Introduction

The definition of intravenous is to administer a medication and/or fluid directly into a vein. All medications administered intravenously must be in liquid form and must be sterile. IV fluids may be given in large volumes for continuous infusion in such basic fluids in 1000 mL amounts as sterile water or normal saline with dextrose added to meet caloric needs. Medications, such as electrolytes or antibiotics, may also be added to these containers to supply drugs or nutritional needs over a period of time. The physician’s order will include the type and total fluid volume to be administered over a total period of time. In other cases, medications may be added to small volumes of fluids for administration on an intermittent basis either through an injection port in the tubing or a secondary line called IV piggyback (IVPB).

Intravenous medication prescriptions (intermittent, IVPB) specify the drug (solute), the dose to be given, and frequency of dosing but do not commonly state infusion rate or infusion time. The pharmacy determines the solvent, solvent volume, and time to be infused while the physician’s order provides the solute to be added. This information from both the physician’s order and the determinations made by the pharmacy is the information to be included on the label added to the parenteral fluid container for the specific person.

Fluids may be given as replacements for electrolytes or lost fluids such as with patients who have dehydration. Maintenance therapy provides the nutrients necessary to meet the daily needs for water, electrolytes, and glucose. With a deficit of fluids and electrolytes over a period of time, usually 48 hours, replacement therapy may be necessary to meet the fluid and electrolyte needs of the person. Finally, restorative therapy is a day-by-day restoration of vital fluids and electrolytes. With this therapy, the types of fluids being lost are those that are replaced. Often, several different types of fluids will be ordered for the patient on the same day.

Fluids may also be ordered as a means for transporting medications needing rapid absorption in the body. With the addition of drugs, the infusion is used as prophylaxis or therapeutically for disease processes.

Intravenous solutions are available in 50-mL to 1000-mL containers (commonly in flexible plastic bags) with each containing solutes and solvents prescribed for the patient’s specific needs. The reason for therapy dictates the type of fluid and rate of infusion ordered. Fluids given to keep a vein open are given slowly, whereas replacement fluids are usually given at a rate that will provide the necessary fluids while preventing an overload on the vascular system. The rate of flow depends on the patient’s physical condition. Most IV fluids are found in percentages of solutes (solids) in the total volume of solvent (solution) such as D-5-W, which is 5% dextrose in water. As learned in Chapter 11, this means that 5 g of dextrose are dissolved in every 100 mL of sterile water, or 50 g of dextrose are found in 1000 mL of water. While most IV fluids are infused by pump today, it is still important to be conscious of selecting the correct fluids for the IV infusion and ensuring an infusion is administered at the prescribed rate.

This chapter will focus on how to determine flow rates in drops per minute and determining the infusion time. You may need to determine the total time necessary for an amount of fluid to be administered as ordered, or you may need to calculate the flow rate when a total time of administration has been specified in the physician’s order.

Persons allowed to prepare and administer IV fluids are regulated by state law and the regulations of the facility where the fluids are to be administered. In some states, technicians may prepare the IV fluids for infusion, whereas in others this preparation must be done by the pharmacist. As a pharmacy technician, you must always be cognizant of the laws of your state of practice and regulations of the place of employment.

Pharmacy technicians who work in retail pharmacy may find that they do not use this chapter often, because IV infusion preparation is rarely performed in a community pharmacy. On the other hand, IV fluids are often used in the hospital setting. Understanding the calculations related to IV infusions is important for the hospital pharmacy technician but is also necessary for the retail pharmacy technician, who might one day practice in the hospital setting.

Interpreting Amounts of Solutes in Intravenous Fluids

To provide patients with continuous medications or for fluid replacement over a period of time, IV fluids are often administered to them rather than requiring them to undergo repeated injections by other parenteral routes. The medications found in fluids may be standard medications found in prepared IV fluids, such as dextrose or sodium chloride, or they may be added in the pharmacy to fill the physician’s orders, such as antibiotics or electrolyte replacements. In some instances medications may be prepared by manufacturers as commonly seen with premixed IV piggyback solutions containing antibiotics found in routinely used volumes such as 50-mL containers. The health care professional must have the ability to read the physician’s order and select the correct fluids and additives for the patient’s needs. Remember that once the fluids have been injected into the vein, the medications cannot be retrieved because the medication circulates throughout the body instantaneously. Therefore it is imperative for patient safety that the correct fluids with the correct additives (medications) are used at a safe flow rate depending on the patient’s physical condition and the medication being administered. Calculations for IV medications are performed using either ratio and proportion, formula (Dose desired/Dose on hand × Quantity = Dose to be given), or dimensional analysis, depending on method of choice.

In most cases the physician will use common abbreviations for ordering IV fluids. These are shown in Table 12-1. Notice fluids are labeled with a percentage of solute in the container of fluids or the amount of solute found in the solvent. D-5-W indicates that 5% dextrose is available in the solvent (sterile water). Remember that percentage is based on 100. So if the percentage is shown in 100 mL of solution, the 5% indicates that 5 g of dextrose is found in 100 mL of fluid. However, if the 5% is shown in 500 mL of a solvent such as water, then the total weight of the solute must be calculated. The easiest method for calculating the weight of solute is ratio and proportion (Known solute : Known volume :: Desired-to-know solute : Desired-to-know volume). To review percentage and ratio and proportion, see Chapter 2.

TABLE 12.1

Abbreviations for Common Intravenous Solutions

ABBREVIATION	SOLUTION
NS	Normal saline; 0.9% sodium chloride
	Half-normal saline; 0.45% sodium chloride; or strength normal saline
D-5-W or 5% D/W	Dextrose 5% in water
D-5-LR	Dextrose 5% in lactated Ringer’s
RL or LR	Ringer’s lactate solution or lactated Ringer’s
D-5-NS	Dextrose 5% in 0.9% sodium chloride; dextrose 5% in normal saline
D-5-	Dextrose 5% in normal saline or 0.45% sodium chloride
D-2.5-t	2.5% dextrose in 0.45% sodium chloride
D-2-W	dextrose in water

Example 12-1

A physician orders 500 mL 5% D/W to be given to a patient. What is the metric weight (in grams) of the dextrose in this bag of fluids? Remember, 5% means that 5 g (solute) of dextrose is found in 100 mL of water (solvent).

5 g:100::x:500

100x=5 g×500or2500

x=25 g of DEXTROSE in 500 mL of the above fluids

In some cases it is necessary to calculate the amount of medication a patient has received when the entire amount of ordered fluids is not infused.

Example 12-2

A 1000-mL container of D-5-W contains 80 mEq KCl. The patient has received 650 mL of the fluids when it is discontinued. How many mEq KCl has the patient received?

KnownUnknown80 mEq:1000 mL::x:650 mL

1000x=650×80 mEqor52,000 mEq

x=52 mEq of KCl were received by the patient

Practice Problems A

Calculate the solute volume found in the IV fluids. Use the method of choice for the calculations. Round answers to the nearest tenth. In some cases, the answer must be shown in hundredths; these will be noted with an asterisk. Supply answers in metric weight such as grams, unless otherwise noted. Show all of your work.

 1. What is the weight of SODIUM CHLORIDE in these fluids? ____________________

What is the weight of DEXTROSE in these fluids? ____________________

 2. What is the weight of DEXTROSE in these fluids? ____________________

 3.  A 50-mL IVPB contains PENICILLIN 1.5 million units. The patient has received 35 mL of the medication.

How many units of PENICILLIN has the patient received? ____________________

 4. What is the weight in grams of SODIUM CHLORIDE in the fluids shown in the following illustration? ____________________

What is the weight in grams of DEXTROSE in the fluids shown in the following illustration? ____________________

 5. *What is the weight of SODIUM CHLORIDE in grams found in the fluids shown below? ____________________

 6.  A physician orders PENICILLIN G POTASSIUM 2.4 million units to be added to 1 L NS. You have on hand a vial of this medication that has been reconstituted to 1,000,000 units/mL.

How many milliliters of medication should be added to the fluids? ____________________

If only 750 mL of fluids are administered, how many units of PENICILLIN G POTASSIUM has the patient received? ____________________

 7.  One liter of D-5-NS contains the POTASSIUM CHLORIDE as shown on the following label using the entire vial. The vein infiltrates after 900 mL have been infused.

How many milliequivalents of KCl were added to the fluids? ____________________

How many milliliters of KCl were added to the fluids? ____________________

How many grams of DEXTROSE did the patient receive before infiltration? ____________________

How many grams of SODIUM CHLORIDE did the patient receive before infiltration? ____________________

How many milliequivalents of KCl did the patient receive before the infusion was discontinued? ____________________

 8. A physician orders FUROSEMIDE 100 mg in 200-mL NS. The patient receives 150 mL of the medication. Available medication is FUROSEMIDE 10 mg/mL.

*What total amount of SODIUM CHLORIDE did the patient receive? ____________________

What amount of FUROSEMIDE did the patient receive? ____________________

 9.  A physician orders FENTANYL CITRATE 50 mcg to be added to D-5-W 500 mL. The medication is available as 10 mcg/mL.

How many milliliters of FENTANYL should be added to the fluids? ____________________

If the patient receives 400 mL of the fluids, how many grams of dextrose has the patient received? ____________________

*How many milligrams of FENTANYL has the patient received? (Do not round this answer.) ____________________

10. A physician orders 1 L of DEXTROSE 3% to be administered over 6 hours.

If the complete bag of fluids is administered, how many grams of DEXTROSE would the patient receive? ____________________

If the fluids run for 5 hours only and the patient is discharged, how many grams of DEXTROSE would the patient receive? ____________________

11.  A physician desires that a patient receive LIDOCAINE 150 mg in D-5-W 200 mL IVPB. The available medication is 1% LIDOCAINE for injection.

*How many milligrams of LIDOCAINE are in each milliliter of fluids? ____________________

If the patient receives 65 mL of the IV fluids, how many milligrams of LIDOCAINE would the patient receive? ____________________

12.  A physician orders AMPICILLIN 2000 mcg/kg IV stat for a patient who weighs 165 lb. The medication is to be added to 50 mL of D-5-W to infuse for 20 minutes. The AMPICILLIN is reconstituted to 250 mg/5 mL.

What total strength in milligrams of AMPICILLIN should be added to the fluids? ____________________

How many milliliters of AMPICILLIN should be added to the D-5-W? ____________________

If the IV fluids are stopped at 15 minutes, how many milligrams of AMPICILLIN did the patient receive? ____________________

13.  A physician orders METHYLPREDNISOLONE 125 mg IV in D-5-W 100 mL to run for an hour for a patient with asthma. The medication comes in a vial containing 250 mg/5 mL.

How many milliliters of METHYLPREDNISOLONE would be added to the fluids to complete the order? ____________________

If the patient receives the medication for 50 minutes, how many milligrams of METHYLPREDNISOLONE would the patient receive? ____________________

14.  A 50 mL container of D-10-NS contains PENICILLIN 1.5 million units. These fluids are to be infused over 30 minutes.

How many grams of DEXTROSE are contained in the fluids? ____________________

If the patient receives the medication for 25 minutes, how many units of PENICILLIN did the patient receive? ____________________

15.  A physician orders AMINOPHYLLINE as a loading dose of 5 mg/kg to be administered IVPB over 1 hour for a patient who weighs 154 lb. The available medication is AMINOPHYLLINE 250 mg/10 mL.

How many milligrams of medication should the patient receive? ____________________

How many milligrams of medication should the patient receive each hour if the order is changed and the dose is to be infused over 2 hours? ____________________

The medication is to be administered at the prescribed mg/kg dose for 2 hours when added to 200 mL of IV fluids for infusion. If the infusion stops after hours, how many milligrams of medication would the patient receive? ____________________

16.  A physician orders OXYTOCIN 2 units added to 1 L of D-5-W. The available medication is OXYTOCIN 10 units/mL.

How many units would be in 100 mL of solution? ____________________

If the patient receives 750 mL of the IV fluids, how much OXYTOCIN does the patient receive? ____________________

17. A physician orders MAGNESIUM SULFATE 10 g to be added to LACTATED RINGER’S solution 1 L. The available medication is 50% MAGNESIUM SULFATE.

What is the concentration of MAGNESIUM SULFATE in mg/mL? ____________________

If this is to infuse over 5 hours, how many milligrams of MAGNESIUM SULFATE would the patient receive each hour? ____________________

18. A physician orders 1 L of D-10- to infuse over 10 hours.

How many grams of DEXTROSE would the patient receive per hour? ____________________

*How many grams of SODIUM CHLORIDE would the patient receive per hour? ____________________

< div class='tao-gold-member'>

Only gold members can continue reading. Log In or Register to continue

Share this:

• Click to share on Twitter (Opens in new window)
• Click to share on Facebook (Opens in new window)

Like this:

Like Loading...

Related

Related posts:

1. Assessment of Mathematical Calculation Skills Needed for Pharmacy Technicians
2. Interpretation of Medication Labels and Orders
3. Calculation of Mixtures from Stock Medications
4. Review of Basic Mathematical Skills

Stay updated, free articles. Join our Telegram channel

Join