1. Enzyme Dehydration Using Microglassification™ Preserves the Protein's Structure and Function.
- Author
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Aniket, Gaul, David A., Bitterfield, Deborah L., Su, Jonathan T., Li, Victoria M., Singh, Ishita, Morton, Jackson, and Needham, David
- Subjects
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ENZYMES , *DEHYDRATION reactions , *PROTEIN structure , *MICRODROPLETS , *CHYMOTRYPSIN , *CATALASE , *HORSERADISH peroxidase - Abstract
Controlled enzyme dehydration using a new processing technique of Microglassification™ has been investigated. Aqueous solution microdroplets of lysozyme, α-chymotrypsin, catalase, and horseradish peroxidase were dehydrated in n-pentanol, n-octanol, n-decanol, triacetin, or butyl lactate, and changes in their structure and function were analyzed upon rehydration. Water solubility and microdroplet dissolution rate in each solvent decreased in the order: butyl lactate > n-pentanol > triacetin > n-octanol > n-decanol. Enzymes Microglassified™ in n-pentanol retained higher activity (93%-98%) than n-octanol (78%-85%) or n-decanol (75%-89%), whereas those Microglassified™ in triacetin (36%-75%) and butyl lactate (48%-79%) retained markedly lower activity. FTIR spectroscopy analyses showed α-helix to β-sheet transformation for all enzymes upon Microglassification™, reflecting a loss of bound water in the dried state; however, the enzymes reverted to native-like conformation upon rehydration. Accelerated stressed-storage tests using Microglassified™ lysozyme showed a significant ( p < 0.01) decrease in enzymatic activity from 46,560 ± 2736 to 31,060 ± 4327 units/mg after 3 months of incubation; however, it was comparable to the activity of the lyophilized formulation throughout the test period. These results establish Microglassification™ as a viable technique for enzyme preservation without affecting its structure or function. © 2014 Wiley Periodicals, Inc. and the American Pharmacists Association J Pharm Sci 104:640-651, 2015 [ABSTRACT FROM AUTHOR]
- Published
- 2015
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