This document provides an overview of colon specific drug delivery systems. It discusses the advantages of targeting drug delivery to the colon which includes reduced dosing, lower side effects, and improved patient compliance. It also reviews some limitations such as multiple manufacturing steps and potential for drug degradation by colonic microflora. The document then examines the anatomy and physiology of the colon, factors that influence colonic drug delivery such as pH and transit time, and how drugs are absorbed in the colon. It concludes by outlining several approaches to colon specific drug delivery including pH dependent coatings, time release systems, prodrugs activated by colonic bacteria, and the use of carriers degraded by colonic microflora.
2. Contents
Introduction
Advantages & limitations
Anatomy of physiology of colon
Factors related to colonic drug delivery
Drug absorption in the colon
Role of absorption enhancers
Approaches to colon specific drug delivery
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3. Introduction
Colonic delivery refers to targeted delivery of drugs
into the lower GI tract, which occurs primarily in the
large intestine i.e. colon.
Most of the conventional drug delivery for treating
colon disorders are failing as the drugs do not reach
the site of action in appropriate concentrations.
Colonic drug delivery has gained importance not
just for delivery of drugs for the treatment of local
diseases associated with colon but also for systemic
delivery of proteins, therapeutic peptides etc.
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4. Advantages of C.S.D.D.S
Targeted drug delivery
Require small drug dose
Reduce dosing frequency
Less incidence of side effect
Reduce gastric irritation
Improve patient compliance
It has low hostile environment, less peptidase activity
so peptides, oral vaccines, insulin, growth hormones,
can be given through this route.
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5. Multiple manufacturing steps.
Microflora affects activity of drug via metabolic degradation of
the drug.
Bioavailability of drug may be low due to potentially binding of
drug in a nonspecific way to dietary residues, intestinal
secretions, mucus or faecal matter.
Non availability of an appropriate dissolution testing method to
evaluate the dosage form in-vitro.
Drug should be in solution form before absorption and there for
rate limiting step for poor soluble drugs.
Limitations
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6. Anatomy & physiology of colon
The GI tract is divided into stomach, small intestine & large
intestine.
The colon itself is made up of the caecum, ascending colon,
hepatic flexure, transverse colon, splenic flexure, descending
colon, sigmoid colon.
It is about 1.5 m long.
Although it varies in diameter from approx 9 cm in caecum
& 2 cm in sigmoid colon.
The wall of colon is composed of 4 layers: serosa,
muscularis externa, sub mucosa & mucosa.
Serosa consists of areolar tissue, muscularis externa
composed of an inner circular layer of fibers, sub mucosa is
layer of connective tissue, mucosa is divided into epithelium
lamina propria & muscularis mucosae
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8. The colon serves 4 major function:
1.Creation of suitable environment for growth of colonic
microbes.
2.Storage reservoir of faecal contents
3.Expulsion of the contents of the colon at an appropriate
time.
4.Absorption of potassium & water from the lumen,
concentrating the faecal content.
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9. Factors to be considered for colonic drug delivery
1. pH in the colon:
pH of the GI tract is subjected to both inter & intra subject
variation.
On entry in to the colon, the pH dropped to 6.4 . The pH in
the mid colon & the left colon is 6.0- 7.6
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Location pH
Oral cavity 6.2-7.4
Esophagus 5.0-6.0
Stomach Fasted condition 1.5-2.0
Fed condition 3.0-5.0
Small intestine Jejunum 5.0-6.5
Ileum 6.0-7.5
Large intestine Right colon 6.4
Mid & left colon 6.0-7.6
10. 2. Gastrointestinal transit:
Gastric emptying of dosage forms is highly variable &
depends primarily on whether the subject is fed or fasted.
The arrival of an oral dosage form at the colon is determined
by the rate of gastric emptying & the small intestinal transit
time.
The transit time of dosage form in GIT:
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Organ Transit time (hrs)
Stomach <1 (fasting), >3 (fed)
Small intestine 3-4
large intestine 20-30
11. 3. Colonic microflora:
Many compounds taken orally are metabolized by gut
bacteria.
Drug release depends on enzymes that are derived from
microflora present in colon.
These enzymes are used to degrade coatings/matrices as well
as to break bonds between an inert carrier and an active agent
resulting in the drug release from the formulation.
Important metabolic reactions carried out by intestinal
bacteria : hydrolysis, reduction, dehydroxylation,
decarboxylation, dehalogenation, deamination, acetylation,
esterification.
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12. Drug absorption in the colon
Drugs are absorbed passively by either paracellular or
transcellular route.
Transcellular absorption involves the passage of drugs
through cells.(Lipophilic drug)
Paracellular absorption involves the transport of drug
through tight junction between cells. ( Hydrophilic drug)
The colon may not be the best site for drug absorption since
the colonic mucosa lacks well defined villi as found in the
small intestine.
The colon contents become more viscous with progressive
absorption of water as one travels further through the colon.
This causes a reduced dissolution rate, slow diffusion of drug
through the mucosa. 12
13. Role of absorption enhancers
The permeability of drugs can be modified by the use of
chemical enhancers.
These enhancers increase transcellular & paracellular
transport through one of the following mechanism:
1.By modifying epithelial permeability via denaturating
membrane proteins.
2.By reversibly disrupting the integrity of lipid bilayer of
colon.
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Category Example
NSAIDs Indomethacin
Calcium ion chelating agent EDTA
Surfactants Polyoxyethylene lauryl ether
Bile salts Glycocholate
Fatty acids Sodium caprylate
Mixed micelles Oleic acid glycocholate
14. Approaches to colon specific drug delivery
1. Coating with pH dependent polymers:
The underlying principle of this approach has been
employment of polymers that are able to withstand the
lower pH values of the stomach, but that disintegrate and
release the drug as the pH in the small bowel increases.
Selection of enteric polymer dissolving at pH 7 is likely
to cause drug release in terminal small bowel.
Examples: Cellulose Acetate Phthalate (CAP)
CAP is a white free-flowing powder. It is insoluble in water,
alcohols, and chlorinated hydrocarbons, but soluble in
acetone and its mixtures with alcohols, ethyl acetate–IPA
mixture.
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15. Cellulose Acetate Phthalate:
Methacrylic Acid Copolymers:
These are anionic copolymers and are very commonly utilized
for enteric coating, including application in colonic delivery.
Eudragit L
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16. Shellac:
Shellac is a material of natural origin used for enteric
coatings. It is a purified resinous secretion of the insect
Laccifer lacca.
Hydroxypropyl Methylcellulose Phthalate (HPMCP):
HPMCP is a white powder or granular material. It is a more
flexible polymer than CAP. Commercially, the available
forms are HPMCP-50 and HPMCP-55.
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17. 2. Time release dosage forms:
Nonbiodegradable polymers are used.
They are generally nonspecific with respect to pH-solubility
characteristics and the employment of these polymers as carrier
matrices for colonic delivery often utilizes a time-dependent
mechanism.
This provides an initial lag phase of low or no release during
transit through the upper gastrointestinal tract.
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18. Available Technologies:
Colon targeted delivery system:
This system, first described by Shah & co-workers, uses lag
time to achieve colon delivery.
System consist of 3 main parts: An outer enteric coat, inner
semipermeable polymer membrane, and a central core having
swelling excipients and an active component.
The outer enteric coating prevents drug release until the
tablet reaches the small intestine.
In the small intestine, the enteric coating dissolves allowing
gastrointestinal fluids to diffuse through the semipermeable
membrane into the core.
The core swells until after a period of 4–6 h, when it bursts,
and releases the active component in the colon. 18
22. Delivery based on metabolic activity of colonic bacteria
Prodrugs:
Example,
Sulfasalazine is mainly used for the treatment of
inflammatory bowl diseases.
Chemically it is 5-amino salicylic acid (5-ASA) coupled
with sulphapyridine by azo bonding.
On reaching the colon, the azo bond is reduced by
azoreductases to 5-ASA & sulphapyridine.
The active moiety is 5-ASA & sulphapyridine acts as
carrier to deliver 5-ASA in colon.
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23. Hydrogels:
The Hydrogels are composing of acidic commoners and
enzymatically degradable azo aromatic cross-links.
In the acidic pH, gels shows less swelling that protect the
drug against degradation in stomach.
As the pH of environment increases i.e. become basic,
swelling increases.
This results in easy access of enzymes like azoreductase.
The cross-links are then degraded & drug is released.
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24. Polysaccharides as carriers:
The colonic microflora secretes a number of enzymes that
are capable of hydrolytic cleavage of glycosidic bonds.
These include β-d-glucosidase, β-dgalactosidase, amylase,
pectinase, xylanase, α-d-xylosidase, and dextranases.
Natural polysaccharides like pectin & inulin are not
digested in stomach & small intestine but are degraded in
colon by resident bacteria.
The bacteria converts polysaccharides to gases such as
methane, carbon dioxide, hydrogen & to short chain fatty
acids.
These polysaccharides thus have the potential as non-toxic
carriers for colon specific drug delivery. 24