利用植物废料生产中链羧酸盐：动力学研究及富集微生物群落的影响

Medium-chain carboxylates production from plant waste: kinetic study and effect of an enriched microbiome.

作者信息

Undiandeye Jerome, Gallegos Daniela, Bonatelli Maria L, Kleinsteuber Sabine, Bin-Hudari Mohammad Sufian, Abdulkadir Nafi'u, Stinner Walter, Sträuber Heike

机构信息

Department of Biochemical Conversion, DBFZ Deutsches Biomasseforschungszentrum Gemeinnützige GmbH, 04347, Leipzig, Germany.

Department of Chemical Engineering, University of Port Harcourt, PMB 5323, Port Harcourt, Nigeria.

出版信息

Biotechnol Biofuels Bioprod. 2024 Jun 12;17(1):79. doi: 10.1186/s13068-024-02528-y.

DOI:10.1186/s13068-024-02528-y

PMID:38867271

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11167882/

Abstract

BACKGROUND

The need for addition of external electron donors such as ethanol or lactate impairs the economic viability of chain elongation (CE) processes for the production of medium-chain carboxylates (MCC). However, using feedstocks with inherent electron donors such as silages of waste biomass can improve the economics. Moreover, the use of an appropriate inoculum is critical to the overall efficiency of the CE process, as the production of a desired MCC can significantly be influenced by the presence or absence of specific microorganisms and their metabolic interactions. Beyond, it is necessary to generate data that can be used for reactor design, simulation and optimization of a given CE process. Such data can be obtained using appropriate mathematical models to predict the dynamics of the CE process.

RESULTS

In batch experiments using silages of sugar beet leaves, cassava leaves, and Elodea/wheat straw as substrates, caproate was the only MCC produced with maximum yields of 1.97, 3.48, and 0.88 g/kgVS, respectively. The MCC concentrations were accurately predicted with the modified Gompertz model. In a semi-continuous fermentation with ensiled sugar beet leaves as substrate and digestate from a biogas reactor as the sole inoculum, a prolonged lag phase of 7 days was observed for the production of MCC (C6-C8). The lag phase was significantly shortened by at least 4 days when an enriched inoculum was added to the system. With the enriched inoculum, an MCC yield of 93.67 g/kgVS and a productivity of 2.05 gMCC/L/d were achieved. Without the enriched inoculum, MCC yield and productivity were 43.30 g/kgVS and 0.95 gMCC/L/d, respectively. The higher MCC production was accompanied by higher relative abundances of Lachnospiraceae and Eubacteriaceae.

CONCLUSIONS

Ensiled waste biomass is a suitable substrate for MCC production using CE. For an enhanced production of MCC from ensiled sugar beet leaves, the use of an enriched inoculum is recommended for a fast process start and high production performance.

摘要

背景

添加乙醇或乳酸等外部电子供体的需求削弱了用于生产中链羧酸盐（MCC）的链延长（CE）工艺的经济可行性。然而，使用含有固有电子供体的原料，如废弃生物质的青贮饲料，可以提高经济性。此外，使用合适的接种物对于CE工艺的整体效率至关重要，因为特定微生物的存在与否及其代谢相互作用会显著影响所需MCC的生产。此外，有必要生成可用于给定CE工艺的反应器设计、模拟和优化的数据。可以使用适当的数学模型来预测CE工艺的动态，从而获得此类数据。

结果

在以甜菜叶、木薯叶青贮饲料以及伊乐藻/小麦秸秆为底物的批次实验中，己酸盐是唯一产生的MCC，最大产量分别为1.97、3.48和0.88 g/kgVS。用修正的Gompertz模型准确预测了MCC浓度。在以青贮甜菜叶为底物、以沼气反应器的沼渣为唯一接种物的半连续发酵中，观察到MCC（C6 - C8）生产有7天的延长延迟期。当向系统中添加富集接种物时，延迟期至少显著缩短了4天。使用富集接种物时，MCC产量为93.67 g/kgVS，生产率为2.05 gMCC/L/d。不使用富集接种物时，MCC产量和生产率分别为43.30 g/kgVS和0.95 gMCC/L/d。较高的MCC产量伴随着较高丰度的毛螺菌科和真杆菌科。

结论

青贮废弃生物质是使用CE生产MCC的合适底物。为了从青贮甜菜叶中提高MCC产量，建议使用富集接种物以实现快速的工艺启动和高生产性能。

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利用植物废料生产中链羧酸盐：动力学研究及富集微生物群落的影响

Medium-chain carboxylates production from plant waste: kinetic study and effect of an enriched microbiome.

作者信息

机构信息

出版信息

BACKGROUND

RESULTS

CONCLUSIONS

背景

结果

结论

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