Stability, compatibility, and plasticizer extraction of taxol (NSC-125973) injection diluted in infusion solutions and stored in various containers.

The stability of taxol (NSC-125973) in various diluents and containers was determined, and the extent of leaching of di(2-ethylhexyl) phthalate (DEHP) from polyvinyl chloride (PVC) bags caused by the taxol formulation was measured. A taxol formulation consisting of a 6-mg/mL solution of taxol in 50% polyoxyethylated castor oil and 50% dehydrated ethanol was added to 50- and 100-mL glass bottles, PVC infusion bags, and polyolefin containers containing 5% dextrose injection or 0.9% sodium chloride injection to give initial nominal taxol concentrations of 0.3, 0.6, 0.9, and 1.2 mg/mL. The containers were maintained at 20-23 degrees C for 12-24 hours. Samples were assayed by stability-indicating high-performance liquid chromatography, and clarity was determined visually. An experiment was run to ascertain whether DEHP would leach from a PVC administration set during a simulated infusion. There was no substantial loss of taxol over 24 hours. Filtration through a membrane resulted in no loss of taxol. All the solutions initially appeared hazy. Solutions stored in PVC bags became more hazy with time than solutions stored in glass or polyolefin containers. The haze seen in PVC bags was traced to leaching of DEHP. Agitation had no effect on the extent of leaching. Leaching was also seen during simulated delivery through PVC administration sets. No DEHP was detected when solutions were stored in glass or polyolefin containers and infused through polyethylene-lined sets. At the dilutions studied, taxol was visually and chemically stable for up to 24 hours.(ABSTRACT TRUNCATED AT 250 WORDS)     

Stability of nizatidine in commonly used intravenous fluids and containers

The stability of nizatidine in commonly used i.v. fluids stored in glass and plastic containers was studied. Stock solutions of nizatidine 0.75, 1.5, and 3.0 mg/mL in 15 i.v. fluids were prepared using nizatidine injection 25 mg/mL. Six 50-mL aliquots of each solution were transferred to separate glass infusion bottles and stored at room temperature or under refrigeration. Twenty-one 40-mL aliquots of additional stock solutions of nizatidine 0.75 and 3.0 mg/mL in 0.9% sodium chloride injection or 5% dextrose injection were transferred to polyvinyl chloride (PVC) bags and stored at room or refrigerated temperature; some of these solutions were frozen, thawed, and refrigerated before analysis. Samples of each admixture were analyzed after 0.5, 1, 2, 3, and 7 days of storage for nizatidine concentration using a stability-indicating high-performance liquid chromatographic assay and also for visible changes and pH. The concentration of nizatidine in each admixture remained within 92%-106% of actual initial storage concentration throughout the study period, with the exception of nizatidine 3.0 mg/mL in 8.5% amino acid injection. The stability of nizatidine in admixtures stored in polyvinyl chloride bags was similar to that of admixtures stored in glass bottles. In the i.v. fluids, concentrations, and containers studied, nizatidine admixtures are stable for at least 7 days at either room or refrigerated temperature and 30 days when stored frozen in polyvinyl chloride bags. Admixtures of nizatidine 3.0 mg/mL in 8.5% amino acid injection should not be stored at room temperature for longer than four days.     

Stability of morphine sulfate in Cormed III (Kalex) intravenous bags

The stability of various concentrations of morphine sulfate solution stored in Cormed III (Kalex) i.v. bags at two temperatures was investigated. Solutions of morphine sulfate 0.5, 15, 30, and 60 mg/mL were prepared under a horizontal-laminar-airflow hood with 0.9% sodium chloride solution and placed into 100-mL Kalex bags. Two bags were prepared for each concentration; one was stored at 5 degrees C and the other at 37 degrees C. Samples were analyzed in triplicate by high-performance liquid chromatography on days 0, 2, 5, 9, and 14. All morphine sulfate solutions were stable for 14 days at 37 degrees C, and the 0.5-, 15-, and 30-mg/mL solutions were stable for 14 days at 5 degrees C. However, the 60-mg/mL solution stored at 5 degrees C was found to contain 57% of the actual initial concentration on day 9 and 51% on day 14; the decrease coincided with the appearance of a white precipitate. Beginning on day 5, all the solutions displayed a light brown color that darkened as the study proceeded. This qualitative change was not associated with any change in morphine concentration. Solutions of morphine sulfate 0.5 to 60 mg/mL stored at 5 or 37 degrees C were stable for 14 days in Kalex bags, except for 60-mg/mL solutions stored at 5 degrees C for nine days or longer.     

Stability and compatibility of reconstituted ertapenem with commonly used i.v. infusion and coinfusion solutions.

PURPOSE: The stability of ertapenem sodium in various commonly used i.v. infusion solutions and its compatibility with coinfusion solutions was studied. METHODS: Ertapenem was reconstituted with sterile water for injection and then diluted with various commercial i.v. infusion solutions to concentrations of 10 and 20 mg/mL. The solutions were stored in flexible polyvinyl chloride containers at 4 and 25 degrees C and in sterile glass vials at -20 degrees C. The drug's stability at 4 degrees C was monitored daily for up to 10 days, at 25 degrees C at appropriate hourly intervals for up to 30 hours, and at -20 degrees C. The daily for up to 14 days. Compatibility with the coinfusion solutions was monitored for up to eight hours at room temperature. Stability assays were conducted until the ertapenem concentration decreased by 10% or the corresponding degradation products exceeded the approved specifications. Ertapenem concentrations were determined by a stability-indicating high-performance liquid chromatography assay. RESULTS: Ertapenem was more stable in solutions stored at 4 degrees C versus 25 degrees C. Samples frozen at -20 degrees C showed extreme variability. Ertapenem 10 mg/mL was stable for a longer time than at the 20-mg/mL concentration. Ertapenem demonstrated the greatest stability in 0.9% and 0.225% sodium chloride solutions. CONCLUSION: Ertapenem sodium injection 10 and 20 mg/mL are relatively stable in sodium chloride injections and Ringer's solution when stored at 25 and 4 degrees C, but are unstable in mannitol and dextrose solutions. The drug can be coinfused with hetastarch, heparin sodium, and potassium chloride over several hours.     

Stability of Reconstituted Telavancin Drug Product in Frozen Intravenous Bags

Background and Objective:

Intravenous (IV) infusions of telavancin for injection are generally administered in-hospital, but in some circumstances they may be administered in an outpatient environment. In that setting, antibiotics may be premixed and frozen. This study determined the chemical stability of nonpreserved telavancin in various commonly used reconstitution diluents stored in IV bags (polyvinyl chloride [PVC] and PVC-free) at -20°C (-4°F) without light.

Methods:

Telavancin (750 mg/vial) was reconstituted with 5% dextrose injection USP (D5W) or 0.9% sodium chloride injection USP (NS) to obtain drug solutions at approximately 15 mg/mL. Infusion solutions of telavancin at diluted concentrations of 0.6 mg/mL and 8.0 mg/mL covering the range utilized in clinical practice were prepared in both PVC and PVC-free IV bags using D5W or NS solutions. The infusion solutions were stored under frozen conditions (-20°C ± 5°C [-4°F ± 41°F]) and the chemical stability was evaluated for up to 32 days. Telavancin concentration, purity, and degradant levels were determined using a stability-indicating high-performance liquid chromatography (HPLC) method.

Results:

Telavancin IV infusion solutions in D5W or NS at 0.6 mg/mL and 8 mg/mL and stored at -20°C (-4°F) met the chemical stability criteria when tested on days 0, 7, 14, and 32. The assayed telavancin concentration at each time point was within 97% to 103% of the initial mean assay value. The total degradants quantified by the HPLC stability-indicating method did not show any significant change over the 32-day study period.

Conclusion:

Telavancin IV infusion solutions (in D5W or NS) in both PVC and PVC-free IV bags were stable for at least 32 days when stored at -20°C (-4°F) without light. These results provide prolonged frozen stability data further to that previously established for 7 days under refrigerated conditions (2°C-8°C [36°F -46°F]), and for 12 hours at room temperature when diluted into IV bags containing D5W, NS, or lactated Ringer’s solution.     

Stability, compatibility and plasticizer extraction of quinine injection added to infusion solutions and stored in polyvinyl chloride (PVC) containers

The stability of quinine was determined in various diluents and in polyvinyl chloride (PVC) containers. The release of diethyhexyl phthalate (DEHP) from PVC bags into intravenous infusions of quinine was also measured. We used an injection of two doses of quinine; quiniforme at 500 mg and quinimax at 400 mg in either 250- or 500-ml PVC infusion bags containing 5% dextrose, to give initial nominal concentrations of 2 or 1 mg ml(-1) quiniforme and 1.6 or 0.8 mg ml(-1) quinimax, the mean concentrations commonly used in clinical practice. Samples were assayed by stability-indicating high-performance liquid chromatography (HPLC) and the clarity was determined visually. Experiments were conducted to determine whether the stability and compatibility of quinine would be compromised, and whether DEHP would be leached from PVC bags and PVC administration sets during storage and simulated infusion. There was no substantial loss of quiniforme and quinimax over 1- or 2-h simulated infusion irrespective of the diluent, and storage during 8 h at 22 degrees C, 48 or 72 h at 4 degrees C and 96 h at 45 degrees C. Leaching of DEHP was also detected during simulated infusion delivery using PVC bags and PVC administration sets. The quantity was less than 2 microg ml(-1). During storage at 4 degrees C and room temperature the leaching of DEHP was low, but when the temperature was 45 degrees C the quantity was high, 21 microg ml(-1). To minimise patient exposure to DEHP, quinine solutions with all drugs should be infused immediately or stored for a maximum of 48 h at 4 degrees C.     

Stability of morphine sulfate in infusion devices and containers for intravenous administration

The stability of morphine sulfate in one brand of polyvinyl chloride (PVC) container, one brand of glass syringe, and two brands of disposable infusion devices was determined. Solutions of morphine sulfate 2 and 15 mg/mL were used to fill the PVC containers and drug administration devices. Stability was determined for both concentrations of morphine sulfate at room temperature (23-25 degrees C) and 4 degrees C in the PVC containers, glass syringes, and disposable infusion devices; stability was also determined at 31 degrees C in the disposable infusion devices. At 0, 1, 2, 4, 7, 12, and 15 days, portions of the solutions were removed and assayed in triplicate by a stability-indicating high-performance liquid chromatographic method. At each time point the drug-infusion fluid combinations were inspected visually for color changes and the presence of particulate matter, and pH was measured. Morphine sulfate 2 and 15 mg/mL remained stable for at least 12 days in all the containers and devices at each temperature tested. No substantial changes in the pH or physical appearance of the solutions were observed. Morphine sulfate can be repackaged in the disposable glass syringe, PVC container, and both disposable infusion devices for routine clinical use.     

Stability of dilute solutions of ganciclovir sodium (Cymevan) in polypropylene syringes and PVC perfusion bags]

The stability of ganciclovir sodium solutions stored in polypropylene syringes and PVC bags was tested in 0.9% sodium chloride at three concentrations 70, 200 and 350 mg/50 ml for polypropylene syringes, and two concentrations (70 and 350 mg/250 ml) for PVC bags and at three temperatures (-20 degrees C, + 4 degrees C, room temperature). The solutions, which had been initially frozen, were thawed by exposure to microwave radiations. The stability of each sample was determined by high-performance liquid chromatography. The results of this study indicate that admixtures of ganciclovir sodium at the concentration rates tested can be frozen for at least one year and are stable for at least 80 days at + 4 degrees C and 7 days at room temperature.     

Factors affecting the availability of diazepam stored in plastic bags and administered through intravenous sets

Factors affecting the loss of diazepam from i.v. admixtures to flexible polyvinyl chloride (PVC) bags and to various administration sets were studied. Admixtures containing diazepam and 0.9% sodium chloride injection were stored for up to 550 hours in flexible PVC bags and in glass vials at various temperatures. Diazepam injection containing two different solvents was used. Initial diazepam concentrations in storage studies ranged from 25 to 100 micrograms/ml and pH ranged from 4.2 to 7.5. To determine availability of diazepam after infusion through administration sets, solutions (50 micrograms/ml) from glass containers were run through six different sets at 1 ml/min for seven hours. In storage studies, the difference in composition of the solvent was found to have only a slight effect on the rate and extent of diazepam loss. Diazepam loss was unaffected by pH. For admixtures stored in 1000-ml flexible PVC bags, the fractional loss of diazepam was greater at small volumes. The diazepam concentration of solutions in flexible PVC bags decreased more rapidly during infusion than during storage of the total original volume. The fraction of diazepam remaining in stored solutions was independent of the initial concentration, but the rate and extent of diazepam loss was greater at higher temperatures. Diazepam loss was dependent on length of flexible PVC tubing, and diazepam availability was greater with faster flow rates. In solutions infused through the polyolefin Tridilset, 100% of the diazepam remained. When storage of diazepam admixtures in PVC bags or administration through PVC tubing cannot be avoided, measures to minimize the rate and extent of diazepam loss include decreasing the temperature and the storage time and increasing the surface-area-to-volume ratio and the flow rate. Equations are presented for calculating the amount of diazepam delivered.     

Stability of dacarbazine in amber glass vials and polyvinyl chloride bags.

The stability of dacarbazine in commercial glass vials and polyvinyl chloride (PVC) bags in various storage conditions and the emergence of 2-azahypoxanthine, a major degradation product possibly linked with some adverse effects, were studied. Triplicate samples of reconstituted (11 mg/mL) and diluted (1.40 mg/mL) dacarbazine admixtures were prepared and stored at 4 degrees C or at 25 degrees C in daylight, fluorescent light, or the dark. The effect of several light-protective measures (amber glass vials, aluminum foil wrapping, and opaque tubing) on dacarbazine stability in a simulated i.v. infusion system was also evaluated. Dacarbazine quantification and main degradation product determination were performed by high-performance liquid chromatography. Stability was defined as conservation of 90-105% of initial dacarbazine concentration without major variations in clarity, color, or pH and without precipitate formation. Reconstituted dacarbazine solutions were stable for 24 hours at room temperature and during light exposure and stable for at least 96 hours at 2-6 degrees C when stored in the dark. After dilution in PVC bags, stability time increased from 2 hours in daylight to 24 hours in fluorescent light and to 72 hours when covered with aluminum foil. After two hours of simulated infusion, dacarbazine remained stable. Diluted dacarbazine solutions stored at 2-6 degrees C were stable for at least 168 hours. The only degradation product found was 2-azahypoxanthine, which was detected in every sample. The storage and handling of dacarbazine should take into account both the loss of the drug and the production of its potentially toxic degradation product. Dacarbazine must be carefully protected from light, administered using opaque infusion tubing, and, if necessary, refrigerated before administration to reduce 2-azahypoxanthine formation.     

Stability study of fotemustine in PVC infusion bags and sets under various conditions using a stability-indicating high-performance liquid chromatographic assay

The stability and compatibility of fotemustine, a nitrosourea anticancer agent, in 5% dextrose solution with polyvinyl chloride (PVC) containers and administration sets were studied under different conditions of temperature and light. The drug was diluted to 0.8 and 2 mg ml(-1) in 100 or 250 ml 5% dextrose injection solutions for 1-h simulated infusions using PVC bags and administration sets with protection from light. After preparation in the PVC bags containing 5% dextrose, fotemustine was also prepared at the same concentrations and stored at 4 degrees C for 48 h and at room temperature (22 degrees C) or at sunray exposure ( > 30 degrees C) over 8 h with or without protection from light. The solution samples were removed immediately at various time points of simulated infusions and storage, and stored at -20 degrees C until analysis. The physical compatibility with PVC and chemical stability in solution of fotemustine were assessed by visual examination and by measuring the concentration of the drug in duplicate using a stability-indicating high-performance chromatographic assay. When admixed with a 5% dextrose solution, fotemustine 2 and 0.8 mg ml(-1) was compatible and stable over 1-h of simulated infusion using PVC bags through PVC administration sets with protection from light. On the other hand, in the same diluent, fotemustine was compatible and stable with PVC bags for at least 8 h at 22 degrees C with protection from light and for at least 48 h at 4 degrees C with protection from light. There were no pH variation, no visual change, no color change, no visible precipitation and no loss of the drug. Conversely, when the solutions were exposed to light (ambient or solar), the drug concentration decreased rapidly, leading to the production of a degradation product as shown by mass spectral analysis and a discoloration of the solutions. Finally, in all cases, no DEHP (di-2-ethylhexyl phthalate) was detected in the injection solution.     

Stability of pibenzimol hydrochloride in commonly used infusion solutions and after filtration

The stability of pibenzimol hydrochloride was evaluated after reconstitution, after addition to several intravenous fluids, and after filtration. Vials containing pibenzimol hydrochloride 50 mg were reconstituted with 2.5 mL of 0.9% sodium chloride injection to 20 mg/mL. For determination of drug stability in intravenous fluids, vial contents were further diluted to 0.15 mg/mL by injection into glass containers and polyvinyl chloride (PVC) bags containing 250 mL of 5% dextrose injection, 0.9% sodium chloride injection, or lactated Ringer's injection. Pibenzimol concentrations were determined immediately after preparation and at various intervals after storage at 4-6 degrees C or 25 degrees C by means of a stability-indicating, high-performance liquid chromatographic technique. Vial contents were inspected visually for color changes, and pH was measured. Determinations were also made of the stability of pibenzimol 0.15 mg/mL in 0.9% sodium chloride injection after simulated infusions using a 0.22-micron filter set at 25 degrees C. All study solutions and admixtures retained more than 90% of the initial pibenzimol concentration. The greatest loss of drug (6-7%) occurred after 24 hours in lactated Ringer's injection in both glass and PVC containers and in 0.9% sodium chloride injection in PVC bags. No drug loss occurred as a result of filtration. Reconstituted pibenzimol hydrochloride and admixtures of pibenzimol in 5% dextrose injection, 0.9% sodium chloride injection, or lactated Ringer's injection in glass or PVC containers are stable for at least 24 hours at 25 degrees C. Filtration has no effect on stability.     

Stability of heroin hydrochloride in infusion devices and containers for intravenous administration

The stability of heroin hydrochloride in various drug-administration devices was studied. Heroin hydrochloride was supplied as the bulk powder by the National Institute on Drug Abuse and in the formulated dosage form by Evans Medical, Ltd. Stability was determined at concentrations of 1 and 20 mg/mL at room temperature (23-25 degrees C) and at 4 degrees C in a polyvinyl chloride (PVC) bag, a disposable glass syringe, and two disposable infusion devices. Studies at both concentrations also were conducted at 31 degrees C in the disposable infusion devices. All experiments were conducted in triplicate. A validated, stability-indicating, high-performance liquid chromatography assay was used. Heroin hydrochloride remained stable for a minimum of 15 days in the PVC bag and the Infusor infusion device at the tested temperatures and concentrations. In the glass syringe, heroin hydrochloride was shown to be stable for a minimum of 15 days at both 1 mg/mL and 20 mg/mL if refrigerated at 4 degrees C, whereas at room temperature it was stable for a minimum of 7 days at 1 mg/mL and for 12 days at 20 mg/mL. In the Intermate 200 infusion device, heroin hydrochloride was stable for a minimum of 15 days at both concentrations and all temperatures except for the 1 mg/mL concentration at 31 degrees C. In the latter case, stability was for a minimum of two days. No substantial changes in physical appearance or pH were observed in any of the containers under the conditions studied. Heroin hydrochloride can be repackaged in the disposable glass syringe, PVC bag, and each of the disposable infusion devices for routine clinical use.     

Physical and chemical stability of etoposide phosphate solutions

OBJECTIVE: To evaluate the physical and chemical stability of etoposide phosphate solutions over 7 days at 32 degrees C and 31 days at 4 degrees C and 23 degrees C: (1) at etoposide concentrations of 0.1 and 10 mg/mL as phosphate in 0.9% sodium chloride injection and 5% dextrose injection and (2) at etoposide concentrations of 10 and 20 mg/mL as phosphate in bacteriostatic water for injection packaged in plastic syringes. DESIGN: Test samples of etoposide phosphate were prepared in polyvinyl chloride (PVC) bags of the two infusion solutions at etoposide concentrations of 0.1 and 10 mg/mL as phosphate. Additional test samples were prepared in bacteriostatic water for injection containing benzyl alcohol 0.9% at etoposide concentrations of 10 and 20 mg/mL as phosphate and were packaged in 5 mL plastic syringes. Evaluations for physical and chemical stability were performed initially; after 1 and 7 days of storage at 32 degrees C; and after 1, 7, 14, and 31 days of storage at 4 degrees C and 23 degrees C. Physical stability was assessed using visual observation in normal light and using a high-intensity monodirectional light beam. Turbidity and particle content were measured electronically. Chemical stability of the drug was evaluated by using a stability-indicating high-performance liquid chromatographic (HPLC) analytic technique. RESULTS: All samples were physically stable throughout the study. Little or no change in particulate burden and haze level were found. In the intravenous infusion solutions, little or no loss of etoposide phosphate occurred in any of the samples throughout the study period. The 10 and 20 mg/mL samples in bacteriostatic water for injection repackaged in syringes were also stable throughout the study, exhibiting a maximum of 6% or 7% loss after 31 days of storage at 23 degrees C and less than 4% in 31 days at 4 degrees C. CONCLUSION: Etoposide phosphate prepared as intravenous admixtures of etoposide 0.1 and 10 mg/mL as phosphate in 5% dextrose injection and 0.9% sodium chloride injection in PVC bags and as etoposide 10 and 20 mg/mL as phosphate in bacteriostatic water for injection packaged in plastic syringes is physically and chemically stable for at least 7 days at 32 degrees C and 31 days at 4 degrees C and 23 degrees C. This new water-soluble phosphate-ester of etoposide formulation solves the precipitation problems associated with the old organic solvent and surfactant-based formulation.     

Stability of ranitidine hydrochloride at dilute concentration in intravenous infusion fluids at room temperature

The stability of ranitidine at low concentration (0.05 mg/mL) in five intravenous infusion solutions (0.9% sodium chloride, 5% dextrose, 10% dextrose, 5% dextrose with 0.45% sodium chloride, and 5% dextrose with lactated Ringer's injections) was studied. Admixtures were stored for seven days at room temperature in 150-mL and 1-L polyvinyl chloride infusion bags. Ranitidine stability in 0.9% sodium chloride injection and in 5% dextrose injection was also examined for up to 28 days, and these data were compared with data obtained at higher ranitidine concentrations (0.5-2.0 mg/mL). At intervals during the storage periods, color, clarity, and solution pH were examined and ranitidine content was determined by a stability-indicating high-performance liquid chromatographic assay. Ranitidine content remained greater than 90% of the initial concentration for more than 48 hours in all infusion fluids except 5% dextrose with lactated Ringer's injection. No visual changes or appreciable changes in pH were observed for any of the solutions. At the dilute concentration, ranitidine was markedly more stable after eight hours in 0.9% sodium chloride injection than in 5% dextrose injection. In 0.9% sodium chloride injection, ranitidine concentrations remained above 95% for up to 28 days, but drug concentrations in 5% dextrose injection fell below 90% after seven days. Stability in 5% dextrose injection improved as ranitidine concentrations increased from 0.05 to 2.0 mg/mL. Ranitidine (0.05 mg/mL) is stable for at least 48 hours at room temperature in all infusion fluids tested except 5% dextrose with lactated Ringer's injection.     

Effect of flow rate and type of i.v. container on adsorption of diazepam to i.v. administration systems

The effect of flow rate and type of i.v. solution container on adsorption of diazepam to i.v. administration systems was studied. Diazepam solutions were prepared in 500 mL of 0.9% sodium chloride injection in glass, polyethylene, and polyvinyl chloride (PVC) containers to a final theoretical concentration of 50 micrograms/mL. PVC administration sets were attached to the containers, and diazepam solution was infused at flow rates of 30, 45, 60, 90, and 120 mL/hr. Solution samples were taken initially and at 0.25, 0.5, 0.75, 1.00, 1.50, 2.00, 3.00, and 4.00 hours after infusion of the first 5 mL of solution through the system. Three infusion trials were performed using each type of container. Adsorption of diazepam to each type of container was evaluated by serial measurements of diazepam concentration over a 168-hour period using five containers of each type. The effect of shaking the container on diazepam adsorption to PVC containers was tested by comparing concentrations in five containers that were shaken during a two-hour period with concentrations in five unshaken containers. Diazepam concentrations were measured spectrophotometrically in duplicate. Diazepam concentrations in glass containers remained unchanged throughout the 168-hour study period; concentrations decreased by about 5% in polyethylene containers and as much as 75% in PVC bags. Shaking increased diazepam adsorption to the PVC container. In the infusion trials, the percentage of diazepam adsorbed increased as flow rate decreased. The amount of diazepam adsorbed to the i.v. administration system was ore dependent on flow rate and infusion time than on the type of container used.(ABSTRACT TRUNCATED AT 250 WORDS)     

Stability of miconazole in peritoneal dialysis fluid

The stability of miconazole when mixed with peritoneal dialysis (PD) fluid and stored in plastic bags or glass ampuls was determined. Admixtures of miconazole and PD fluid were prepared in 2-L polyvinyl chloride (PVC) bags and in 1-mL glass ampuls to give a nominal initial concentration of 20 mg/mL. Duplicate samples of each solution were assayed in duplicate by high-performance liquid chromatography immediately after preparation and at various intervals up to nine days. All admixtures were stored in ambient light at 20 +/- 2 degrees C. A substantial loss of miconazole (greater than 10% of the initial concentration) occurred within four hours for admixtures stored in PVC bags, whereas similar solutions retained more than 90% of their initial miconazole concentration for at least three days when stored in glass ampuls under the same conditions. This suggests that the observed loss of miconazole from the PVC bags was largely due to an interaction with the container, rather than to chemical degradation in solution. About 28% of the miconazole lost from the solution during storage in PVC bags was recovered from the plastic by methanolic extraction. The rapid loss of miconazole when the drug was mixed with PD fluid and stored in PVC bags indicates that such admixtures should be prepared immediately before administration.     

Physical and chemical stability of gemcitabine hydrochloride solutions.

OBJECTIVE: To evaluate the physical and chemical stability of gemcitabine hydrochloride (Gemzar-Eli Lilly and Company) solutions in a variety of solution concentrations, packaging, and storage conditions. DESIGN: Controlled experimental trial. SETTING: Laboratory. INTERVENTIONS: Test conditions included (1) reconstituted gemcitabine at a concentration of 38 mg/mL as the hydrochloride salt in 0.9% sodium chloride or sterile water for injection in the original 200 mg and 1 gram vials; (2) reconstituted gemcitabine 38 mg/mL as the hydrochloride salt in 0.9% sodium chloride injection packaged in plastic syringes; (3) diluted gemcitabine at concentrations of 0.1 and 10 mg/mL as the hydrochloride salt in polyvinyl chloride (PVC) minibags of 0.9% sodium chloride injection and 5% dextrose injection; and (4) gemcitabine 0.1, 10, and 38 mg/mL as the hydrochloride salt in 5% dextrose in water and 0.9% sodium chloride injection as simulated ambulatory infusions at 32 degrees C. Test samples of gemcitabine hydrochloride were prepared in the concentrations, solutions, and packaging required. MAIN OUTCOME MEASURES: Physical and chemical stability based on drug concentrations initially and after 1, 3, and 7 days of storage at 32 degrees C and after 1, 7, 14, 21, and 35 days of storage at 4 degrees C and 23 degrees C. RESULTS: The reconstituted solutions at a gemcitabine concentration of 38 mg/mL as the hydrochloride salt in the original vials occasionally exhibited large crystal formation when stored at 4 degrees C for 14 days or more. These crystals did not redissolve upon warming to room temperature. All other samples were physically stable throughout the study. Little or no change in particulate burden or the presence of haze were found. Gemcitabine as the hydrochloride salt in the solutions tested was found to be chemically stable at all concentrations and temperatures tested that did not exhibit crystallization. Little or no loss of gemcitabine occurred in any of the samples throughout the entire study period. However, refrigerated vials that developed crystals also exhibited losses of 20% to 35% in gemcitabine content. Exposure to or protection from light did not alter the stability of gemcitabine as the hydrochloride salt in the solutions tested. CONCLUSION: Reconstituted gemcitabine as the hydrochloride salt in the original vials is chemically stable at room temperature for 35 days but may develop crystals when stored at 4 degrees C. The crystals do not redissolve upon warming. Gemcitabine prepared as intravenous admixtures of 0.1 and 10 mg/mL as the hydrochloride salt in 5% dextrose injection and 0.9% sodium chloride injection in PVC bags and as a solution of 38 mg/mL in 0.9% sodium chloride injection packaged in plastic syringes is physically and chemically stable for at least 35 days at 4 degrees C and 23 degrees C. Gemcitabine as the hydrochloride salt is stable for at least 7 days at concentrations of 0.1, 10, and 38 mg/mL in 5% dextrose injection and 0.9% sodium chloride injection stored at 32 degrees C during simulated ambulatory infusion.     

Stability of pentamidine isethionate in 5% dextrose and 0.9% sodium chloride injections

The stability of pentamidine isethionate in small-volume intravenous admixtures was studied. In an initial experiment, duplicate admixtures containing pentamidine 1 or 2 mg/mL were prepared using 100 mL each of 5% dextrose injection and 0.9% sodium chloride injection in polyvinyl chloride (PVC) bags. All solutions were kept at room temperature and were assayed at various times up to 48 hours by high-performance liquid chromatography. Solutions were also examined visually and tested for pH at each assay time. In a second experiment, single admixtures containing pentamidine 2 mg/mL were prepared in 100-mL PVC bags of both 5% dextrose injection and 0.9% sodium chloride injection. After time-zero determinations of pentamidine concentration, pH, and visual clarity, solutions were allowed to run through PVC infusion sets at 20 mL/hr. Samples were collected at the distal end of each set at various times up to five hours for analysis of pentamidine concentration, pH, and clarity. All admixtures in the initial experiment retained greater than 90% of initial concentration for the 48-hour study period. However, 5% dextrose admixtures infused through PVC administration sets showed a loss in initial concentration of about 2%, while 0.9% sodium chloride admixtures lost about 10% of initial concentration after infusion through these sets. The pH of all solutions in both experiments varied by less than 0.5 units, and no particulate matter or color change was noted in any of the admixtures. In the concentrations and diluents studied, pentamidine appears to be stable for 48 hours in PVC bags. Slight losses in the initial concentrations of these solutions after infusing them through PVC infusion sets may be caused by adsorption to the set.     

Compatibility of clindamycin phosphate with cefotaxime sodium or netilmicin sulfate in small-volume admixtures

The stability and compatibility of clindamycin phosphate plus either cefotaxime sodium or netilmicin sulfate in small-volume intravenous admixtures were studied. Admixtures containing each drug alone and two-drug admixtures of clindamycin phosphate plus cefotaxime sodium or netilmicin sulfate were prepared in 100 mL of 5% dextrose injection and 0.9% sodium chloride injection in both glass bottles and polyvinyl chloride (PVC) bags. Final concentrations of clindamycin, cefotaxime, and netilmicin were 9, 20, and 3 mg/mL, respectively. All solutions were prepared in duplicate and stored at room temperature (24 +/- 2 degrees C). Samples were visually inspected, tested for pH, and assayed for antibiotic concentration using stability-indicating assays at 0, 1, 4, 8, 16, and 24 hours for admixtures in glass bottles and at 0, 8, and 24 hours for admixtures in PVC bags. No substantial changes in color, clarity, pH, or drug concentration were observed in any of the solutions. Clindamycin phosphate is compatible with cefotaxime sodium or netilmicin sulfate in 5% dextrose and 0.9% sodium chloride injections in glass bottles or PVC bags for 24 hours.