Stability of 70% alcohol solutions in polypropylene syringes for use in ethanol-lock therapy.

PURPOSE: The stability of 70% alcohol solutions in two diluents stored at 23-25 degrees C over 14 days in two brands of polypropylene syringes was studied. METHODS: A 70% alcohol solution was aseptically prepared by adding Dehydrated Alcohol Injection, USP, to Sterile Water for Injection, USP (SWI), in an evacuated i.v. bag. This process was repeated with Bacteriostatic Water for Injection, USP (BWI). Identical 3-mL samples of each of the two solutions were drawn into 10-and 12-mL syringes (each a different brand) and stored at 23-25 degrees C. The stability of the samples was analyzed with high-performance liquid chromatography immediately after preparation and at 3, 7, and 14 days. RESULTS: At least 96% of the initial concentration of alcohol remained throughout the 14-day study period in all syringes. There were no detectable changes in color or volume and no visible evidence of precipitation or microbial growth in any sample. CONCLUSION: Extemporaneously prepared 70% alcohol solutions in SWI or BWI were stable for at least 14 days at 23-25 degrees C in two brands of polypropylene syringes.     

Urokinase activity after freezing: implications for thrombolysis in intraventricular hemorrhage.

The retention of urokinase activity after frozen storage was studied. Urokinase powder was reconstituted aseptically in sterile water for injection or preservative-free 0.9% sodium chloride injection to a final concentration of 5000 IU/mL. Samples were stored in 5-mL plastic syringes at -20 or -70 degrees C for up to six months. Samples containing urokinase 25,000 IU/mL were similarly prepared by using sodium chloride injection as the diluent and were stored frozen at the same temperatures for up to 93 days. Urokinase activity was measured with a chromogenic assay at each test interval. Samples were also cultured after thawing to evaluate their potential to support microbial growth. The activity of urokinase at either concentration did not change appreciably during the study period. The method of thawing-at room temperature or in a refrigerator-had no effect on urokinase activity. No microbial growth was observed. Urokinase 5000 IU/mL did not show any changes in activity when reconstituted with sterile water for injection or 0.9% sodium chloride injection and frozen for up to six months. Urokinase 25,000 IU/mL in sodium chloride injection was also stable after 93 days of frozen storage.     

Stability of phenylephrine hydrochloride injection in polypropylene syringes.

PURPOSE: The stability of extemporaneously prepared phenylephrine hydrochloride injection stored in polypropylene syringes was studied. METHODS: Dilution of phenylephrine hydrochloride to a nominal concentration of 100 mug/mL was performed under aseptic conditions by adding 100 mg of phenylephrine hydrochloride (total of 10 mL from two 5-mL 10-mg/mL vials) to 1000 mL of 0.9% sodium chloride injection. The resulting solution was drawn into 10-mL polypropylene syringes and sealed with syringe caps. The syringes were then frozen (-20 degrees C), refrigerated (3-5 degrees C), or kept at room temperature (23-25 degrees C). Four samples of each preparation were analyzed on days 0, 7, 15, 21, and 30. Physical stability was assessed by visual examination. The pH of each syringe was also measured at each time point. Sterility of the samples was not assessed. Chemical stability of phenylephrine hydrochloride was evaluated using high-performance liquid chromatography. To demonstrate the stability-indicating nature of the assay, forced degradation of phenylephrine was conducted. Samples were considered stable if there was less than 10% degradation of the initial concentration. RESULTS: Phenylephrine hydrochloride diluted to 100 microg/mL with 0.9% sodium chloride injection was physically stable throughout the study. No precipitation was observed. Minimal to no degradation was observed over the 30-day study period. CONCLUSION: Phenylephrine hydrochloride diluted to a concentration of 100 mug/mL in 0.9% sodium chloride injection was stable for at least 30 days when stored in polypropylene syringes at -20 degrees C, 3-5 degrees C, and 23-25 degrees C.     

Stability of morphine sulfate and meperidine hydrochloride in a parenteral nutrient formulation

The compatibility, stability, and availability of morphine sulfate and meperidine hydrochloride prepared in total parenteral nutrient (TPN) solution, 5% dextrose injection, and sterile water for injection in polyvinyl chloride (PVC) bags were evaluated. A 300-mg dose of each narcotic was mixed in 0.25-L bags of 5% dextrose injection and sterile water for injection, and in 3-L bags of TPN and sterile water for injection. Each solution was examined visually for precipitation, color change, turbidity, and the evolution of gas immediately after the addition of the drug to the bag and every 12 hours for a 36-hour period. Narcotic concentrations in each solution were determined by high-pressure liquid chromatography before and for 36 hours after the addition of the drugs to the bags. No loss of either drug because of adsorption to the PVC bags was found. Morphine sulfate and meperidine hydrochloride were chemically compatible and stable in TPN and 5% dextrose injection for 36 hours. Solutions of morphine sulfate or meperidine hydrochloride in PVC bags containing TPN or 5% dextrose injection are visually and chemically compatible, as well as stable and available for 36 hours when stored at 21.5 degrees C with no protection from environmental light.     

Stability of dolasetron in two oral liquid vehicles.

The stability of dolasetron 10 mg/mL over 90 days when prepared as an oral liquid formulation from commercially available tablets in both strawberry syrup and a sugar-free vehicle was studied. A liquid suspension of dolasetron mesylate 10 mg/mL was prepared from commercially available dolasetron tablets, OraPlus, and Ora-Sweet or strawberry syrup. Six samples of each formulation were prepared and stored in amber plastic bottles. Three samples of each formulation were refrigerated (3-5 degrees C) and three were stored at room temperature (23-25 degrees C). A 1-mL sample was withdrawn from each of the 12 bottles immediately and after 7, 14, 30, 60, and 90 days. After further dilution to an expected concentration of 10 micrograms/mL with sample diluent, the solutions were assayed in duplicate using high-performance liquid chromatography. The samples were also inspected for color and odor changes, and the pH of each sample was determined. The stability-indicating capability of the dolasetron assay was determined by forced degradation of four separate 10-mg/mL samples exposed to direct sunlight for 90 days. There were no detectable changes in color, odor, or taste and no visible microbial growth in any sample. At least 98% of the initial dolasetron concentration remained throughout the 90-day study period for all samples. An extemporaneously compounded oral liquid preparation of dolasetron mesylate 10 mg/mL in a 1:1 mixture of Ora-Plus and strawberry syrup or Ora-Sweet was stable for at least 90 days when stored at 3-5 or 23-25 degrees C.     

Stability of meropenem in polyvinyl chloride bags and an elastomeric infusion device.

PURPOSE: The stability of meropenem in i.v. solutions stored in polyvinyl chloride (PVC) bags and an elastomeric infusion device at concentrations commonly used in home care was studied. METHODS: Vials of meropenem were reconstituted with sterile water for injection and mixed with 0.9% sodium chloride injection (NS) to yield concentrations of 4, 10, and 20 mg/mL. Six replicate solutions were prepared in PVC containers and six in the Homepump ECLIPSE elastomeric infusion device. All solutions were stored at an average temperature of 5 degrees C and sampled immediately after preparation and at intervals up to 120 hours (five days); the 4-mg/mL solution was also sampled at 144 and 168 hours (seven days). Samples were assayed for meropenem concentration by stability-indicating high-performance liquid chromatography. RESULTS: All solutions of meropenem retained over 90% of the initial drug concentration at five days. The 4-mg/mL solutions retained over 93% of the initial concentration at seven days. The rate of meropenem decay did not differ significantly between PVC and elastomeric infusion containers for the 4- and 20-mg/mL solutions; however, there was a difference for the 10-mg/mL solutions. CONCLUSION: Meropenem 4 mg/mL in NS was stable for at least seven days in PVC bags and elastomeric infusion containers when stored at 5 degrees C, and meropenem 10 and 20 mg/mL in NS was stable for at least five days in both containers at 5 degrees C.     

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 fumagillin in an extemporaneously prepared ophthalmic solution.

The stability of fumagillin 70 microg/mL (as the bicyclohexylammonium crystal) in an extemporaneously prepared ophthalmic solution was studied. An ophthalmic solution of fumagillin 70 microg/mL was prepared by combining 120 mg of fumagillin bicyclohexylammonium crystals with 20 mL of 0.9% Sodium Chloride Injection, USP, and 20 mL of an ophthalmic irrigating solution. The solution was stored in 12 sterile semi-opaque dropper bottles; 4 bottles were stored at 25 degrees C exposed to light, 4 were stored at 25 degrees C in the dark, and 4 were stored at 4 degrees C in the dark. Samples were taken on days 0, 7, 14, 21, and 28 and analyzed by high-performance liquid chromatography. Sterility was tested as well. In the solutions stored at 25 degrees C, 17-30% of the initial drug concentration was lost during the first week. The solution protected from light and stored at 4 degrees C lost about 12% of active drug by week 4. There was no change in color or odor in any of the solutions and only a minor change in pH over the study period. There was no evidence of microbial growth in any of the solutions tested. Fumagillin 70 microg/mL (as the bicyclohexylammonium crystal) in 0.9% sodium chloride injection and an ophthalmic irrigating solution containing benzalkonium chloride was stable in the dark for 14 days at 4 degrees C.     

Stability of ganciclovir in extemporaneously compounded oral liquids.

The stability of ganciclovir in extemporaneously prepared sugar-containing and sugar-free oral liquids was studied. The contents of 80 250-mg capsules of ganciclovir were combined with Ora-Sweet or Ora-Sweet SF (sugar free) (Paddock Laboratories) to produce 200 mL of suspension with a ganciclovir concentration of 100 mg/mL. Five 1-mL samples were analyzed immediately, and the rest of the suspension was poured into five 60-mL amber polyethylene terephthalate bottles and stored at 23-25 degrees C. Samples were removed and analyzed with stability-indicating high-performance liquid chromatography on days 15, 35, 60, 91, and 123. The suspensions retained at least 96% of the initial ganciclovir concentration for 123 days. The pH of the suspensions was initially 4.5 and remained unchanged throughout the study. There was no detectable change in color or odor and no visible microbial growth in any sample. Ganciclovir 100 mg/mL was stable for 123 days in sugar-containing and sugar-free oral liquids stored at 23-25 degrees C in amber polyethylene terephthalate bottles.     

Stability of codeine phosphate in an extemporaneously compounded syrup.

PURPOSE: The stability of codeine phosphate in an extemporaneously compounded syrup is described. METHODS: Codeine phosphate 3-mg/mL syrup was prepared using commercially available Codeine Phosphate, USP, Sterile Water for Irrigation, USP, and Ora-Sweet syrup vehicle. Samples were stored in amber polyethylene terephthalate bottles with child-resistant caps. A second batch of codeine phosphate 3-mg/mL syrup was prepared and drawn into amber polyethylene oral syringes with silicon elastomer tips. All samples were stored at room temperature and in the dark. Samples were analyzed immediately and at 7, 14, 28, 42, 56, 70, and 98 days. Codeine phosphate concentrations were measured using a modified stability-indicating high-performance liquid chromatographic method. At each test interval, the density of the syrup was determined gravimetrically using a 10-mL amber oral syringe. Excessive degradation was defined as a greater than 7% loss of the initial concentration. RESULTS: The stock internal standard was stable for at least 98 days at room temperature. The compounded syrup retained more than 93% of the initial codeine phosphate concentration for at least 98 days at 22-25 degrees C. No changes in color, clarity, or odor and no visible solids or microbial growth were observed in any sample. The pH of the syrup was initially 4.2 and remained unchanged throughout the study. CONCLUSION: Codeine phosphate 3 mg/mL in Ora-Sweet syrup vehicle was stable in both amber polyethylene terephthalate bottles and amber polyethylene oral syringes for at least 98 days when stored at 22-25 degrees C and protected from light.     

Stability and preservative effectiveness of treprostinil sodium after dilution in common intravenous diluents.

The stability of treprostinil sodium after dilution in three common i.v. infusion vehicles was assessed. The chemical stability of treprostinil sodium was tested over a 48-hour period at 40 degrees C and 75% relative humidity after dilution in each of three diluents: sterile water for injection, 0.9% sodium chloride injection, and 5% dextrose injection, and after passage through an i.v. delivery system. Chemical analysis was conducted by using a validated stability-indicating high-performance liquid chromatographic assay, visually inspecting the solutions, and measuring the pH of each solution. The preservative effectiveness of the solutions was tested by the recovery of inoculations of compendial microorganisms after 48 hours in dilute solutions of treprostinil sodium. All assay results for treprostinil were within 90.0% to 110.0% of the prepared solutions diluted at 0.004 and 0.13 mg/mL treprostinil sodium in sterile water for injection and 0.9% sodium chloride injection. The assay results were the same for dilute treprostinil solutions in 5% dextrose injection at concentrations of 0.02 and 0.13 mg/mL. The pH values for these solutions remained within acceptable values of 6.0 to 7.2 for the stability study. No change in physical appearance or any visible particulate matter was observed. Approximately 70% of metacresol, the preservative, in the dilute treprostinil sodium solutions was removed before reaching the terminal end of the tubing. None of the dilute treprostinil sodium solutions supported microbial growth in the cassette reservoirs for the organisms considered. Treprostinil sodium 0.13 mg/mL solution in sterile water for injection, 0.9% sodium chloride for injection, and 5% dextrose for injection appeared to be stable after storage in controlled ambulatory drug-delivery systems for 48 hours at 40 degrees C and 75% relative humidity. Treprostinil sodium 0.004 mg/mL in sterile water and 0.9% sodium chloride for injection and 0.02 mg/mL in 5% dextrose injection was also stable under the same conditions. None of the solutions showed signs of microbial growth.     

Stability of midazolam hydrochloride in a flavored, dye-free oral solution.

The stability of injectable midazolam hydrochloride in a solution for oral use was studied at three temperatures over 56 days. A 2.5-mg/mL oral solution was prepared from injectable midazolam hydrochloride and a flavored, dye-free syrup. Samples of solution were stored in amber glass bottles at 7, 20, or 40 degrees C. Duplicate samples were analyzed by high-performance liquid chromatography on days 0, 1, 3, 5, 14, 21, 35, and 56. Samples were also visually inspected on each sampling day. The concentrations of all samples remained greater than 90% of the original concentration and there were no visual signs of microbial growth or changes in color, turbidity, or odor throughout the 56-day period. A 2.5-mg/mL solution of injectable midazolam in syrup was stable for 56 days at 7, 20, or 40 degrees C.     

Stability of cefazolin sodium, cefoxitin sodium, ceftazidime, and penicillin G sodium in portable pump reservoirs

The stability of cefazolin sodium, cefoxitin sodium, ceftazidime, and penicillin G sodium in prefilled drug reservoirs that were stored at -20 degrees C for 30 days, thawed at 5 degrees C for four days, and pumped at 37 degrees C for one day was studied. Each antimicrobial agent was diluted with sterile water for injection to a concentration representative of the most common dosage when administered via a portable infusion pump. Ten milliliters of each drug solution was placed in individual glass vials to serve as controls, and volumes appropriate to deliver the designated dosages were loaded into the drug reservoirs. Triplicate reservoirs were prepared for each drug. One-milliliter samples from all containers were taken on days 0, 30, 31, 32, 33, 34, 34.5, and 35. All solutions were observed for color change and precipitation. Drug concentrations were determined using high-performance liquid chromatography. Leaching of the plasticizer diethylhexyl phthalate (DEHP) was analyzed by packed-column gas chromatography on days 0 and 35. No color change or precipitation was observed. No DEHP concentrations above 1 ppm were detected. More than 90% of the initial concentrations of each drug remained, except penicillin G sodium, which had a mean concentration of 83.9 +/- 0.5% at the end of the study. Cefazolin sodium, cefoxitin sodium, and ceftazidime in admixtures with sterile water for injection are stable under the conditions of this study. Penicillin G sodium should not be administered for more than 12 hours after such a cycle of freezing and thawing.     

Stability of captopril in tap water.

The stability of captopril in tap water was studied. Twenty 25-mg captopril tablets were crushed separately, added to 25 mL of tap water in individual volumetric flasks, and shaken vigorously. Five flasks each were incubated at 25, 50, and 75 degrees C in a shaking water bath and refrigerated at 5 degrees C. Samples were taken from each flask immediately after dissolving the drug and at intervals up to 28 days for 5 and 25 degrees C, 15 days for 50 degrees C, and 16 days for 75 degrees C. Captopril concentrations were analyzed by high-performance liquid chromatography. First-order rate constants were calculated for each temperature setting, and the Arrhenius plot was applied to estimate the shelf life of captopril at 5 degrees C. More than 90% of the initial concentration of captopril remained after 28 days at 5 degrees C. Captopril concentration in the samples stored at 75, 50, and 25 degrees C decreased to 90% of the initial concentration at calculated times (mean +/- S.E.) of 2.1 +/- 0.1, 3.6 +/- 0.4, and 11.8 +/- 1.2 days, respectively. The estimated time required for the concentration of a 1-mg/mL solution of captopril stored at 5 degrees C to decrease to 90% of initial concentration was 27 days. The shelf life of a solution of captopril 1 mg/mL in tap water stored at 5 degrees C was 27 days.     

Stability of amphotericin B in four concentrations of dextrose injection.

The stability of amphotericin B in 5%, 10%, 15%, and 20% dextrose injection was investigated. The dextrose solutions were prepared in triplicate from sterile water for injection and 70% dextrose injection and placed in empty 50-mL polyvinyl chloride bags. The pH of each solution was determined before amphotericin B was added to a concentration of approximately 100 micrograms/mL. The bags were stored at 15-25 degrees C and protected from light. Three 1-mL samples were taken from each bag at various times up to 24 hours. One sample was analyzed for precipitation and color and pH changes. Two samples were analyzed in duplicate by stability-indicating high-performance liquid chromatography. No visual changes were observed, and pH did not change substantially. The mean amphotericin B concentration was greater than 90% of the initial concentration at each sampling time. However, the drug concentration in 3 of the 27 samples from the admixtures with 10% dextrose injection and 5 of the 27 samples from the admixtures with 20% dextrose injection fell below 90% of the initial concentration. Amphotericin B 100 micrograms/mL was stable in 5%, 10%, 15%, and 20% dextrose injection when stored for up to 24 hours at 15-25 degrees C and protected from light.     

Stability of ceftazidime in plastic syringes and glass vials under various storage conditions.

The stability of ceftazidime solutions (100 and 200 mg/mL) in plastic syringes and glass vials under various storage conditions was examined. Solutions of ceftazidime 100 and 200 mg/mL in sterile water were placed in polypropylene plastic syringes or glass vials and stored (1) at 21-23 degrees C for up to 8 hours, (2) at 4 degrees C for up to 96 hours, (3) at -20 degrees C for 28 days and then 21-23 degrees C for up to 8 hours, (4) at -20 degrees C for 28 days and then 4 degrees C for up to 96 hours, (5) at -20 degrees C for 91 days and then 21-23 degrees C for up to 8 hours, or (6) at-20 degrees C for 91 days and then 4 degrees C for up to 96 hours. Samples were withdrawn from each syringe and vial at designated times and assayed by high-performance liquid chromatography. Solutions were judged to be stable if drug concentrations remained above 90% of the initial values. The number of particles in each container under each storage condition was also evaluated. Ceftazidime was stable under all storage conditions. In all containers, particulate matter was within USP specifications for small-volume injections, with no change in particle count as a result of the freezing and thawing. Ceftazidime in sterile water in either glass vials or plastic syringes is stable for 8 hours at room temperature or 96 hours at 4 degrees C when such storage occurs (1) immediately after constitution, (2) after 28 days of frozen storage, or (3) after 91 days of frozen storage.     

Stability of ceftazidime and amino acids in parenteral nutrient solutions

The stability of ceftazidime was studied under conditions simulating administration via a Y-injection site into a primary infusion of parenteral nutrient (PN) solution; the stabilities of ceftazidime and amino acids when the drug was added directly to PN solutions were also studied. Three PN solutions containing 25% dextrose were used; the amino acid contents were 0, 2.5%, and 5%. Ceftazidime with sodium carbonate was used to prepare stock solutions of ceftazidime 40 mg/mL in both 0.9% sodium chloride injection and 5% dextrose injection; to simulate Y-site injection, samples were added to the three PN solutions to achieve ceftazidime concentrations of 10 and 20 mg/mL, or 1:1 and 1:3 ratios of drug solution to PN solution. Samples of these admixtures were assayed by high-performance liquid chromatography (HPLC) initially and after room-temperature (22 degrees C) storage for one and two hours. Additional solutions were prepared by adding sterile water for injection to ceftazidime with sodium carbonate; drug solutions were added to each PN solution in polyvinyl chloride bags to achieve ceftazidime concentrations of 1 and 6 mg/mL. The samples were assayed by HPLC for ceftazidime concentration after storage at 22 degrees C for 3, 6, 12, 24, and 36 hours and at 4 degrees C for 1, 3, 7, and 14 days. Amino acid stability was analyzed in admixtures containing 5% amino acids and ceftazidime 6 mg/mL after 24 and 48 hours at 22 degrees C and after 7 and 10 days at 4 degrees C.(ABSTRACT TRUNCATED AT 250 WORDS)     

Stability of oxaliplatin in infusion bags containing 5% dextrose injection.

PURPOSE: The stability of oxaliplatin in infusion bags containing 5% dextrose injection was studied. METHODS: Solutions of oxaliplatin 0.7 mg/mL were prepared in polyolefin infusion bags containing 5% dextrose injection and stored at 3-7 degrees C in a lightproof bag, at 20-24 degrees C with continuous exposure to artificial light, and at 20-24 degrees C with continuous exposure to fluorescent light in a lightproof bag. Samples were analyzed at 1, 2, 3, 4, 5, 7, 14, and 30 days and assayed in duplicate. Stability was measured using a stability-indicating high-performance liquid chromatographic method. Samples were also examined for changes in color and pH and for the presence of particulate matter. RESULTS: All samples retained over 90% of their initial concentration over the study period. No color changes or visible precipitation was observed, and the pH of all samples remained stable. Neither temperature nor artificial light had any significant effect on the stability of oxaliplatin. CONCLUSION: Oxaliplatin 0.7 mg/mL in infusion bags containing 5% dextrose injection was chemically stable for at least 30 days at both 3-7 degrees C and 20-24 degrees C without regard to light exposure.