Preparing Sterile Intravenous Products

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Preparing Sterile Intravenous Products

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Title: Preparing Sterile Intravenous Products

1
(No Transcript)
2
Chapter 11
Preparing Sterile Intravenous Products
3
Chapter 11 Topics

Intravenous Preparations
Equipment Used in IV Preparation
Preparing IVs
Calculations for the Hospital Pharmacy Technician

4
Learning Objectives

Describe the characteristics of intravenous
solutions including solubility, osmolality, and
pH
Identify common vehicles for intravenous
solutions
Describe the equipment and procedures used in
preparing parenterals
Identify the components of an intravenous
administration set
Convert from Fahrenheit to Centigrade and vice
versa
Calculate the molecular weight and
milliequivalents of certain substances used in
the pharmacy
Compute the specific gravity of liquids
Calculate intravenous rates and administration

5
Intravenous Preparations

The IV route of administration is used
to reach appropriate drug serum levels
to guarantee compliance
for drugs with unreliable gastrointestinal (GI)
absorption
for the patient who can have nothing by mouth
for the patient who is unconscious or
uncooperative, and for rapid correction of fluid
or electrolytes
Most parenterals are introduced directly into the
bloodstream
must be free of air bubbles or particulate matter
have many characteristics including solubility,
osmolality, and pH

6
Characteristics of IV Preparations

Intravenous (IV) preparations are either
solutions (in which ingredients are dissolved)
suspensions (in which ingredients are suspended)
Most parenteral preparations are made of
ingredients in a sterile water medium
Some parenteral preparations may be oleaginous
(oily)

7
Characteristics of IV Preparations

Parenteral IV preparations must have chemical
properties that will not
damage vessels or blood cells
alter the chemical properties of the blood serum
With blood, IVs must be
iso-osmotic (having the same number of particles
in solution per unit volume)
isotonic (have the same osmotic pressure, meaning
the pressure produced by or associated with
osmosis)

8
Characteristics of IV Preparations

The osmolality is the amount of particulate per
unit volume of a liquid preparation
measured in milliosmoles (mOsm)
osmolality of blood serum 285 mOsm/L
An isotonic solution is a solution in which body
cells can be bathed without a net flow of water
across a semipermeable membrane
0.9 normal saline (NS)

9
Characteristics of IV Preparations

Pharmacists sometimes must adjust tonicity of
parenteral preparations to ensure they are near
isotonic
A hypertonic solution has a greater number of
particles than the blood cells themselves
50 dextrose or 3 sodium chloride
A solution of less than normal tonicity is
hypotonic, which has fewer numbers of particles
than blood cells
0.45 NS

10
Characteristics of IV Preparations

The pH value is the degree of acidity or
alkalinity of a solution
acidic solution pH of less than 7
alkaline solution pH value more than 7
Human blood plasma has a pH of 7.4
slightly alkaline
parenteral IV solutions should have a pH that is
neutral (near 7)

11
Methods of Injection

The bolus, or injection, is one of the most
common routes of IV administration
The injection is performed using a syringe
prepackaged in the form of filled, disposable
plastic syringes
injectable drug must be taken up into the syringe
from a single- or multi-dose glass or plastic
vial, or from a glass ampule
Sometimes the solid drug in the vial has to be
reconstituted by addition of a liquid before use

12
Methods of Injection

IV infusions deliver
large amounts of liquid into the bloodstream over
prolonged periods of time
IV infusion is used to deliver

blood electrolytes
water drugs
other fluids nutrients

13
Discussion
What are some characteristics of parenteral
preparations, and why are they important?
14
Discussion
What are some characteristics of parenteral
preparations, and why are they important? Answer
Tonicity, osmolality, and pH are characteristics
of parenteral preparations. It is important that
they be adjusted to be as close as possible to
the values for human blood, to prevent damage to
blood cells and organs.
15
Terms to Remember

osmotic pressure
osmolality
isotonic solution
hypertonic solution
pH value

16
Equipment Used in IV Preparation

Pharmacies use plastic disposable products to
save time and money
provide the patient with an inexpensive sterile
product
Often the entire system sent out to the patient
floors is composed of plastic
thin, flexible plastic catheters are replacing
metal shafts that deliver the medication into the
vein
in many cases the only durable, nondisposable
product used to deliver IV medication is the IV
pump or controller

17
Commonly Used IV AbbreviationsFluids
IV Component Abbreviation
2.5 dextrose in water D2.5W
5 dextrose in water D5W
5 dextrose and lactated Ringers solution D5RL or D5LR
10 dextrose in water D10W
5 dextrose and normal saline D5NS
2.5 dextrose and 0.45 normal saline D2.5½ NS
5 dextrose and 0.45 normal saline D5 ½ NS
18
Commonly Used IV AbbreviationsFluids
IV Component Abbreviation
normal saline NS
0.45 normal saline 0.45NS or ½ NS
lactated Ringers solution RL or LR
sterile water for injection SWFI
bacteriostatic water for injection BWFI
sterile water for irrigation SW for irrigation
normal saline for irrigation NS for irrigation
19
Commonly Used IV AbbreviationsElectrolytes
IV Component Abbreviation
potassium chloride KCl
potassium phosphate K phos or KPO4
potassium acetate K acet
sodium phosphate Na phos or NaPO4
sodium chloride NaCl
20
Commonly Used IV AbbreviationsAdditives
IV Component Abbreviation
multivitamin for injection MVI
trace elements TE
zinc (a trace element) Zn
selenium (a trace element) Se
21
Syringes and Needles

Syringes are used for IV push and in the
preparation of infusions, are made of glass or
plastic
Glass syringes are more expensive
use limited to medications that are absorbed by
plastic
Plastic syringes
are less expensive
are disposable
come from the
manufacturer sterile

22
Syringes and Needles

Needles are made of stainless steel or aluminum
needle lengths range from 3/8 of an inch to 6
inches
needles come in gauges ranging from 30 to 13
(higher the gauge, smaller the lumen)
After use, needles must be discarded in a
designated sharps container

23
IV Sets

An IV administration set is a sterile,
pyrogen-free disposable device used to deliver IV
fluids to patients
The set may
be sterilized before use by means of radiation or
ethylene oxide
come in sterile packaging and a sealed plastic
wrap
Sets do not carry expiration dates
Sets carry the following legend
Federal law restricts this device to sale by or
on the order of a physician.

24
IV Sets

Nurses generally have the responsibility for
attaching IV tubing to the fluid container
establishing and maintaining flow rate
overall regulation of the system
Pharmacy personnel must assess aspects of IV
systems, including infusion sets
A complete understanding of IV sets and their
operation is important to pharmacists and
pharmacy personnel

25
IV Sets

IV sets are sterile and nonpyrogenic
Each unit is supplied in packaging that ensures
the maintenance of sterility
Flanges and other rigid parts of an IV set are
molded from tough plastic
Most of the length of the tubing is molded from a
pliable polyvinyl chloride (PVC)
PVC sets should not be used for
nitroglycerin, which is absorbed by the tubing
IV fat emulsions, which may leach out of the
tubing

26
IV Sets
Safety Note
A damaged package cannot ensure sterility, even
if all protectors are in place. It is best to
discard sets that are found in unoriginal,
opened, or damaged packages.
27
IV Sets
Safety Note
Do not use PVC IV sets for nitroglycerin or fat
emulsions. Special types of plastic sets are
required for such infusions.
28
IV Sets

The length of sets varies from 6-inch extensions
up to 110- to 120-inch sets used in surgery
the priming of tubing depends on the length of
the set
Standard sets have a lumen diameter of 0.28 cm
varying the size of the lumen diameter achieves
different flow rates
regulation of flow rates is critical in neonates
and infants

29
IV Sets

The tubings interior lumen may contain particles
that flush out when fluid is run through the set
Use of final filtration has reduced the need for
flushing the line with the IV fluid before
attaching the set to the patient

30
IV Sets

A spike to pierce the rubber stopper or port on
the IV container
A drip chamber for trapping air and adjusting
flow rate
A control clamp for adjusting flow rate or
shutting down the flow
Flexible tubing to convey the fluid

31
IV Sets

A needle adapter for attaching a needle or a
catheter
A catheter, or tube, may be implanted into the
patient and fixed with tape to avoid having to
repuncture the patient each time an infusion is
given

32
IV Sets

Most IV sets contain a Y-site, or injection port
a rigid piece of plastic with one arm terminating
in a resealable port
used for adding medication to the IV
Some IV sets also contain resealable in-line
filters
protection for the patient against particulates,
including bacteria and emboli

Go to www.baxter.com to see IV tubing products
from a major manufacturer
33
IV Sets

The spike is a rigid, sharpened plastic piece
used proximal to the IV fluid container
covered with a protective unit to maintain
sterility
generally has a rigid area to grip while it is
inserted into the IV container
If an air vent is present on a set, it is located
below the spike
the air vent points downward and has a bacterial
filter covering
the vent allows air to enter the bottle as fluid
flows out of it
necessary for glass bottles without an air tube

34
IV Sets

The drip chamber is a transparent, hollow chamber
located below the sets spike
drops of fluid fall into the chamber from an
opening at the uppermost end, closest to the
spike
number of drops it takes to make 1 mL identifies
an IV set

35
IV Sets

The most common IV drop sets are
10 (10 gtt/mL)
15 (15 gtt/mL)
20 (20 gtt/mL)
60 (60 gtt/mL)

An opening that provides 10, 15, or
20 gtt/mL is commonly used for adults
An opening that provides 60 gtt/mL is used for
pediatric patients and is called a mini-drip set

36
IV Sets

The person administering the fluid starts the
flow by filling the chamber with fluid from an
attached inverted IV container
the chamber sides are squeezed and released
fluid flows into the chamber
procedure is repeated until an indicated level is
reached or approximately half the chamber is
filled
entering drops are counted for 15 seconds
adjustments made until approximate number of
drops desired is obtained
rate should be checked five times, at 30-second
intervals, and again for a last count of 1 minute

37
IV Sets

Clamps allow for adjusting the rate of the flow
and for shutting down the flow
Clamps may be located at any position along the
flexible tubing
Usually a clamp moves freely, allowing its
location to be changed to one that is convenient
for the health professional administering the
medication

38
IV Sets

Types of clamps used for IV solutions include
slide clamp has an increasingly narrow channel
that constricts IV tubing as it is pressed
further into the narrowed area
screw clamp consists of a thumbscrew that is
tightened or loosened to speed or slow the flow
roller clamp a small roller that is pushed along
an incline
moving down the incline, constricts tubing and
reduces fluid flow
moving up the incline, increases the flow

39
IV Sets

Clamp accuracy can be affected by
creep tendency of some clamps to return to a
more open position with increased fluid flow
cold flow tendency of PVC tubing to return to
its previous position
The needle adapter
usually located at the distal end of the IV set,
close to the patient
has a standard taper to fit all needles or
catheters
is covered by a sterile cover before removal for
connection

40
IV Sets

A set may have a built-in or in-line filter
Final filtration should protect the patient
against particulate matter, bacteria, air emboli,
and phlebitis
a 0.22-micron filter is optimal
a 5-micron filter removes particles that block
pulmonary microcirculation but will not ensure
sterility
A Y-site is an injection port found on most sets
the Y is a rigid plastic piece with one arm
terminating in a resealable port
the port, once disinfected with alcohol, is ready
for the insertion of a needle and the injection
of medication

41
Filters

Filters are devices used to remove contaminants
such as glass, paint, fibers, and rubber cores
will not remove virus particles or toxins
will occasionally become clogged, thus slowing
expected flow rates
Filter sizes include
5.0 microns random path membrane (RPM) filter,
removes large particulate matter
0.45 microns in-line filter for IV suspension
drug
0.22 microns removes bacteria and produces a
sterile solution

42
Catheters

IV administration for fluids and drug therapy can
be accomplished through needle-like devices
called catheters
Catheters are devices inserted into veins for
direct access to the blood vascular system and
are used in two primary ways
peripheral venous catheters, which are inserted
into a vein close to the surface of the skin
central venous catheters, which are inserted
deeper in the body

43
Catheters

A peripheral venous catheter is inserted into
veins close to the surface of the skin and used
for up to 72 hours
unit is inserted into a vein
needle portion is withdrawn
flexible, Teflon catheter is left in place
Peripheral catheters are easy to insert, and most
nurses can do this at a patients bedside
usually inserted in sites on the arms or hands
can be inserted in the feet and scalp if the
nurse or physician cannot locate good veins in
the arms or hands

44
Catheters

Peripheral venous catheters will likely cause
problems 20 to 50 of patients
pain
irritation
infiltration
Infiltration is a breakdown or collapse of a vein
that allows the drug to leak into tissues
surrounding the catheter site, causing edema
and/or tissue damage

45
Catheters

A central venous catheter is one placed deep into
the body
more complicated to place
inserted by a physician to minimize the risk of
infection
Central catheters are commonly used for therapy
of 1 to 2 weeks or even longer
A central venous catheter is used to administer
hypertonic solutions such as total parenteral
nutrition (TPN) solutions
potentially toxic drugs such as cancer
chemotherapeutic drugs

46
Catheters

The most common sites of insertion are
subclavian vein, lying below the clavicle and
joining the jugular vein
jugular vein, in the neck
femoral vein, in the groin area
Placed deep in the vein so that the end enters
the superior vena cava close to the heart where
the blood flow is the greatest

Visit the Web site of the American Society of
Enteral and Parenteral Nutrition, a good source
for information and networking
47
Catheters

Problems with subclavian catheters are
possibility of subclavian vein laceration (i.e.,
missing the vein and puncturing a lung)
greater risk of infection because the procedure
is more invasive
A larger blood flow in the subclavian vein will
dilute a more concentrated solution such as TPN
TPN solutions provide
needed calories in the form of amino acids and
dextrose
vitamins, minerals, trace elements, and
electrolytes

48
Catheters

A multiple-lumen catheter is used to separately
administer potentially physically incompatible
drugs
comes with one, two, three, or four lumens
Each lumen exits the catheter at a different
location
no opportunity exists for the drugs to mix before
being diluted in the bloodstream

49
Catheters

Midline catheters are longer peripheral catheters
that go from insertion site into a deep vein
designed to stay in place 1 week or longer
The peripherally inserted central (PIC) line is a
very fine line that is threaded through the
peripheral vein into the subclavian vein
has the same characteristics as a central line
can be inserted by a skilled nurse at the bedside

50
Catheters

Some patients may be on TPN therapy for months or
even years in the hospital or at home
Infusion devices are surgically implanted to
provide long-term therapy
reduce the risk of infection

51
Catheters

Implantable infusion devices include the Hickman
and Broviac external catheters
Surgeon inserts the catheter below the breast and
tunnels it under the skin into the subclavian
vein
catheter has a cuff to which the bodys
connective tissue heals, sealing off bacterial
entry
lower point of body insertion makes the catheter
easier for the patient to see and clean

52
Catheters

Another form of implantable device is the
internal port, such as the Port-A-Cath, Life Port
when implanted the only evidence is a bump in the
skin
drugs, especially cancer chemotherapeutic drugs,
are administered by a small needle through the
skin in an injection port in the device

53
Pumps and Controllers

Fluids and drugs are often delivered to catheters
by some form of device, including electronic
devices, to control the infusion rate
The first system to deliver a drug IV was the
syringe system
Care must be taken when administering drugs that
have to be diluted or given very slowly
The syringe system is very nurse labor-intensive
and pharmacy labor-intensive

54
Pumps and Controllers

The Buretrol or Soluset were in use before
infusion pumps and replaced the syringe system
and has a built-in graduated cylinder
fluid is run into the cylinder
nurse can add a drug in the top of the cylinder
injection port for dilution and mixing before it
is infused
Safer than the syringe system because the drug is
being diluted in the cylinder and it can be
infused over a long period of time

55
Pumps and Controllers

The Buretrol or the Soluset have the following
problems
labor intensive
potential drug incompatibility
controllers are low-pressure devices (2 to 3
psi)
pressure of controller is generated by gravity
flow rate is controlled by rate of fluid drops
falling through a counting chamber
alarms sound with a kink in a line or even
interruption of blood flow when patient bends an
elbow

56
Pumps and Controllers

Infusion pumps are preferred by both nurses and
physicians
produce a positive pressure of 10 to 25 psi
are more accurate than controllers
have fewer flow interruptions
Infusion pumps control the flow of IV
medications
Maximum flow is 999 mL/hr
provides a higher rate of infusion
higher pressure increases possibility
of infiltration

57
Pumps and Controllers

A patient-controlled analgesia (PCA) device is a
type of medication delivery that uses a
parenteral route and allows the patient to
administer analgesics by pressing a button
controls the medication so the patient cannot
overdose or give the medication too soon after
the previous dose
Often, after surgery or severe injuries, a
physician will order a PCA for the patient for 24
to 72 hours

58
Pumps and Controllers
Safety Note
PCA pumps should carry the following label This
PCA pump button should be pushed only by the
patient.
59
Discussion
What is the most important characteristic that
all equipment used in IV preparation and
administration have in common?
60
Discussion
What is the most important characteristic that
all equipment used in IV preparation and
administration have in common? Answer Sterility
is a requirement for all equipment used in IV
preparation and administration.
61
Terms to Remember

IV administration set
filter
catheter
peripheral venous catheter
infiltration

central venous catheter
subclavian vein
multiple-lumen catheter
peripherally inserted central (PIC) line

62
Preparing IVs

Pharmacists and technicians prepare drugs and IV
solutions in a form ready to be administered to a
patient
IV push (i.e., bolus) and IV infusion dose forms
should be prepared in laminar airflow hoods using
aseptic techniques
products used during the preparation must always
be sterile and handled in such a manner as to
prevent contamination

63
Preparing IVs

Preparation should always
be done under the
supervision of a
licensed pharmacist
Medication that is prepared by the technician
must be reviewed and approved by the pharmacist

Visit the ASHP Web site for a standard for
quality assurance of sterile products
64
IV Preparation Guidelines

Begin any IV preparation by washing your hands
thoroughly using a germicidal agent such as
chlorhexidine gluconate or povidone-iodine
All jewelry should be removed from the hands and
wrists before scrubbing and while making a
sterile product
Wear gloves during procedures
Laminar airflow hoods are normally kept running
Eating, drinking, talking, or coughing is
prohibited in the laminar airflow hood
Working in the laminar flow hood should be free
from interruptions

65
IV Preparation Guidelines

Before making the product, thoroughly clean all
interior working surfaces
Gather all the necessary materials for the
operation and make sure they are
not expired
free from particulate matter such as dust
check for leaks by squeezing plastic solution
containers
Only essential objects and materials necessary
for product preparation should be placed in the
airflow hood

66
IV Preparation Guidelines

Work in the center of the work area within the
laminar airflow hood
at least six inches inside the edge of the hood
make sure nothing obstructs the flow of air from
the high-efficiency particulate air (HEPA) filter
over the preparation area
nothing should pass behind a sterile object and
the HEPA filter in a horizontal airflow hood or
above a sterile object in a vertical airflow hood

67
IV Preparation Guidelines

Follow proper procedure for handling sterile
devices and medication containers
Remember that the plunger and tip of the syringe
are sterile and must not be touched
For greatest accuracy, use the smallest syringe
that can hold the desired amount of solution
syringe should not be larger than twice the
volume to be measured
syringe is considered accurate to half the
smallest measurement mark on its barrel

68
IV Preparation Guidelines

The volume of solution drawn into a syringe is
measured at the point of contact between the
rubber piston and the side of the syringe barrel
Additives are commonly added to IV solutions
medications, electrolytes, vitamins and/or
minerals
Additives may be packaged in vials or ampules
Proper technique in using vials and ampules is an
important skill for the pharmacy technician to
learn

69
Vials

Powders are reconstituted by introducing a
diluent (e.g., sterile water for injection)
Vials are closed systems
the amount of air introduced should be equal to
the volume of fluid removed
an exception to this guideline is the withdrawal
of cytotoxic drugs from vials

70
Vials
Safety Note
With the exception of cytotoxic drugs, inject an
equal amount of air into the vial with the
syringe and needle before withdrawing the
medication.
71
Vials
Use a Syringe to Draw Liquid from a Vial

Choose the smallest gauge needle appropriate for
the task, and avoid coring the rubber top of the
vial and thus introducing particulate into the
liquid within it
2. Attach the needle to the syringe.
3. Draw into the syringe an amount of air equal
to the amount of drug to be drawn from the vial.

72
Vials

Swab or spray the top of the vial with alcohol
before entering the laminar flow hood allow the
alcohol to dry. Puncture the rubber top of the
vial with the needle bevel up. Then bring the
syringe and needle straight up, penetrate the
stopper, and depress the plunger of the syringe,
emptying the air into the vial.

73
Vials

5. Invert the vial with the attached syringe.
Draw up from the vial the amount of liquid
required.
7. Withdraw the needle from the vial. In the case
of a multidose vial, the rubber cap will close,
sealing the contents of the vial.
8. Remove and properly dispose of the needle, and
cap the syringe. A new needle will be attached at
the time of injection into a patient.

74
Ampules

An ampule is a single-dose-only drug container
The glass ampule offers another challenge because
one must first break the top off the ampule
before withdrawing the medication

75
Ampules
Opening an Ampule

Gently tap the top of the ampule to bring the
medication to the lower portion of the ampule.

76
Ampules
Opening an Ampule

Clean the neck with an alcohol swab then grasp
the ampule between the thumb and index finger at
the neck with the swab still in place.

77
Ampules
Opening an Ampule

Forcefully snap the neck away from you.

78
Ampules

To withdraw from an ampule, tilt the ampule,
place the needle bevel of a filter needle or tip
of a filter straw in the corner near the opening,
and withdraw the medication
Use a needle equipped with a filter for filtering
out any tiny glass particles, fibers, or paint
chips that may have fallen into the ampule

79
Ampules

Before injecting the contents of a syringe into
an IV, the needle must be changed to avoid
introducing glass or particles into the admixture
A standard needle could be used to withdraw the
drug from the ampule it is then replaced with a
filter device before the drug is pushed out of
the syringe
Filter needles are for one directional use only

80
IV Solutions

Most IV, intrathecal, intra-arterial, and
intracardiac injections will be solutions
A diluent is a sterile fluid to be added to a
powder to reconstitute or dissolve the medication
check the medication package insert to verify
which diluent and what volume should be added to
the medication vial to make a sterile solution
Alternative routes of administration may also
require special preparation, storage, and needles
it is best to check with the pharmacist if such a
medication order is received

81
IV Solutions

The vehicles most commonly used for IV infusions
are
dextrose in water
NS solution
dextrose in saline solution
The two main types of IV solutions are
small-volume parenterals (SVPs) of 50 or 100 mL
large-volume parenterals (LVPs) of more than 100
mL

82
IV Solutions

SVPs are typically used for delivering
medications at a controlled infusion rate
Large-volume parenterals (LVPs) are used
to replenish fluids
to provide electrolytes (i.e., essential
minerals)
to provide nutrients such as vitamins and glucose
LVPs are commonly available in 250 mL, 500 mL,
and 1000 mL sizes

83
Different Types of IV Containers
84
IV Solutions

A piggyback is a small-volume parenteral
admixture that is attached to an existing IV line
The piggybacked solution is infused into the
tubing of the running IV
usually over a short time, from 30 minutes to 1
hour
Some IV piggybacks are prepared in 250 mL
solution because they contain a medication that
is irritating to the veins
In some cases, syringes are used instead of
piggyback containers to deliver medication into a
running IV

85
IV Solutions

A LVP usually contains one or more electrolytes
potassium chloride is the most common additive
other salts of potassium, magnesium, or sodium
can be added
Additives to IV solutions can also be
multivitamins or trace elements

86
Preparing a Label for an IV Admixture

Labels for IV admixtures should bear the
following information
patients name and identification number
room number
fluid and amount
drug name and strength (if appropriate)
infusion period
flow rate (e.g., 100 mL/hr or infuse over 30
min)
expiration date and time
additional information as required by the
institution or by state or federal guidelines

87
Examples of Pharmacy-prepared Labels

for a minibag
for a large-volume parenteral (LVP)

88
Discussion
What principle guides the techniques and
procedures applied to IV solution preparation?
89
Discussion
What principle guides the techniques and
procedures applied to IV solution
preparation? Answer IV preparation is based on
aseptic technique and all dosage forms and
equipment must be handled in a way that prevents
contamination.
90
Terms to Remember

ampule
diluent
small-volume parenterals (SVPs)
large-volume parenterals (LVPs)
piggyback

91
Calculations for the Hospital Pharmacy Technician

In preparing sterile IV preparations in the
hospital or home healthcare setting, it is
important to
understand math skills somewhat unique to these
environments
double- and triple-check calculations and flow
rates for IV admixtures or TPN solutions

92
Calculations for the Hospital Pharmacy Technician

Important math skills are needed in the areas of
reading time
temperature and temperature conversions
electrolyte replacement therapy
specific gravity
IV infusion flow rates

93
Calculations for the Hospital Pharmacy Technician
Safety Note

Always carefully check and double check all
calculations.

94
Time Conversions

Hospital medication orders are often stamped with
international or military time
dose administration schedules for unit dose and
IV admixtures also use this method
This time is based on a 24-hour clock, with
midnight being considered time 0000
time in hours are the first two digits
time in minutes are the last two digits
no A.M. or P.M. are used

95
Time Conversions

Examples
0000 Midnight
0600 6 AM
1200 Noon
1800 6 PM

96
Temperature Conversions

The United States is one of the few countries in
the world where the Fahrenheit temperature scale
is commonly used
The Fahrenheit temperature scale uses 32 F as
the temperature when ice freezes and 212 F as
the temperature that water boils
the difference between these two extremes is 180
F

97
Temperature Conversions

The Celsius temperature scale is commonly used in
Europe and globally in science, and it is often
the scale used in the pharmacy
the Celsius temperature scale uses 0 C as the
temperature when ice freezes and 100 C as the
temperature that water boils
the difference between these two extremes is 100
C

98
Temperature Conversions

Storing drugs under the proper refrigeration and
maintaining refrigerating equipment at the
appropriate temperature are responsibilities of
the pharmacy technician
most refrigerators in the pharmacy need to
maintain a temperature of 5º C to 10º C
Temperatures in the drug package inserts or in
the policy and procedure manual are often in
centigrade
pharmacy technicians will need to know how to
convert between the Celsius scale and the
Fahrenheit scales

99
Temperature Conversions
Temperature Equivalencies

Every 5 C change in temperature is equivalent to
a 9 F change

Celsius Fahrenheit
0º C 32º F
5º C 41º F
10º C 50º F
15º C 59º F
20º C 68º F
100
Temperature Conversions

These equations allow conversions between the two
temperature scales
º F (1.8 º C) 32
º C (º F 32) 1.8
An alternative method uses this equation
5F 9C 160
The final temperature is usually rounded up to
the closest whole number

101
Electrolytes

Many IV fluids used in pharmacy practice contain
electrolytes
dissolved mineral salts
so-named because they conduct an electrical
charge through the solution when connected to
electrodes
Electrolytes are measured in millimoles (mM) and
milliequivalents (mEq)

102
Understanding Millimoles and Milliequivalents

Milliequivalents (mEq) are related to molecular
weight
Molecular weights are based on the atomic weights
of elements
the atomic weight of an element is the weight of
a single atom of that element compared with the
weight of one atom of hydrogen
the molecular weight of a compound is the sum of
the atomic weights of all the atoms in one
molecule of the compound

103
Understanding Millimoles and Milliequivalents

A millimole (mM) is an amount of a substance
weighing its molecular weight in milligrams
The valence of an element is a number that
represents its capacity to combine to form a
molecule of a stable compound
an element can exist in various forms
valence may vary depending on an elemental form

104
Valences and Atomic Weights of Common Elements
Element Valence Atomic Weight Rounded Value
hydrogen (H) 1 1.008 g 1 g
carbon (C) 2, 4 12.011 g 12 g
nitrogen (N) 3, 5 14.007 g 14 g
oxygen (O) 2 15.999 g 16 g
sodium (Na) 1 22.9898 g 23 g
sulphur (S) 2, 4, 6 32.064 g 32.1 g
chlorine (Cl) 1, 3, 5, 7 35.453 g 35.5 g
potassium (K) 1 39.102 g 39.1 g
calcium (Ca) 2 40.08 g 40.1 g

For pharmaceutical calculations, atomic weights
are usually rounded to the nearest tenth (i.e.,
one unit to the right of the decimal point).

105
Understanding Millimoles and Milliequivalents

One mole (M) of an element weighs its atomic
weight in grams
one mole of sodium (Na) is 22.9898 (rounded to 23
g)
Compounds are also measured in moles
one mole of salt or sodium chloride (NaCl) would
weigh its molecular weight in grams
atomic weight of sodium (23 g) atomic weight of
chlorine (35.5 g) 58.5 g
1 mM is an amount equal to the molecular weight
in milligrams
because 1 g equals 1000 mg, 1 mole equals 1000 mM
1 mM of sodium chloride equals 58.5 mg

106
Understanding Millimoles and Milliequivalents

One equivalent (Eq) is equal to one mole divided
by its valence
One milliequivalent (mEq) is equal to 1 millimole
divided by its valence
thus one equivalent equals 1000 mEq, or one
thousandth of a gram equivalent

Equivalent weight molecular weight (expressed
in milligrams)
valence

107
Determining Milliequivalents of Compounds

To determine the number of milliequivalents of a
compound
(1) identify the formula of the compound
(2) separate the formula into atoms
(3) determine the moleclular weight of the
compound
multiply the weight of each atom by the number of
those atoms
add the products together, the sum is the
molecular weight

mEq molecular weight (expressed in milligrams) valence
108
Measuring Electrolytes

Milliequivalents (and sometimes millimoles) are
used to measure electrolytes in the bloodstream
and/or in an IV preparation
Example
You must add 44 mEq of sodium chloride (NaCl) to
an IV bag. Sodium chloride is available as a 4
mEq/mL solution. How many milliliters will you
add to the bag?

109
Measuring Electrolytes

You must add 44 mEq of sodium chloride (NaCl) to
an IV bag. Sodium chloride is available as a 4
mEq/mL solution. How many milliliters will you
add to the bag?
set up a proportion, comparing the solution you
will need to create to the available solution,
and solve for the unknown

110
Measuring Electrolytes

Set up a proportion, comparing the solution you
will need to create to the available solution,
and solve for the unknown

x mL 44 mEq 1 mL 4 mEq
(44 mEq) x mL 44 mEq (44 mEq) 1 mL 4 mEq
x mL 44 mL 4
x mL 11 mL
111
Specific Gravity

Specific gravity can be defined as the ratio of
the weight of a substance to the weight of an
equal volume of water when both have the same
temperature
Final weight can be measured in grams because 1
mL of water weighs 1 g
1 mL, volume of water 1 g, weight of water
specific gravity of water 1

specific gravity weight of a substance weight of an equal volume of water
112
Specific Gravity

When the specific gravity is known, certain
assumptions can be made regarding the physical
properties of a liquid
liquids that are viscous or have particles
floating in them often have a specific gravity
higher than 1
solutions that contain volatile chemicals (or
something that is prone to quick evaporation),
such as alcohol, often have a specific gravity
lower than 1

113
Specific Gravity
Safety Note

Usually numbers are not written without units
however, no units exist for specific gravity.
Therefore, you must label specific gravity
carefully.

114
Calculation of IV Rate and Administration

IV flow rates are usually described as
milliliters per hour or as drops per minute
(expressed as gtt/min)
pharmacy usually uses milliliters per hour
nurses sometimes prefer drops per minute
The formula used to determine the rate in drops
per minute is as follows

x gtt/min (volume of fluid delivery time in hrs) (drop rate of administration set) 60 min/hr
115
Calculation of IV Rate and Administration

Example
A physician orders 4000 mL of a 5 dextrose and
normal saline (D5NS) IV over a 36-hour period. If
the IV set will deliver 15 gtt/mL, then how many
drops must be administered per minute?
Begin by identifying the amounts to insert into
the equation.

volume of fluid 4000 mL
delivery time 36 hr
drop rate of the administration set 15 gtt/mL
116
Calculation of IV Rate and Administration
x gtt/min (volume of fluid delivery time in hrs) (drop rate of administration set) 60 min/hr
x gtt/min (4000 mL 36 hr) (15 gtt/mL) 60 min/hr
x gtt/min 111 mL/hr) (15 gtt/mL) 60 min/hr
x gtt/min 27.75 gtt/min, rounded to 28 gtt/min
117
Calculation of IV Rate and Administration

The number of hours that the IV will last can be
determined by dividing
the volume of the IV bag (expressed in
milliliters)
by
the flow rate (expressed in milliliters per hour)

118
Calculation of IV Rate and Administration

Example
A 1 L IV is running at 125 mL/hr. How often will
a new bag have to be administered?
Begin by converting 1 L to 1000 mL, and then
divide the volume by the volume per hour rate.

hours the IV will last 1000 mL 125ml/hr 8 hr
119
Discussion
What are some of the special areas of
calculations skills that are important for
technicians preparing IV solutions?
120
Discussion
What are some of the special areas of
calculations skills that are important for
technicians preparing IV solutions? Answer
Skills for accurate conversion between time and
temperature systems, electrolyte measurement,
specific gravity determinations, and infusion
flow rate calculations are vital in IV
preparation and labeling.
121
Terms to Remember