Improved lactic acid productivity by simultaneous recovery during fermentation using resin exchanger

Q3 Agricultural and Biological Sciences
Tanapawarin Rampai, S. Thitiprasert, Wasinee Boonkong, K. Kodama, Vasana Tolieng, N. Thongchul
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引用次数: 5

Abstract

Lactic acid is a versatile organic acid that can be used in various applications. One of the promising applications of lactic acid is in bioplastic industry. Lactic acid is used as  the monomer building block in polylactic acid synthesis. Unlike the existing applications in food and pharmaceutical industries in which lactic acid is used as the additive, it becomes the major raw material in polylactic acid production. This, therefore, raises the demand of  lactic acid and eventually increases the market price. In order to expedite the bioplastic industry, cost competitiveness to the existing plastic is a big concern. The cost effectiveness and process robustness are the key success factors in bioplastic industry. Currently, lactic  acid is produced via bacterial fermentation using the lime-based process. After fermentation, lactic acid was recovered from the fermentation broth by various techniques including solvent extraction, reactive distillation, ion exchanger, and electrodialysis. To achieve low  production cost, not only high fermentation rate is necessary, effective recovery process is also required. In this study, we attempted simultaneous recovery of lactic acid coupled with fermentation to drive the productivity and long-term operation in continuous culture. Anion exchange resin, Amberlite IRA-400, was selected for recovering lactic acid from the bacterial culture. The preliminary results in batch adsorption showed that among other resins studied, Amberlite IRA-400 provided the best separation efficiency. Further study on fixed bed adsorption and simultaneous fermentation and lactic acid recovery using this resin were conducted and the results will be discussed in this presentation.
利用树脂交换剂发酵过程中同时回收乳酸,提高乳酸产率
乳酸是一种用途广泛的有机酸,可用于各种用途。乳酸在生物塑料工业上的应用前景十分广阔。在聚乳酸的合成中,乳酸被用作单体构件。与目前在食品和制药工业中使用乳酸作为添加剂的应用不同,它成为生产聚乳酸的主要原料。因此,这提高了乳酸的需求,最终提高了市场价格。为了加快生物塑料产业的发展,对现有塑料的成本竞争力是一个大问题。成本效益和工艺稳健性是生物塑料工业成功的关键因素。目前,乳酸是通过细菌发酵使用石灰基工艺生产的。发酵后,通过溶剂萃取、反应蒸馏、离子交换和电渗析等多种技术从发酵液中回收乳酸。为了实现低生产成本,不仅需要高的发酵速率,还需要有效的回收工艺。在本研究中,我们试图同时回收乳酸与发酵相结合,以提高连续培养的生产率和长期运行。选择阴离子交换树脂Amberlite IRA-400用于乳酸的回收。间歇式吸附的初步结果表明,在所研究的树脂中,Amberlite IRA-400具有最佳的分离效率。进一步研究了该树脂的固定床吸附、同步发酵和乳酸回收,并将在本报告中讨论结果。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Asia-Pacific Journal of Science and Technology
Asia-Pacific Journal of Science and Technology Agricultural and Biological Sciences-Agricultural and Biological Sciences (all)
CiteScore
0.90
自引率
0.00%
发文量
0
审稿时长
8 weeks
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