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Lookup NU author(s): Dr Zeng-ping Chen, Emeritus Professor Julian Morris
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There is an increasing interest in using Raman spectroscopy to identify polymorphic forms and monitor phase changes in pharmaceutical products for quality control. Compared with other analytical techniques for the identification of polymorphs such as X-ray powder diffractometry and infrared spectroscopy, FT-Raman spectroscopy has the advantages of enabling fast, in situ, and nondestructive measurements of complex systems such as suspension samples. However, for suspension samples, Raman intensities depend on the analyte concentrations as well as the particle size, overall solid content, and homogeneity of the solid phase in the mixtures, which makes quantitative Raman analysis rather difficult. In this contribution, an advanced model has been derived to explicitiy account for the confounding effects of a sample's physical properties on Raman intensities. On the basis of this model, a unique calibration strategy called multiplicative effects correction (MEC) was proposed to separate the Raman contributions due to changes in analyte concentration from those caused by the multiplicative confounding effects of the sample's physical properties. MEC has been applied to predict the anhydrate concentrations from in situ FT-Raman measurements made during the crystallization and phase transition processes of citric acid in water. The experimental results show that MEC can effectively correct for the confounding effects of the particle size and overall solid content of the solid phase on Raman intensities and, therefore, provide much more accurate in situ quantitative predictions of anhydrate concentration during crystallization and phase transition processes than traditional PLS calibration methods. © 2008 American Chemical Society.
Author(s): Chen Z-P, Fevotte G, Caillet A, Littlejohn D, Morris J
Publication type: Article
Publication status: Published
Journal: Analytical Chemistry
Year: 2008
Volume: 80
Issue: 17
Pages: 6658-6665
Print publication date: 01/09/2008
ISSN (print): 0003-2700
ISSN (electronic): 1520-6882
Publisher: American Chemical Society
URL: http://dx.doi.org/10.1021/ac800987m
DOI: 10.1021/ac800987m
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