添加了厨余垃圾厌氧消化废水的海水使淡水湖泊中的脂质生产率提高了一倍。

Lipid productivity in limnetic is doubled by seawater added with anaerobically digested effluent from kitchen waste.

作者信息

Jiang Liqun, Zhang Lijie, Nie Changliang, Pei Haiyan

机构信息

1School of Environmental Science and Engineering, Shandong University, No. 27 Shanda Nan Road, Jinan, 250100 China.

Shandong Provincial Engineering Centre on Environmental Science and Technology, No. 17923 Jingshi Road, Jinan, 250061 China.

出版信息

Biotechnol Biofuels. 2018 Mar 14;11:68. doi: 10.1186/s13068-018-1064-5. eCollection 2018.

DOI:10.1186/s13068-018-1064-5

PMID:29563971

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5851330/

Abstract

BACKGROUND

An economical strategy for producing microalgae as biofuel feedstock is driven by the freshwater and nutrients input. In this study, seawater was applied to limnetic algal cultivation and the behavior of algae in seawater media was observed including growth, lipid synthesis, and ultrastructure. To make seawater cater algae, a kind of wastewater, anaerobically digested effluent from kitchen waste (ADE-KW), was used as nutrient sources.

RESULTS

Pure seawater cannot support the growth demand of freshwater microalga, due to high salinity and lack of nutrients. However, it is the conditions triggered the algae to synthesize lipids of 60%, double of lipid content in standard medium BG11. Introducing 3 or 5% ADE-KW (volume percentage) into seawater made algal growth reach the level attained in BG11, while lipid content compared favourably with the level (60%) in pure seawater. This method achieved the goal of fast growth and lipid accumulation simultaneously with the highest lipid productivity (19 mg/L day) at the exponential stage, while BG11 obtained 10.55 mg/L day at the stationary stage as the highest lipid productivity, almost half of that in seawater media. Moreover, the condition for highest lipid productivity enlarged algal cells compared to BG11. Under the condition for highest lipid productivity, SDEC-18 had enlarged cells and increased settling efficiency compared to BG11, which facilitated harvest in an energy saving way.

CONCLUSIONS

The results suggested that combining seawater with ADE-KW to cultivate microalgae had a double function: nutrients and water for algal growth, and high salinity for stimulating lipid accumulation. If this technology was operated in practice, freshwater and non-waste nutrient consumption would be completely obviated.

摘要

背景

一种将微藻作为生物燃料原料的经济策略受淡水和养分输入的驱动。在本研究中，海水被用于淡水藻类培养，并观察了藻类在海水培养基中的行为，包括生长、脂质合成和超微结构。为使海水适合藻类生长，一种废水，即厨余垃圾厌氧消化液（ADE-KW），被用作营养源。

结果

由于盐度高且缺乏养分，纯海水无法满足淡水微藻的生长需求。然而，正是这种条件促使藻类合成了60%的脂质，是标准培养基BG11中脂质含量的两倍。向海水中引入3%或5%（体积百分比）的ADE-KW可使藻类生长达到BG11中的水平，而脂质含量与纯海水中的水平（60%）相当。该方法实现了快速生长和脂质积累的目标，在指数期脂质生产率最高（19毫克/升·天），而BG11在稳定期脂质生产率最高为10.55毫克/升·天，几乎是海水培养基中的一半。此外，与BG11相比，脂质生产率最高的条件下藻类细胞增大。在脂质生产率最高的条件下，与BG11相比，SDEC-18细胞增大且沉降效率提高，这有利于以节能方式收获。

结论

结果表明，将海水与ADE-KW结合用于培养微藻具有双重作用：为藻类生长提供养分和水分，以及高盐度刺激脂质积累。如果该技术在实际中应用，将完全避免淡水和非废弃养分的消耗。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/34d3/5851330/1f7080a62256/13068_2018_1064_Fig1_HTML.jpg

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添加了厨余垃圾厌氧消化废水的海水使淡水湖泊中的脂质生产率提高了一倍。

Lipid productivity in limnetic is doubled by seawater added with anaerobically digested effluent from kitchen waste.

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