In situ monitoring of stirring effects on polymorphic transformations during cooling crystallization of carbamazepine

Sypek, Katarzyna and Burns, Iain and Florence, Alastair J. and Sefcik, Jan (2012) In situ monitoring of stirring effects on polymorphic transformations during cooling crystallization of carbamazepine. Crystal Growth and Design, 12 (10). pp. 4821-4828. ISSN 1528-7483 (https://doi.org/10.1021/cg3005689)

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Abstract

The influence of experimental conditions on polymorphic outcome and transformations during cooling crystallization of carbamazepine (CBZ) from anhydrous ethanol has been investigated. Stirring was found to be the most important controlling factor for the initial polymorphic outcome in solutions prepared using commercial CBZ powder. For quiescent conditions, a few large crystals of the metastable trigonal α form (II) initially appeared, undergoing subsequent slow transformation into the stable P-monoclinic β form (III). Under sufficiently vigorous stirring, the induction times observed were clearly defined by the onset of turbidity, which was due to formation of a large number of small form III prismatic crystals. In experiments with solutions prepared by using recrystallized CBZ, significantly shorter induction times were observed under stirring conditions: a large number of small form II needle-shaped crystals initially formed at the onset of turbidity and then relatively rapidly transformed to small crystals of form III. This indicates a possible effect of impurities in the commercial CBZ powder inhibiting rapid nucleation of form II under stirring conditions. In situ monitoring of CBZ polymorphic outcome was performed using custom-built experimental setup for simultaneous measurement of intensity of transmitted and scattered light. Distinct pathways in two-variable intensity plots were observed for formation of each respective polymorph under stirring conditions. The same monitoring technique should be readily applicable to other systems.