ABSTRACT
The dissolution anisotropy of paracetamol crystals grown in the presence and absence of the molecularly similar additive, p-acetoxyacetanilide (PAA) was studied under controlled conditions using a single crystal dissolution method in undersaturated aqueous solutions. Linear dissolution rates were determined for all the major habit faces by measuring their movement (regression) with time in a flow cell using a microscope. The rates of dissolution of particular faces of the pure material were distinctly different in crystals of different morphology grown at different supersaturations. The dissolution rates of [001] and [110] faces of crystals grown in the presence of PAA (6.02% w/w in solution) are higher than those of pure paracetamol. The results correlate with the distribution of strain in the crystal and support the concept that integral strain increases the solubility and hence the dissolution rate of the material. The mechanism of the dissolution process at the [001], [201;] and [110] faces was defined using optical microscopy and X-ray topography. At all undersaturations above 1% the dissolution studies yielded well developed, structurally oriented, etch pits on both [001] and [201;] faces while on the [110] face rough shallow etch pits were observed. On all three faces, this etch-pitting was considerably more widespread than the dislocation content of the sector and probably reflects a 2-dimensional nucleation process rather than a dislocation controlled mechanism.
