endocytosis, there are three process
A) Phagocytosis
B) Pinocytosis
C) Transcytosis

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A) Phagocytosis
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B) Pinocytosis

This process is important in the absorption of
oil soluble vitamins in the uptake of nutrients.

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C) Transcytosis

It is a phenomenon in which endocytic vesicle is
transferred from one extracellular compartment to
another.

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Diagram Representing Absorption, Distribution,
Metabolism and Excretion The ultimate goal is
to have the drug reach the site of action in a
concentration which produces a pharmacological
effect. No matter how the drug is given (other
than IV) it must pass through a number of
biological membranes before it reaches the site
of action.
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DIFFUSION THROUGH MEMBRANES

Rate dependent on polarity and size.
Polarity estimated using the partition
coefficient.
The greater the lipid solubility the faster the
rate of diffusion
Smaller molecules (nm/A0) penetrate more rapidly.
Highly permeable to O2, CO2, NO and H2O .
Large polar molecules sugar, aa, phosphorylated
intermediates poor permeability
These are essential for cell function must be
actively transported

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MOVEMENT OF SUBSTANCES ACROSS CELL MEMBRANES
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BIOLOGICAL FACTORS

Penetration Of Drugs Through Gastro-intestinal
Tract
Penetration Of Drugs Through Blood Brain
Barrier
Penetration Of Drugs Through Placental Barrier
Penetration Of Drugs Through Across The Skin
Penetration Of Drugs Through The Mucous
Membrane Of The Nose, Throat, Trachea, Buccal
Cavity, Lungs ,Vaginal And Rectal Surfaces
PHYSIOLOGICAL FACTORS
Gastrointestinal (Gi) Physiology
Influence Of Drug Pka And Gi Ph On Drug
Absorbtion
Git Blood Flow
Gastric Emptying
Disease States

48
PENETRATION OF DRUGS THROUGH GASTRO-INTESTINAL
TRACT

The Git barrier that separates the lumen of the
stomach and intestine from systemic circulation
and is composed of lipids, proteins and
polysaccharides.
Git mucosa is a semi permeable membrane across
which various nutrients like Carbohydrates, Amino
acids, Vitamins and foreign substances are
transported and absorbed into the blood by
various mechanisms like
1. Passive diffusion
2. Pore transport
3. Facilitated transport
4. Active transport
5. Pinocytosis

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1. PASSIVE DIFFUSION

Major process for absorption of more than 90 of
drugs
Diffusion follows Ficks law
The drug molecules diffuse from a region of
higher concentration to a region of lower
concentration till equilibrium is attained.
Rate of diffusion is directly proportional to the
concentration gradient across the membrane.
Factors affecting Passive diffusion
Diffusion coefficient of the drug
Related to lipid solubility and molecular wt.
Thickness and surface area of the membrane
Size of the molecule

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2. PORE TRANSPORT

It involves the passage of ions through Aq. Pores
(4-40 A0)
Low molecular weight molecules (less than 100
Daltons) eg- urea, water, sugar are absorbed.
Also imp. In renal excretion, removal of drug
from CSF and entry
of drugs into liver.

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3. FACILITATED DIFFUSION

Carrier mediated transport (downhill transport)
Faster than passive diffusion
No energy expenditure is involved
Not inhibited by metabolic poisons
Important in transport of Polar molecules and
charged ions that dissolve in water but they can
not diffuse freely across cell membranes due to
the hydrophobic nature of the phospholipids.
Eg. 1. entry of glucose into RBCs
2. intestinal absorption vitamin B1 ,B2
3. transport of amino acids thru
permeases

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4. ACTIVE TRANSPORT

Carrier mediated transport (uphill transport)
Energy is required in the work done by the
carrier
Inhibited by metabolic poisons
Endogenous substances that are transported
actively include sodium, potassium, calcium,
iron, glucose, amino acids and vitamins like
niacin, pyridoxin.
Drugs having structural similarity to such
agents are absorbed actively
Eg. 1. Pyrimidine transport system absorption
of 5 FU
and 5 BU
2. L-amino acid transport system
absorption of
methyldopa and levodopa

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5. PINOCYTOSIS

Pinocytosis ("cell-drinking")
Uptake of fluid solute.
A form of endocytosis in which small particles
are brought into the cell in the form of small
vesicles which subsequently fuse with lysosomes
to hydrolyze, or to break down, the particles.
This process requires energy in the form of
(ATP).
Polio vaccine and large protein molecules are
absorbed by pinocytosis

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PENETRATION OF DRUGS THROUGH BLOOD BRAIN BARRIER

A stealth of endothelial cells lining the
capillaries.
It has tight junctions and lack large intra
cellular pores.
Further, neural tissue covers the capillaries.
Together , they constitute the so called BLOOD
BRAIN BARRIER
Astrocytes Special cells / elements of
supporting tissue found at the base of
endothelial membrane.
The blood-brain barrier (BBB) is a separation of
circulating blood and cerebrospinal fluid (CSF)
maintained by the choroid plexus in the central
nervous system (CNS).

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Since BBB is a lipoidal barrier, It allows
only the drugs having high o/w partition
coefficient to diffuse passively where as
moderately lipid soluble and partially ionised
molecules penetrate at a slow rate.
Endothelial cells restrict the diffusion of
microscopic objects (e.g. bacteria ) and large or
hydrophillic molecules into the CSF, while
allowing the diffusion of small hydrophobic
molecules (O2, hormones, CO2). Cells of the
barrier actively transport metabolic products
such as glucose across the barrier with specific
proteins.

Various approaches to promote crossing the BBB
by drugs
Use of Permeation enhancers such as dimethyl
sulfoxide (DMSO)
Osmotic disruption of the BBB by infusing
internal carotid artery
with mannitol
Use of Dihydropyridine redox system as drug
carriers to the brain
( the lipid soluble dihydropyridine is linked as
a carrier to the polar
drug to form a prodrug that rapidly crosses the
BBB )

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PENETRATION OF DRUGS THROUGH PLACENTAL BARRIER

Placenta is the membrane separating fetal blood
from the maternal blood.
It is made up of fetal trophoblast basement
membrane and the endothelium.
Mean thickness (25 µ) in early pregnancy and
reduces to (2 µ) at full term
Many drugs having mol. wt. lt 1000 daltons and
moderate to high lipid solubility e.g. ethanol,
sulfonamides , barbiturates, steroids ,
anticonvulsants and some antibiotics cross the
barrier by simple diffusion quite rapidly .
Nutrients essential for fetal growth are
transported by carrier mediated processes

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PENETRATION OF DRUGS THROUGH ACROSS THE SKIN

Skin is composed of three primary layers
the epidermis , which provides waterproofing and
serves as a barrier to infection
the dermis , which serves as a location for the
appendages of skin and
the hypodermis (subcutaneous adipose layer).
The stratum corneum is the outermost layer of
the epidermis and is composed mainly of dead
keratinised cells (from lack of oxygen and
nutrients). It has a thickness between 10 - 40
µm.
The dermis is the layer of skin beneath the
epidermis. It contains the hair follicles, sweat
glands, sebaceous glands, apocrine glands,
lymphatic vessels and blood vessels.
Hypodermis - Its purpose is to attach the skin
to underlying bone and muscle as well as
supplying it with blood vessels and nerves. The
main cell types are fibroblasts, macrophages and
adipocytes (the hypodermis contains 50 of body
fat).

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ROUTES OF PENETRATION
Through follicular region
Through sweat ducts
Through unbroken stratum corneum
FACTORS IN SKIN PERMEATION
Thickness of the skin layer
(Thickest on palms and soles thinest on the
face)
Skin condition permeability of skin is affected
by age, disease state or injury.
Skin temp. permeability increases with increase
in temp.
Hydration state
APPROACHES TO ENHANCE SKIN PERMEATION
Innuction
Iontophoresis
Sonophoresis
Magnetophoresis

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Penetration Of Drugs Through The Mucous Membrane
Of The Nose, Throat, Trachea, Buccal Cavity,
Lungs ,Vaginal And Rectal Surfaces

The barrier for the drug absorption is the
capillary endothelial membrane which is lipoidal
and consists of pores .
Thus, lipid soluble drugs can easily penetrate by
diffusion and smaller drug molecules can
penetrate by pore transport.

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Gastrointestinal (GI) Physiology
68

SMALL INTESTINE
Major site for absorption of most drugs due to
its large surface area (0.33 m2 ).
It is 7 meters in length and is approximately
2.5-3 cm in diameter.
The Folds in small intestine called as folds of
kerckring, result in 3 fold increase in surface
area ( 1 m2).
These folds possess finger like projections
called Villi which increase the surface area 30
times ( 10 m2).
From the surface of villi protrude several
microvilli which increase the surface area 600
times ( 200 m2).
Blood flow is 6-10 times that of stomach.
PH Range is 57.5 , favourable for most drugs to
remain unionised.
Peristaltic movement is slow, while transit time
is long.
Permeability is high.
All these factors make intestine the best site
for absorbtion of most drugs.

69
INFLUENCE OF DRUG pKa AND GI PH ON DRUG
ABSORBTION
70
GIT BLOOD FLOW

It plays an imp. role in drug absorption by
continuously maintaining the conc. Gradient
across the epithelial membrane
Polar molecules that are slowly absorbed show
no dependence on blood flow
The absorption of lipid soluble drugs and
molecules that are small enough to easily
penetrate through Aq. pores is rapid and highly
dependent on rate of blood flow

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GASTRIC EMPTYING

The process by which food leaves the stomach and
enters the duodenum.
It is a RDS in drug absorbtion.
Rapid Gastric Emptying Advisable when
Rapid onset of action is desired eg. Sedatives
Dissolution occurs in the intestine eg. Enteric
coated tablets
Drugs not stable in gi fluids eg. penicillin G
Drug is best absorbed from small intestine eg.
Vitamin B12
Delay in Gastric Emptying recommended when
Food promotes drug dissolution and absorbtion eg.
Gresiofulvin
Disintegration and dissolution is is promoted by
gastric fluids

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Factors affecting Gastric Emptying
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DISEASE STATES

CHF decreases blood flow to the Git, alters GI
PH, secretions and microbial flora.
Cirrhosis influences bioavailability mainly of
drugs that undergo considerable 1st pass
metabolism eg. Propranolol
Git infections like cholera and food poisoning
also result in malabsorbtion.

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PHYSIO-CHEMICAL FACTORS

PHYSICAL FACTORS

PHYSIO-CHEMICAL FACTORS

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PHYSICAL FACTORS

PARTICLE SIZE

Smaller particle size, greater surface area
then higher will be dissolution rate, because
dissolution is thought to take place at the
surface area of the solute( Drug).
This study is imp. for drugs that have low
aqueous solubility. Absorption of such drugs can
be increased by increasing particle size by
Micronization.
ex. Griseofulvin, active intravenously but not
effective when given orally.

To poor soluble drug, disintegration agents and
surface active agents may be added .
ex. Bioavailability of Phenacetin is increased
by tween 80.
Micronization also reduces the dose of some
drugs
ex. the dose of griseofulvin is reduced to one
half while the dose of spironolactone is reduced
to one twentieth.

PARTICLE SIZE

Lesser particle size is always not helpful
Ex. Micronization of Aspirin, phenobarbital,
lesser effective
surface area and hence lesser dissolution
rate
Reasons
On their surface, hydrophobic drugs absorb air
and reduce their wettability
Particle having size below 0.1 micron
reaggregate to form large particle
Particle having certain micro size get
electrical charge which preventing contact with
wetting medium

78
Finally drug size reduction and subsequent
increase in surface area and dissolution rate is
always not useful. Ex. of such drugs are
Penicillin G Erythromycin These Drugs are
unstable and degrade quickly in solution.
Sometime, reduction in particle size of
nitrofurantoin and piroxicam increase gastric
irritation These problem can be overcome by
Microencapsulation.
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2. Crystal Form Substance can exist
either in a crystalline or amorphous form. When
substance exist in more than one crystalline
form, the different form are called polymorphs
and the phenomena as polymorphism . Two types of
Polymorphism 1) Enantiotropic polymorph ex.
Sulfur 2) Monotropic polymorph ex. Glyceryl
Stearates Polymorphs have the same chemical
structure but different physical properties such
as solubility, density, hardness etc. ex.
Chlormphenicol has a several crystal form, and
when given orally as a suspension, the drug
concentration in the body was found to be
dependent on the percentage of ß - polymorph in
the suspension. The form is more soluble and
better absorbed.
80
One of the several form of polymorphic forms is
more stable than other. Such a stable form having
low energy state and high melting point and least
aqueous solubility The remaining polymorphs are
called as metastable forms which have high energy
state, low melting point and high aqueous
solubilities. About 40 of all organic
compounds exhibit polymorphism. Some drug exists
in amorphous form which have no internal crystal
structure. Such drugs have high energy states
than crystal form hence they have greater aqueous
solubility than crystalline form. Ex. Novobiocin,
cortisone acetate.
81
4. Complexation
This property can influence the effective drug
concentration in gi fluids. Complexation of
drug and gi fluids may alter the rate and
extent of absorption
eg. Intestinal Mucin form complex with
Streptomycin and Dihydro Streptomycin.
In some cases, Poor water soluble drugs can be
administered as water soluble complexes. eg.
Hydroquinone with Digoxin.
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5.Adsorption
It is a physical and surface phenomena where the
drug molecules are held on the surface of some
inert substances by vanderwalls forces.
ex. Charcoal used as an antidote When it is
co-administered with promazine, then it reduces
the rate and extent of absorption
Cholestyramine reduces the absorption of warfarin.
6.Drug Stability And Hydrolysis In GIT
Drugs undergoes various reactions due to wide
spectrum of ph and enzymatic activity of GI
fluid namely acid and enzymatic hydrolysis.
eg. T½ of Penicillin G 1 min. at pH 1
T½ of Penicillin G 9 min. at pH2 So it means
Penicillin G is stable at less acidic pH
Erythromycin and its esters are unstable at
gastric fluid (T½Less than 2 min.)
83

Certain salts also may have low solubility and
dissolution rate.

8. Presence Of Surfactant
Use of wetting agent and Solubilizing agent
improve the Dissolution rate absorption of
drugs. Ex. Tween 80 increase the rate extent of
absorption of Phenacetin.
9. Dissolution
Disintegration is the formation of dispersed
granules from an intact solid dosage form whereas
the dissolution is the formation of solvated drug
molecules from the drug
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SOLID DRUG
DISSOLUTION
DRUG AT ABSORPTION SITE
ABSORPTION
DRUG IN SYSTEMIC CIRCULATION
85
NOYES AND WHITNEYS EQUATION
dc/dt KS(CS-C)
Where, dc/dt Rate constant, K constant,
S surface area of the dissolving solid,
Cssolubility of the drug in the solvent,
Cconcentration of drug in the solvent at time t.
Constant KD/h
Where, D is the diffusion coefficient of the
dissolving material and h is the thickness of
the diffusion layer
Here, C will always negligible compared to Cs
So, dc/dtDSCs/h
86
PHYSICOCHEMICAL FACTORS

1) pH PARTITION THEORY (Brodie)
It explain drug absorption from GIT and its
distribution across biomembranes.
Drug(gt100 daltons) transported by passive
diffusion depend upon
dissociation constant, pKa of the drug
lipid solubility, K o/w
pH at absorption site.
Most drugs are either weak acids or weak bases
whose degree of ionization is depend upon pH of
biological fluid.

For a drug to be absorbed, it should be unionized
and the unionized portion should be lipid
soluble.
The fraction of drug remaining unionized is a
function of both
Dissociation constant (pKa) and pH of solution.
The pH partition theory is based on following
assumption
GIT acts as a lipoidal barrier to the transport
of the drug
The rate of absorption of drug is directly
proportional to its fraction of unionised drug
Higher the lipophilicity of the unionised
degree, better the absorption.

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HENDERSON HASSELBATCH EQUATION For acid,
pKa - pH log Cu/Ci
For base, pKa pH
log Ci/Cu Eg. Weak acid aspirin (pKa3.5) in
stomach (pH1) will have gt 99of unionized form
so gets absorbed in stomach Weak base quinine
(pKa8.5) will have very negligible unionization
in gastric pH so negligible absorption
Several prodrugs have been developed which are
lipid soluble to overcome poor oral absorption of
their parent compounds.
89
eg. Pivampicilin, the pivaloyloxy-methyl ester
of ampicilin is More lipid soluble than
ampicilin. Lipid solubility is provided to a
drug by its partition coefficient between An
organic solvent and water or an aq. Buffer (same
pH of ab. Site) E.g. Barbital has a p.c. of
0.7 its absorption is 12
Phenobarbital ( p.c 4.8 absorption12)
Secobarbital (p.c 50.7 absorption40)
90
2)DRUG SOLUBILITY The absorption of drug
requires that molecule be in solution at
absorption site. Dissolution, an important step,
depends upon solubility of drug substance. pH
solubility profile pH environment of GIT varies
from Acidic in stomach to slightly Alkaline in a
small intestine.

soluble
1)Basic drug 1) Acidic
medium( stomach) 2)Acidic drug
2) basic medium( intestestine)
91

Improvement of solubility
Addition of acidic or basic excipient
Ex Solubility of Aspirin (weak acid) increased
by addition of basic excipient.
For formulation of CRD , buffering agents may be
added to slow or modify the release rate of a
fast dissolving drug.

92
PHARMACEUTICAL FACTORS MEANS Absorption rate
depends on the dosage Form which is
administred,ingredients used, procedures Used in
formulation of dosage forms. The
availability of the drug for absorption from the
dosage forms is in order. Solutions gt
Suspensions gt capsules gt Compressed Tablets gt
Coated tablets.
93

SOLUTIONS
Shows maximum bioavailability and factors
affecting
Absorption from solution are as follows
Chemical stability of drug
Complexation between drug and exipients of
formulation
to increase the solubility, stability.
3. Solubilization incorporation of drug into
micelles to increase the solubility of drugs.
4. Viscosity
5. Type of solution Whether aqueous or oily
solution.

SUSPENSIONS
It comes next after solutions with respect to
bioavailability
Factors that affects absorption from
suspensions are
Particle size and effective surface area of
dispersed phase
2. Crystal form of drug some drug can change
their crystal
structure.
Eg. Sulfathiazole can change its polymorphic
form, it can be
overcome by addition by adding PVP.
3. Complexation Formation of nonabsorbable
complex between
drug and other ingredients.
Eg. Promazine forms a complex with
attapulgite.

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4. Inclusion of surfactant Eg. The
absorption of phenacitin from suspension is
increased in presence of tween 80. 5.
Viscosity of suspension Eg. Methyl cellulose
reduces the rate and absorption of
nitrofurantoin 6. Inclusion of colourants
Eg. Brilliant blue in phenobarbitone suspension.
96

CAPSULES
Two types of capsule
Hard gelatin capsule
2. Soft gelatin capsule

97
HARD GELATIN CAPSULE The rate of absorption of
drugs from capsule is function Of some
factors. 1.Dissolution rate of gelatin
shell. 2.The rate of penetration of GI fluids
into encapsulated mass 3.The rate at which the
mass disaggregates in the GI fluid 4. The rate of
dissolution. 5. Effect of excipients a).Diluents
b).Lubricants c). Wetting characteristics of
drug d).Packing density
98
SOFT GELATIN CAPSULE SGS has a gelatin shell
thicker than HGS,but shell is Plasticized by
adding glycerin,sorbitol.SGS may used To contain
non aqueous solution or liquid or semi
solid. SGC have a better bioavailability than
powder filled HGC And are equivalent to
emulsions. Eg. Quinine derivative was better
absorbed from SGC Containing drug base compared
with HGC containing HCl salts. Grieseoflavin
exhibited 88 absorption from soft
gelatin Capsules compared to HGC(30)
99
TABLETS 1.Compressed tablets 2. Coated tablets
100
Compressed tablets Bioavailability are more due
to large reduction in surface area.
A
B
Intact tablets a granules
primary drug particles
K2
K1
K3
Drug in GI fluid
K4
Drug absorbed in body
101
The rate constants decrease in the following
order.
K3gtgtK2gtgtK1 The overall dissolution rate and
bioavailability of a poor Soluble drugs is
influenced by 1.The physicochemical properties of
liberated particles. 2. The nature and quantity
of additives. 3. The compaction pressure and
speed of compression. 4. The storage and age of
tablet
102
1.Effect of diluents Na Salicylates starch
Faster dissolution Na salicylates
lactosePoor dissolution. 2.Effect of
Granulating agent Phenobarbital Gelatin
solutionFaster dissolution PhenobarbitalPEG
6000 poor dissolution. 3.Effect of
lubricants Magnesium stearate will retard the
dissolution of aspirin tablet Whereas SLS
enhance the dissolution.
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4.Effect of disintegrants Starch tend to swell
with wetting and break apart the dosage form. It
is reported that 325mg of salicylic acid tablet
were prepared by using different concentrations
(5,10,20) and max. dissolution was achieved
With 20 starch. 5. Effect of
colorants 6.Effect of Compression force
104
COATED TABLETS There are three types of
coating Sugar coating Film coating Enteric
coating SUGAR COATING Sugar,Shellac,fatty
glycerides, bees wax, silicone resin Sub coating
agent Talc,acacia,starch. FILM
COATING Polymers, dispersible cellulose
derivatives like HPMC CMC. ENTERIC
COATING Shellac, cellulose acetate phthalate etc.
105
Factors affecting the drug release
are 1.Thickness of coating e.g.. Quinine shows
decrease in rate of absorption if coated with
cellulose acetate phthalate. 2.The amount of
dusting powder 3.Effect of ageing e.g. The
shellac coated tablets of Para amino
salicylic acid when given after two years plasma
concentration of 6-7mg/100ml. However the tablets
stored for 3½ years showed plasma concentration
of only 2mg/100ml which is the sub therapeutic
effect.
106
SUBLINGUAL / BUCCAL ROUTE
SUBLINGUAL / BUCCAL ROUTE

SUBLINGUAL ROUTE the dosage form is placed
beneath the tongue.
BUCCAL ROUTE Dosage form is placed between the
cheek and teeth or In the cheek pouch.
Drugs administered by this route are supposed to
produce systemic drug effects, and consequently,
they must have good absorption from oral mucosa.
Oral mucosal regions are highly vascularised
therefore rapid onset of action is observed.
For Eg, anti-anginal drug Nitroglycerin.

107

SUBLINGUAL / BUCCAL ROUTE
Blood perfuses oral regions drains directly into
the general circulation.
Barrier to drug absorption from these routes is
epithelium of oral mucosa.
Passive diffusion is the major mechanism of
absorption of most drugs.
In general, sublingual tablets are designed to
dissolve slowly to minimize possibility of
swallowing the dose.
Exception include Nitroglycerin, Isosorbide
dinitrate tablets which dissolves within minutes
in buccal cavity to provide prompt treatment of
acute anginal episodes.

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Factors to be considered

Lipophilicity of drug The lipid solubility
should be high for absorption.
Salivary secretion drug should be soluble in
buccal fluid.
pH of saliva pH of saliva is usually 6.
Storage compartment some drugs have storage
compartment in buccal mucosa. Eg, Buprenorphine
Thickness of oral epithelium Sublingual
absorption is faster than buccal, because
former region is thinner than that of buccal
mucosa.

111
FACTORS LIMITTING DRUG ADMINISTRATION

Limited mucosal surface area.
Taste of medicament and discomfort.
EXAMPLES Nitroglycerin, Isosorbide
dinitrate, Progesterone, Oxytocin, Fenosterol,
Morphine.

112
RECTAL ADMINISTRATION

Absorption across the rectal mucosa occurs by
passive diffusion.
This route of administration is useful in
children, old people and unconscious patients.
Eg., drugs that administered are aspirin,
acetaminophen, theophylline, indomethacin,
promethazine certain barbiturates.

113
PARENTERAL ROUTES

114
INTRAVENOUS ROUTE
INTRAVENOUS ROUTE

Absorption phase is bypassed
(100 bioavailability)
1.Precise, accurate and almost immediate onset of
action,
2. Large quantities can be given, fairly pain
free
3. Greater risk of adverse effects
a. High concentration attained rapidly
b. Risk of embolism

115
INTRAVENOUS ROUTE

This route is used when a rapid clinical response
is required like treatment of epileptic seizures,
acute asthmatic and cardiac arrhythmias.
There may also be a danger of precipitation of
drug in the vein if the inj. is too rapidly. This
could result in thrombophlebitis.
This mode of administration is required with
drugs having short half lives and narrow
therapeutic index.
Bioavailability is not considered by this route.
Mainly antibiotics are administered by this route.

116
Intra arterial injection

In this route the drugs are injected directly
into the artery.
It is mainly used for cancer chemotherapy.
It increased drug delivery to the area supplied
by the infused artery and decreased drug delivery
to systemic circulation.

117
INTRA MUSCULAR INJECTION

Absorption of drug from muscles is rapid and
absorption rate is perfusion rate limited.
Polypeptides of less than approx 5000 gram per
mole primarily pass through capillary pathway
Greater than about 20000 g/mol are less able to
traverse capillary wall, they primarily enter
blood via lymphatic pathway.

118
Factors determining rate of drug absorption

1. Vascularity to the inj. Site
Blood flow rates to intramuscular tissues
are
Arm (deltoid) gt thigh (vastus lateralis) gt
buttocks (gluteus maximus).
2. Lipid solubility and ionisation of drug.
3. Molecular size of drug.
4. Volume of inj. And drug concentration.
5. pH viscosity of inj. vehicle.

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SUBCUTANOUS ROUTE 1. Slow and
constant absorption 2. Absorption is limited by
blood flow, affected if
circulatory problems exist. 3. The blood supply
to this is poorer than that of muscular
tissue. 4. Concurrent administration of
vasoconstrictor will slow absorption, e.g.
Epinephrine. 5. The absorption is hastened by
massage, application of heat to increase
blood flow and inclusion of enzyme Hyaluronidase
in drug solution. eg. Insulin.
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121

TOPICAL ADMINISTRATION
MUCOSAL MEMBRANES(eye drops, antiseptic,
sunscreen, nasal, etc.)
SKIN
a. Dermal - rubbing in of oil or ointment
(local action)
b. Transdermal - absorption of drug through
skin (systemic action)
i. stable blood levels
ii. no first pass metabolism
iii. drug must be potent.

122

Skin consist of three layers
Epidermis
Dermis
Subcutaneous fat tissue
The main route for the penetration of the drugs
is generally through epidermal layer
Stratum corneum is the rate limiting barrier in
passive percutaneous absorption of drug.

123

The stratum corneum is the outermost layer of
the epidermis and is composed mainly of dead
keratinized cells (from lack of oxygen and
nutrients). It has a thickness between 10 - 40
µm.
The dermis is the layer of skin beneath the
epidermis. It contains the hair follicles, sweat
glands, sebaceous glands, apocrine glands,
lymphatic vessels and blood vessels.
Hypodermis - Its purpose is to attach the skin
to underlying bone and muscle as well as
supplying it with blood vessels and nerves. The
main cell types are fibroblasts, macrophages and
adiposities (the hypodermis contains 50 of body
fat).

124

125
OCULAR ADMINISTRATION

Eye is the most easily accessible site for
topical administration of a medication.
Topical application of drug to eyes meant for
Mydriasis, miosis, anaesthesia, treatment of
infection, glaucoma etc.
Opthalmic solution are administered into
cul-de-sac.
Barrier to intra occular penetration is cornea.
It possess both hydrophilic and lipophilic
characterstics.
pH of lacrimal fluid is 7.4.
pH of lacrimal fluid influences absorption of
weak electrolyte like Pilocarpine.

126
OCULAR ADMINISTRATION

High pH of formulation decrease tear flow and
Low pH of formulation increases tear flow.
Human eye can hold around 10 microlitre of
fluid. So small volume in concentrated form
increases effectiveness.
Viscosity empartners increases bioavailability
eg, oily solutions, ointment etc.
Systemic entry of drug occur by lacrimal duct
which drains lacrimal fluid into nasal cavity.

127
Composition of eye

Water - 98
Solid -1.8
Organic element
Protein - 0.67, sugar - 0.65, Nacl - 0.66
Other mineral element sodium, potassium and
ammonia - 0.79

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129
Characteristics required to optimize ocular drug
delivery system

Good corneal penetration.
Prolong contact time with corneal tissue.
Simplicity of instillation for the patient.
Non irritative and comfortable form (viscous
solution should not provoke lachrymal secretion
and reflex blinking)
Appropriate rheological properties
concentrations of the viscous system.

130
Advantages

Increase ocular residence.. Improving
bioavailability
Prolonged drug release.. better efficacy
Less visual systemic side effects
Increased shelf life
Exclusion of preservatives
Reduction of systemic side effects
Reduction of the number of administration
Better patient compliance
Accurate dose in the eye. a better therapy

131
FACTOR INFLUENCING PERCUTANEOUS ABSORPTION

Drug release from dosage form
Drug concentration in the formulation
Drug oil water partition coefficient.
Drug affinity to the skin tissue
Surface area
Site of application
Hydration of skin
Nature of vehicle used

132
FACTOR INFLUENCING PERCUTANEOUS ABSORPTION

9. Rubbing
10. Contact period
11. Permeation enhancers

133
INHALATIONAL ROUTE 1.Gaseous and
volatile agents and aerosols. 2.Rapid onset of
action due to rapid access to circulation
a.Large surface area b.Thin membranes
separates alveoli from circulation
c.High blood flow Particles larger than 20
micron and the particles impact in the mouth and
throat. Smaller than 0.5 micron and they aren't
retained.
134

Intra nasal administration
Drugs generally administered by intra nasal route
for treatment of local condition such as
perennial rhinitis, allergic rhinitis and nasal
decongestion etc.
Absorption of lipophilic drugs through nasal
mucosa by passive diffusion and absorption of
polar drugs by pore transport.
Rate of absorption of lipophilic drugs depend on
their molecular weight.
Drugs with molecular weight less than 400 daltons
exhibit higher rate of absorption.

135

cont
Drugs with molecular weight 1000 daltons show
moderate rate of absorption.
Presently nasal route is becoming popular for
systemic delivery of peptide and proteins, this
is because of high permeability of nasal mucosa
with vasculature.

136

137
Advantages

Rapid drug absorption via highly-vascularized
mucosa
Rapid onset of action
Ease of administration, non-invasive
Avoidance of the gastrointestinal tract and
first-pass metabolism
Improved bioavailability
Lower dose/reduced side effects
Improved convenience and compliance
Self-administration.

138
Disadvantages

Nasal cavity provides smaller absorption surface
area when compared to GIT.
Relatively inconvenient to patients when compared
to oral delivery since there is possibility of
nasal irritation.
The histological toxicity of absorption enhancers
used in the nasal drug delivery system is not yet
clearly established.

139
Enhancement in absorption

Following approaches used for absorption
enhancement -
Use of absorption enhancers
Increase in residence time.
Administration of drug in the form of
microspheres.
Use of physiological modifying agents

140
Enhancement in absorption

Use of absorption enhancers-
Absorption enhancers work by increasing the
rate at which the drug pass through the nasal
mucosa.
Various enhancers used are surfactants, bile
salts, chelaters, fatty acid salts,
phospholipids, cyclodextrins, glycols etc.

141
Various mechanisms involved in absorption
enhancements are-

Increased drug solubility
Decreased mucosal viscosity
Decrease enzymatic degradation
Increased Paracellular transport
Increased transcellular transport

142
Various mechanisms involved in absorption
enhancements are-

Increase in residence time-
By increasing the residence time the
increase in the higher local drug concentration
in the mucous lining of the nasal mucosa is
obtained.
Various mucoadhesive polymers like
methylcellulose, carboxy methyl cellulose or
polyarcylic acid are used for increasing the
residence time.

143
Various mechanisms involved in absorption
enhancements are-

Use of physiological modifying agents-
These agents are vasoactive agents and exert
their action by increasing the nasal blood flow.
The example of such agents are histamine,
leukotrienene D4, prostaglandin E1 and
ß-adrenergic agents like isoprenaline and
terbutaline.

144
Applications of nasal drug delivery

Nasal delivery of organic based pharmaceuticals
-
Various organic based pharmaceuticals have been
investigated for nasal delivery which includes
drug with extensive presystemic metabolism.
E.g. Progesterone, Estradiol, Nitroglycerin,
Propranolol, etc.

145
Applications of nasal drug delivery

Nasal delivery of peptide based drugs -
Nasal delivery of peptides and proteins is depend
on
The structure and size of the molecule.
Nasal residence time
Formulation variables (pH, viscosity)
E.g. calcitonin, secretin, albumins, insulin,
glucagon, etc.

146

PULMONARY ADMINISTRATION
The drugs may be administered for local action of
bronchioles or their systemic effects through
absorption of lungs.
Inhalation sprays and aerosols are used to
deliver the drugs to the lungs.
Larger surface area of alveoli, high permeability
of alveolar epithelium for drug penetration, and
a rich vasculature are responsible for rapid
absorption of drugs by this route

147

PULMONARY ADMINISTRATION
In general particles greater than 10mm are
retained in the throat and upper airways whereas
fine particles reach the pulmonary epithelium
Drugs generally administered by this route are
bronchodilators (e.g.. Salbutamol,
isoproterenol), antiallergic (e.g.. Cromolym
sodium), and antiinflammatory (e.g..
Betamethasone, dexamethasone).

148

149
Advantages

Smaller doses can be administered locally.
Reduce the potential incidence of adverse
systemic effect.
It used when a drug is poorly absorbed orally,
e.g. Na cromoglicate.
It is used when drug is rapidly metabolized
orally, e.g. isoprenaline

150
IN-VITRO METHODS

Everted small intestine sac method.
Everted sac modification.
Circulation technique.
Everted intestinal ring or slice technique.

151
Why in-vitro studies

Because of economical ethical limitations of
in-vivo studies.
Simple provide valuable information.
To assess the major factors involved in
absorption.
Predict the rate extent of drug absorption.
Procedures are of great value during screening of
new drug candidates.
Carried out outside the body.
Used to assess permeability of drug using animal
tissues.

152
Everted small intestine sac technique
Isolation of rat intestine
Inverting the intestine
Filling the sac with drug free buffer solution
Immersion of sac in Erlenmeyer flask containing
drug buffer solution
Contd
153
Flask its contents oxygenated agitated at
37oC for specific period of time
After incubation, the serosal content is assayed
for drug content
154
Figure( reverted sac technique)
Serosal side
Mucosal side
(intestinal segment before eversion)
Serosal side
Buffer solution
Ligature
Mucosal side
(after eversion)
155
Advantages

Prolongs the viability integrity of the
preparation after removal from the animal.
Convenience accuracy with respect to drug
analysis.
The epithelial cells of the mucosal surface are
exposed directly to the oxygenated mucosal fluid.

DISADVANTAGES

Difficulty in obtaining more than one sample per
intestinal segment

156
Everted sac modification

Crane Wilson modification.
Essential features of simple sac methods are
retained.
Modification- the intestine is tied to a cannula.

157
cannula
Plain buffer
Buffer solution with drug
Water maintained at 37o C
aerator
(FIG EVERTED SAC MODIFICATION)
158
Procedure
Animal fasted for 20-24hrs
Water is allowed ad libitum
Animal killed with blow on head or anesthetized
with ether or chloroform
Entire small intestine is everted
Contd.
159
Segments of 5-15cm length are cut from specific
region of the intestine
Distal ends tied proximal end is attached to
cannula
Segments suspended in 40-100ml of drug mucosal
solution.
About 1ml/5cm length of drug free buffer is then
placed in serosal compartment
Mucosal solution aerated
160
How to determine the rate of drug transfer

The entire volume of serosal solution is removed
from the sac at each time interval with the help
of syringe it is replaced with fresh buffer
solution.
The amount of drug that permeates the intestinal
mucosa is plotted against time to describe the
absorption profile of the drug at any specific pH.

161
Advantages

A number of different solutions may be tested
with a single segment of the intestine unlike in
the sac technique.
Simple reproducible.
It distinguishes between active passive
absorption.
It determines the region of the small intestine
where absorption is optimal, particularly in the
case of active transport.
Also used to study the effect of pH, surface
active agents, complexation enzymatic reaction.

162
Disadvantages

The intestinal preparation is removed from the
animal as well as from its blood supply. Under
these conditions, the permeability
characteristics of the membrane are significantly
altered.
The rate of transport of drug as determined from
the everted sac technique, may be slower than in
the intact animal.

163
Circulation technique

Small intestine may or may not be everted.
In this method either entire small intestine of
small lab animal or a segment is isolated.
Oxygenated buffer containing the drug is
circulated through the lumen.
Drug free buffer is also circulated on the
serosal side

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