Stability of zidovudine in 5% dextrose injection and 0.9% sodium chloride injection

The stability of zidovudine at a concentration of 4 mg/mL in 5% dextrose injection and 0.9% sodium chloride injection in polyvinyl chloride infusion bags stored at room and refrigerated temperatures for up to eight days was studied. Zidovudine was diluted in 5% dextrose injection and in 0.9% sodium chloride injection to a concentration of 4 mg/mL. Six admixtures were prepared with each diluent; three were stored at room temperature (25 +/- 1 degree C) and three were refrigerated (4 +/- 1 degree C). At 0, 3, 6, 24, 48, 72, and 192 hours, 2-mL aliquots were removed. One milliliter of each aliquot was diluted to a zidovudine concentration of approximately 40 micrograms/mL and assayed in duplicate by a stability-indicating high-performance liquid chromatographic method. Visual inspection was performed at each sampling time for precipitation, turbidity, color change, and gas formation. Sample pH was recorded at 0 and 192 hours. In all admixtures, more than 97% of the initial zidovudine concentration remained throughout the study period. No visual or pH changes were observed. Zidovudine 4 mg/mL in admixtures with 5% dextrose injection or 0.9% sodium chloride injection stored in polyvinyl chloride infusion bags was stable for up to 192 hours (eight days) at room temperature and under refrigeration.     

Stability of procainamide hydrochloride in neutralized 5% dextrose injection

The stability of procainamide hydrochloride in neutralized 5% dextrose injection was studied. Sixty-four admixtures were prepared by adding either 2 mL (for 0.4% admixtures) or 4 mL (for 0.8% admixtures) of procainamide hydrochloride to 250 mL of 5% dextrose injection in plastic containers. The pH of 32 of these admixtures (16 of each type) was adjusted to 7.5. These 32 admixtures represented the neutralized group, and the remaining 32 represented the control group. The admixtures were stored at either 23-25 degrees C (room temperature) or 5 degrees C (refrigeration) for 24 hours. Procainamide hydrochloride concentrations in each sample were determined by high-performance liquid chromatography immediately after the admixtures were prepared and at various intervals during storage. Procainamide concentrations decreased over time in 5% dextrose injection. The decrease was significantly less for admixtures in neutralized 5% dextrose injection, those stored under refrigeration, and those with an 0.8% concentration of drug. Decreases in procainamide hydrochloride concentrations in the control admixtures might have been caused by procainamide-dextrose complexation. Initial concentrations of procainamide hydrochloride in 5% dextrose injection can be adequately maintained over a 24-hour storage period by neutralizing the 5% dextrose injection or storing the admixture at 5 degrees C. However, because it is impractical to maintain the necessary temperature condition during a 24-hour infusion, neutralization might be the most viable alternative when extended stability of procainamide hydrochloride in 5% dextrose injection is required.     

Stability and availability of cyclosporine in 5% dextrose injection or 0.9% sodium chloride injection

The stability of cyclosporine in commonly used i.v. solutions and the percentage of the drug delivered via polyvinyl chloride administration tubing were studied. Cyclosporine injection was prepared according to the manufacturer's instructions and diluted with 5% dextrose injection (D5W) or with 0.9% sodium chloride injection (NS). Admixtures containing cyclosporine 2 mg/mL were prepared in polyvinyl chloride minibags (five for each solution) and in glass containers (three for each solution). The sample obtained at time zero from a glass container protected from light was the control. Additional samples were prepared in minibags and run through 70-inch polyvinyl chloride administration sets. An HPLC assay for cyclosporine was used. Exposure to room light did not significantly affect cyclosporine concentrations. More than 90% of the initial drug concentration remained after 24 hours under all storage conditions, but less than 95% remained after 6 hours in samples diluted with NS and stored in plastic. At times up to 60 minutes, cyclosporine concentrations were significantly different in solutions infused from the minibags through polyvinyl chloride tubing from those in control solutions. Under these conditions, cyclosporine is stable in D5W in glass containers or polyvinyl chloride minibags for 24 hours and in NS for 6 hours (polyvinyl chloride) to 12 hours (glass). However, because of the potential for leaching of plasticizers, cyclosporine admixtures should be stored in glass or used within six hours if stored in polyvinyl chloride minibags. Approximately 10% of the initial drug concentration is lost to 70-inch length polyvinyl chloride infusion tubing.     

Stability of levodopa in 5% dextrose injection at pH 5 or 6

The stability of solutions of levodopa 1 mg/mL in 5% dextrose injection adjusted to pH 5 or 6 and stored at one of three temperatures was determined. Solutions were adjusted to pH 5 or 6 with sodium acetate injection or sodium phosphate injection, respectively. Three samples of solution adjusted to pH 5 were stored at each of three temperatures (4, 25, and 45 degrees C), and three samples of solution adjusted to pH 6 were stored at 25 degrees C. Samples were assayed for levodopa concentration by high-performance liquid chromatography at various times during the 21-day study period. All solutions maintained at least 90% of the initial concentration of levodopa for seven days. Discoloration of all solutions except those stored at 4 degrees C was noted at some point during the study period; solutions stored at 45 degrees C began to darken within 12 hours. The pH values of the solutions did not change during the study period. Under the conditions studied, solutions of levodopa 1 mg/mL in 5% dextrose injection adjusted to pH 5 or 6 are stable for seven days. Slight degradation of levodopa may cause a brownish-black discoloration of the admixtures.     

Stability of ganciclovir sodium in 5% dextrose injection and in 0.9% sodium chloride injection over 35 days.

The stability of ganciclovir 1 and 5 mg/mL in 5% dextrose injection and in 0.9% sodium chloride injection was studied at 25 degrees C and 5 degrees C over 35 days. Ganciclovir (as the sodium salt) was added to 120 polyvinyl chloride bags containing either 5% dextrose injection or 0.9% sodium chloride injection to attain ganciclovir concentrations of 1 and 5 mg/mL. Thirty bags were prepared for each combination of drug concentration and i.v. solution. Half of the bags in each group were stored at 25 degrees C; the other half were stored at 5 degrees C. Samples withdrawn from all 120 bags immediately after preparation were frozen for later determination of initial concentration. At 7, 14, 21, 28, and 35 days after preparation, approximately 5-mL samples representing each test condition were withdrawn for analysis. The samples were visually examined, tested for pH, and assayed by high-performance liquid chromatography. There was no significant loss of ganciclovir under any of the study conditions over 35 days. All solutions were clear throughout the study period. The pH decreased slightly in both diluents at both ganciclovir concentrations but did not deviate from the manufacturer's range (9-11). Admixtures containing ganciclovir 1 and 5 mg/mL (as the sodium salt) in 5% dextrose injection and 0.9% sodium chloride injection were stable in polyvinyl chloride bags stored at 25 degrees C and 5 degrees C for 35 days.     

Stability and compatibility of ganciclovir sodium in 5% dextrose injection over 35 days.

The stability and compatibility of ganciclovir sodium in 5% dextrose injection over 35 days were assessed. Nine admixtures of ganciclovir sodium 1, 5, and 10 mg/mL in 5% dextrose injection were aseptically prepared. Immediately thereafter, six samples were aseptically withdrawn from each admixture into sterile collection tubes. Three of the samples were frozen for stability-indicating high-performance liquid chromatographic (HPLC) assay at a later date, and the other three were immediately assessed for pH. Each admixture was also assessed visually for color change, turbidity, gas evolution, and precipitation. The admixtures were stored in the dark at 4-8 degrees C and sampled at 10 and 35 days. There was no significant loss of ganciclovir over the 35-day study period. No admixture at any time contained less than 93.4% or more than 103.7% of its initial ganciclovir concentration. There were no appreciable pH changes, and there was no evidence of visual incompatibility. Ganciclovir sodium 1, 5, and 10 mg/mL in 5% dextrose injection was stable for at least 35 days when stored in the dark at 4-8 degrees C.     

Long-term stability of sodium folinate in dextrose 5% polyolefin bags at 4degreesC.

OBJECTIVES: Preparation of intravenous solutions in advance could be an efficient approach to improve quality assurance, security, time management, and cost saving of drug provision. The purpose of this paper is to investigate the stability of sodium folinate solutions at 3.2 mg mL-1 in 5% dextrose polyolefin bags at 4degreesC. METHODS: The stability of five polyolefin bags of solution containing approximately 3.2 mg mL-1 of sodium folinate in 5% dextrose prepared under aseptic conditions and stored at 48degreesC have been studied over 30 days. Sodium folinate concentrations have been measured by high performance liquid chromatography and the results have been analysed by regression analysis. Solutions have been visually inspected and pH measured. RESULTS: No colour change or precipitation occurred in the preparations. Based on a shelf-life of 90% residual potency, sodium folinate solutions have been observed to be stable for a period of at least 30 days at 4degreesC, where lower confidence limits of the results value remain above 90% of the initial concentration. During this stability period, the pH values of infusions have been observed to decrease slightly without affecting chromatographic parameters. CONCLUSION: Within these limits, sodium folinate in 5% dextrose infusion may be prepared and stored in advance by a centralized intravenous admixture service.     

Stability and compatibility of cimetidine hydrochloride and aminophylline in dextrose 5% in water injection

A controlled study was conducted to assess the physical compatibility of cimetidine hydrochloride (HCl) and aminophylline and the chemical stability of an admixture of the two medications in dextrose 5% in water (D5W) injection, over 48 hours at room temperature. Three one-liter admixtures were prepared, each containing cimetidine HCl 1200 mg and aminophylline 500 mg in D5W. One liter of only cimetidine HCl 1200 mg in D5W and one liter of only aminophylline 500 mg in D5W served as controls. Samples drawn from the five admixtures and immediately frozen were analyzed for cimetidine and theophylline content at times 0, 1, 6, 24, and 48 hours using high-performance liquid chromatography. Chemical stability of each drug was assessed relative to its time-zero concentration. Samples were also drawn from each test and control solution at every time interval to assess the pH. Admixtures were stored at room temperature out of direct sunlight for the duration of the study, and were visually inspected for color change, turbidity, cloudiness, and precipitation. Recovery of cimetidine and theophylline at all test intervals, pH assessments, and visual inspections of the admixtures showed that cimetidine HCl and aminophylline are both chemically stable and physically compatible for 48 hours at room temperature in one liter of D5W.     

Stability of ondansetron and fluconazole in 5% dextrose injection and normal saline during Y-site administration

The stability of ondansetron and fluconazole in 5% dextrose injection and normal saline during simulated Y-site injection at room temperature was studied. Ondansetron 0.03, 0.1 and 0.3 mg/ml were admixed 1ratio1 with fluconazole 2 mg/ml. The solutions were stored at room temperature and samples were retrieved at time 0, 1, 2, 4 and 12 hr for immediate assay. At the time of the assay and before any dilution, each sample was visually inspected for clarity, color, precipitation, and the pH was determined. Drug concentrations were measured by a stability-indicating high performance liquid chromatograph. Ondansetron 0.03, 0.1 and 0.3 mg/ml were stable when mixed with concentration of fluconazole 2 mg/ml. There were no change in clarity and color and no precipitates in any admixture for 12 hr of inspection. The pH measurements did not have a particular trend in any direction over time.     

Compatibility of cefoperazone sodium and furosemide in 5% dextrose injection

The compatibility of cefoperazone sodium and furosemide in 5% dextrose injection stored at two temperatures was studied. Cefoperazone sodium and furosemide were added to 5% dextrose injection to achieve a cefoperazone concentration of 10 mg/mL and a furosemide concentration of 0.2 mg/mL. The admixture was stored in 100-mL vented i.v. containers in the dark under refrigeration (4 degrees C) and at room temperature (25 degrees C); three containers were stored at each temperature. A 1-mL sample was taken from each i.v. container immediately after preparation and after 1, 2, 5, 10, 15, 20, and 25 days to be inspected visually, checked for pH value, and analyzed by a stability-indicating high-performance liquid chromatographic method. No color change or precipitation was observed in any sample at any time during the study. More than 95% of the initial concentrations of both drugs remained for five days at 4 degrees C but for only two days at 25 degrees C. Cefoperazone sodium was somewhat more stable than furosemide under the same storage conditions for 25 days; however, less than a 2% difference between the drugs was noted. Under the conditions of this study, cefoperazone sodium 10 mg/mL and furosemide 0.2 mg/mL in admixtures in 5% dextrose injection are stable for only two days at 25 degrees C and five days at 4 degrees C.