Microaerobic biodegradation of aromatic hydrocarbon mixtures: strategies for efficient nitrate and oxygen dosage

IF 3.9 3区生物学 Q2 BIOTECHNOLOGY & APPLIED MICROBIOLOGY

Applied Microbiology and Biotechnology Pub Date : 2025-01-16 DOI:10.1007/s00253-024-13388-9

Dilan Camille Aydin, Andrea Aldas-Vargas, Tim Grotenhuis, Huub Rijnaarts

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引用次数: 0

Abstract

The biodegradation of organic aromatic compounds in subsurface environments is often hindered by limited dissolved oxygen. While oxygen supplementation can enhance in situ biodegradation, it poses financial and technical challenges. This study explores introducing low-oxygen concentrations in anaerobic environments for efficient contaminant removal, particularly in scenarios where coexisting pollutants are present. An innovative strategy of alternating nitrate-reducing and microaerobic conditions to stimulate biodegradation is proposed, utilizing nitrate initially to degrade easily-degradable compounds, and potentially reducing the need for additional oxygen. Batch experiments were conducted to assess the biodegradation of a BTEX, indene, indane, and naphthalene mixture using groundwater and sediments from an anaerobic contaminated aquifer. Two set-ups were incubated for 98 days to assess the redox transitions between microaerobic (oxygen concentrations < 0.5 mg O₂ L⁻¹) and nitrate-reducing conditions, aiming to minimize external electron acceptor usage while maximizing degradation. Comparative experiments under fully aerobic and fully anaerobic (nitrate-reducing) conditions were conducted, revealing that under microaerobic conditions, all compounds were completely degraded, achieving removal efficiencies comparable to fully aerobic conditions. A pre-treatment phase involving nitrate-reducing conditions followed by microaerobic conditions showed more effective utilization of oxygen specifically for contaminant degradation compared to fully aerobic conditions. Contrarily, under fully anaerobic conditions, without oxygen addition, partial degradation of ethylbenzene was observed after 400 days, while other compounds remained. The outcomes of this study can provide valuable insights for refining strategies involving oxygen and nitrate dosages, thereby enhancing the efficacy of in situ bioremediation approaches targeting complex hydrocarbon mixtures within anaerobic subsurface environments.

• BTEX, indene, indane, and naphthalene mix biodegraded under microaerobic conditions

• Subsurface microorganisms swiftly adapt from nitrate to microaerobic conditions

• More oxygen directed to hydrocarbon biodegradation via a pre-anaerobic treatment

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芳烃混合物的微氧生物降解：有效硝酸盐和氧气用量的策略

有机芳香族化合物在地下环境中的生物降解常常受到溶解氧限制的阻碍。虽然补充氧气可以增强原位生物降解，但它带来了资金和技术挑战。本研究探讨了在厌氧环境中引入低氧浓度以有效去除污染物，特别是在共存污染物存在的情况下。提出了一种创新的策略，交替使用硝酸盐还原和微氧条件来刺激生物降解，首先利用硝酸盐来降解容易降解的化合物，并潜在地减少对额外氧气的需求。采用厌氧污染含水层的地下水和沉积物进行了批量实验，以评估BTEX、茚、茚和萘混合物的生物降解效果。两种设置孵育了98天，以评估微氧（氧气浓度& 0.5 mg O2 L−1）和硝酸盐还原条件之间的氧化还原转变，旨在最大限度地减少外部电子受体的使用，同时最大限度地降解。在全好氧和全厌氧（硝酸盐还原）条件下进行了对比实验，结果表明，在微好氧条件下，所有化合物都被完全降解，去除效率与全好氧条件相当。预处理阶段包括硝酸盐还原条件，然后是微有氧条件，与完全有氧条件相比，可以更有效地利用氧气，专门用于污染物降解。相反，在完全厌氧条件下，不加氧，400天后乙苯部分降解，而其他化合物仍存在。本研究的结果可以为涉及氧气和硝酸盐剂量的精炼策略提供有价值的见解，从而提高针对厌氧地下环境中复杂碳氢化合物混合物的原位生物修复方法的有效性。•BTEX、茚、茚和萘混合物在微氧条件下可被生物降解•地下微生物可迅速从硝酸盐环境适应到微氧环境•通过预厌氧处理，更多的氧气被用于碳氢化合物的生物降解

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来源期刊

Applied Microbiology and Biotechnology 工程技术-生物工程与应用微生物

CiteScore

10.00

自引率

4.00%

发文量

535

审稿时长

2 months

期刊介绍： Applied Microbiology and Biotechnology focusses on prokaryotic or eukaryotic cells, relevant enzymes and proteins; applied genetics and molecular biotechnology; genomics and proteomics; applied microbial and cell physiology; environmental biotechnology; process and products and more. The journal welcomes full-length papers and mini-reviews of new and emerging products, processes and technologies.