Abstract. Developing amorphous solid dispersions of water-insoluble molecules using polymeric materials is a well-defined approach to improve the dissolution rate and bioavailability. While the selected polymer plays a vital role in stabilizing the amorphous solid dispersion physically, it is equally important to improve the dissolution profile by inhibiting crystallization from the supersaturated solution generated by dissolution of the amorphous material. Furthermore, understanding the mechanism of dissolution rate enhancement is of vital importance. In this work, wetting kinetics was taken up as an alternative approach for understanding the enhanced dissolution rate for amorphous solid dispersion of a poorly soluble drug. While cilostazol (CIL) was selected as the model drug, povidone (PVP), copovidone, and hypromellose (HPMC) were the polymers of choice. The concentrations against time profiles were evaluated for the supersaturated solutions of CIL in the presence and absence of the selected polymers. The degree of supersaturation increased significantly with increase in polymer content within the solid dispersion. While povidone was found to maintain the highest level of supersaturation for the greatest length of time both in dissolution and solution crystallization experiments, copovidone and hypromellose were found to be the less effective as crystallization inhibitor. The ability of polymers to generate and maintain supersaturated drug solutions was assessed by dissolution studies. The wetting kinetics was compared against the solid dispersion composition to establish a correlation with enhanced dissolution rate.
The objective of the present study was to define a systematic approach to design and prepare solid dispersions of poorly water-soluble drug. The systematic approach can be defined in four phases. In the first phase, glass forming ability is assessed, and in the second phase, probable excipients are screened. The screened excipients are evaluated (third phase) for glass transition temperatures (Tg) and miscibility studies according to Florey-Huggins interaction parameter. The predicted excipients are used to prepare the solid dispersion and evaluated for Tg and any interactions using Fourier transfer infrared studies (fourth phase), and the findings are correlated with phase three predictions. For this investigation, cilostazol (CIL) was selected as model drug, which was classified as a poor glass former. As per the physical chemical properties of CIL, ten excipients, both polymeric and non-polymeric, were selected and screened. Out of these, povidone, copovidone, hypromellose and Eudragit EPO were found theoretically miscible with CIL. After going through phase 2 to phase 4, only povidone, copovidone and hypromellose were confirmed as polymer of choice for preparing the solid dispersion of CIL with a prediction of better physical solid-state stability on the basis of good miscibility between drug and carrier.
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