利用碳酸氢钠作为外加碳源在非无菌条件下培养微藻的潜力。

Potential of using sodium bicarbonate as external carbon source to cultivate microalga in non-sterile condition.

机构信息

Guangdong Key Laboratory of Fermentation and Enzyme Engineering, School of Biology and Biological Engineering, South China University of Technology, Guangzhou 510006, PR China.

出版信息

Bioresour Technol. 2018 Oct;266:109-115. doi: 10.1016/j.biortech.2018.06.076. Epub 2018 Jun 23.

DOI:10.1016/j.biortech.2018.06.076

PMID:29958148

Abstract

In this study, a saline-alkaline tolerant microalgal strain was isolated and identified as Chlorella sp. LPF. This strain was able to grow at pH values up to 10 and at salinities up to 5%, and tolerated to 80 g L of sodium bicarbonate. The utilization of bicarbonate as carbon source significantly promoted microalgal growth and lipid production. In the non-sterile cultivation supplying with 80 g L of sodium bicarbonate, the microalgal growth had no difference with their growth in the sterile medium; however, the bacterial growth was suppressed and the cell number decreased to low levels after six days cultivation. This study gives an insight into the potential that using high concentration of sodium bicarbonate as external carbon source to cultivate microalga in non-sterile condition, and suggests a possibility of using bicarbonate as growth promoter and antibacterial agent for the microalgal outdoor cultivation.

摘要

在这项研究中，分离并鉴定出一种耐盐碱性的微藻菌株，命名为 Chlorella sp. LPF。该菌株能在 pH 值高达 10 和盐度高达 5%的条件下生长，并能耐受 80g/L 的碳酸氢钠。将碳酸氢盐作为碳源显著促进了微藻的生长和脂质的产生。在非无菌培养条件下，当供应 80g/L 的碳酸氢钠时，微藻的生长与在无菌培养基中的生长没有区别；然而，细菌的生长受到抑制，六天后细胞数量减少到很低的水平。本研究深入了解了在非无菌条件下使用高浓度碳酸氢钠作为外部碳源培养微藻的潜力，并提出了将碳酸氢盐作为生长促进剂和抗菌剂用于微藻户外养殖的可能性。

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利用碳酸氢钠作为外加碳源在非无菌条件下培养微藻的潜力。

Potential of using sodium bicarbonate as external carbon source to cultivate microalga in non-sterile condition.

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