Rate limiting steps in drug absorption 1.Disintegration time
2.Dissolution and solubility
3.Physical and chemical nature of active drug substance
4.Nature of excipients
5.Method of granulation
6.Dissolution test conditions
7.Gastric emptying
3. INTRODUCTION
DRUG ABSORPTION
It is defined as the process of movement of unchanged
drug from the site of administration to the site of measurement i.e.,
plasma.
A drug that is completely but slowly absorbed may fail to show
therapeutic response as the plasma concentration for desired
effect is never achieved.
On the contrary, a rapidly absorbed drug attains the therapeutic
level easily to elicit pharmacological effect.
4. In a series of kinetic or rate processes, the rate at which the drug
reaches the systemic circulation is determined by the slowest of the
various steps involved in the sequence. Such a step is called as the
rate-determining or rate-limiting step.
Systemic drug absorption from a drug product consists of a succession
of rate processes.
For solid oral, immediate release drug products (eg: tablets, capsules)
the rate processes include
Disintegration of drug product and its release
Dissolution of drug in aqueous environment
Absorption across cell membranes into systemic circulation
5. The rate and extent of drug absorption from its dosage form can be
influenced by a number of factors
1.Disintegration time
2.Dissolution and solubility
3.Physical and chemical nature of active drug substance
4.Nature of excipients
5.Method of granulation
6.Dissolution test conditions
7.Gastric emptying
6. DISINTEGRATION TIME
In vitro disintegration test is by no means a guarantee of drugs
bioavailability because if the disintegrated drug particles do not
dissolve, absorption is not possible.
The process of disintegration does not imply complete dissolution
of the tablet or the drug.
The official apparatus used for disintegration test and procedure is
described in the USP
Separate specifications are given for drug products that are
designed not to disintegrate such as troches, chewable tablets etc.
7. Biopharmaceutical Classification System(BCS) for highly soluble
and highly permeable drugs. In general, the disintegration test serves
as a component in the overall quality control of tablet manufacture.
Class Solubility Permeability Absorption
pattern
Rate limiting
step in
absorption
Examples
I High High Well
absorbed
Gastric
emptying
Diltiazem
II Low High Variable Dissolution Nifidipine
III High Low Variable Permeability Insulin
IV Low Low Poorly
absorbed
Case by case Taxol
8. DISSOLUTION
Dissolution is the process by which a solid drug substance
becomes dissolved in a solvent.
The steps in dissolution include the process of drug dissolution at
the surface of the solid particle, thus forming a saturated solution
around the particle.
The dissolved drug in the saturated solution, known as the
stagnant layer, diffuses to the bulk of the solvent from regions of
higher drug concentration to regions of low drug concentration.
9. The overall rate of drug dissolution may be described by the
Noyes-Whitney equation
Where,
dc/dt = rate of drug dissolution at time t
D = diffusion rate constant
A = surface area of the particle
Cs = concentration of drug in the stagnant layer
C = concentration of drug in the bulk solvent
h = thickness of the stagnant layer
10. This equation shows that dissolution in a flask may be influenced by
the physicochemical characteristics of the drug, formulation and
solvent.
The dissolution of drug in the body, particularly in the
gastrointestinal tract, is considered to be dissolving in an aqueous
environment.
Permeation of drug across the gut wall is affected by the ability of
the drug to diffuse and to partition between the lipid membranes.
A favourable partition coefficient (K oil/water) will facilitate drug
absorption.
11. PHYSICAL AND CHEMICAL NATURE OF ACTIVE DRUG
SUBSTANCE
DRUG SOLUBILITY
SALT FORMATION
• It is one of the common approaches used to increase drug
solubility and dissolution rate.
• It has always been assumed that sodium salts dissolve faster than
their corresponding insoluble acids.
12. E.G :- sodium and potassium salts of Pencillin G, phenytoin,
barbiturates, tolbutamide etc.
• Hydrochlorides and sulphates of weak bases are commonly used
due to high solubility.
E.G :- epinephrine, tetracycline
PARTICLE SIZE
• Surface area increases with decrease in particle size, higher
dissolution rates may be achieved through reduction of particle
size.
• Micronization of sparingly soluble drug to reduce particle size,
there is no guarantee of better dissolution and bioavailability.
13. NATURE OF EXCIPIENTS
DILUENTS
studies of starch on dissolution rate of salicylic acid tablet by
dry double compression process.
DISINTEGRANTS
Studies of various disintegrating agents on Phenobarbital
tablet showed that when Copagel(low viscosity grade of sodium
CMC) added before granulation decreased dissolution rate but
added after did not had any effect on dissolution rate
• Eg :- Microcrystalline cellulose
Starch
14. BINDERS AND GRANULATING AGENTS
Hydrophilic binder increase dissolution rate of poorly wettable
drug.
Large amount of binder increase hardness and decrease
disintegration/dissolution rate of tablet.
SURFACTANTS
They enhance the dissolution rate of poorly soluble drugs.
Eg :- Non-ionic surfactant polysorbate 80 increase dissolution rate of
phenacetin granules.
15. METHOD OF MANUFACTURE
METHOD OF GRANUALATION
A newer technology called as APOC
“Agglomerative Phase of Comminution” was found to produce
mechanically stronger tablets with higher dissolution rates than
those made by wet granulation. A possible mechanism is increased
internal surface area of granules produced by APOC method.
DRUG EXCIPIENT INTERACTION
These interactions occur during any unit operation such as mixing,
milling, blending, drying or granulating results in change in
dissolution.
Eg :- Prednisolone
16. COMPRESSION FORCE
The compression force influence density,
porosity, hardness, disintegration time and dissolution of tablet.
17. DISSOLUTION TEST CONDITIONS
AGITATION
• Speed of agitation generates a flow that continuously change the
liquid/solid interface between solvent and drug.
• In order to prevent turbulence and sustain a reproducible laminar
flow which is essential for obtaining reliable results, agitation
should be maintained at a relatively flow rate.
In general relatively low agitation should be applied
1. Basket method- 100rpm
2. Paddle method- 50-75rpm
18. TEMPERATURE
Drug solubility is temperature dependent.
A temperature of 37º ± 0.5 is maintained during dissolution of
oral dosage forms and suppositories.
Topical preparations - 25° and 30° are used.
DISSOLUTION MEDIUM
Addition of sodium sulphate decrease the dissolution rate.
Addition urea increases dissolution rate.
If drug is poorly soluble, a relatively large amount of fluid should
be used if complete dissolution is to be expected.
19. GASTRIC EMPTYING
Apart from dissolution of a drug and its permeation through
the bio membrane, the passage from stomach to the small intestine,
called as gastric emptying, can also be aa rate limiting step in drug
absorption in intestine.
Rapid gastric emptying is advisable where:
A rapid onset of action is desired
Dissolution of drug occurs in the intestine
The drugs are not stable in gastric fluids
Delay in gastric emptying is recommended in particular where:
The food promotes drug dissolution and absorption
Dis integration and dissolution of dosage form is promoted by
gastric fluids
The drugs irritate the gastric mucosa
20. Factors influence gastric emptying are
• Volume of meal
• Composition of meal
• Physical state and viscosity of meal
• Temperature of the meal
• Gastrointestinal pH
• Body posture
• Emotional state
• Exercise
• Drugs
21. CONCLUSION
In this process the drug disintegration and rate of drug reaches the
circulatory system can be determined.
The rate and extent of the drug absorption is determined.
22. REFERENCES
Applied Biopharmaceutics and pharmacokinetics by Shargel
Biopharmaceutics and Pharmacokinetics A Treatise by D.M.
Brahmankar
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