富集同源丙酮,将H2/CO2转化为酸和乙醇,同时产生甲烷

IF 3.9 4区 生物学 Q2 BIOTECHNOLOGY & APPLIED MICROBIOLOGY
Yaxue He, Chiara Cassarini, Piet N.L. Lens
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引用次数: 2

摘要

通过应用预期产生乙酸、丁酸和乙醇的操作条件,在连续气体供给的上流厌氧污泥反应器中富集厌氧颗粒污泥以利用H2/CO2。发现了三个发酵阶段:第一阶段乙酸积累,最高浓度为35mM,pH从最初的6降至4.5。在第二阶段,H2/CO2被100%H2取代以诱导溶剂生成,而丁酸的最高浓度为2.5 mM。在第三阶段,添加10µM钨(W),异戊酸、戊酸和己酸的pH值为4.5–5.0。然而,在用来自生物反应器的富集污泥接种的分批试验中(第70天),甲烷的产生发生在pH 6。与富集污泥的外源10、30和45mM乙酸盐相比,外源15mM乙酸盐的添加提高了H2和CO2的消耗率。使用H2作为电子供体的外源乙酸盐未能通过富集的乙酸根转化为乙醇。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Enrichment of homoacetogens converting H2/CO2 into acids and ethanol and simultaneous methane production

Enrichment of homoacetogens converting H2/CO2 into acids and ethanol and simultaneous methane production

An anaerobic granular sludge was enriched to utilize H2/CO2 in a continuous gas-fed up-flow anaerobic sludge reactor by applying operating conditions expected to produce acetic acid, butyric acid, and ethanol. Three stages of fermentation were found: Stage I with acetic acid accumulation with the highest concentration of 35 mM along with a pH decrease from initial 6 to 4.5. In Stage II, H2/CO2 was replaced by 100% H2 to induce solventogenesis, whereas butyric acid was produced with the highest concentration of 2.5 mM. At stage III with 10 µM tungsten (W) addition, iso-valeric acid, valeric acid, and caproic acid were produced at pH 4.5–5.0. In the batch tests inoculated with the enriched sludge taken from the bioreactor (day 70), however, methane production occurred at pH 6. Exogenous 15 mM acetate addition enhanced both the H2 and CO2 consumption rate compared to exogenous 10, 30, and 45 mM acetate by the enriched sludge. Exogenous acetate was failed to be converted to ethanol using H2 as electron donor by the enriched acetogens.

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来源期刊
Engineering in Life Sciences
Engineering in Life Sciences 工程技术-生物工程与应用微生物
CiteScore
6.40
自引率
3.70%
发文量
81
审稿时长
3 months
期刊介绍: Engineering in Life Sciences (ELS) focuses on engineering principles and innovations in life sciences and biotechnology. Life sciences and biotechnology covered in ELS encompass the use of biomolecules (e.g. proteins/enzymes), cells (microbial, plant and mammalian origins) and biomaterials for biosynthesis, biotransformation, cell-based treatment and bio-based solutions in industrial and pharmaceutical biotechnologies as well as in biomedicine. ELS especially aims to promote interdisciplinary collaborations among biologists, biotechnologists and engineers for quantitative understanding and holistic engineering (design-built-test) of biological parts and processes in the different application areas.
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