Jolly M. Sankalia

Papain entrapment in alginate beads for stability improvement and site-specific delivery: Physicochemical characterization and factorial optimization using neural network modeling

This work examines the influence of various process parameters (like sodium alginate concentration, calcium chloride concentration, and hardening time) on papain entrapped in ionotropically cross-linked alginate beads for stability improvement and site-specific delivery to the small intestine using neural network modeling. A 33 full-factorial design and feed-forward neural network with multilayer perceptron was used to investigate the effect of process variables on percentage of entrapment, time required for 50% and 90% of the enzyme release, particle size, and angle of repose. Topographical characterization was conducted by scanning electron microscopy, and entrapment was confirmed by Fourier transform infrared spectroscopy and differential scanning calorimetry. Times required for 50% (T50) and 90% (T90) of enzyme release were increased in all 3 of the process variables. Percentage entrapment and particle size were found to be directly proportional to sodium alginate concentration and inversely proportional to calcium chloride concentration and hardening time, whereas angle of repose and degree of cross-linking showed exactly opposite proportionality. Beads with >90% entrapment and T50 of <10 minutes could be obtained at the low levels of all 3 of the process variables. The inability of beads to dissolve in acidic environment, with complete dissolution in buffer of pH≥6.8, showed the suitability of beads to release papain into the small intestine. The shelf-life of the capsules prepared using the papain-loaded alginate beads was found to be 3.60 years compared with 1.01 years of the marketed formulation. It can be inferred from the above results that the proposed methodology can be used to prepare papain-loaded alginate beads for stability improvement and site-specific delivery.

Effect of hydrophilic swellable polymers on dissolution enhancement of carbamazepine solid dispersions studied using response surface methodology.

The objective of this work was to study dissolution enhancement efficiency and solid dispersion formation ability of hydrophilic swellable polymers such as sodium carboxymethyl cellulose (Na-CMC), sodium starch glycolate (SSG), pregelatinized starch (PGS), and hydroxypropylmethyl cellulose (HPMC) with carbamazepine using 32 full factorial design for each of the polymers. Solid dispersions of carbamazepine were prepared using solvent evaporation method with around 70% solvent recovery. The independent variables were the amount of polymer and organic solvent. The dependent variables assessed were percentage drug dissolved at various time points and dispersion efficiency (ie, in terms of particle size of solid dispersion). Solid dispersions were evaluated for percentage drug dissolved, wettability, differential scanning calorimetry, scanning electron microscopy, and angle of repose. Multiple linear regression of results obtained led to equations, which generated contour plots to relate the dependent variables. Similarity factor and mean dissolution time were used to compare dissolution patterns obtained in distilled water and simulated gastric fluid United States Pharmacopeia (USP) XXVI of pH 1.2. Maximum drug dissolution was obtained with polymer order Na-CMC>SSG>PGS>HPMC. Particle size of drug was reduced ≈ 10–15, 3–5, 5–7, and 10–25 times in Na-CMC, SSG, PGS, and HPMC solid dispersions, respectively; whereas wettability of solid dispersions was found in the order of Na-CMC>HPMC>PGS>SSG. Angle of repose was found to be in the range of 29° to 35° for all solid dispersions, which shows good flowability characteristics. HPMC showed increase in drug dissolution up to an optimized level; however, furthers increase in its concentration decreased drug dissolution.

Effect of pH on In Vitro Permeation of Ondansetron Hydrochloride Across Porcine Buccal Mucosa

The influence of drug concentration, pH in donor chamber, and 1-octanol/buffer partition coefficient on transbuccal permeation of ondansetron hydrochloride (pKa, 7.4) across porcine buccal mucosa was studied by using an in-line Franz type diffusion cell at 37°C. The pH was adjusted to several values and the solubility of the drug in different pH was measured. Solubility of ondansetron hydrochloride decreases with increasing pH. The permeability of the drug was evaluated at different donor pH and drug concentrations. Permeability of un-ionized (Pu) and ionized (Pi) species of drug was calculated by fitting the data to a mathematical model. The steady state flux increased linearly with the donor concentration (r2 = 0.9843) at pH 7.4. The permeability coefficient and the partition coefficient of the drug increased with increasing pH. The values of Pu and Pi were 4.86 × 10− 6 cm/sec and 7.18 × 10− 7 cm/sec, respectively. The observed permeability coefficients and the permeability coefficients calculated from the mathematical model at various pH showed good linearity (r2 = 0.9799). The total permeability coefficient increased with increasing the fraction of un-ionized form of the drug. The drug permeated through buccal mucosa by a passive diffusion process. The non-ionized species of drug penetrated well through buccal mucosa and the permeation was a function of pH. Transbuccal delivery is a potential route for the administration of ondansetron hydrochloride.

Spectroscopic Determination of Trace Amounts of Selenium(IV) in Multivitamin with Multimineral Formulations Using 3,3′‐Diaminobenzidine Hydrochloride

Abstract A simple, rapid, sensitive, and selective spectroscopic technique has been developed for the determination of Se(IV) from multivitamin with multimineral pharmaceutical formulations. The method is based on the formation of stable yellow‐colored piazselenol complex by reaction of Se(IV) with 3,3′‐diaminobenzidine hydrochloride, which is then extracted in toluene and detected spectroscopically at 434 nm. The different analytical parameters affecting the method such as dye concentration, pH for extraction, solvent for extraction, stability of colored complex, Se(IV):dye ratio, and so forth, have been optimized. The method was found to be linear over an analytical range of 1–7 μg mL−1 with correlation coefficient of 0.9994. Limit of detection, limit of quantitation, and Sandells sensitivity were found to be 0.1665 μg mL−1, 0.5549 μg mL−1, and 0.0339 μg cm−2, respectively. The method was validated and found to be suitable for estimation of Se(IV) species in tablets and capsules. Satisfactory recovery from the spiked samples of standard Se(IV) suggests no interference of any excipients. The influence of foreign ions at the normal formulation levels are readily tolerated, and interference from Fe(II) ion is circumvented by the addition of EDTA. The developed method was compared with atomic absorption spectroscopy by t‐test, and no significant difference was observed.