Utilization of palm sludge oil for rhamnolipid biosynthesis by Pseudomonas aeruginosa USM-AR2 in a stirred tank reactor.

IF 3.5 3区生物学 Q2 BIOTECHNOLOGY & APPLIED MICROBIOLOGY

Bioprocess and Biosystems Engineering Pub Date : 2024-11-13 DOI:10.1007/s00449-024-03103-3

Mohd Shafiq Nasir, Ahmad Ramli Mohd Yahya, Nur Asshifa Md Noh

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引用次数: 0

Abstract

The study focused on rhamnolipid production by batch fermentation of Pseudomonas aeruginosa USM-AR2 in a 3-L stirred-tank reactor (STR) using palm sludge oil (PSO) as the sole carbon source. The impact of various agitation rates towards the dispersion of PSO in the medium was evaluated to improve biomass growth and rhamnolipid production. A mechanical foam collection and recycling system was designed and retrofitted to the STR to overcome severe foam formation during fermentation. The maximum biomass produced was 11.29 ± 0.20 g/L obtained at 400 rpm, while the maximum rhamnolipid production was 5.06 ± 1.17 g/L at 600 rpm, giving a rhamnolipid productivity of 0.023 g/L/h. High agitation enhances substrate availability by breaking the hydrophobic semi-solid PSO into smaller substrate particles, increasing surface contact area, thus facilitating the PSO utilisation by P. aeruginosa USM-AR2, thereby inducing rhamnolipid production. This study further demonstrates the ability of rhamnolipid to solubilize and disperse sludge oil, which typically remains a solid at room temperature, in the liquid medium. GCMS analysis showed that five fatty acids, namely palmitic acid, myristic acid, stearic acid, methyl ester and linoleic acid, have been utilised. The rhamnolipid showed an oil spreading test result of 160 mm of waste engine oil displacement compared to control using distilled water that remained non-displaced, and a critical micelle concentration (CMC) of 17 mg/L. In emulsification index (E₂₄) assay, the rhamnolipid was shown to emulsify toluene (66.7% ± 7.2), waste engine oil (58.3% ± 7.2), kerosene (41.8% ± 4.8) and n-hexane (33.1% ± 5.7). UPLC analysis on rhamnolipid revealed a congener mixture of rhamnolipid, namely di-rhamnolipid and mono-rhamnolipid mixture. This is the first report on the employment of an integrated foam control reactor system with PSO as the carbon source for rhamnolipid production by P. aeruginosa USM-AR2 culture.

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铜绿假单胞菌 USM-AR2 在搅拌罐反应器中利用棕榈污泥油进行鼠李糖脂生物合成。

本研究的重点是以棕榈污泥油（PSO）为唯一碳源，在 3 升搅拌槽反应器（STR）中通过铜绿假单胞菌 USM-AR2 的批量发酵生产鼠李糖脂。评估了各种搅拌速率对 PSO 在培养基中分散的影响，以改善生物质的生长和鼠李糖脂的生产。设计并在 STR 上加装了一个机械泡沫收集和循环系统，以克服发酵过程中形成的严重泡沫。在转速为 400 rpm 时，生物量的最大产量为 11.29 ± 0.20 克/升，而在转速为 600 rpm 时，鼠李糖脂的最大产量为 5.06 ± 1.17 克/升，鼠李糖脂的生产率为 0.023 克/升/小时。高搅动可将疏水性半固态 PSO 打碎成更小的基质颗粒，增加表面接触面积，从而提高基质的可用性，促进铜绿微囊藻 USM-AR2 对 PSO 的利用，进而诱导鼠李糖脂的产生。这项研究进一步证明了鼠李糖脂在液体介质中溶解和分散污泥油的能力，污泥油在室温下通常是固体。GCMS 分析表明，五种脂肪酸，即棕榈酸、肉豆蔻酸、硬脂酸、甲酯和亚油酸得到了利用。鼠李糖脂的铺油试验结果表明，与使用蒸馏水的对照组相比，废机油的铺油量为 160 毫米，临界胶束浓度（CMC）为 17 毫克/升。在乳化指数（E24）测定中，鼠李糖脂对甲苯（66.7% ± 7.2）、废机油（58.3% ± 7.2）、煤油（41.8% ± 4.8）和正己烷（33.1% ± 5.7）均有乳化作用。鼠李糖脂的超高效液相色谱分析显示了鼠李糖脂的同系物混合物，即二鼠李糖脂和单鼠李糖脂混合物。这是首次报道铜绿微囊藻 USM-AR2 培养物利用以 PSO 为碳源的综合泡沫控制反应器系统生产鼠李糖脂。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Bioprocess and Biosystems Engineering 工程技术-工程：化工

CiteScore

7.90

自引率

2.60%

发文量

147

审稿时长

2.6 months

期刊介绍： Bioprocess and Biosystems Engineering provides an international peer-reviewed forum to facilitate the discussion between engineering and biological science to find efficient solutions in the development and improvement of bioprocesses. The aim of the journal is to focus more attention on the multidisciplinary approaches for integrative bioprocess design. Of special interest are the rational manipulation of biosystems through metabolic engineering techniques to provide new biocatalysts as well as the model based design of bioprocesses (up-stream processing, bioreactor operation and downstream processing) that will lead to new and sustainable production processes. Contributions are targeted at new approaches for rational and evolutive design of cellular systems by taking into account the environment and constraints of technical production processes, integration of recombinant technology and process design, as well as new hybrid intersections such as bioinformatics and process systems engineering. Manuscripts concerning the design, simulation, experimental validation, control, and economic as well as ecological evaluation of novel processes using biosystems or parts thereof (e.g., enzymes, microorganisms, mammalian cells, plant cells, or tissue), their related products, or technical devices are also encouraged. The Editors will consider papers for publication based on novelty, their impact on biotechnological production and their contribution to the advancement of bioprocess and biosystems engineering science. Submission of papers dealing with routine aspects of bioprocess engineering (e.g., routine application of established methodologies, and description of established equipment) are discouraged.