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http://dx.doi.org/10.4014/jmb.1904.04058

Enhanced Biotransformation Productivity of Gamma-Decalactone from Ricinoleic Acid Based on the Expanded Vermiculite Delivery System  

Guan, Shimin (Department of Biological Engineering, Shanghai Institute of Technology)
Rong, Shaofeng (Department of Biological Engineering, Shanghai Institute of Technology)
Wang, Mengze (Department of Biological Engineering, Shanghai Institute of Technology)
Cai, Baoguo (Department of Biological Engineering, Shanghai Institute of Technology)
Li, Qianqian (Department of Biological Engineering, Shanghai Institute of Technology)
Zhang, Shuo (Department of Biological Engineering, Shanghai Institute of Technology)
Publication Information
Journal of Microbiology and Biotechnology / v.29, no.7, 2019 , pp. 1071-1077 More about this Journal
Abstract
Natural gamma-decalactone (GDL) produced by biotransformation is an essential food additive with a peach-like aroma. However, the difficulty of effectively controlling the concentration of the substrate ricinoleic acid (RA) in water limits the biotransformation productivity, which is a bottleneck for industrialization. In this study, expanded vermiculite (E-V) was utilized as a carrier of RA to increase its distribution in the medium. E-V and three commonly used organic compounds were compared with respect to their effects on the biotransformation process, and the mechanism was revealed. Scanning electron microscopy, Fourier transform infrared spectroscopy and thermogravimetric analysis indicated that RA was physically adsorbed onto the surface of and inside E-V instead of undergoing a chemical reaction, which increased the opportunity for interactions between microorganisms and the substrate. The highest concentration of GDL obtained in the medium with E-V was 6.2 g/l, which was 50% higher than that in the reference sample. In addition, the presence of E-V had no negative effect on the viability of the microorganisms. This study provides a new method for producing natural GDL through biotransformation on an industrial scale.
Keywords
Biotransformation; gamma-decalactone; ricinoleic acid; expanded vermiculite;
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