Dissolution properties of direcet compression tablets containing an agglomerated cellulose powder

Abstract

In previous studies a novel agglomerated cellulose powder was shown to own advantageous properties for direct compression. Due to the favourable particle and powder properties this material has good binding and disintegration ability in direct compression tablets. In this study the dissolution properties of direct compression tablets containing the agglomerated cellulose powder as a fillerbinder were evaluated. Especially the effect of the amount of cellulose, the porosity of tablets, the solubility of drug material and the amount and the amount and mixing method of lubricant, magnesium stearate were studied.

Tablets containing different amounts of cellulose with dicalcium phosphate as a filler and 10 wt % of water soluble sodium tolmetin as a drug were compressed at a constant pressure of 150 MPa. The breaking strength of tablets increased with increasing amounts of agglomerated cellulose powder. However, the dissolution of drug accelerated up to cellulose amount of 50 wt %. This was due to the ability of the agglomerated cellulose powder to enhance the water penetration into powder compact and the loosening of tablet structure, i.e. formation of cracks.

Tablets containing 20 wt % of cellulose material and 10 wt % of drug material were compressed to different porosities. Tablet porosity had no effect on dissolution of poorly water soluble tolfenamic acid. Also the dissolution of water soluble sodium tolmetin was only slightly affected by the porosity of tablets. This supports the suggested disintegrant mechanism of the agglomerated cellulose powder. The expansion of cellulose agglomerates, which have been deformed, under compression, is widely responsible for the disintegration of the tablets. An increase in the amount as well as in the mixing intensity of magncsium stearate decreased the dissolution of sodium tolmetin from tablets containing 20 wt % of agglomerated cellulose. However, the intrinsic wetting and dissolution phenomens were practically unchanged when the amount of magnesium stearate was below 2 wt %. Thus, the retardation of drug dissolution was acceptable at low lubricant concentrations.

The properties of tablets containing the agglomerated cellulose were compared to those containing microcrystalline cellulose. In all cases tablets containing the agglomerated cellulose powder liberated drug clearly faster and more properly than corresponding microcrystalline cellulose tablets.