Question

Calculate the dosages as indicated. Use the labels where provided. Order: Levophed \(4 \mathrm{mcg} / \mathrm{min}\) to maintain BP systolic greater than \(100 \mathrm{~mm} \mathrm{Hg}\). to a maximum of \(12 \mathrm{mcg} / \mathrm{min}\). Available solution: Levophed \(4 \mathrm{mg}\) in \(500 \mathrm{~mL}\) D5W. Develop a titration table in \(2 \mathrm{mcg} / \mathrm{min}\) increments.

Short answer

Use flow rates from 0.5 to 1.5 mL/min in 0.25 mL/min increments.

Step-by-step solution

Understand the Dosage Required

The order is for Levophed to be administered at a rate starting from 4 mcg/min, with a maximum of 12 mcg/min. You need to provide a titration table for this dosed in 2 mcg/min increments from 4 to 12 mcg/min.

Calculate the Concentration of the Solution

Levophed is provided at a concentration of 4 mg in 500 mL of D5W. First, convert milligrams to micrograms: \[4 \text{ mg} = 4000 \text{ mcg} \]This means the solution contains 4000 mcg of Levophed in 500 mL, giving a concentration of: \[ \text{Concentration} = \frac{4000 \text{ mcg}}{500 \text{ mL}} = 8 \text{ mcg/mL}\].

Determine Flow Rates for 2 mcg/min Increments

Start by calculating the flow rate in mL/min required for each increment of 2 mcg/min. Use the concentration from Step 2: - For 4 mcg/min: \[ \frac{4 \text{ mcg/min}}{8 \text{ mcg/mL}} = 0.5 \text{ mL/min} \] - For 6 mcg/min: \[ \frac{6 \text{ mcg/min}}{8 \text{ mcg/mL}} = 0.75 \text{ mL/min} \] - For 8 mcg/min: \[ \frac{8 \text{ mcg/min}}{8 \text{ mcg/mL}} = 1 \text{ mL/min} \] - For 10 mcg/min: \[ \frac{10 \text{ mcg/min}}{8 \text{ mcg/mL}} = 1.25 \text{ mL/min} \] - For 12 mcg/min: \[ \frac{12 \text{ mcg/min}}{8 \text{ mcg/mL}} = 1.5 \text{ mL/min} \]

Arrange the Titration Table

Compile the calculated flow rates into a titration table: - 4 mcg/min: 0.5 mL/min - 6 mcg/min: 0.75 mL/min - 8 mcg/min: 1 mL/min - 10 mcg/min: 1.25 mL/min - 12 mcg/min: 1.5 mL/min

Key concepts

Titration Table

When dealing with medications like Levophed, ensuring exact dosages is vital. A titration table is a helpful tool for this. It allows you to easily adjust the medicine's dosage based on the patient's needs, usually given in specific increments.
For Levophed, the increment specified is 2 micrograms per minute. Starting at 4 micrograms per minute and moving to a maximum of 12 micrograms per minute in these steps ensures you don't exceed the safe limits. A titration table simply lists each dosage increment and the corresponding flow rate needed to deliver that dosage.
It's an efficient way to monitor and adjust the infusion rate, ensuring you maintain the proper medicinal dosage quickly and accurately.

Unit Conversion

Before accurately administering medication, you often need to convert units. Frequently, as in this example, the medication's retail unit (milligrams) isn't the same as the administration unit (micrograms). Levophed is supplied in 4 milligrams, and for titration purposes, we need this in micrograms.
Remember, 1 milligram is equal to 1000 micrograms. Thus, converting 4 milligrams results in 4000 micrograms. This is crucial because it determines the concentration availability in the given solution.
Such conversions are integral to ensuring safe and precise drug dosing, preventing potential errors in medication administration.

Flow Rate Calculation

Flow rate calculation helps determine the speed at which a medication is delivered to a patient via an intravenous line. This becomes critical, especially when drugs need precise dosages like Levophed. Using the concentration (8 micrograms per milliliter), you can calculate the necessary flow rates.
For each 2 micrograms per minute increment, divide the micrograms by the concentration (8 mcg/mL) to get the flow rate in mL/min.

• For 4 mcg/min: 0.5 mL/min
• For 6 mcg/min: 0.75 mL/min
• For 8 mcg/min: 1 mL/min
• For 10 mcg/min: 1.25 mL/min
• For 12 mcg/min: 1.5 mL/min

Understanding these calculations is fundamental to maintaining accurate and safe administration rates.