To make rapidly disintegrating tablets with sufficient mechanical integrity as well as a pleasant taste, microcrystalline cellulose (MCC), Tablettose (TT), and crosslinked sodium carboxymethyl cellulose (Ac-di-sol) or erythritol (ET) were formulated. Tablets were made by a direct compression method (I). Tablet properties such as porosity, tensile strength, and disintegration time were determined. The tensile strength and disintegration time were selected as response variables, tablet porosity and parameters representing the characteristics of formulation were selected as controlling factors, and their relation was determined by the polynomial regression method. Response surface plots and contour plots of tablet tensile strength and disintegration time were also constructed. The optimum combination of tablet porosity and formulation was obtained by superimposing the contour diagrams of tablet tensile strength and disintegration time. Rapidly disintegrating tablets with durable structure and desirable taste could be prepared within the obtained optimum region.
To make rapidly disintegrating tablets with sufficient mechanical integrity, tablets were prepared by compressing wet granules under low compression force and then drying the resulting wet mass in a circulating-air oven (wet compression method). Lactose with various particle sizes was used as the excipient, and water was used as a wetting agent. The effect of drying time, compression force, size of lactose particles, and moisture content of wet granules on tablet properties indicated that the formation and disintegration time of tablets were related to the effect of the formation of solid bridges between lactose particles. By optimizing compression force, size of lactose particles, and moisture content of the granules, tablets meeting tensile strength greater than 0.5 MPa and disintegration time shorter than 15 s were obtained by the wet compression method.
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