Stability of sufentanil and levobupivacaine solutions and a mixture in a 0.9% sodium chloride infusion stored in polypropylene syringes.

We have evaluated the chemical and microbiological stability of sufentanil citrate, levobupivacaine hydrochloride and a mixture in a 0.9% sodium chloride infusion in order to provide background information on the storage of a sufentanil-levobupivacaine mixture in polypropylene (PP) syringes. Chemical assays were performed by HPLC on days 0, 1, 2, 3, 8, 14, 23, 28 and 30 after storage at 4, 21, and 36 degrees C. Microbiological stability was evaluated under aseptic conditions using a laminar air flow station, with a grade A environment and a B background. The samples taken for microbiological analysis were collected immediately after preparation of the solutions and then after 7, 14, 21 and 28 days storage. At 4 degrees C the sufentanil citrate solution was stable for 23 days. At 21 degrees C the sufentanil citrate solution maintained chemical stability for 3 days, but thereafter the concentration of sufentanil decreased 15% from day 3 to day 8. At 36 degrees C a similar decrease was noticed from day 1 to day 3. On the contrary, the levobupivacaine hydrochloride solution maintained chemical stability for 28 days at 4 and 21 degrees C and for 23 days at 36 degrees C. The sufentanil-levobupivacaine mixture maintained chemical stability for 28 days at 4, 21 and 36 degrees C. The sufentanil and levobupivacaine solutions and the mixture studied maintained microbiological stability for 28 days. According to the chemical and microbiological stability studies, the sufentanil-levobupivacaine mixture in PP syringes could be stored for 28 days at 4 and 21 degrees C.     

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 cephalexin monohydrate suspension in polypropylene oral syringes

The stability of cephalexin monohydrate suspension in plastic oral syringes was studied. Commercially available cephalexin monohydrate powder for oral administration was reconstituted according to the manufacturer's instructions and stored in the original containers or drawn into 5-mL clear polypropylene oral syringes. The original containers and syringes were divided into groups and stored at -20, 4, 25, 40, 60, or 80 degrees C. Powder from two additional lots was similarly reconstituted and packaged; these original containers and syringes were stored at 80 degrees C only to assess interlot variability. Immediately after reconstitution and at specified times during storage, three syringes and the corresponding three original containers stored at each temperature were removed, and their contents were analyzed for cephalexin concentration using the standard USP iodometric assay for antibiotics. The stability-indicating nature of the assay was documented. Cephalexin monohydrate followed a first-order rate of degradation at temperatures of 40, 60, and 80 degrees C. At temperatures of -20, 4, and 25 degrees C, cephalexin monohydrate exhibited no appreciable degradation during the 90-day study period. Cephalexin monohydrate suspension reconstituted from powder as a suspension and repackaged in clear polypropylene oral syringes was stable for 90 days when stored under ambient, refrigerated, and frozen conditions.     

Stability of vecuronium in sterile water for injection stored in polypropylene syringes for 21 days.

PURPOSE: The stability of vecuronium bromide 1 mg/mL in preservative-free sterile water for injection for up to 21 days was studied. METHODS: A vecuronium bromide 1-mg/mL solution was prepared by diluting 15 vials of 10-mg Vecuronium Bromide for Injection, USP, powder with preservative-free sterile water for injection and adding the solution to an evacuated i.v. bag. Identical 10-mL volumes of the solution were prepared and stored at 23-25 or 3-5 degrees C in polypropylene syringes. The stability of vecuronium was analyzed in triplicate with stability-indicating high-performance liquid chromatography immediately after preparation of solutions and at 3, 7, 14, and 21 days. The samples were also inspected for volume and color change and for visible precipitation and microbial growth. RESULTS: The percentage of the initial vecuronium bromide concentration remaining at each time point was greater than 100% at both 23-25 and 3-5 degrees C. There were no detectable changes in volume or color and no precipitation or visible microbial growth. CONCLUSION: Vecuronium bromide in an extemporaneously prepared solution in preservative-free sterile water for injection was stable for at least 21 days at 23-25 or 3-5 degrees C.     

Stability of dicloxacillin sodium oral suspension stored in polypropylene syringes

The stability of dicloxacillin sodium in oral suspension stored in clear polypropylene oral syringes was studied. Commercially available dicloxacillin sodium powder for oral suspension from a single lot was reconstituted according to the manufacturer's instructions and drawn into 5-mL clear polypropylene oral syringes. The syringes were divided into groups and stored at -20, 4, 25, 40, 60 or 80 degrees C. Two additional lots were similarly reconstituted, repackaged, and stored at 80 degrees C only to assess interlot variability. Powder in the original containers was similarly reconstituted according to the manufacturer's instructions, and the containers were divided into groups and stored with the syringes. Immediately after reconstitution and at specified times during storage, three syringes and the original containers at each storage temperature were removed, and their contents were analyzed for dicloxacillin sodium concentration using the Standard USP Iodometric Assay. Dicloxacillin sodium follows a first-order rate of degradation at temperatures of 40, 60, and 80 degrees C. The rate of degradation changes to a zero-order process at temperatures of 25, 4, and -20 degrees C. At all temperatures, degradation occurred more rapidly when the drug was repackaged into unit dose polypropylene oral syringes than in the manufacturer's original container. Dicloxacillin sodium reconstituted from powder as oral suspension and repackaged in clear polypropylene syringes was stable for no longer than 7, 10, and 21 days when stored under ambient, refrigerated, and frozen conditions, respectively.     

Stability of cefazolin sodium in polypropylene syringes and polyvinylchloride minibags

Background:

Cefazolin is a semisynthetic penicillin derivative with a narrow spectrum of activity covering some gram-positive organisms and a few gram-negative aerobic bacteria.

Objective:

To determine the physical and chemical stability of cefazolin sodium reconstituted with sterile water for injection and stored in polypropylene syringes or diluted with either 5% dextrose in water (D5W) or 0.9% sodium chloride (normal saline [NS]) and stored in polyvinylchloride (PVC) minibags.

Methods:

Reconstituted solutions of cefazolin (100 or 200 mg/mL) were packaged in polypropylene syringes. More dilute solutions (20 or 40 mg/mL) were prepared in D5W or NS and packaged in PVC minibags. For each concentration–diluent–container combination, 3 containers were designated for each day of analysis (days 7, 14, 21, and 30). Containers were stored under refrigeration (5°C) with protection from light until the designated day of analysis, at which time one 5-mL sample was collected from each the designated container. The designated containers were then stored at room temperature (21°C to 25°C) with exposure to light for an additional 72 h, and additional samples were drawn. The samples were assayed using a validated, stability-indicating high-performance liquid chromatography method. The colour and clarity of the solutions, as well as their pH, were also monitored on each sampling day.

Results:

All samples remained clear for the duration of the study; they had a slight yellow colour that darkened over time, and there was an increase in pH. Solutions diluted with sterile water for injection and stored in polypropylene syringes retained at least 94.5% of the initial concentration after 30 days of refrigerated storage and at least 92.1% after an additional 72 h at room temperature with exposure to light. Samples diluted in D5W or NS and stored in PVC minibags retained at least 95.8% of the initial concentration after 30 days of refrigerated storage and at least 91.8% after an additional 72 h at room temperature with exposure to light.

Conclusions:

Cefazolin at various concentrations stored in polypropylene syringes or PVC minibags was stable for up to 30 days with storage at 5°C with protection from light, followed by an additional 72 h at 21°C to 25°C with exposure to light.     

Stability of azacitidine in lactated Ringer's injection frozen in polypropylene syringes

The stability of azacitidine diluted in lactated Ringer's injection was studied. Azacitidine was reconstituted with ice-cold lactated Ringer's injection to concentrations of 2.0 and 0.5 mg/mL and stored in polypropylene syringes at -20 degrees C. On days 1, 3, 7, and 14, the solutions were thawed over 30-45 minutes and the azacitidine concentration was determined by high-performance liquid chromatography immediately after thawing and one, three, and six hours later. Other studies were conducted at 37, 20, and 0-4 degrees C to determine decomposition rate constants for azacitidine at both concentrations. Hydrolysis of azacitidine resulted in a biphasic decline when the log of the percentage of drug remaining was plotted against time. No substantial decomposition occurred during storage at -20 degrees C. In thawed samples, azacitidine concentrations decreased to 90% of the initial concentrations within three hours after reaching room temperature; similar decreases in concentration were seen in nonfrozen samples stored at room temperature. The results of these studies indicate that azacitidine solutions in lactated Ringer's injection can be stored in polypropylene syringes at -20 degrees C for two weeks without decomposition. The thawed solutions should be used within three hours.     

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.     

Maintenance of sterility in 1-mL polypropylene syringes.

PURPOSE: The sterility of syringes filled with a growth-promoting broth when stored under various temperature conditions was studied. METHODS: Samples of tryptic soy broth (TSB) were injected into 150 1-mL polypropylene syringes and incubated at 33-37 degrees C for 14 days, after which time they were visually inspected for microbial contamination. In addition to visual inspection, the sterility of all syringes was tested by inoculating samples into 10-mL tubes of thioglycollate broth, incubating at 35 degrees C, and observing for growth for 5 days. After the 14-day incubation period, 30 syringes were removed for sterility validation and microbial growth promotion. TSB from 15 syringes was transferred into sterile culture tubes and challenged with Staphylococcus aureus, Escherichia coli, Bacillus cereus, Candida albicans, and Aspergillus niger. The remaining 120 syringes were repackaged and stored at room temperature (22 degrees C), in a refrigerator (5 degrees C), or in a freezer (-20 degrees C). The sterility of the samples was evaluated at 30 days, 45 days, three months, and six months. RESULTS: No microbial growth was detected by visual inspection in any of the 15 syringes examined for turbidity during validation testing. All study syringes (n = 120) remained sterile throughout the respective evaluation periods, regardless of storage condition. CONCLUSION: Growth-promoting broth stored in 1-mL polypropylene syringes remained sterile when stored at room temperature, in a refrigerator, or in a freezer for six months.     

Stability of pantoprazole sodium in glass vials, polyvinyl chloride minibags, and polypropylene syringes

Background:

Pantoprazole sodium, a proton-pump inhibitor, is approved for the short-term treatment of several types of ulcer, Zollinger–Ellison syndrome, and gastroesophageal reflux disease.

Objective:

To determine the physical compatibility and chemical stability of ethylenediaminetetra-acetic acid (EDTA)–free pantoprazole in glass vials, polypropylene syringes, and polyvinylchloride (PVC) minibags, after storage at 2°C to 8°C with protection from light or at 20°C to 25°C with exposure to light.

Methods:

Solutions of pantoprazole 4 mg/mL reconstituted in 0.9% sodium chloride (normal saline [NS]) were stored in glass vials at 20°C to 25°C. Similar solutions were transferred to polypropylene syringes and stored at 2°C to 8°C. Stock solution was further diluted, in 5% dextrose in water (D5W) or NS, to 0.4 or 0.8 mg/mL, and samples were then packaged in PVC minibags for storage at 2°C to 8°C or at 20°C to 25°C. Samples collected on days 0, 2, 3, 7, 14, 21, and 28 were analyzed in duplicate with a stability-indicating high-performance liquid chromatography assay.

Results:

Pantoprazole 4 mg/mL was stable (i.e., retained at least 90% of initial concentration) for 3 days when stored in glass vials at 20°C to 25°C or for 28 days when stored in polypropylene syringes at 2°C to 8°C. Pantoprazole 0.4 mg/mL diluted in D5W and stored in PVC minibags was stable for 2 days at 20°C to 25°C or for 14 days at 2°C to 8°C. At 0.8 mg/mL, pantoprazole in D5W was stable for 3 days at 20°C to 25°C or 28 days at 2°C to 8°C. Pantoprazole diluted to either 0.4 or 0.8 mg/mL in NS and stored in PVC minibags was stable for 3 days at 20°C to 25°C or 28 days at 2°C to 8°C.

Conclusions:

The present study confirmed or extended previously reported expiry dates for pantoprazole sodium packaged in glass vials, polypropylene syringes, and PVC minibags.