Compounding III: Documentation & Preparation (RxPrep 2022)

Summary

This document discusses compounding procedures for non-sterile preparations, including documentation, preparation steps, and beyond use dates for various formulations. It includes examples of master formulas and compounding records.

Full Transcript

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COMPOUNDING & HAZARDOUS DRUGS

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CHAPTER 17
COMPOUNDING Ill:
DOCUMENTATION & PREPARATION
NON-STERILE PREPARATIONS
DOCUMENTATION
Two very important records that each compounded product must
have are the master formula record and the compounding record.
The master formula re.cord is the recipe that is followed to compound
a preparation. The compounding log (or record) is the log book of all
products made at the pharmacy (see images on the following pages).
The documentation in the compounding log must be detailed enough
that another trained person can replicate the steps involved in the
preparation, evaluate if the procedure was correct and trace the origin
of all components.
The pharmacy must keep records of steps and processes that relate to
the compounded product, such as equipment cleaning, calibration and
maintenance, temperature logs for the refrigerator, freezer and room
(ambient) air, and records of chemicals, bulk drugs and drug products.

PREPARATION STEPS
Prior to preparing to compound, the pharmacist will need to evaluate
the prescription and determine if it is appropriate for the patient,
and whether the proposed formulation is reasonable (e.g., is the
formulation likely to have acceptable stability and palatability?).
When ready to compound, the initial steps will be similar for most
formulations, such as calibrating equipment and weighing ingredients.
The final steps will be similar, and include packaging and performing
quality control (QC). What changes most are the steps in between,
which depend on the type of formulation to be prepared.
Always review the Safety Data Sheets (SOS) for each bulk ingredient
to determine safety procedures for the staff who will compound
the preparation, including the recommended personal protective
equipment (PPE).

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MASTER FORMULA #3755
IBUPROFEN 200 mg SUPPOSITORIES
Formula:
Ibuprofen 200mg Suppositories

Strength:

Quantity:

200mg

In redients:

Quanti

Ibuprofen

0 .2 gm

SilicaGel

0.02 gm

Base MBK (Fatty Acid Base)

Calculate

Procedure:
Note: calculations should be made to make an excess amount of 10% of the amount needed.
l . Calculate and weigh ingredients to prepare 10 Ibuprofen 200mg suppositories in the blue
mold which is calibrated to 1.28 gm of Base MBK per suppository. Use the Suppository,
General Formula worksheet.
2. Melt Base MBK at 50 degrees C using a hot water bath.

3. Using a mortar and pestle, triturate ibuprofen and Si/icaGe/ together to a fine powder.

4 . Sift the powder from Step 3 into the melted Base MBK while stirring . The use of a strainer
helps to ensure small particle size.
5 . Turn off heat and stir until mixture looks consistently suspended .

6. Pour into molds (may use a large bore syringe if available) and allow to cool to room
temperature.

7. Package in universal sleeve and label.

MASTER FORMULA
Recommended Expiration:

180 days

Recommended Storage/

Refrigerate

Auxiliary Labels:
Notes:

Compound's Official or Assigned Name
Strength, Dosage Form
Calculations
Ingredients, with quantities
Stability & Compatibility data,
with references
Equipment
Preparation/Mixing instructions
Labeling information
Packaging/Storage requirements
Quality Control (QC) procedures,
with expected results
BUD, recommended
Description of final product

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IFormula# 3755

J

Raindrop Compounding Pharmacy
COMPOUNDING RECORD

PRODUCT
Drug Name and Strength

Use/Dosage Form

Q.iantity

Ibu r ofen 200 m

Su

#10

ositories

Control/Rx#
37-865

Date
6-7-21

INGREDIENTS
Ingredient

NDC or Manufacturer#

QTY

LOT

EXP

Ibuprofen powder USP
Silica qel
MBK base
Disposable supp molds

18100-25, Spectrum
51935, Spectrum
30-156, PCCA
Apothecary

2q
0.2 q
12.8 g

A3472-19
51008-19
1234-18

3/24
12/23
2/23

COMPOUNDING DIRECTIONS & PROCEDURES
2.

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9.

Trimm

laced in refri erator to harden for 1 hour
form sur face, even color
ositor i

COMPOUNDING RECORD OR LOG
Weighed by: Dae
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Compound's Official Name or Assigned Name
Reference # for the Master Formula

Prepared by: -Dae
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Strength, Dosage Form
Specific to t his preparation
Ingredients (including manufacturers/sources, lot
numbers & expiration dates)
Steps followed
QC results
BUD, actual (assigned)
Description of final product
The product's assigned lot or prescription numbera duplicate prescription label can be attached to the log
Staff involved with the preparation

(1) Compounder, (2) Person who did QC, (3) RPh who
approved final product, with dates

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_ _ _ _ _ (QI

What you DID
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Preparation of Non-Sterile HDs

Compounding Steps

Non-sterile hazardous drugs (HDs) should preferably be
compounded in a containment primary engineering control
(C-PEC), discussed in the Compounding I chapter. This option
is not always available, and efforts must be made to protect
the staff with techniques to reduce exposure (e.g., splitting
tablets while enclosed in a sealed plastic bag). All equipment
used for HDs, including counting trays and spatulas, must be
dedicated for HDs only, and sanitized after use.

Make the product according to the maste1• formula.

The final formulations, when
possible, should be placed into unitdose sealed packaging, and placed
into a plastic bag with a hazardous
label (see the image on the right).

The Formulation Determines
the Type of Garb

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Initial Steps
1. Calculate the quantities needed for each component.

2. Gather aii the components and the equipment needed.
3. Wash equipment, if needed, and calibrate.
4. Perform hand hygiene and garb.
The calculations required for compounding will often
require unit conversions, percentage and ratio strengths,
basic algebra and changing concentrations with Q1C1 =
Q2C2 and alligation.

22%

274

Completion Steps
1. Package the product and apply the container label and any

2. Perform QC: validate the weight, check the product for

PPE is reviewed in the Compounding I chapter.

Percentage Strength:
20 g = Xg X = 22.222 g
or
90g 100 g

Other steps are unique to the formulation type, such as
calculating the density factor to make suppositories.

needed auxiliary labels. A duplicate container label can be
placed on the compounding record.

Minimally, PPE (i.e., garb) should include a clean lab coat
and gloves when preparing non-sterile, non-hazardous
preparations. The SDS will provide information if other PPE
is needed. For example, the SDS for benzalkonium chloride
recommends using gloves, a gown and eye/face protection.
Benzalkonium chloride should not be exposed to skin or
mucus membranes, and the SDS provides instructions to
manage exposure, such as steps to take if the compound is
inhaled.

Example:
What is the percentage strength
(w/w) of ketamine in the
compounded topical pain gel?
(Round to the nearest WHOLE
number.)

Most formulations will require common techniques, such
as trituration, levigation and geometric dilution.

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TOPICA.l PJ\IM GU

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20,
10,

21,

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75g

Pro&.toliaJOr~t,

200mg

Poloumer F 127 JO'Jlo

Q~ ~d 90g

mixing adequacy, color, clarity, odor, consistency and
pH. Enter the measurements and observations in the
compounding record.
3. Counsel the patient, and if any subsequent ADRs are
reported, add them to the compounding record.

PREPARING POWDERS
REDUCING PARTICLE SIZE
When making a compound with dry ingredients, the goal is
to make an evenly-distributed mixture with fine powder.
Comminution means to reduce pa1,ticle size by grinding,
crushing, milling, vibrating or other processes (manual or
mechanical).
The compounder likely starts off
with coarse granules or broken tablet
pieces. Powders will be finely ground
into particles that range in size from
0.1 - 10 microns. After the powder
has been ground, it is placed into a
sieve.

Using a powder sieve
ensures uniform
particle size
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Sieves, which are sifters, are used to ensure that the particle
size is uniform. The powder is put into the sieve and sifted
through the mesh. Once placed into the sieve, the powder
is stirred with a sieve brush or a plastic spatula to force
the particles through the mesh. A high mesh size has many
wires that make many holes, and only a fine powder will get
through the mesh. The sieve number is based on the number
of holes per inch (e.g., #100 sieve has 100 openings/inch).

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Three Main Methods of Comminution
Trituration: a general term used to mean "mix thoroughly"
(or make the product homogenous) . Pharmacists most
commonly associate trituration with grinding tablets with
a mortar and pestle until a fine powder is achieved, but the
term can describe liqu ids (e.g., tritu t·ating an emulsion by
shaking it).

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© 2021, © 2022

Comminution

Levigation and spatulation:
Levigation involves triturating the powder with a mortar
and pestle and incorporating a small amount of liquid
(called a levigating agent or wetting agent). This helps
with the gl'inding process and creates a uniform paste.

Grind into a fine powder

Just like trituration,
but with a
levigating agent
<{;JRxPrep

o Spatulation is similar to levigation, but performed on an ointment slab with a spatula (not with a mortar and pestle).
Pulverization by intervention is used for crystalline powders that will not crush easily. The Cl'ystals are dissolved with an
intervening solvent and mixed until the solvent evaporates. When the powder recrystallizes, the particles are finer.

MIXING INGREDIENTS
Geometric dilution is a method of mixing ingredients to ensure that ingredients are evenly distributed in a diluent or delivery
vehicle. A small amount of the drug is mixed into an equal amount of the diluent. After the initial small amount is thoroughly
mixed, another equal amount of the ingredients is mixed in. This is repeated until all the ingredients are mixed together.
Geometric dilution can be used with dry powder ingredients alone, or when making a paste. When using multiple ingredients,
begin with the ingredient that has the smallest quantity, followed by the ingredient with the next smallest quantity, and up
until each has been added. With each addition, the amount should be roughly doubled.

Geometric Dilution is used to Prepare Homogenous Products
Let me explain how to do geometric dilution. We use
geometric dilution to mix all types of components together to
make a smooth, evenly-distributed (homogenous) preparation.

•

•

The drug powder (ground
smooth!) is already on the
ointment slab. A (roughly) equal
amount of the ointment base is
added. This will make about
double the amount, then we
repeat the process.

Why didn't you dump it all in at once?

w-;;

-

It will not be a homogenous~
(even) mixture. The
ointment will feel gritty
and the drug dose will
be provided unevenly.
;e .::

Would you use the same ,' Both would be fine! Geometric dilution
works well to mix two (or more)
process if you were
mixing in a mortar? What substances together. Bakers use a similar
process, adding a little at a time, to make
if you were mixing two
an even, smooth batter for a yummy
powders together?
cake! Who wants to eat a lumpy cake?

,jjj,'

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DOSAGE FORMS
SOLUTIONS, SUSPENSIONS AND EMULSIONS

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1

A SOLUTION is a solute dissolve~

a solvent (such as NaCl, dissolved in water).

Solutions are homogenous (consistent, uniform throughout), If the solute concentration is too high, it can lead to unwanted
precipitation (see below).
Solutions are usually for oral use. Lotions are topical solutions.
TYPES OF SOLUTIONS:

Syrups are oral solutions with sucrose, other sugars or artificial sugars.
Elixirs are sweet hydroalcoholic solutions used for drugs that would be insoluble in a purely aqueous formulation.
Hydroalcohol is a mixture of alcohol and water.
Tinctures are plant or animal extracts dissolved in alcohol or hydroalcohol.
Spirits are alcohols or hydroalcohols of volatile, aromatic compounds such as camphor. Volatile means the compound
vaporizes (evaporates) easily.
A SUSPENSION is a solid dispersed in a liquid. It is a two-phase heterogeneous mixture.
A wetting agenVlevigatlng agent is a type of surfactant used to incorporate an insoluble drug into a liquid, which makes a suspension.
A desirable suspension does not have rapid precipitation of the solids; particles can be redlspersed easily by shaking.

An EMULSION is a liquid dispersed in a liquid. It is a two-phase heterogeneous mixture. Emulsions are oil-in-water (oil droplets in an
aqueous vehicle) or water-in-oil.·
An emulsifier is a type of surfactant that is used to reduce the surface tension between two liquids (e.g., oil and water).
The emulsifier allows the two phases to come closer together.
To make the emulsion, the emulsifier will need to be carefully chosen, according to the hydroph!llc·lfpophillc b~lance [1-tlB) number
(see the Compounding II chapter).
·rhe phase that is present as droplets is the dispersed, internal phase or discontinuous phase, and the phase in which the droplets are suspended is the continuous or
external phase.

PRECIPITATION/SEDIMENTATION is when the dispersed phase settles (clumps) together. The process of a solid settling on the
bottom of a container is sedimentation.

This can happen with suspensions and ~ulsions, and less commonly with solutions. Shake or gently roll to re-disperse.

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How to Prepare Solutions
Prepare the ingredients, and reduce the particle size of the drug/s to form a fine powder. The initial step in preparing any solution will be
to determine if the solute will dissolve in the solution. The drug should remain soluble at different temperatures that may be encountered,
including during refrigeration, if required for stability. If the drug is not soluble (e.g., will not dissolve in water), a suspension or a different
solvent may be preferable. The dissolution rate can be used to determine the time it will take for the solute to dissolve. The dissolution rate is
calculated using Fick'S First Law of Diffusion. A larger surface area (i.e., smaller particles), stirring the preparation and using heat will increase
the dissolution rate.
Determine if the solution will be stable at the desired temperature. A buffer system may be needed to resist changes In pH (see the end of this
chapter). A preservative may be needed to protect against microbial growth, including bacteria, fungi and yeast. Flavorings, sweeteners and
coloring agents can be added. Package the solution and apply appropriate auxiliary labels.

How to Prepare Suspensions
Prepare the ingredients, and reduce the particle size of the drug/s to form a fine powder. Wet the powder, and levigate to form a paste.
Continue to add liquid in portions. Add a surfactant to help keep the suspension dispersed. Transfer the mixture into a conical graduate or the
container in which it will be dispensed, and QS to the final volume. A homogenizer will help make a uniform suspension. A preservative may
be needed to protect against microbial growth, including bacteria, fungi and yeast. Flavorings, sweeteners and coloring agents can be added.
Package the suspension and apply a BUD.
Even with surfactants used as suspending agents, suspensions are inherently unstable, and will need to be redispersed (i.e., shaken) prior to use.

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ingredients by the melting temperature, and melt in that
order, starting with the highest melting point.

How to Prepare Emulsions

(

4partsoil

j

( 2 parts water )

1 part gum

(e.g., acacia)

Emulsions can be made by either the Continental or English gum
method; mixing oil, water, and an emulsifier (gum) in a 4:2:1 ratio .

Continental (dry gum) method:
1. Levigate the gum with oil.

2. Add the water all at once.
3. Triturate by shaking in a
bottle or mixing in a mortar
until a cracking sound is
heard and mixture is creamy
white.

English (wet gum) method:
1. Triturate the gum with water
to form a mucilage (thick
and sticky like mucus).

2. Add oil slowly while shaking
or mixing.

3. Add other ingredients as in
the dry gum method.

4. Add other ingredients
by dissolving them first
in solution and adding a
quantity of water sufficient
to make (QS) up to the final
volume.
5. Homogenize (with a
homogenizer machine).

Hint: It rains a lot in England
(wet), and the oil is added slowly
because you cannot drive too
fast in the rain. The continent is
dry, and you can add the water
quickly (all at once).

Eutectic Mixtures
A eutectic mixture means that the combination of the
ingredients (when mixed together} will melt at a lower
temperature than either of the individual component's
melting tempel'atures (see comic). The lower melting point
of the eutectic mixture allows it to penetrate the skin more
easily than the individual components.
Eutectic mixtures can create difficulty during compounding:

If a pharmacist is not aware that the components form a
eutectic mixture, the temperature on the hot plate can be
set too high and the mixture can burn.
If the components are solid powders at room temperature,
the mixture of the powders can melt and turn the
mixture into a sticky mess, ruining the dry preparation.
An adsorbent powder (magnesium oxide, magnesium
carbonate or kaolin) can be used to keep the powder dry.

The yellow one melted at
76°C, and the blue one
melted at s2°c.

POWDERS
Powders are fine particles of a solid. A dose of medication can
be given as the dry powder (put into liquid or a small amount
of soft food) for someone who is not able to swallow capsules
or tablets, such as a small child or an elderly person with
dysphagia. Powders are used to prepare tablets, capsules,
inhalations, suspensions, ointments, creams and other
topical treatments. Powders often include excipients. The
excipients listed here are specific to the powder part of the
preparation, and are commonly used for the purpose stated:
Glidant/lubricant to improve the flowability of a powder:
magnesium stearate.
Surfactant to neutralize the static charge and keep the
powder from floating away: sodium lauryl sulfate.

That's strange! When I mixed them
together, the two compounds melted at
~ • c . It's lower than either one of t ~ e m !

r•

•
•

The two ingredients formed
a eutectic mixture, with a
lower melting point than
either of the components.

How to Prepare Powders
Reduce the size of the powder. This may require breaking down
tablets with a grinder. followed by trituration or levigation. Sift the
powder through a sieve (pictured previously) onto glassine paper.
If the amount of powder per dose is very small. it will be necessary
to add an inert filler (diluent). A filler could also be needed to
provide a minimum weighable quantity if using a torsion balance
(see the Compounding 11 chapter). A common diluent is lactose.
Add the filler and other excipients using geometric dilution.

Melting Point Order
For any formulation, if melting ingredients, melt the
ingredient with the highest melting point prior to adding
the ingredient/s with lower melting points. Line up the

Be careful! If two powders
are mixed together, and they
form a eutectic mixture, the
powders could start to melt.
A nice powder mixture can
become a sticky mess!

•

,.
•

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CAPSULES

LOZENGES/TROCHES

Capsules are soluble shells
of gelatin (an animal
product) or hypromellose (a
vegetable product}, which
are filled with the active
drug, diluents (fillers} and
Capsule-filling machine
any other excipients. HardfQJ fe/iµe caprn ros/Shutterstock.co,n
shell capsules are used most
commonly in compounding, and are filled with powders.
Soft-shell capsules are used mostly for oils. Glycerol and
sorbitol are used as plasticizers to make the capsules less
brittle and more flexible.

Lozenges (or troches) can be hard or soft tablets that slowly
dissolve in the mouth, or chewable tablets that are easily
chewed and swallowed. Lozenges/troches are generally
used to deliver a medication that acts locally in the mouth . A
commercially available example is a clotrimazole troche for
treatment of oral thrush.
A lozenge contains the active drug in a base of sucrose or
syrup for hard lozenges, PEG for soft lozenges and glycerin or
gelatin for chewable lozenges. Flavoring agents and coloring
agents may be added. The base is melted, mixed with the API
and excipients, placed into a mold and allowed to cool back
into a solid.

How to Prepare Capsules
Capsules are made by first triturating the dry ingredients and
geometrically mixing with the fillers/other excipients. The powder
is put into the capsules by either hand filling (also known as the
"punch method") or by using a capsule-filling machine (see the
Compounding II chapter for information on equipment).
Hand filling: to begin, the powder is placed on powder paper or on
an ointment slab. The pile of powder is smoothed with a spatula
to a height about a third of the length of the capsule. The open
end of the capsule is repeatedly "punched" into the pile of powder
until the capsule is filled. When the base is filled, it is fitted with
the cap.
Manual capsule-tilling machine: these are small devices that help
the pharmacist quickly load 50, 100 or 300 capsules. Plates help
sort the capsule bodies and hold them upright and in place. The
powder is put above the capsules on to a plastic sheet where a
plastic spreader is used to move the powder into the capsules.
A comb or tamper and a spreader are used repeatedly until the
powder is packed into the capsules. Then, the caps are put over
the capsule bodies.

Common capsule sizes range from largest (size 000, -1 inch
long} to smallest (size 5, -0.4 inches long}.
Capsule bodies can be filled by hand (for a small number}
or with a capsule-filling machine (for larger amounts).
In addition to using a capsule-filling machine to add a
powder formulation, liquids can be added to upright
capsule bodies with a pipette or dropper.

TABLETS
There are many types of tablets, including molded tablets,
sublingual tablets, buccal tablets, orally disintegrating
tablets, chewable tablets, effervescent tablets and compressed
tablets. The molded tablet is the most common tablet type
made in compounding, and the compressed tablet is the most
common type made in manufac turing.
How to Prepare Molded Tablets
The first step to compound a molded tablet is to triturate the dry
ingredients and mix by geometric dilution. Alcohol and/or water is
added to moisten the powder. The powder mixture should have a
pasty consistency, which can be molded into tablets (using tablet
molds), and allowed to dry. Coloring and a coating may be added.
278

CREAMS
Creams, lotions, ointments, pastes and gels are delivery
vehicles, and are described in more detail in the Compounding
II chapter. Creams are semi-solid formulations intended for
topical use. They contain more than 20% water and up to 50%
oil. They spread easily and are reasonably hydrating. Creams
are packaged in tubes and tubs.

LOTIONS
Lotions contain the most water (compared to other topicals),
are more fluid than creams, and can be poured. They are easy
to spread on the skin and they absorb quickly. Since lotions
contain a lot of water, they can be delivered in pumps.

OINTMENTS
Ointments contain the least water; 0 - 20%, with the
remainder composed of oil-based product/s. Ointments are
a good delivery vehicle to provide a barrier to exposure (e.g.,
organisms, sun) and they prevent moisture loss which helps
burn and scar healing. They are packaged in tubes or tubs.
How to Prepare Ointments
Powders should be triturated well, using a levigatlng agent. The
levigating agent must be miscible with the base, which means
they can mix together well (mixing "like with like" is a common
compounding principle). The powder will be mixed into the
ointment base, using geometric dilution.
Certain ointments will require heat in order to mix the components
together well. This is called the fusion method. Always use the
lowest temperature possible. First, melt the ingredients with
the highest mel ting point, then add the others, according to
their decreasing melting points. Otherwise, undesired chemical
reactions could occur. A water bath used to heat the ointment
components will help prevent over-heating.

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PASTES

How to Prepare Suppositories

The ingredients in pastes are similar to ointments, but
they are made thicker by adding more solid ingredients.
They provide a protective barrier because they do not melt
significantly at body temperature.

There are three methods to prepare a suppository:
Hand molding can be used when only a few suppositories are to
be prepared, using a cocoa butter base. The cocoa butter is not
melted. It is grated and then mixed with the drug/ s in a mortar
and pestle or on a pill tile with a spatula. The mass is rolled into a
cylinder, which is cut into suppository-size pieces. A tip is formed
on one end to make insertion easier.

GELS

In the commonly-used fusion molding method, the base is gently
heated, the ingredients are added, the mixture is poured into
room temperature molds, and left to harden. If the base is poured
into a cold mold, it can cause the suppository to crack and split. If
the suppository does not harden, the molds can be refrigerated .
Disposable plastic molds can be used for molding. Often, the
suppositories are dispensed in the mold; suppositories are soft,
and easily damaged. They are stored in the mold until needed.

Gels are semisolids interpenetrated by a liquid. Gels serve
as a versatile drug delivery system for various routes of
administration; they can be used orally, topically (for local
or transdermal drug delivery), vaginally and rectally. Gelling
agents are added to increase the viscosity and thicken
the product. Alcohol is added to some gels to decrease the
viscosity. Pluronic lecithin organogel ("PLO gel") can be used
for transdermal drug administration. Pre-mixed PLO gels are
available. See the Compounding II chapter for details.

In the compression molding method, the pharmacist will need to
know the weight of each mold, and the drug's density factor (see
above). The amount of base required to fill each mold is calculated,
the base is grated, mixed with the drug and put into a cold
compression mold.
Lubricants can be applied to the mold so the suppositories can be
removed more easily. If a lubricant is used it must be opposite of
the suppository base in terms of solubility. The goal is to reduce
friction. For example: glycerin or pmpylene glycol (both watersoluble) are good lubricants for suppositories made with oil-soluble
suppository bases, while mineral oil or vegetable oil spray (oil·
soluble) are good lubricants for water-soluble bases.

SUPPOSITORIES
A suppository base is either oil-soluble (oleaginous) or
water-soluble. Oil-soluble bases include cocoa butter (known
as theobroma oil) and hydrogenated vegetable oils (palm,
palm kernel and coconut oils). Water-soluble bases include
polyethylene glycol (PEG) polymers and glycerinated gelatin.
If a drug powder is added to a base, the powder should be
triturated to a fine consistency.
If the preparation softens or melts easily, such as with
theobroma oil (cocoa butter), the molds will need to
be stored in the refrigerator. The melting point of
theobroma oil is slightly below human body temperature.
When theobroma oil is used as a suppository base, the
suppository will start to melt when held in the hand. It is
not possible to insert a melting suppository. Storing it in
the refrigerator will make the suppository hard, and easier
to insert. Storing it in the mold in which it was formed
would be preferable.
The drug will displace part of the base. If the drug has the
same density as the base, it will displace an equal amount of
volume. If the density is greater, it will displace less, and if
it is lower, it will displace more. To calculate the amount of
base displaced, the density factor of the drug is needed. The
density factor can be found in compounding references, or
calculated with the Paddock Method:

l~:~:; " A-:+B

© 20 22

Vaginal suppositories are used to treat conditions
inside the vagina, such as a Candida infection,
or conditions related to the female reproductive
system, such as hormone replacement in a
patient with menopausal symptoms.
Rectal suppositories are used either to treat a local condition, such
as hemorrhoids or distal ulcerative colitis, or to treat a systemic
condition, such as pain and fever in a patient who cannot take
oral medication (e.g., acetaminophen suppository). Suppositories
bypass the oral route and largely avoid first-pass metabolism.
Suppository bases must be hard enough to be briefly handled, but
soft enough to melt easily once inserted. Storing the suppository
in the refrigerator can make insertion easier.

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COMPOUNDING KITS
There are some companies that package pre-measured
ingredients for a compounded product into "compounding
kits." If the pharmacy does not routinely receive
prescriptions for a certain product, it can be cost-effective
(and easier) to purchase compounding kits as needed
instead of purchasing the bulk ingredients.

A = weight of the suppository blank, B = weight of medication per
suppository, C = weight of medicated suppository.

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17

I COMPOUNDIN G

Ill: DO C UMEN TATION & PREPAR AT ION

SELECTING THE BEYOND-USE DATE
FOR NON-STERILE PREPARATIONS
The beyond-use date (BUD) is the date or time after which
the compounded product should not be used. The Study Tip
Gal provides the default BUDs for non-sterile compounded
preparations that are packaged in tight, light-resistant
containers, per USP 795 standards.
USP specifies refrigeration for water-containing oral
formulations only. Individual products may have shorter
stability and/or different storage requirements which will
override USP-provided defaults. Other exceptions include:
If any ingredient expires before the BUD, use the earlier
expiration date.

FORMULATION

BEYOND-USE DATE

Nonaqueous Formulations
(e.g., a drug in petrolatum)

Not later than 6 months (180
days). Store at room temperature.

Water-Containing Oral
Formulations (such as an
oral suspension)

Not later than 14 days
when stored at controlled
cold temperatures. Store in
refrigerator.

----- .,A,,iA

Not later than 30 days. Store at
Water-Containing Topical/
Dermal and Mucosa! Liquid 1 room temperature.
and Semisolid Formulations
(such as a cream or lotion)

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BUDs can be extended if stability data is obtained that
determines the drug is stable for a longer period.

Beyond-Use Date Examples
FORMULATION

MAXIMUM BUD

Metronidazole topical solution prepared with propylene glycol and distilled water

Topical, aqueous

30 days

Acetaminophen, diphenhydramine and hydroxyzine oral suspension prepared in lemon syrup
(citric acid, purified water, lemon flavoring)

Oral, aqueous

14 days, refrigerated

Topical preparation of zinc oxide in white petrolatum

Non-aqueous

180 days

Nystatin in a strawberry-flavored popsicle with an 80% sorbitol and purified water solution

Oral, aqueous

Polymyxin and hydrocortisone prepared in a commercial emulsion cream for skin rash

Topical, aqueous

30 days

Topical, aqueous

30 days

Estradiol powder, black cohosh powder and soybean oil preparation in hypromellose capsules

Non-aqueous

180 days

Morphine powder with stevia sweetener in a PEG lozenge

Non-aqueous

180 days

Progesterone suppository in an oleaginous base

Non -aqueous

Calamine powder prepared with glycerin in 70% isopropyl alcohol for poison ivy

Topical, aqueous

30 days

Lidocaine and diphenhydramine in poloxamer gel with lecithin/isopropyl palmitate

Topical , aqueous

30 days

Non-aqueous

180 days

Topical, aqueous

30 days

PREPARATION

- - - - - - - - - - - - - ---

Ciprofloxacin and dexamethasone in

Versabase lotion

Diclofenac powder in propylene glycol
Lidocaine, alcohol USP and distilled water buccal dental gel

Unit-Dose Repackaging
A unit-dose refers to a small package that contains one dose
of a medication. Unit-dose preparations can come from the
manufacturer or a repackaging company, or a pharmacy can
repackage multi-dose containers into unit-dose packages.
Example: repackaging clopidogrel 75 mg from a multidose container of 100 tablets, with each unit-dose package
containing one 75 mg tablet, which is the usual dose.

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Unit-dose repackaging is not compounding, but shares some
commonalities, including the assignment of a BUD, and safety
requirements if repackaging HDs. BUDs for repackaged
drugs should be the manufacturer's expiration date from the
original container or 6 months from the repackaging date,
whichever is earlier.

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180 days

NON-STERILE QUALITY ASSURANCE
A quality assurance (QA) plan outlines the steps and actions
that ensure proper standards are maintained. It includes the
Standard Ope1•ating Procedures (SOPs), which are itemized
steps on how to perform routine and expected tasks. The QA
plan must be reviewed and updated regularly.
The QA program should include periodic testing of the
finished compounded preparations. A pharmacy may do
some QA testing in-house (e.g., confirming weight and
consistency) and outsource others (e.g., sending products out
to another company for sterility or stability testing).
QA records need to include the names of the compounding
staff, including their job orientation and training records.