Dissolution kinetics of single crystals of alpha-lactose monohydrate

Dissolution kinetics of single crystals of alpha-lactose monohydrate

The dissolution kinetics of alpha-lactose monohydrate (alphaLM) single crystals were studied by a flow-cell method at different undersaturations. Linear dissolution profiles were obtained as a function of time for all the faces except the (010) face. The dissolution rates, obtained from these profil...

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Bibliographic Details
Published in:Journal of pharmaceutical sciences Vol. 91; no. 10; p. 2166
Main Authors: Raghavan, S L, Ristic, R I, Sheen, D B, Sherwood, J N
Format: Journal Article
Language:English
Published: United States 01-10-2002
Subjects:
Crystallization
Kinetics
Lactose - chemistry
Lactose - radiation effects
Molecular Conformation
Solubility
Temperature
X-Ray Diffraction
X-Rays
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Description
Summary:The dissolution kinetics of alpha-lactose monohydrate (alphaLM) single crystals were studied by a flow-cell method at different undersaturations. Linear dissolution profiles were obtained as a function of time for all the faces except the (010) face. The dissolution rates, obtained from these profiles, were anisotropic and varied considerably with undersaturation. At low undersaturations (0-2%), the order of dissolution rate was (110) > (100) > (011) = (110) > (010). This order changed with increasing undersaturation (>5%) to (011) >> (100) > (110) > (110) > (010). In alphaLM crystals in which lattice strain was induced by synchrotron X-irradiation, the rates of dissolution of all faces increased with increasing strain. The increase was less significant for the (011) faces than for the remainder. Under this constraint, the (010) face became the fastest dissolving one and the [011]face became the slowest one. The results of all experiments are explained on the basis that although dislocations may act as initiating dissolution centers at very low undersaturations, these sources rapidly give way to two-dimensional nucleation of randomly distributed dissolution sites as the undersaturation is increased. Under these conditions, which better reflect the normal dissolution processes of materials, bulk lattice strain plays the most significant role in defining the dissolution rate. The results show a potential route to the controlled engineering of the dissolution behavior of crystalline materials.
ISSN:0022-3549
DOI:10.1002/jps.10208