期刊文献+

Enhanced production of glycyrrhetic acid 3-O-mono-β-D-glucuronide by fed-batch fermentation using p H and dissolved oxygen as feedback parameters 被引量:2

Enhanced production of glycyrrhetic acid 3-O-mono-β-D-glucuronide by fed-batch fermentation using p H and dissolved oxygen as feedback parameters
下载PDF
导出
摘要 Glycyrrhetic acid 3-O-mono-β-D-glucuronide (GAMG), the major functional ingredient in licorice, has widespread applications in food, pharmacy and cosmetics industry. The production of GAMG through Penicillium purpurogenum Li-3 cultivation was for the first time performed through both batch and fed-batch processes in bioreactors. In batch process, under optimal conditions (pH 5.0, temperature 32℃, agitation speed 100 r. rain 1), 3.55 g. L^-1 GAMG was obtained in a 2.5 L fermentor. To further enhance GAMG production, a fine fed-batch process was developed by using pH and DO as feedback parameters. Starting from 48 h, 100 m190 g-L 1 substrate Glycyrrhizin (GL) was fed each time when pH increased to above 5.0 and DO was increased to above 80%. This strategy can significantly enhance GAMG production: the achieved GL conversion was 95.34% with GAMG yield of 95.15%, and GAMG concentration was 16.62 g. L^-1 which was 5 times higher than that of batch. Then, a two-step separation strat- egy was established to separate GAMG from fermentation broth by crude extraction of 15 ml column packed with D10I resin followed by fine purification with preparative C18 chromatography. The obtained GAMG purity was 95.79%. This study provides a new insight into the industrial bioprocess of high-level GAMG production. Glycyrrhetic acid 3-O-mono-β-D-glucuronide(GAMG), the major functional ingredient in licorice, has widespread applications in food, pharmacy and cosmetics industry. The production of GAMG through Penicillium purpurogenum Li-3 cultivation was for the first time performed through both batch and fed-batch processes in bioreactors. In batch process, under optimal conditions(p H 5.0, temperature 32 °C, agitation speed 100 r·min-1), 3.55 g·L-1GAMG was obtained in a 2.5 L fermentor. To further enhance GAMG production, a fine fed-batch process was developed by using p H and DO as feedback parameters. Starting from 48 h, 100 ml 90 g·L-1substrate Glycyrrhizin(GL) was fed each time when p H increased to above 5.0 and DO was increased to above 80%. This strategy can significantly enhance GAMG production: the achieved GL conversion was 95.34% with GAMG yield of 95.15%, and GAMG concentration was 16.62 g·L-1which was 5 times higher than that of batch. Then, a two-step separation strategy was established to separate GAMG from fermentation broth by crude extraction of 15 ml column packed with D101 resin followed by fine purification with preparative C18 chromatography. The obtained GAMG purity was 95.79%. This study provides a new insight into the industrial bioprocess of high-level GAMG production.
机构地区 School of Life Science
出处 《Chinese Journal of Chemical Engineering》 SCIE EI CAS CSCD 2016年第4期506-512,共7页 中国化学工程学报(英文版)
基金 Supported by the National Natural Science Foundation of China(21176028 and21506011) the National Science Fund for Distinguished Young Scholars of China(21425624) Doctoral Fund of Ministry of Education of China(20121101110050)
关键词 Glycyrrhetic acid 3-O-mono-β -D-glucuronideFed-batch fermentationPenicillium purpurogenum Li-3D1 O1 resin separation 甘草次酸 反馈参数 pH值 发酵罐 生产 溶解氧 化妆品行业 生物反应器
  • 相关文献

参考文献2

二级参考文献82

  • 1Elam C C, Padr6 C E G, Sandrock G, Luzzi A, Lindblad P, Hagen E F. Realizing the hydrogen future: the International Energy Agency'sefforts to advance hydrogen energy technologies. International Journal of Hydrogen Energy, 2003, 28(6): 601- 607.
  • 2Nayak B K, Pandit S, Das D. Biohydrogen. In: Kennes C, Veiga ria C, editors. Air Pollution Prevention and Control. John Wiley & Sons Ltd, 2013, 345- 381.
  • 3Oh Y K, Raj S M, Jung G Y, Park S. Current status of the metabolic engineering of microorganisms for biohydrogen production. Bioresource Technology, 2011, 102(18): 8357 -8367.
  • 4Das D, Vezirolu T N. Hydrogen production by biological processes: A survey of literature. International Journal of Hydrogen Energy, 2001, 26(1): 13-28.
  • 5Levin D B, Pitt L, Love M. Biohydrogen production: Prospects and limitations to practical application. International Journal of Hydro- gen Energy, 2004, 29(2): 173 -185.
  • 6Jung G Y, Jung H O, Kim J R, Ahn Y, Park S. Isolation and characterization of Rhodopseudomonas palustris P4 which utilizes CO with the production of H2. Biotechnology Letters, 1999, 21(6): 525-529.
  • 7Benemann J. Hydrogen biotechnology: progress and prospects. Nature Biotechnology, 1996, 14(9): 1101- 1103.
  • 8Mohan S V, Srikanth S, Velvizhi G, Babu M L. Microbial Fuel Cells for Sustainable Bioenergy Generation: Principles and Perspective Applications. In: Gupta V K, Tuohy M G, eds. Biofuel Technologies. Bedim Springer Berlin Heidelberg, 2013, 335-368.
  • 9Momirlan M, Veziroglu T. Current status of hydrogen energy. Renewable & Sustainable Energy Reviews, 2002, 6(1-2): 141 179.
  • 10Lovley D R. The microbe electric: conversion of organic matter to electricity. Current Opinion in Biotechnology, 2008, 19(6): 564-571.

共引文献2

同被引文献14

引证文献2

二级引证文献25

相关作者

内容加载中请稍等...

相关机构

内容加载中请稍等...

相关主题

内容加载中请稍等...

浏览历史

内容加载中请稍等...
;
使用帮助 返回顶部