Physicochemical and Microbiological Stability of Pyrimethamine in Paraben-free PCCA Base, SuspendIt.

Pyrimethamine is an antiparasitic compound available only in tablet form for oral administration. A review of the therapeutic uses of pyrimethamine reveals the need for flexibility in dosing. This flexibility is readily achieved using an oral liquid dosage form. However, no commercial liquid dosage form of pyrimethamine currently exists. Pyrimethamine is available commercially only as 25-mg tablets. An extemporaneously compounded suspension from pure drug powder would provide a flexible, customizable option to meet unique patient needs with convenient and accurate dosing options. The purpose of this study was to determine the physicochemical and microbiological stability of extemporaneously compounded pyrimethamine suspension in PCCA Base, SuspendIt. This base is a sugar-free, paraben-free, dye-free, and gluten-free thixotropic vehicle containing a natural sweetener obtained from the monk fruit. A robust stability-indicating high-performance liquid chromatographic assay for the determination of the chemical stability of pyrimethamine in PCCA SuspendIt was developed and validated. Suspensions of pyrimethamine were prepared in PCCA SuspendIt at a 2-mg/mL concentration, selected to provide flexibility in customizing individual doses. Samples were stored in amber plastic prescription bottles at two temperature conditions (5°C and 25°C). Samples were assayed initially, and on the following time points (days): 7, 14, 28, and 42. Physical data such as pH, viscosity, and appearance were also noted. Microbiological stability was tested. All measurements were obtained in triplicate. A stable extemporaneous product is defined as one that retains at least 90% of the initial drug concentration throughout the sampling period and is protected against microbial growth. The study showed that pyrimethamine concentrations did not go below 96% of the label claim (initial drug concentration) at both temperatures studied. No microbial growth was observed. pH values remained constant. The viscosity of the suspensions allowed easy re-dispersal of the drug particles upon shaking. This study demonstrates that pyrimethamine is physically, chemically, and microbiologically stable in PCCA SuspendIt for 42 days stored in the refrigerator and at room temperature, thus providing a viable, compounded alternative for pyrimethamine in a liquid dosage form.

Physicochemical and Microbiological Stability of Amitriptyline Hydrochloride Oral Liquid Dosage Forms in PCCA Base, SuspendIt.

Amitriptyline hydrochloride is indicated for the relief of symptoms of depression. A review of the therapeutic uses of amitriptyline hydrochloride reveals the need for flexibility in dosing. This flexibility is readily achieved using an oral liquid dosage form. However, no commercial liquid dosage form of amitriptyline currently exists. Amitriptyline hydrochloride is commercially available only as 10-mg, 25-mg, 50-mg, 75-mg, 100-mg, and 150-mg tablets. An extemporaneously compounded suspension from pure drug powder would provide a flexible, customizable option to meet unique patient needs with convenient and accurate dosing options. The purpose of this study was to determine the physicochemical and microbiological stability of extemporaneously compounded amitriptyline hydrochloride suspensions in PCCA Base, SuspendIt. This base is a sugar-free, paraben-free, dye-free, and gluten-free thixotropic vehicle containing a natural sweetener obtained from the monk fruit. The study design included two amitriptyline hydrochloride concentrations to provide stability documentation over a bracketed concentration range for eventual use by compounding pharmacists. A robust stability- indicating high-performance liquid chromatographic assay for the determination of the chemical stability of amitriptyline hydrochloride in PCCA SuspendIt was developed and validated. Suspensions of amitriptyline hydro- chloride were prepared in PCCA SuspendIt at 1-mg/mL and 5-mg/mL concentrations, selected to represent a range within which the drug is commonly dosed. Samples were stored in amber plastic prescription bottles at two temperature conditions (5°C and 25°C). Samples were assayed initially, and on the following time points (days): 7, 14, 28, 49, 63, 91, 119, and 185. Physical data such as pH, viscosity, and appearance were also noted. Microbiological stability was tested. All measurements were obtained in triplicate. A stable extemporaneous product is defined as one that retains at least 90% of the initial drug concentration throughout the sampling period and is protected against microbial growth. The study showed that amitriptyline hydrochloride concentrations did not go below 99.8% of the label claim (initial drug concentration) at both temperatures studied. No microbial growth was observed. The pH values remained constant. The viscosity of the suspensions allowed easy re-dispersal of the drug particles upon shaking. This study demonstrates that amitriptyline hydrochloride is physically, chemically, and microbiologically stable in PCCA SuspendIt for 185 days in the refrigerator and at room temperature, thus providing a viable, compounded alternative for amitriptyline hydrochloride in a liquid dosage form, with an extended beyond-use date to meet patient needs.

Physicochemical and Microbiological Stability of Extemporaneously Compounded Hydrocortisone Oral Suspensions in PCCA Base, SuspendIt.

Hydrocortisone is indicated in the treatment of primary or secondary adrenal insufficiency. The oral dosage regimen of hydrocortisone needs to be individualized in the treatment of congenital adrenal hyperplasia, especially in pediatric patients. A review of the therapeutic uses of hydrocortisone reveals the need for flexibility in dosing. This flexibility is readily achieved using an oral liquid dosage form. However, no commercial liquid dosage form of hydrocortisone currently exists. Hydrocortisone is commercially available as 5-mg, 10-mg, and 20-mg tablets. An extemporaneously compounded suspension from pure drug powder would provide a convenient option to meet unique patient needs. The purpose of this study was to determine the physicochemical and microbiological stability of extemporaneously compounded hydrocortisone suspensions in PCCA Base, SuspendIt. This base is a sugar-free, paraben-free, dye-free, and gluten-free thixotropic vehicle containing a natural sweetener obtained from the monk fruit. The study design included two hydrocortisone concentrations to provide stability documentation over a bracketed concentration range for eventual use by compounding pharmacists. A robust stability-indicating high-performance liquid chromatographic assay for the determination of the chemical stability of hydrocortisone in SuspendIt was developed and validated. Suspensions of hydrocortisone were prepared in SuspendIt at 1-mg/mL and 20-mg/mL concentrations, selected to represent a range within which the drug is commonly dosed. Samples were stored in plastic amber prescription bottles at two temperature conditions (5°C and 25°C). Samples were assayed initially and on the following days: 7, 15, 28, 45, 60, 91, 120, and 185. Physical data such as pH, viscosity, and appearance were also noted. Microbiological stability was tested. All measurements were obtained in triplicate. A stable extemporaneous product is defined as one that retains at least 90% of the initial drug concentration throughout the sampling period and is protected against microbial growth. The study showed that hydrocortisone concentrations did not go below 94% of the label claim (initial drug concentration) at both temperatures studied. No microbial growth was observed. Viscosity and pH values did not change significantly. This study demonstrates that hydrocortisone is physically, chemically, and microbiologically stable in SuspendIt for 185 days in the refrigerator and at room temperature, thus providing a viable, compounded alternative for hydrocortisone in a liquid dosage form, with an extended beyond-use date to meet patient needs.

Physicochemical and Microbiological Stability of Compounded Metronidazole Suspensions in PCCA SuspendIt.

Metronidazole is indicated for the treatment of trichomoniasis, amebiasis, and anaerobic bacterial infections. The dosage regimen of metronidazole needs to be individualized in the treatment of trichomoniasis, in patients with hepatic impairment, and in pediatric as well as geriatric patients. A review of the therapeutic uses of metronidazole reveals the need for flexibility in dosing. This flexibility is readily achieved using an oral liquid dosage form. However, no commercial liquid dosage form of metronidazole currently exists. Metronidazole is commercially available only as 250-mg and 500-mg film-coated tablets. An extemporaneously compounded suspension from pure drug powder or commercial tablets would provide a convenient option to meet unique patient needs. The purpose of this study was to determine the physicochemical and microbiological stability of extemporaneously compounded metronidazole suspensions in PCCA SuspendIt. This base is a sugar-free, paraben-free, dye-free, and gluten-free thixotropic vehicle containing a natural sweetener obtained from the monk fruit. The study design included two metronidazole concentrations to provide stability documentation over a bracketed concentration range for eventual use by compounding pharmacists. A robust stability-indicating ultra-performance liquid chromatographic assay for the determination of the chemical stability of metronidazole in PCCA SuspendIt was developed and validated. Suspensions of metronidazole were prepared in PCCA SuspendIt at 25-mg/mL and 50-mg/mL concentrations, selected to represent a range within which the drug is commonly dosed. Samples were stored in plastic amber prescription bottles at two temperature conditions (5ÆC and 25ÆC). Samples were assayed initially and on the following time points (days): 7, 14, 28, 42, 59, 90, 122, and 180. Physical data such as pH, viscosity, and appearance were also noted. Microbiological stability was also tested. All measurements were obtained in triplicate. A stable extemporaneous product is defined as one that retains at least 90% of the initial drug concentration throughout the sampling period and is protected against microbial growth. The study showed that metronidazole concentrations did not go below 97% of the label claim (initial drug concentration) at both temperatures studied. No microbial growth was observed. Viscosity and pH values also did not change significantly. This study demonstrates that metronidazole is physically, chemically, and microbiologically stable in PCCA SuspendIt for 180 days in the refrigerator and at room temperature, thus providing a viable, compounded alternative for metronidazole in a liquid dosage form, with an extended beyond-use-date to meet patient needs.

Physicochemical Stability of Compounded Allopurinol Suspensions in PCCA Base, SuspendIt.

Allopurinol is an orally administered inhibitor of xanthine oxidase used primarily in the treatment of hyperuricemia associated with gout. Allopurinol reduces serum and urinary uric acid concentrations. Its use should be individualized for each patient. The dosage of allopurinol to accomplish full control of gout and to lower serum uric acid to normal or near-normal levels varies with the severity of the disease, and needs to be flexible to permit precise, customized dose titration for individual patients. This flexibility is readily achieved using an oral liquid dosage form. However, no commercial liquid dosage form of allopurinol currently exists. Allopurinol is commercially available as 100-mg and 300-mg scored tablets. An extemporaneously compounded suspension from pure drug powder or commercial tablets would provide a convenient option to meet unique patient needs. The purpose of this study was to determine the physicochemical stability of extemporaneously compounded allopurinol suspensions in the PCCA Base SuspendIt. This base is a sugar-free, paraben-free, dye-free, and gluten-free thixotropic vehicle containing a natural sweetener obtained from the monk fruit. The study design included two allopurinol concentrations to provide stability documentation over a bracketed concentration range for eventual use by compounding pharmacists. A robust stability-indicating ultra-performance liquid chromatography assay for the determination of the chemical stability of allopurinol in SuspendIt was developed and validated. Suspensions of allopurinol were prepared in SuspendIt at 10.0-mg/mL and 20.0-mg/mL concentrations, selected to represent a range within which the drug is commonly dosed. Samples were stored in plastic amber prescription bottles at two temperature conditions (5°C and 25°C). Samples were assayed initially and at the following time points: 7 days, 14 days, 30 days, 45 days, 60 days, 88 days, 120 days, and 182 days. Physical data such as pH, viscosity, and appearance were also noted. All measurements were obtained in triplicate. A stable extemporaneous product is defined as one that retains at least 90% of the initial drug concentration throughout the sampling period. The study showed that allopurinol concentrations did not go below 93% of the label claim (initial drug concentration) at both temperatures studied. Viscosity and pH values also did not change significantly. This study demonstrates that allopurinol is physically and chemically stable in SuspendIt for 180 days in the refrigerator and at room temperature, thus providing a viable, compounded alternative for allopurinol in a liquid dosage form, with an extended beyond-use-date to meet patient needs.

Physicochemical Stability of Compounded Amlodipine Besylate Suspensions in PCCA Base, SuspendIt.

Amlodipine besylate is an antihypertensive agent recommended for the management of hypertension in children and adolescents. The commercially available 2.5-mg, 5-mg, and 10-mg amlodipine besylate tablets do not provide the necessary flexibility in dosing needed for treating children. This flexibility is readily achieved using an oral, liquid dosage form. However, no commercial liquid dosage form of amlodipine currently exists. An extemporaneously compounded suspension from pure drug powder or commercial tablets would provide a convenient option to meet unique patient needs. The purpose of this study was to determine the physicochemical stability of extemporaneously compounded amlodipine besylate suspensions in the PCCA Base, SuspendIt. This base is a sugar-free, paraben-free, dye-free, and gluten-free thixotropic vehicle containing a natural sweetener obtained from the monk fruit. The study design included two amlodipine besylate concentrations to provide stability documentation over a bracketed concentration range for eventual use by compounding pharmacists. A robust stabilityindicating high-performance liquid chromatographic assay for the determination of the chemical stability of amlodipine besylate in SuspendIt was developed and validated. Suspensions of amlodipine were prepared in SuspendIt at 0.5-mg/mL and 10.0-mg/mL concentrations, selected to represent a range within which the drug is commonly dosed. Samples were stored in plastic amber prescription bottles at two temperature conditions (5°C and 25°C). Samples were assayed initially, and at the following time points: 7 days, 14 days, 29 days, 46 days, 60 days, 90 days, 120 days, and 180 days. Physical data such as pH, viscosity, and appearance were also noted. All measurements were obtained in triplicate. A stable extemporaneous product is defined as one that retains at least 90% of the initial drug concentration throughout the sampling period. This study demonstrates that amlodipine besylate is physically and chemically stable in SuspendIt for 90 days in the refrigerator and 7 days at room temperature, retaining 90% of the label claim (initial drug concentration) at both concentrations. The pH values did not change significantly. The viscosity of the refrigerated samples at both concentrations decreased slightly, while that of the room temperature samples showed a marked increase in viscosity. This study provides a viable, compounded alternative for amlodipine in a liquid dosage form, with an adequate beyond-use-date to meet patient needs. The study further provides stability documentation over a bracketed amlodipine concentration range of 0.5 mg/mL to 10.0 mg/mL, allowing compounding pharmacists more flexibility in customizing their formulations.

Physicochemical Stability of Compounded Naltrexone Hydrochloride Solutions in PCCA Base SuspendIt.

Naltrexone hydrochloride is an orally active narcotic antagonist used to facilitate rapid transition from methadone maintenance. The dosing schedule of naltrexone hydrochloride in detoxification protocols needs to be flexible to permit precise, customized dose titration for individual patients. This flexibility is readily achieved using an oral liquid dosage form. However, no commercial liquid dosage form of naltrexone hydrochloride currently exists. Naltrexone hydrochloride is commercially available as a scored, filmcoated, 50-mg tablet. An extemporaneously compounded suspension from pure drug powder or commercial tablets would provide a convenient option to meet unique patient needs. The purpose of this study was to determine the physicochemical stability of extemporaneously compounded naltrexone hydrochloride solutions in PCCA base SuspendIt. This base is a sugar-free, paraben-free, dye-free, and gluten-free thixotropic vehicle containing a natural sweetener obtained from the monk fruit. The study design included two naltrexone hydrochloride concentrations to provide stability documentation over a bracketed concentration range for eventual use by compounding pharmacists. A robust stability-indicating HPLC assay for the determination of the chemical stability of naltrexone hydrochloride in SuspendIt was developed and validated. Solutions of naltrexone hydrochloride were prepared in SuspendIt at 0.5-mg/mL and 5.0-mg/mL concentrations, selected to represent a range within which the drug is commonly dosed. Samples were stored in plastic, amber prescription bottles at two temperature conditions (5°C and 25°C). Samples were assayed initially, and at the following time points: 7 days, 14 days, 29 days, 44 days, 61 days, 90 days, 120 days, and 180 days. Physical data such as pH, viscosity, and appearance were also noted. All measurements were obtained in triplicate. A stable extemporaneous preparation is defined as one that retains at least 90% of the initial drug concentration throughout the sampling period. The study showed that naltrexone hydrochloride concentrations did not go below 94% of the label claim (initial drug concentration) at both temperatures studied. Viscosity and pH values also did not change significantly. This study demonstrates that naltrexone hydrochloride is physically and chemically stable in SuspendIt for 180 days in the refrigerator and at room temperature, thus providing a viable, compounded alternative for naltrexone hydrochloride in a liquid dosage form, with an extended beyond-use date to meet patient needs.

Stability of Compounded Ursodiol Suspensions in PCCA Base, SuspendIt.

Ursodiol (ursodeoxycholic acid) is a nontoxic, naturally occurring bile acid that constitutes 1% to 2% of human bile. It suppresses hepatic synthesis of cholesterol, aids in the desaturation of biliary cholesterol, and aids in the dissolution of cholesterol gallstones. Ursodiol is commercially available as a 300-mg capsule and a 250-mg tablet. However, no commercial liquid dosage form of ursodiol exists. An extemporaneously compounded suspension from pure drug powder or commercial tablets/capsules would provide an alternative option to meet unique patient needs. The purpose of this study was to determine the physicochemical stability of extemporaneously compounded ursodiol suspensions in PCCA base SuspendIt. This base is a sugar-free, paraben-free, dye-free, and gluten-free thixotropic vehicle containing a natural sweetener obtained from the monk fruit. It thickens upon standing to minimize settling of any insoluble drug particles and becomes fluid upon shaking to allow convenient pouring during administration to the patient. The study design included two ursodiol concentrations to provide stability documentation over a bracketed concentration range for eventual use by compounding pharmacists. A robust, stability-indicating high-performance liquid chromatographic assay for the determination of the chemical stability of ursodiol in SuspendIt was developed and validated. Suspensions of ursodiol were prepared in SuspendIt at 50-mg/mL and 100-mg/mL concentrations, selected to represent a range within which the drug is commonly dosed. Samples were stored in plastic amber prescription bottles at two temperature conditions (5°C and 25°C). Samples were assayed initially and at the following time points: 7 days, 14 days, 30 days, 42 days, 59 days, 91 days, 120 days, and 181 days. Physical data such as pH, viscosity, and appearance were also noted. All measurements were obtained in triplicate. A stable extemporaneous product is defined as one that retains at least 90% of the initial drug concentration throughout the sampling period. The study showed that ursodiol concentration did not go below 97% of the label claim (initial drug concentration) at both temperatures studied. Viscosity and pH values also did not change significantly. This study demonstrates that ursodiol is physically and chemically stable in SuspendIt for 181 days in the refrigerator and at room temperature, thus providing a viable, compounded alternative for ursodiol in a liquid-dosage form, with an extended beyond-use-date to meet patient needs.

Physicochemical Stability of an Oral Suspension of Trimethoprim 20 mg/mL in Combination with Sulfadiazine 200 mg/mL in PCCA Base SuspendIt.

Trimethoprim is a diaminopyrimidine antibacterial agent that, like sulfonamides, inhibits bacterial folic acid synthesis, but at a different stage in the metabolic pathway. It has a similar spectrum of activity to the sulfonamides and is given by mouth or by injection, either alone or in conjunction with a sulfonamide, such as sulfadiazine. Sulfadiazine is a bacteriostatic antibacterial agent that interferes with folic acid synthesis in susceptible bacteria. The combination of the two drugs produces a synergistic effect against both Gram-positive and Gram-negative aerobic bacteria, by inhibiting enzymes in the folic acid pathways, which in turn inhibits bacterial thymidine synthesis. There are no published studies of the stability of the combination of trimethoprim and sulfadiazine in a liquid dosage form. An extemporaneously compounded suspension from pure drug powders or commercial tablets would provide an alternative option to meet unique patient needs. The purpose of this study was to determine the physicochemical stability of trimethoprim combined with sulfadiazine in PCCA base SuspendIt. PCCA base SuspendIt is a sugar-free, paraben-free, dye-free, and gluten-free thixotropic vehicle containing a natural sweetener obtained from the monk fruit. It thickens upon standing to minimize settling of any insoluble drug particles and becomes fluid upon shaking to allow convenient pouring during administration to the patient. A robust stability-indicating high-performance liquid chromatographic assay for the simultaneous determination of trimethoprim and sulfadiazine in SuspendIt was developed and validated. This assay was used to determine the chemical stability of both drugs in SuspendIt. Samples were prepared and stored under three different temperature conditions (5°C, 25°C, 40°C), and assayed using the high-performance liquid chromatographic assay at pre-determined intervals over an extended period of time as follows: 0, 7, 14, 30, 45, 60, 91, 120, and 182 days at each designated temperature. Physical data such as pH, viscosity, appearance, and average particle size were also monitored. The study showed that drug concentration did not go below 90% of the label claim (initial drug concentration) at room temperature and in the refrigerator. The pH values also did not change significantly. There was some variability in viscosity and average particle size. This study demonstrates that trimethoprim and sulfadiazine are physically and chemically stable in combination in SuspendIt for 182 days at room temperature and in the refrigerator, thus providing a viable, compounded alternative for both drugs in a liquid dosage form, with an extended beyond-use-date to meet patient needs.

Stability of Spironolactone Oral Suspension in PCCA Base, SuspendIt.

Spironolactone (Aldactone) is a potassium-sparing diuretic used to treat hypertension and heart failure and may also be used to treat edema resulting from kidney disease, low potassium levels, or excess aldosterone. No commercial liquid dosage form of spironolactone exists. An extemporaneously compounded suspension from pure drug powder or commercial tablets would provide an alternative option to meet unique patient needs. The purpose of this study was to determine the physicochemical stability of spironolactone in the PCCA base SuspendIt. This base is a sugar-free, paraben-free, dye-free, and gluten-free thixotropic vehicle containing a natural sweetener obtained from the monk fruit. It thickens upon standing to minimize settling of any insoluble drug particles and becomes fluid upon shaking to allow convenient pouring during administration to the patient. A robust stability-indicating highperformance liquid chromatographic assay for the determination of spironolactone in PCCA base SuspendIt was developed and validated. This assay was used to determine the chemical stability of the drug in SuspendIt. Samples were prepared and stored under three different temperature conditions (5°C, 25°C, 40°C) and assayed using the high-performance liquid chromatographic assay at pre-determined intervals over an extended period of time as follows: 0, 7, 14, 29, 46, 60, 90, 120, and 180 days at each designated temperature. Physical data such as pH, viscosity, and appearance were also monitored. The study showed that drug concentration did not go below 90% of the label claim (initial drug concentration) at all three temperatures studied. Viscosity and pH values also did not change significantly. This study demonstrates that spironolactone is physically and chemically stable in SuspendIt for 180 days in the refrigerator and at room temperature, thus providing a viable, compounded alternative for spironolactone in a liquid dosage form, with an extended beyond-use date to meet patient needs.

Stability of Clindamycin Hydrochloride in PCCA Base SuspendIt.

Clindamycin is an effective antibiotic in the treatment of infections caused by certain gram-positive and gram-negative anaerobic microorganisms. While manufactured forms of the drug for pediatric use are available, there are instances when a compounded liquid dosage form is essential to meet unique patient needs. The purpose of this study was to determine the chemical stability of clindamycin hydrochloride in the PCCA base SuspendIt, a sugar-free, paraben- free, dye-free, and gluten-free thixotropic vehicle containing a natural sweetener obtained from the monk fruit. It thickens upon standing to minimize settling of any insoluble drug particles and becomes fluid upon shaking to allow convenient pouring during administration to the patient. A robust stability-indicating high-performance liquid chromatographic assay for the determination of clindamycin hydrochloride in SuspendIt was developed and validated. This assay was used to determine the chemical stability of the drug in SuspendIt. Samples were prepared and stored under three different temperature conditions (5°C, 25°C, and 40°C), and assayed using the high-performance liquid chromatographic assay at pre-determined intervals over an extended period of time as follows: 7, 14, 30, 45, 60, 91, 120, and 182 days at each designated temperature. Physical data such as pH, viscosity, and appearance were also monitored. The study showed that drug concentration did not go below 90% of the label claim (initial drug concentration) at all three temperatures studied, barring isolated experimental errors. Viscosity and pH values also did not change significantly. Some variations in viscosity were attributed to the thixotropic nature of the vehicle. This study demonstrates that clindamycin hydrochloride is physically and chemically stable in SuspendIt for 182 days in the refrigerator and at room temperature, thus providing a viable, compounded alternative for clindamycin hydrochloride in a liquid dosage form, with an extended beyond-use date to meet patient needs.

Effect of squalane on mebendazole-loaded Compritol® nanoparticles.

The objective of this study is to develop nanostructured lipid formulations of Compritol for the delivery of mebendazole. The formulations were prepared with Compritol 888 ATO, squalane, and Pluronic F68. Nine batches with different amounts of modifier, squalane, and drug were prepared. The formulations were characterized by evaluating particle size, morphology, and zeta potential. The thermal properties of the formulations were analyzed by differential scanning calorimetry (DSC). The encapsulation efficiency of each formulation and the drug release rates from each formulation were quantified by UPLC. The particles were spherical and had median particle sizes between 300 and 600 nm (50th percentile). A linear relationship was observed between Compritol/squalane composition and the melting point of the mixture. The DSC scans of the formulations revealed some recrystallization of the drug from the formulations, and the amount of recrystallization correlated with the amount of squalane in the formulation. Approximately, 70% efficiency of encapsulation was observed in the formulations with 30% (w/w) squalane, and these formulations also had faster dissolution rates compared to the other formulations. Overall, the formulations with 30% squalane are the preferred formulation for future testing.

An ultra-high performance chromatographic method for the determination of artemisinin.

OBJECTIVE: The goal of this study is to develop an ultra-high performance liquid chromatographic method for the quantitative determination of artemisinin at very low concentrations using selective ion mass spectroscopic detection. MATERIALS AND METHODS: Separation was conducted using a C4 100 mm× 2.1 mm column, and the mobile phase consisted of an isocratic two-component system consisting of 60% of a 0.1% aqueous solution of formic acid and 40% acetonitrile at a flow rate of 0.4 ml/min. The drug was detected by means of an electrospray mass spectrometer with selective ion monitoring of the [M-H2O+H](+) with m/z of 265.3 in positive ion mode. RESULTS: The calibration curves of artemisinin obtained from the UPLC/MS system were linear in the three ranges analyzed, with a correlation coefficient of no less than 0.9996 for all sets of standards. The peak tailing factor for all measurements were ≤1.7. The method proved to have good repeatability and linearity. DISCUSSION: The described analytical method reached a LOQ of 0.010 µg/ml with an isocratic system and enables an analysis rate of 20 samples per hour. The linearity of the standards was excellent for all sets of standards analyzed. CONCLUSION: The method presented in this study provides a rapid and suitable means for the determination of artemisinin at very low concentrations. This is especially significant when performing dissolution studies where, due to the low solubility of artemisinin, a method that can measure the drug at nanogram levels is necessary.

Development and optimization of nanosomal formulations for siRNA delivery to the liver.

The objective of this study is to develop an effective siRNA delivery system for successful delivery to the liver for the treatment of HCV. Nanosize liposomes (nanosomes) have been prepared using a mixture of cholesterol and DOTAP. A functional siRNA was encapsulated into nanosomes following condensation with protamine sulfate. The delivery of siRNA was optimized in an in vitro cell culture system. The efficacy of the formulations was evaluated by measuring functional gene silencing and cytotoxicity. Encapsulation of siRNA ≥ 7.4 nM resulted in successful delivery of siRNA to nearly 100% of cells. The formulations containing lipid-to-siRNA ratio ≥ 10.56:1 instantly cleared approximately 85% of HCV while maintaining cell viability at about 90%. The formulations were sonicated to further reduce the particle size. The size of these formulations was decreased up to 100 nm. However, there were no significant changes observed in zeta potential, or in siRNA encapsulation and integrity following sonication. The sonicated formulations also showed higher liver hepatocytes deposition and gene silencing properties. This study therefore provides a novel approach of siRNA delivery to liver hepatocytes, which can also be applied to treat HCV in chronic liver diseases.

Stability of lyophilized siRNA nanosome formulations.

The goal of this study is to evaluate the stability of lyophilized siRNA formulations. The gene silencing efficiency of a stored lyophilized siRNA formulation (i.e. siRNA nanosomes) was evaluated in interferon-α (IFN-α) resistant hepatitis C virus (HCV) at different time points up to three months in an in vitro cell culture model and compared with freshly prepared siRNA formulations. Novel siRNA sequences were encapsulated within nanosize liposomes following condensation with protamine sulfate. The siRNA encapsulated nanosomes were lyophilized and stored at 4 °C for 3 months, along with liquid liposomes (L) and lyophilized liposome powder (P) which were subsequently used to prepare siRNA nanosomes (L) and siRNA nanosomes (P), respectively at different time points. Physiochemical and biological properties of all three formulations were compared at different time points up to 3 months. The particle size of the stored siRNA nanosomes (642 ± 25 nm) was considerably larger initially in comparison with the liquid liposomes (134 ± 5 nm) and lyophilized liposomes (118 ± 3). However, the particle size gradually became smaller over time (413 ± 128 nm by the third month). The zeta potential of all three formulations was initially very high (> +40 mV), followed by a gradual decrease over time. The amount of siRNA in the stored siRNA nanosomes decreased ∼18 % during the 3 month storage period (1.16 ± 0.03 nmol initially on day 1 vs. 0.95 ± 0.04 nmol after 3 months). With respect to biological potency, all three formulations were significantly effective to knock-down HCV throughout the storage time. The cell viability was well-maintained throughout this period. Thus, this study indicates that the stored lyophilized siRNA formulation is as effective as the fresh preparation and that long-term storage could be a viable option to treat deadly diseases such as cancer and viral infection.

Development of nanosomes using high-pressure homogenization for gene therapy.

OBJECTIVES: The aim of this project was to develop a novel lipid-based formulation suitable for gene therapy. METHODS: Novel nanosize liposome (nanosome) formulations containing pDNA (plasmid DNA) were developed using high-pressure homogenization (HPH). The effect of lipid concentration was studied at two levels: 3 mm and 20 mm. The preformed nanosomes were incubated for 18-20 h with pDNA or pDNA/protamine sulfate (PS) complex. The physical properties of the pDNA nanosomes were compared by particle size distribution and zeta-potential measurements. Their biological properties were also compared by pDNA efficiency of encapsulation/complexation, integrity, nuclease digestion, transfection efficiency and cell cytotoxicity. KEY FINDINGS: pDNA nanosomes prepared with 20 mM lipid (nanosomes:pDNA:PS at a ratio of 8.6:1:2) had particle sizes of 170-422 nm (90% confidence). The zeta-potential of the formulation was 49.2 +/- 1.5 mV, and the pDNA encapsulation/complexation efficiency was approximately 98%. pDNA nanosomes prepared with 3 mM lipid (nanosomes:pDNA PS at a ratio of 2.09:1:2) had particle sizes of 140-263 nm (90% confidence). The zeta-potential of this formulation was 36.4 +/- 1.2 mV, and the pDNA encapsulation/complexation efficiency was approximately 100%. However, a comparison of the efficiency of transfection indicated that pDNA nanosomes prepared with low-concentration lipids (3 mM) showed significantly higher transfection efficiency compared with the pDNA nanosomes prepared with high-concentration lipids (20 mM), as well as those prepared with Fugene-6 (a commercially available transfection reagent). This particular formulation (pDNA nanosomes, 3 mM lipids) also showed significantly less cytotoxicity compared with the other pDNA nanosome formulations. CONCLUSIONS: To conclude, these results indicate that condensing pDNA with PS followed by subsequent complexation with low-concentration nanosomes generated from HPH can produce a pDNA nanosome formulation that will boost transfection efficiency, while minimizing cytotoxicity. This new technology appears to be an efficient tool for future commercial or large-scale manufacture of DNA delivery systems for gene therapy.