Capsules PDF

Summary

This document provides a detailed description and analysis of capsules, covering their different types, materials, and manufacturing processes. It discusses hard and soft gelatin capsules, highlighting the advantages of each over conventional tablets.

Full Transcript

Pharmaceutics-3 PT 505
Pharmaceutics department

Capsules
Asmaa Ashraf El-kashef, PhD.
 Capsule in Latin "capsula": meaning a small box.
Capsules are considered the second most popular oral dosage form.
❖ Capsule administration
1. Swallowed as whole.
2. Capsule is opened & contents are sprinkled on food.
❖ Capsules advantages over compressed tablets:
1. Elegant.
2. Easier to swallow.
3. Completely mask unpleasant odours & tastes.
4. Can be easily made opaque (advantage in photosensitive drugs).
❖ Types of capsules
Hard gelatine capsule Soft gelatine capsule
Consists of two pieces: cap & body that Manufactured & filled in a single
fit one inside the other. operation.
Produced empty & filled in a separate
operation.
❖ Raw material for gelatine capsules:
Raw materials used are similar for both hard & soft capsules.
First stage of process is to prepare a gelatine solution in demineralized water
1. Gelatine
Major component. The only material from which capsules successfully made.
1. Good film forming material.
2. Water-glycerol blend undergoes a reversible phase change from a solution to a gel at
temperature only a few degrees above ambient.
3. Readily soluble in biological fluids at body temperature.
4. Non-toxic.
**** Animal bones & skins are the raw material. It is prepared by hydrolysis of collagen.
There are 2 types of gelatine:
1. Type A: produced by acid hydrolysis.
2. Type B: produced by basic hydrolysis.
*** We should maintain hard capsules in an environment free from excessive humidity or
dryness.
Gelatine is subject to microbial decomposition when it becomes moist, distorted and lose their
rigid shape. In extreme dryness, the capsules may become brittle.
2. Plasticizers Walls of hard gelatine Walls of soft gelatine capsules are softer &
capsules are firm & rigid. more flexible. It contains a large
It contains a smaller proportion of plasticizers.
proportion of plasticizers.
Plasticizer most frequently used: glycerol, sorbitol, propylene glycol,
sucrose & acacia have been used also.
3. Colorants Soluble dyes: Insoluble pigments: The pigments used are
Mainly synthetic in either:
origin. 1. Titanium dioxide. This is white & is used
as an opacifying agent.
2. Oxides of iron: Black, red, yellow.

In last years, there is a move away from the use o
f soluble dyes over to pigments, particularly the iron oxides.
4. Preservatives Sometimes added as an in-process aid to prevent microbiological
contamination during manufacture.
  Hard gelatine capsules
Made in a range of 8 sizes from: size 000 (the largest) to
size 5 (the smallest). The most popular are sizes 0 to 4.
Capacity (by weight) varies according to density and
compressibility of powder.
Hard capsules filled with (solids like powders, granules,
tablets, pellets, beads, semi-solids, and thermo-
softening materials.
❖ Basic requirements for formulations to be filled into capsules:
1. Accurately dosed.
2. Release their active contents in available form to patient.
3. They should not react with gelatine, e.g. aldehyde.
4. Not interfere with integrity of shell e.g. water soften the wall.
❖ Incompatible drugs can be separated by:
1. Inserting a coated tablet of one ingredient into a capsule containing the other.
2. Pack one substance into a small capsule to be inserted into larger capsule containing the other.
3. Fixed oil should not dissolve gelatine, filling is done with a pipette or calibrated dropper.
4. Liquids could be sorbed into inert carrier to form dry powder suitable for capsule filling.
❖ Locking & Sealing of Capsules
1) To prevent accidental separation of capsules caps during handling & shipping.
2) In high-speed automatic filling & packaging machine.
3) For beads which tend to separate on handling because the fills are not compacted.
❖ Techniques of sealing
1) By a narrow band of gelatine.
2) A small hot probe near the cap to form a spot-weld.
3) A 3-segmented raised collar around inner cap →a positive friction lock
4) By moistening the lower part of the inner surface of the cap with water.
❖ The manufacture of hard gelatine capsule shells
Hard capsule shells are manufactured in two sections, the capsule body and a shorter cap.
The shells are produced by the mechanical dipping of pegs into a temperature-controlled
reservoir of melted gelatine mixture.
The pegs on which the caps are formed are slightly larger in diameter than the pegs on which
the bodies are formed.
The gelatine is dried by a gentle flow of temperature-and humidity-controlled air. Then,
trimmed mechanically to the proper length and removed from the pegs, and the capsule bodies
and caps are joined together.
❖ Filling of Hard Gelatine Capsules:
Small scale filling
1. Hand-operated
For large-scale filling, industry uses
1. Semi-automatic 2. Fully automatic equipment
*** Regardless of process, all have common basic operations of:
1. Removal of caps.
2. Filling of the bodies.
3. Replacement of caps.
4. Ejection of filled capsules.
❖ Semi-automatic machine
The part The role
Rectifier Align the capsules in the filling ring (so that the cap is up and the body
is down)
Capsule filling ring Where capsules are placed.
Hopper contains auger Feeds powder into bodies and ensure filling of capsule by forcing it
into the shell.
Auger is not used when capsules are filled with granules as it’ll break
the granules.

Peg ring 1. Driven by air pressure, pushes the caps & bodies together (to ensure
pressing of cap to the body).
2. Then it ejects the capsule.
❖Fully-automatic machine
Soft gelatine capsules
  Soft gelatine capsules
Composition of soft gelatine differs from hard gelatine in:
1. Sugar is replaced by a plasticizer which imparts elastic properties.
2. However, up to 5 % sugar may be added to formulation to give “chewable” properties.
Spherical or oval capsules called pearls or globules.
Capacities range from 1 to 480 minims.
The fill: it may be single liquids, blends of miscible liquids, solutions, suspensions,
semisolids, dry powders, slugs.
Only liquids that do not dissolve shell (gelatine) may be used, e.g.: animal, vegetable, or
mineral oil & polyethylene glycols.
❖ Advantage:
1) Hermetically sealed, so uniquely suitable for:
a. Liquid medication.
b. Volatile drugs.
c. Drugs subjected to atmospheric oxidation.
2) Attractive odourless & tasteless form of medication.
3) It can be used as a form of rectal or vaginal suppositories, topical, eye, ear, & nose
preparations as well as cosmetics & food stuffs may be dispensed in soft gelatine capsules.
❖ Manufacture:
1. Plate method (Small scale preparation)
a) Place the gelatine sheet over a die plate containing
numerous die pockets.
b) Vacuum is applied to draw the sheet into the die pockets.
c) Fill the pockets with liquid or paste.
d) Place another gelatine sheet over the filled pockets.
e) Sandwich under a die press using pressure where the
capsules are formed and cut out.
* No dose uniformity and high manufacturing loss.

2. Rotary die process (Scherer process)
Part Role

Rotating drums Spread gelatine solution to form a pair of continuous sheets of
gelatine to be fed between two matched rotary dies.

Injection Guides gelatine sheets between rotary dies.
wedges Heats gelatine to proper temperature for sealing.

Metering pump Inject the fill under Pressure causing gelatine to swell into cavities
to form capsules.
Converging dies Seals capsules & cut capsules from gelatine sheets.
3. Seamless Gelatine Capsules:
Since these are not sealed by pressure from two Drug

Gelatine
sheets of gelatine, they are seamless.
Cold liquid paraffin 4°C is used because: Cold liquid
paraffin
1. Non solvent for gelatine.
2. Will congeal it.
 Sustained Released Capsules
❖ Advantages of sustained release medication
1. The drug is more efficiently utilized.
2. Total drug intake is reduced.
3. Administration is more convenient (less frequency of administration).
❖ Sustained release dosage forms consist of 2 parts
(1) Immediate release portion.
(2) Sustained release portion: rate of drug release = rate of its elimination or detoxification.
Suitable for Not suitable for
Drugs used for chronic Antibiotics or muscle relaxants
conditions not acute illness which have large dose →large SR
dosage forms
Digitalis glycosides and reserpine
(long-acting drugs)
❖ Sustained released dosage forms are divided into:
A hard gelatine capsule where the medication is pan coated onto the surface of sugar
starch beads using a non-aqueous solution of the drug.
A portion of these drug-coated beads provide the initial release of medication.
Spansule The remainder (approximately 2/3 to 3/4 of the beads) are then pan coated with a
fatty, waxy material such as beeswax or glyceryl monostearate or ethyl cellulose.
Release of drug is dependent on moisture penetration of the fatty material,
which depends on the composition & thickness of the coat.
The granules of the sustained release portions are coated with styrene-maleic acid
copolymer.
Medules Release is dependent on:
1. PH as (The coat is PH sensitive & disintegrates at intestinal pH)
2. The stomach emptying rate.
A cationic drug is sorbed onto a cationic exchange resin
Drug release depends on:
Strasionic a. PH
resins b. electrolyte in gastro-intestinal fluids
Formed by reacting a drug possessing an amine group with tannic acid in an
alcoholic solution
After precipitation, washing & drying, the complex may be either encapsulated or
Insoluble
tableted.
complex
**** Complex dissolves in stomach (acidic) more than intestine (alkaline).
Too rapid dissolution in the stomach is avoided by adding pectic or galacturonic
acids for buffering effect.
  Enteric Coated Capsules
Capsules are coated to resist dissolution in gastric fluids but release their contents in the intestine.
They are used when:
1. The drug is inactivated in gastric fluids.
2. The drug is irritating to the gastric mucosa.
3. When a high local concentration of the drug is required in the intestine (anthelmintic).
❖ Materials used for enteric coating
1. Shellac, cellulose acetate phthalate.
2. Fatty, waxy materials such as beeswax, carnauba wax and stearic acid.
3. Hard gelatine capsules may be rendered enteric by treatment with formaldehyde that forms
methylene bridges and cross links with gelatine (hardening of gelatine)
❖ An alternative procedure for the enteric coating of capsules:
Dip capsule into 10 % solution of cellulose acetate phthalate in acetone.
Capsule is removed, held for a minute and then placed on gauze to finish drying.
Three coats are applied.
❖ Advantages of this method
1. Avoids heat
2. Add less bulk to the capsules
❖ The dissolution rate of a drug from capsules depends on:
1. The dissolution rate of shell.
2. The rate of penetration of the dissolution medium into the powder.
3. The rate at which the powder mass deaggregate.
4. The nature of the primary particle.
**** The dissolution of a drug is the essential step in the absorption process why?
As the availability of a drug for absorption depends on the drugs dissolving in gastro-
intestinal fluid.
*Dissolution is the rate limiting step (i.e., the slowest step) in the over-all absorption
process.

❖ Formulation Factors Affecting Drugs Availability from
hard Capsules
1. Active ingredients
Physicochemical properties of drug such as solubility, melting point, crystalline
form
The solution rate is proportional to the surface area of drug.
The smaller the particle the greater the relative surface area.
2. Additives include diluents, lubricants & wetting agents.
a. Diluents
Inert materials added to a formulation to increase the volume of the mixture to a
manageable quantity.
Choice of diluent depends on the solubility & proportion of the active ingredient.
Examples of diluents:
Lactose, dicalcium phosphate, & microcrystalline cellulose (Avicel).
b. Disintegrant: help the powder mass to break up without interfering with the solubility
of the active ingredients (As starch grains).
c. Lubricants & Glidants
Added to improve the filling properties of the powder mixture.
Can have an effect on drug release.
Example of lubricants: magnesium stearate.
d. Surfactants & wetting agents
Enhance drug dissolution by increasing the wettability of the powder mixture.
The hydrophobic effect of magnesium stearate could be overcomed by the addition of
wetting agent to formula.
❖ Factors Affecting Bioavailability of Drugs in Soft Gelatine Capsules
1. Solubility of the drug in the vehicle.
Acid-soluble drugs (dissolved or dispersed in water-miscible vehicles) are distributed quickly
throughout the stomach.
Suspended particles dissolve quickly & the bioavailability is good.
2. Particle size of the drug.
3. Nature of the vehicle: The vehicle is either hydrophilic or hydrophobic according to the
nature of the drug.
4. Inclusion of suspending agent for insoluble drugs.

 Evaluation of Commercial Capsules
1. Weight Variation
The uniformity of dosage units may be demonstrated by determining weight variation
and/or content uniformity.
Weight variation may be taken as control for the uniformity of actual drug content if the
dose of the drug is large and there is relatively little diluent or excipient present.
In the case of more potent, low-dose drugs, the control of weight variation does not
assure uniformity of drug content since sufficient blending may not have been
achieved.
 The weight variation method is as follows.
Hard Capsules
10 capsules are individually weighed, and their contents removed. The emptied shells are
individually weighed, and the net weight of the contents is calculated by subtraction.
From the results of an assay performed as directed in the individual monograph, the content
of the active ingredient in each of the capsules is determined.

Soft Capsules
The gross weight of 10 intact capsules is determined individually. Then each capsule is cut
open, and the contents are removed by washing with a suitable solvent.
The solvent is allowed to evaporate at room temperature over about 30 minutes, with
precautions to avoid uptake or loss of moisture.
The individual shells are weighed and the net contents calculated. From the results of the
assay directed in the individual monograph, the content of the active ingredient in each of the
capsules is determined.
2. Content uniformity
Is defined as the degree of uniformity in the actual amount of the drug in the dosage units.
In the official test 30 capsules are selected
10 of them are assayed individually.
At least 9 of this fall within 85 and 115% of average specified in monograph potency
definition.
None may fall below 75% or above 125 % of the average
If more than 1 but less than 3 of them fall outside of the 85 and 115 % limits, the
remaining 20 capsules are individually assayed.
The requirements are said to be met if not less than 27 capsules fall within range 85-115%
of limits and not fall outside 75-125 % of limits.
3. Disintegration
The capsules are placed in the basket rack, which is immersed 30 times per minute into a
thermostatically controlled fluid at 37°C and observed over the time as per monograph.
To satisfy the test, the capsules disintegrate completely into a soft mass having no palpably
firm core and only some fragments of the gelatine shell. “Dissolution”
The dissolution of a capsule shell does not imply complete dissolution of the active
ingredient.
4. The dissolution test
Carried out using the dissolution apparatus official in both the U.S.P.
The capsule is placed in a basket (attached to a stirrer shaft) & caused to rotate at a specified
speed.
The dissolution medium (900 ml) is held in a covered 1000 ml. vessel made of glass or other
transparent material.
If the capsule floats on the surface of the dissolution fluid, a small, loose piece of
nonreactive material, such as a few turns of a wire helix, may be attached to the dosage
form to force it to sink to the bottom of the vessel.
The dissolution medium is maintained at 37°C± 0.5 by means of a suitable constant-
temperature water bath.
Samples are withdrawn at certain time intervals, analysed for the dissolved drug, and
dissolution rate is then calculated.
5. Moisture Permeation Test
The USP requires determination of the moisture permeation characteristics of single-unit and
unit-dose containers to ensure their suitability for packaging capsules. The degree and rate
of moisture penetration are determined by packaging the dosage unit together with a color-
revealing desiccant pellet.
Exposing the packaged unit to known relative humidity over a specified time, observing the
desiccant pellet for color change (indicating the absorption of moisture), and comparing the
pre-test and post-test weight of the packaged unit.