Development of sustained release gastro-retentive tablet formulation of nicardipine hydrochloride using quality by design (QbD) approach.

The objective of the present study was to develop a sustained release gastro-retentive (SRGR) tablet formulation of nicardipine hydrochloride (HCl) for once-a-day dosing using the quality by design (QbD) approach. The quality target product profile of nicardipine HCl SRGR tablet formulation was defined, and critical quality attributes (CQAs) were identified. Potential risk factors were identified using a fish bone diagram and failure mode effect analysis (FMEA) tool and screened by the Plackett-Burman design, and finally nicardipine HCl SRGR tablet formulation was optimized using the Box-Behnken design. The tablets were prepared by a direct compression technique using polymers such as hydroxypropylmethylcellulose (HPMC K15M), glyceryl behenate, alone or in combinations and other standard excipients. Sodium bicarbonate was incorporated as a gas-generating agent. The effects of polymers and sodium bicarbonate on the drug release profile and floating properties were investigated as these parameters are likely to affect the desired once-a-day dosing regimen and finally the therapeutic efficacy of SRGR drug delivery systems. It was observed that formulation variables X1: Glyceryl behenate (mg/tab) and X2: HPMC K15M (mg/tab) strikingly influenced the drug release (%) (Y1), whereas floating lag time (min) (Y2) was significantly impacted by the formulation variable X3: Sodium bicarbonate (mg/tab). A design space plot within which the CQAs remained unchanged was established at a lab scale. In conclusion, this study demonstrated the suitability of a glyceryl behenate-HPMC K15M polymer combination along with sodium bicarbonate to achieve SRGR tablet formulation for once-a-day dosing of nicardipine HCl using the systematic QbD approach.

Thermoreversible nanoethosomal gel for the intranasal delivery of Eletriptan hydrobromide.

The objective of the current study was to formulate and characterize thermoreversible gel of Eletriptan Hydrobromide for brain targeting via the intranasal route. Ethosomes were prepared by 3(2) factorial design with two independent variables (concentration of soya lecithin and ethanol) and two response variables [percent entrapment efficiency and vesicle size (nm)] using ethanol injection method. Formulated ethosomes were evaluated for preliminary microscopic examination followed by percent drug entrapment efficiency, vesicle size analysis, zeta potential, polydispersibility index and Transmission electron microscopy (TEM). TEM confirms spherical morphology of ethosomes, whereas Malvern zeta sizer confirms that the vesicle size was in the range of 191 ± 6.55-381.3 ± 61.0 nm. Ethosomes were incorporated in gel using poloxamer 407 and carbopol 934 as thermoreversible and mucoadhesive polymers, respectively. Ethosomal gels were evaluated for their pH, viscosity, mucoadhesive strength, in vitro drug release and ex vivo drug permeation through the sheep nasal mucosa. Mucoadhesive strength and pH was found to be 4400 ± 45 to 5500 ± 78.10 dynes/cm(2) and 6.0 ± 0.3 to 6.2 ± 0.1, respectively. In-vitro drug release from the optimized ethosomal gel formulation (G4) was found to be almost 100 % and ex vivo permeation of 4980 µg/ml with a permeability coefficient of 11.94 ± 0.04 × 10(-5) cm/s after 24 h. Histopathological study of the nasal mucosa confirmed non-toxic nature of ethosomal gels. Formulated EH loaded ethosomal thermoreversible gel could serve as the better alternative for the brain targeting via the intranasal route which in turn could subsequently improve its bioavailability.

Poloxamer 407-based intranasal thermoreversible gel of zolmitriptan-loaded nanoethosomes: formulation, optimization, evaluation and permeation studies.

Zolmitriptan is the drug of choice for migraine, but low oral bioavailability (<50%) and recurrence of migraine lead to frequent dosing and increase in associated side effects. Increase in the residence time of drug at the site of drug absorption along with direct nose to brain targeting of zolmitriptan can be a solution to the existing problems. Hence, in the present investigation, thermoreversible intranasal gel of zolmitriptan-loaded nanoethosomes was formulated by using mucoadhesive polymers to increase the residence of the drug into the nasal cavity. The preparation of ethosomes was optimized by using 3(2) factorial design for percent drug entrapment efficiency, vesicle size, zeta potential, and polydispersity index. Optimized formulation E6 showed the vesicle size (171.67 nm) and entrapment efficiency (66%) when compared with the other formulations. Thermoreversible gels prepared by using poloxamer 407 showed the phase transition temperature at 32-33 °C which was in line with the nasal physiological temperature. The optimized ethosomes were loaded into the thermoreversible mucoadhesive gel optimized by varying concentrations of poloxamer 407, carbopol 934, HPMC K100, and evaluated for gel strength, gelation temperature, mucoadhesive strength, in vitro drug release, and ex vivo drug permeation, where G3 and G6 were found to be optimized formulations. In vitro drug release was studied by different kinetic models suggested that G3 (n = 0.582) and G6 (n = 0.648) showed Korsemeyer-Peppas (KKP) model indicating non-Fickian release profiles. A permeation coefficient of 5.92 and 5.9 µg/cm(2) for G3 and G6, respectively, revealed very little difference in release rate after 24 h between both the formulations. Non-toxic nature of the gels on columnar epithelial cells was confirmed by histopathological evaluation.

Investigation and Optimization of the Effect of Polymers on Drug Release of Norfloxacin from Floating Tablets.

BACKGROUND: Norfloxacin is fluoroquinolone anti-infective used in the treatment of urinary tract infections, prostatitis, gonorrhea and genital tract infections. It has plasma half life of 3 to 4 h requiring multiple dosing in the treatment. Releaseretarding polymers can be used to modulate the drug release of norfloxacin. OBJECTIVES: The objective of this study was to investigate the effect of release-retarding polymers on the drug release of norfloxacin from floating tablets. MATERIAL AND METHODS: Norfloxacin was procured as a gift sample from Concept Pharma Ltd. Aurangabad (India) and HPMC K100M was procured as a gift sample from Colorcon Asia Pvt. Ltd., Goa (India). The tablets were prepared by direct compression method and various pharmaceutical parameters were evaluated. RESULTS: It was observed that all tablet formulations F1-F9 retained the drug release up to 12 h with good floating property but only Batch-F4 complies with the USP dissolution limits with a minimum floating lag time. The drug release kinetics were evaluated by the model-dependent (curve fitting) method using PCP Disso v3 software shows Batch-F4 shows to best fit with Peppas model for which R2 value was 0.9921 and the release exponent value was 0.6892. CONCLUSIONS: The drug release kinetics study indicates that the floating tablets release the drug by diffusion followed by erosion mechanism. Obtained in-vitro drug release data was analyzed by design expert software for drug release at first hour and at 12th h values and found that release the selected independent variables like HPMC K100M and sodium alginate concentration has a significant effect on drug release.

Recent trends and future of pharmaceutical packaging technology.

The pharmaceutical packaging market is constantly advancing and has experienced annual growth of at least five percent per annum in the past few years. The market is now reckoned to be worth over $20 billion a year. As with most other packaged goods, pharmaceuticals need reliable and speedy packaging solutions that deliver a combination of product protection, quality, tamper evidence, patient comfort and security needs. Constant innovations in the pharmaceuticals themselves such as, blow fill seal (BFS) vials, anti-counterfeit measures, plasma impulse chemical vapor deposition (PICVD) coating technology, snap off ampoules, unit dose vials, two-in-one prefilled vial design, prefilled syringes and child-resistant packs have a direct impact on the packaging. The review details several of the recent pharmaceutical packaging trends that are impacting packaging industry, and offers some predictions for the future.

Design and development of controlled porosity osmotic tablet of diltiazem hydrochloride.

The present work aims towards the design and development of extended release formulation of freely water-soluble drug diltiazem hydrochloride (DLTZ) based on osmotic technology by using controlled porosity approach. DLTZ is an ideal candidate for a zero-order drug delivery system because it is freely water-soluble and has a short half-life (2-3 h). Sodium chloride (Osmogen) was added to the core tablet to alter the solubility of DLTZ in an aqueous medium. Cellulose acetate (CA) and sorbitol were used as semipermeable membrane and pore former, respectively. The effect of different formulation variables namely concentration of osmogen in the core tablet, % pore former, % weight gain, pH of the dissolution medium and agitation intensity on the in vitro release was studied. DLTZ release was directly proportional to % pore former and inversely proportional to % weight gain. The optimized formulation (F8) delivered DLTZ independent of pH and agitation intensity for 12 h at the upper level concentration of % pore former (25% w/w) and middle level concentration of % weight gain (6% w/w). The comparative study of elementary osmotic pump (EOP) and controlled porosity osmotic pump revealed that it superior than conventional EOP and also easier and cost effective to formulate.