Nemichand B. Jain

Is Silicified Wet-Granulated Microcrystalline Cellulose Better than Original Wet-Granulated Microcrystalline Cellulose?

The purpose of this study was to investigate the effect of granulating water level on the physical-mechanical properties of microcrystalline cellulose (MCC) and silicified microcrystalline cellulose (SMCC). Granulations containing either MCC or SMCC were manufactured at different water levels using a high-shear mixer and were then tray-dried. The water level ranged from 0 to 100%. The granules were evaluated for size, granular and true density, porosity, flow, compactibility, compressibility, and strain-rate sensitivity index (SRS). Increasing the water level affected the size, increased the granular density and flow properties of the granules, and decreased the porosity and compactibility. The compactibilities for both materials were similar and acceptable at each granulating water level up to 40%. They both showed poor compactibility at higher water levels. Yield values and SRSs revealed that MCC and SMCC have similar compressibility, and that both exhibit a plastic component to the deformation process. The granulating water level had no statistically significant effect on the compressibility or the SRS for MCC or SMCC. SMCC did not offer practical advantages over MCC, other than better flow in the powder form, which could be attributed to slightly larger particle size and the presence of silicon dioxide in its structure.

Effects of Light Intensity, n-Alcohols, Water-Soluble Colorants, and Solution Viscosity on Photoisomerization of Sorivudine

Effects of various factors, such as light intensity, polarizability of n-alcohol solvents, addition of colorants, and viscosity of solutions on the kinetics of the photoisomerization of therapeutically effective E-isomer of sorivudine to its less effective Z-isomer were studied. Solutions of known concentrations of E-isomer or Z-isomer in water or in a series of n-alcohols were directly exposed to ultraviolet (UV) A light, or visible light of 400 or 900 foot candles (fc). E-isomer solutions containing various colorants at 1% w/v, or in a series of poloxamer solutions of different viscosities, were also exposed to 400 or 900 fc light. Using the stability-indicating HPLC assay, which showed mass-balance between the starting isomer and the converting isomer, the kinetics of photoisomerization were monitored. The photoisomerization reaction, which takes place on the vinyl side chain, was found to be a first-order reversible reaction. In water, the rate of conversion of E-isomer to Z-isomer was faster than that of Z-isomer to E-isomer, since, E-isomer with higher extinction coefficient absorbed substantially more light than Z-isomer. The rate of photoisomerization increased with the intensity of the visible light and was very rapid in the presence of UV A light (300 to 400 nm), which is to be expected based on the 239 nm and 283 nm absorption maxima of sorivudine. Addition of water-soluble colorants retarded the photoisomerization process significantly, especially as the maximum absorption wavelengths (λmax) of the colorants approached the UV region. The rate of photoisomerization increased with increasing polarizability (αs) of the n-alcohol solvents. Polarizable solvents such as alcohols could compensate for the electron density built up in the excited state, and thus facilitated the photoisomerization process. The rate of photoisomerization decreased as the viscosity of solution increased. This may be attributed to the fact that the twisting of the C=C bond in the excited state can be inhibited by the friction imposed by the viscous medium.