Solid Dosage Forms - Capsule - PDF

Summary

This document provides an overview of capsules, a type of solid dosage form in pharmaceutical science. It discusses the different types of capsules, the materials used to make them, the process of preparing capsule shells, advantages and disadvantages of using capsules, and various aspects of capsule production, storage, and evaluation.

Full Transcript

Definition:

Capsules are solid dosage forms in which the medication is contained
within hard or soft gelatin shell.
Types of materials to be filled in capsules:

1-dry solids:
powders-granules-pellets-tablets.
2-semisolids:
thermo-softing materials- thixotropic materials-pastes.
3- liquids:
water-miscible liquids and water-immiscible oils.
4-Granules:
which are produced by granulation and tend to be more irregular than pellets
which are produced by coating or microencapsulation techniques
5-Tablets:
are filled into capsules :
A- to produce special release form,
B- to separate incompatible ingredients or
C- for compounding of potent drugs.

6-Suspension:
Insoluble drugs can be dispersed.

7-Water-immiscible oils:
fixed and aromatic vegetable oils aliphatic, aromatic and chlorinated hydrocarbons, and
liquid ethers and esters

8-Water-miscible liquids:
PEG 400 and 600, alcohols e.g. isopropyl alcohol, polyglycerol, triacetin, glyceryl esters,
sorbitan ester, sugar esters and polyglyceryl esters. Propylene glycol and glycerol can be used
up to 10 % only to prevent migration into gelatin and softening of the shell
Limitation:
1- drugs or excipients containing high concentration of water or other
gelatin solvents cannot be incorporated

2- emulsions are not recommended since they are unstable and will
crack as the is lost from the shell in the manufacturing process.

3- Surfactants may have a deleterious effect on capsule shell

4- Extremes of pH must be avoided. pHs below about 2.5 attack the
gelatin leading to hydrolysis and subsequent leakage and PHs above
about 7.5 having a tanning effect on the gelatin

5- Aldehydes must be avoided since they have a tanning action on the
proteins of the gelatin shell
Advantages:
1- they mask the odor and taste of unpleasant drugs.
2- they are attractive in appearance.
3- they are easy to swallow
4- less additives are required
5- rapid release of drugs.
6- they can be colored to give protection against light.
7- give good protection against air and moisture.
8- the shell is physiologically inert.
9- complicated machines are unnecessary on small scale.
10-offer greater flexibility for physician in dosage and drug
combinations.
Disadvantages:

1- they are not suitable for liquids that dissolve gelatin.

2- very soluble salts such as bromides and iodides should not be dispensed
in capsules. The rapid release of such medications may cause gastric
irritation owing to the formation of localized area of high drug content
Sizes and shapes:
Human use:
8 sizes are available ranging from 000(the largest)
to 5(the smallest).

The largest size normally acceptable to patients is a No. 0.
Storage:

Capsules should be stores in tightly closed glass containers, protected
from dust and extremes of humidity and temperature.

Capsules generally contain from 13 to 16 % of moisture. However:
when stored under condition of high humidity, sufficient moisture
may be absorbed to soften the gelatin and make it tacky.

On the other hand, when stored under condition of low humidity, the
capsules may be dehydrate and become brittle.
Preparation of shell of hard gelatin Capsule :

1. First step is make gelatin solution 30-40% : gelatin and hot demineralized
water are mixed under vacuum to assist in removal of entrapped air from this
viscous solution.
Source of gelatin:

Partial hydrolysis of collagen obtained from skin, bones and white
connective tissues of animals. This long polypeptide chain yields on
hydrolysis 18 amino acids, the most prevalent of which are glycine and
alanine.

There are two basic types of gelatin.
type A
acid hydrolysis of pork skin
type B
alkaline hydrolysis of animal bones
Specifications of gelatin:

A- Bloom strength( gel strength):
Bloom strength is an empirical gel strength measure which gives
an indication of the firmness of the gel. Bloom strengths in the range
150 to 280 g are used for capsules. Higher val for soft gelatin one

B- Viscosity:
The viscosity of gelatin solutions is vital to the control of the
thickness of the cast film. generally in the range 30 to 60 millipoise
(mP).
 3. Dyes, other
ingredients, and
any needed water
2. After aging in
are added to the
stainless steel
gelatin in the
receiving tanks,
feed tanks to
the gelatin
make the dipping
solution is
solution. The
transferred to
feed tanks are
stainless steel
then used to
feed tanks.
gravity-feed
gelatin into the
Capsule Machine.
The other used ingredients are

a) Colorants:
Commonly used pigments are the iron oxides. Colorants not only play a role in
identify the product, but may also play a role in improving patient compliance.

b) Opaquing Agents:
Titanium dioxide may be included to render the shell opaque. Opaque capsules may
be employed to provide protection against light

c) Preservatives
parabens are often selected.
4- Preparation of the shell:

A- Dipping:
Pairs of stainless steel pins are dipped into the
dipping solution, at temperature 50 oC in a heated
jacketed dipping pan. The time is about 12 sec.
the larger the capsule the longer the dipping time.

B- Rotation:
Spinning the pins to distribute the
gelatin uniformly over the pins. During
spinning the gel may be firmed by a blast
of cold air.
C- Drying
The racks of gelatin-coated pins then pass into a
series of four drying ovens.The drying is done by
dehumidification, and the temperature is adjusted to
prevent film melting.

D- Stripping
A series of bronze jaws strip the cap and body
portions of the capsules from the pins.
E- Trimming:
The stripped cap and body portions are
delivered to collets in which they are firmly
held. As the collets rotate, knives are brought
against the shells to trim them to the required
length.

F- Joining:
The cap and body portions are aligned
concentrically in channels and the two
portions are slowly pushed together.
3- Sorting:
The capsules passing on a lighted moving
conveyor are examined visually by inspectors.

Any defective capsules are removed manually.
Defects are classified as follows:
defects that could cause stoppage of a filling
machine, such as imperfect cuts,
capsules with holes.
defects may cause problem on use, such as
splits, long bodies, or grease inside.

4- Printing:
capsules are printed prior to filling. Empty capsules
can be handled faster than filled capsule.
printing is done on rotary presses having throughput
capabilities as high as 3/4 million capsules per hour.
Preparation of hard gelatin capsules
1- Formulation.
2- Filling.
3- Cleansing and polishing.

1- Formulation and selection the suitable size.

Generally additives are added for the following purposes:

A- Bulking agents

B- Lubricants

C- Adsorbents

D- Wetting agents
2- Filling:
A- Small Scale:
Punch method.
Plastic block or suppository
mold
The lower halves of the capsules
may be supported in the holes of
suppository mold or in a plastic
block.

The powders are poured by a
funnel in each capsule..
Hand operating device
The capsules are placed manually and the caps are removed and
replaced mechanically by the top plate.
The powders are distributed uniformly into capsules by spreading it
over a perforated tray which holds the powder over the empty body.
B- Large Scale:
Semiautomatic e.g. Automatic machines
Elanco no.8 Lilly, Park-davis, Zanasi , Hofliger and Karg

1.Empty Capsule hopper
2.Rectifying roller
3.Cap Segment
4.Body disc
5.Powder filling hopper
6.Unopened Capsules rejection unit
7.Joining station
8.Discharge chute
9.Segment cleaning
10.Weight Control unit
11.Control station
12.Auger Motor
13.Auxiliary powder hopper
Basic steps (operation) of filling machines:
1- Rectification (orientation of the empty
capsules):

Capsules firstly are put in capsule hopper

A metal finger strikes them in the middle of
rectifying roller causing them to rotate
causing the
body-end downward.

so, capsule cap can stay in upper holding
ring and capsule body can stay in lower
holding ring.
2- Separation of caps from bodies:
The capsules are feed into sets of holders or bushes, the diameter of
which are designed so that the body can pass through the upper one
but not the caps. This transfer is usually with vacuum.

Separate the holding ring, put the lower (body)
holding ring on the rotary table

pull the powder hopper over the lower (body)
holding ring, then auger inside powder hopper
starts to run and fill powder into the capsule
body.

While Iower holding ring turns one circle, push
powder hopper to its original position.
3- Dosing of fill material:
Various methods are employed for powder
filling, as described below.
1 - The auger:
This system is principally used on
semiautomatic machines.

Empty capsules are fed into a pair of ringed
holders where the caps are retained in one
half and the bodies in the other.
The bodies in their holders are passed
under a powder hopper inside which a
revolving auger or screw.

Materials are transferred into bodies by the
movement of the auger.
The quantity of the powder is depend
upon:
The speed of revolution
The design of the auger,
The quantity of the powder in the hopper
and
The time the body is under the hopper.

To obtain the best uniformity of weight it
is necessary to fill the body as
completely as possible.

The machine is semiautomatic because:
it requires a person to transfer the
capsules from one operation to another;
capsule feeding, filling and closing.
2- The Dosator (the most commonly used)This is used on fully automatic
machines. It consists of:
A dosing tube inside of which there is a spring loaded piston.
The tube is plunged ,open and first, into a powder bed, in which material rises up in
the tube to the piston to form a plug (slug) of powder (the powder must have some
cohesive properties otherwise the powder will leave the dosator).
The assembly is then raised and positioned over the capsule body.
The piston is lowered ejecting the powder plug into the capsule. The fill weight can be
varied by adjusting the position of the piston inside the dosing tube or altering the
depth of the powder bed.
Diagram of a dosator or dosing
3- The dosing disk:
The dosing disk, has a number of holes bored through it.
A solid brass “stop” plate slides along the bottom of the dosing disk to
close off these holes
Five sets of pistons (Hofliger-Karg machines) compress the powder into
the cavities to form plugs. The cavities are indexed under each of the
five sets of pistons so that each plug is compressed five times per cycle.
After the five tamps, the dosing disk indexes to position the plugs
over empty capsules bodies, where they are ejected by transfer
piston.

The dose is controlled by:
The thickness of the dosing disk (i.e. cavity depth)
the depth of the powder bed
the tamping pressure.
4- Replacement of caps and ejection of filled
capsules:
The cap and body pushing portions are rejoined. pins
are used to push the filled bodies up into the caps
for closure, and to push the closed capsules out of
the bushings. Compressed air also may be used to
eject the capsules.

5- Locking and sealing:
To prevent accidental separation of capsules during handling and
shipping.
Techniques:
1- Park davis kapseal :
The sealing is done by a narrow band of colored
gelatin.

2- Coni-snap:
The rims of the body are not straight but
tapered slightly.

3- Coni-snap supro:
The caps extended so far over the body that
only the round edges of the latter is visible.
4- Capsugel low-temperature thermal method:

using a low-temperature thermal method (40 - 45° C). The capsules
are first immersed for fraction of a second in a hydroalcoholic solvent.
Excess solvent is then drained off, leaving traces in the overlapping
area of the cap and body (held by capillary forces). Finally, the
capsules are dried with warm air.
Soft glatin capsules
The capsules consists of units with a continous gelatin shell surrounding a
liquid fill material. The capsules are formed ,filled and sealed in one operation
and may be of different types and shapes.
Properties Hard Gelatin Capsules Soft Gelatin Capsules

1- The Empty The basic shell is made Sugar is replaced by a plasticizer such as glycerol
Shell from gelatin or sorbitol which give elasticity and softness on
the wall.
5% sugar can be added to give chewable property
to the shell.

2-Suitability Mainly for solids. Suitable for liquid drugs, pasty drugs, drug
Liquids (except water) solutions, volatile drugs or drugs susceptible to
can be added. deterioration by air
(hermetically sealed). Solids can be incorporated.
3- Shell wall More thicker
4- No. of pieces Two (cap and body) One: cannot be opened without destroying the
sealed together by a capsules.
banding process or
locked together by
means of spot welding
or by mechanical
interlock built onto
5- Shape Cylindrical Round, oval, oblong, tube and others
6- Small scale Can be prepared It is not easily prepared except on large scale.

7- Accuracy More accurate
8-Manufacture a- The shell in one Both (a) and (b) in one operation
operation
b- Filling in a
completely separate
operation
Advantages of SGC:

1- To solve the problems of compression:
A- Some drugs are liquids and thus cannot be compressed into tablets.
B-Low melting point drugs as piperment oils and phospholipids which
melt at the temperature of compaction and cause picking and sticking
problems.
C- Many are dusty or cohesive and will not flow.

2- To solve the problems of mixing and powder flow:
Powder flow and mixing problems may cause weight variation and
dose content variation in both tablets and HGC. This can result in toxic
side effects(e.g. nausea) or poor therapeutic activity in the case of
potent compounds as hormones with low therapeutic index. But the
pump used in SGC filling machine has very low weight variations.
3- To solve the problems of stability:
Most drug compounds degraded by oxidation, hydrolysis and by
incompatibility reactions during storage after manufacture because of
moisture as vancomycin ( hygroscopic drug).

This can be solved by the use of SGC in which the drug can be dissolved
or dispersed in oil and then encapsulated in a dry shell of gelatin at low
RH or under nitrogen. Such formulations resist gaseous diffusion and
contain little labile water. The stability to oxidation (vitamin C) and
hydrolysis (vitamin A and thiamine) is greater when the actives
ingredients are formulated in SGC.
4- To solve the problems of bioavailability:
Some drugs, such as neutral compounds or organic acids, are
insoluble in water and GIT fluids and the dissolution rate is low. when
these materials are compounded into tablets or HGC, the absorption
rate is sometimes retarded and the bioavailability may be poor.
In a SGC formulation
the medicament is in solution or is dispersed as a fine suspension in
either a hydrophilic vehicle or a hydrophobic base. When SGC is
ingested, the gelatin shell dissolves and the liquid medicament is
released into the gastric contents where water-miscible vehicles
dissolves and oily liquids emulsify to give a drug dispersion of high
surface area and good bioavailability.

EX, Ibuprofen and nifedipine.
 Methods of filling
Rotary die method:
The gelatin mass is maintained at a temperature of 57 to 60° C
before and during the capsulation process.

The gelatin mass is fed by gravity to a metering device (spreader
box) which control the flow of the mass onto air cooled (13-14°C)
rotating drum. Gelatin ribbons of controlled (± 10%) thickness are
formed

The ribbons are fed through a mineral oil lubricating bath, over a
guide roll, and then down between the wedge and the die rolls.
The material to be capsulated flows by gravity into a positive
displacement pump.

The pump accurately meters the material through the leads and wedge
and into the gelatin ribbons between the die rolls.

The capsules is about half sealed when the pressure of the pumped
material forces the gelatin into the die pockets, where the capsules are
simultaneously filled, shaped, hermetically sealed, and cut from the
gelatin ribbon.

The sealing of the capsules is achieved by mechanical pressure on the
die rolls and the heating (37 to 40° C) of the ribbon by the wedge.
 The filled capsules are then deposited on a conveyor which first carries
them through a naphtha ( hydrocarbon distillate left over from refining
wash to remove the mineral oil used to lubricate the gelatin strips ,and
then to an infrared rapid drying stage where most of water is removed
from the shell.

Final drying to moisture content of 6-10 % is accomplished in forced air
drying tunnels where the moisture content of the shell is allowed to
come to equilibrium with relatively dry air (20-30 % relative humidity at
70-75 F)
 Storage of SGC:
Products containing hygroscopic liquids, however, should be
protected against moisture and be packed in containers such as glass
bottles with screw caps and waxed wad seal.

For good stability the temperature should be maintained below 30 C.
Evaluation of capsules
1- Disintegration BP. 1993
Introduce one tablet or capsule in each tube, add a disc to each tube.
Suspend the assembly in the beaker containing the specified liquid and
operate the apparatus for the specified time.
Remove the assembly from the liquid.
The tablets or capsules pass the test if all six have disintegrated.
Disintegration: measure the breakdown of dosage form into granules

Specifications:
1- 15 min. and 30 min. are the normal disintegration time for tablets
and capsules respectively.
2- Water or 0.1 M HCL are liquids for HG.
3- The disc is integral part in case of SC. The disc (plastic disk with
holes) is omitted in two case.
A- If the preparation being examined fails to comply because of
adherence to the disc. In this case the test should be repeated
without it
B- If the liquid ingredient supplied in SGC attack the disc.
2- Dissolution B.P. 1993
There are three types of apparatus:
A- Rotating basket (apparatus I ).
B- Rotating paddle (apparatus II).
C- Flow through cell (apparatus III )

Dissolution measures the drug being solubilized in media (i.e) the
process of dissolving solid solute in liquid solvent.

The apparatus I consists of a cylindrical steel basket into which the
tablet or capsule is placed, and the basket is then rotated in a bath of
dissolution fluid. (the temp is maintained at 37 C ).

A sample is withdrawn from the dissolution medium after a specified
time (usually 45 minutes) and analyzed

Not less than 70 % of the stated content should be dissolved.
Five replicates are carried out and if one of these fails to reach the standard, then
five more tablets or capsules are tested, and now none should fail.

N.B: When capsule shell interfere with analysis, remove the contents of no fewer
than six capsules as completely as possible and dissolve the empty capsule shell in
the specified volume of dissolution medium and make any necessary correction.
Correction factors should not be greater than 25 % of the labeled content.

Specifications:
1- The dissolution fluid is chosen according to the nature of the drug substance:
A- 0.1M HCl is specified for bases such as chloroquine phosphate and quinine
sulfate.
B- A less acid medium (pH 6.8 phosphate buffer) is specified for acidic drugs such
as phenoxy methyl penicillin.
C- Water is suitable for neutral molecules such as digoxin.
2- The test for SGC AS HGC if the liquid fill is hydrophilic. In case of oil fills, the test
is not suitable since the oil float on the surface
- Content uniformity:
It is performed to ensure the proper mixing of the capsule contents
by determining individually
the content of 10 capsules taken randomly and determine average
content.
N.B. (1) According to USP, content uniformity test is done for
capsules containing less than
25% of the total weight.
N.B. (2) When content uniformity test is required, no need for the
weight uniformity test.
Limit: NMT one capsule falls outside the limit 85-115% of the
average content
and none outside the limit 75 - 125% of the average content.
Weight Uniformity:
It is done to ensure homogeneity of dosage by weighing individually
20 capsules taken randomly
and determine average weight.
It is done for HGC containing 25% drug or more of the total weight.
Method:
1- Weigh an intact capsule.
2- Open the capsule without losing any part of the shell and remove
the contents as completely as
possible.
3- Weigh the shell.
4- The weight of the contents is the difference between the
weighing.
5- Repeat the procedure with a further 19 capsules selected at
random. 6- Determine the average weight.
Limit:
Not more than two of the individual weights deviate from the
average weight by more than the
percentage deviation shown in the table below, and none deviates
by more than twice that percentage.
Average weight % Deviation
Less than 300 mg 10%
300 mg or more 7.5%