Sterility and Stability Testing of Preservative-free Albuterol.

BACKGROUND: Continuous albuterol administration (CAA) is commonly used in hospitalized patients for treatment of asthma exacerbations. Due to higher dose requirements, CAA requires large volumes of albuterol obtained from multidose vials containing benzalkonium chloride (BAC). BAC is a common pharmaceutical preservative and potent bronchoconstrictor, which may antagonize the bronchodilation effects of albuterol. Some institutions are using preservative-free (PF) albuterol for their CAA. However, no published data currently exist to support the extended sterility or stability of this formulation. OBJECTIVE: To evaluate the sterility and stability of PF-albuterol. METHODS: Sterility testing was conducted for PF- and BAC-albuterol when stored at room temperature. Samples were incubated for 10 days in aerobic and anaerobic blood culture media to assess for bacterial growth. Stability of both albuterol formulations at high (0.67 mg/mL) and low (0.17 mg/mL) concentrations was determined at room temperature and under refrigeration. High performance liquid chromatography was used to evaluate samples up to 168 hours after preparation. RESULTS: No bacterial growth was witnessed from either albuterol formulation at day 10 of observation. Both high and low concentrations of PF-albuterol and BAC-albuterol were stable at room temperature for up to 168 hours. There were no differences in stability between storage conditions for any formulation. CONCLUSIONS: Under the current study conditions, there was no difference in sterility or stability for PF-albuterol when compared with BAC-albuterol. Thus, based on the findings of this study, PF-albuterol is sterile and stable up to 168 hours when stored at room temperature or under refrigerated conditions. The findings of this study do not confirm the therapeutic efficacy of PF-albuterol compared with BAC-albuterol for the treatment of asthma exacerbations. Further studies are warranted to determine the efficacy of PF-albuterol verses BAC-albuterol when used for CAA.

Gabapentin in Elastic Liposomes: Preparation, Characterization, Drug Release, and Penetration Through Porcine Skin.

In the outpatient pharmacy compounding, gabapentin, an anti-epileptic agent, has been commonly prescribed to be prepared alone or in combination with other agents in Pluronic lecithin organogel for transdermal pain management and palliative care. The objective of this study was to formulate and characterize gabapentin encapsulated elastic liposomes and then compare the gabapentin-based liposomes with compounded gabapentin-based Pluronic lecithin organogel regarding their efficiency in transdermal delivery of gabapentin. We demonstrated that our small 100-nm unilamellar vesicles of gabapentin encapsulated approximately 6.9 mg/mL Å} 0.2 mg/mL with up to 70% of encapsulation efficiency. Gabapentin released slowly from liposomes over 12 hours while it rapidly released from Pluronic lecithin organogel within 4 hours. We also showed that after 24 hours liposomes significantly accelerated the percutaneous penetration of gabapentin through the porcine skin leading to higher cumulative drug concentrations (~98% of drug permeated with a mean flux of 188.94 µg/cm2/h Å} 42.16 µg/cm2/h) as compared to Pluronic lecithin organogel (~55 % of drug permeated with a mean flux of 56.32 µg/cm2/h Å} 41.93 µg/cm2/h). In conclusion, the elastic liposomal formulation showed higher efficiency than the compounded Pluronic lecithin organogel in the transdermal delivery of gabapentin through porcine skin.

Sublingual spray drug delivery of ketorolac-loaded chitosan nanoparticles.

INTRODUCTION: The aim of this study was to investigate ketorolac (KT) systemic absolute bioavailability after sublingual (SL) administration in vivo to conscious rabbits. Furthermore, the study investigated the potential use of chitosan nanoparticles as a delivery system to enhance the systemic bioavailability of KT following SL administration. METHODS: Ketorolac-loaded chitosan nanoparticles were prepared through ionotropic gelation of chitosan with tripolyphosphate anions. The KT-nanoparticles were administered SL as a spray to rabbits and KT plasma concentration at predetermined time points was compared to SL spray administration of KT in solution. The concentrations of KT in plasma were analyzed by ultra-performance liquid chromatography mass spectroscopy (UPLC/MS). RESULTS: KT-loaded chitosan nanoparticles significantly (p < .05) enhanced systemic absorption with 97% absolute bioavailability as compared to 70% after SL administration of KT solution. CONCLUSIONS: The results of the present study suggest that SL absorption of KT illustrated flip-flop kinetics with prolonged persistence in the body compared to intravenous administration. Formulation of KT as chitosan nanoparticles has increased its systemic bioavailability after SL spray administration. The new delivery system could be an attractive approach for the delivery of KT.

Intranasal drug delivery of olanzapine-loaded chitosan nanoparticles.

The aim of this study was to investigate olanzapine (OZ) systemic absolute bioavailability after intranasal (i.n.) administration in vivo to conscious rabbits. Furthermore, the study investigated the potential use of chitosan nanoparticles as a delivery system to enhance the systemic bioavailability of olanzapine following intranasal administration. Olanzapine-loaded chitosan nanoparticles were prepared through ionotropic gelation of chitosan with tripolyphosphate anions and studied in terms of their size, drug loading, and in vitro release. The OZ nanoparticles were administered i.n. to rabbits, and OZ plasma concentration at predetermined time points was compared to i.n. administration of OZ in solution. The concentrations of OZ in plasma were analyzed by ultra performance liquid chromatography mass spectroscopy (UPLC/MS). OZ-loaded chitosan nanoparticles significantly (p < 0.05) enhanced systemic absorption with 51 ± 11.2% absolute bioavailability as compared to 28 ± 6.7% after i.n. administration of OZ solution. The results of the present study suggest that intranasal administration of OZ-loaded chitosan nanoparticles formulation could be an attractive modality for delivery of OZ systemically.