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氮源和中和剂对龙爪稷麸皮水解物生产D-乳酸的影响:比较研究与动力学分析

Effect of nitrogen sources and neutralizing agents on D-lactic acid production from Kodo millet bran hydrolysate: comparative study and kinetic analysis.

作者信息

Balakrishnan Rengesh, Tadi Subbi Rami Reddy, Pavan Allampalli Satya Sai, Sivaprakasam Senthilkumar, Rajaram Shyamkumar

机构信息

1Department of Biotechnology, Kamaraj College of Engineering and Technology, K.Vellakulam, Madurai District, 625701 Tamilnadu India.

2BioPAT Laboratory, Department of Biosciences and Bioengineering, Indian Institute of Technology Guwahati, Guwahati, 781039 Assam India.

出版信息

J Food Sci Technol. 2020 Mar;57(3):915-926. doi: 10.1007/s13197-019-04124-7. Epub 2019 Nov 2.

DOI:10.1007/s13197-019-04124-7
PMID:32123412
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7026326/
Abstract

D-lactic acid (DLA) serves as a key monomer enhancing both the mechanical and thermal properties of Poly(lactic) acid films and coatings, extensively used in the food packaging industry. Economically viable production of optically pure DLA by NBRC3202 was achieved using a low-cost carbon source, Kodo millet bran residue hydrolysate (KMBRH) and nitrogen source (casein enzyme hydrolysate (CEH) resulting in a high DLA yield of 0.99 g g and KMBRH conversion to final product (95.3%). The optimum values for kinetic parameters viz., specific growth rate (0.11 h), yield coefficient of biomass on KMBRH (0.10 g g) and DLA productivity (0.45 g L h) were achieved at 5 g L of CEH dosage under controlled pH environment. A comparative study and kinetic analysis of different neutralizing agents (NaOH, NH, CaCO and NaHCO) under pH controlled environment for KMBRH based DLA production was addressed effectively through bioreactor scale experiments. Maximum cell concentration (1.29 g L) and DLA titer (45.08 g L) were observed with NH as a neutralizing agent. Kinetic analysis of DLA production under different neutralization agents demonstrated that the logistic derived model predicted biomass growth, KMBRH consumption and DLA production efficiently (  > 0.92).

摘要

D-乳酸(DLA)是一种关键单体,可增强聚乳酸薄膜和涂层的机械性能和热性能,广泛应用于食品包装行业。日本生物科学与人类技术研究所3202菌株利用低成本碳源——黍米麸皮残渣水解物(KMBRH)和氮源(酪蛋白酶水解物(CEH))实现了光学纯DLA的经济可行生产,DLA产量高达0.99 g/g,KMBRH转化为最终产物的转化率为95.3%。在受控pH环境下,当CEH用量为5 g/L时,动力学参数的最佳值分别为:比生长速率(0.11 h)、基于KMBRH的生物量产率系数(0.10 g/g)和DLA生产率(0.45 g/L·h)。通过生物反应器规模实验,有效地开展了在pH受控环境下基于KMBRH生产DLA时不同中和剂(NaOH、NH₃、CaCO₃和NaHCO₃)的比较研究和动力学分析。以NH₃作为中和剂时,观察到最大细胞浓度(1.29 g/L)和DLA滴度(45.08 g/L)。对不同中和剂条件下DLA生产的动力学分析表明,逻辑推导模型能够有效地预测生物量生长、KMBRH消耗和DLA生产(R²>0.92)。

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