Biorefinery for a circular carbon paradigm: process benefits to the use of dryland CAM crops for anaerobic volatile fatty acid production

IF 6.1 1区工程技术 Q1 BIOTECHNOLOGY & APPLIED MICROBIOLOGY

Biotechnology for Biofuels Pub Date : 2025-07-31 DOI:10.1186/s13068-025-02636-3

Nicholas A. Tenci, Nichola Austen, Laura K. Martin, J. Andrew C. Smith, Ian P. Thompson

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Abstract

Background

Anaerobic digestion (AD) or acidogenic fermentation (AF) of biomass can generate either biogas fuel or C₂ ‒ C₈ volatile fatty acids (VFAs) as feedstocks for synthesis of other petrochemical products. Typical AD feedstocks require large amounts of land that could otherwise be used for food production. Unlike these traditional bioenergy crops, plants using the crassulacean acid metabolism pathway (CAM), such as cacti and succulents, may be cultivated on degraded or semi-arid land that cannot support conventional agriculture. This could allow significant biorefinery feedstock to be sourced with minimal impact on existing agriculture or biodiversity. Several economically important CAM crops (e.g. pineapple, agave, prickly pear) are cultivated globally, with waste biomass that could be valorised as a biorefinery feedstock.

Results

Here, we investigate the fermentation kinetics of this novel feedstock class (CAM plants) against traditional bioenergy crops with two contrasting inocula: AD sludge and rumen fluid. Fermentations were performed under the influence of a methanogenesis inhibitor (bromoethane sulfonate) to isolate the acidogenic fermentation processes. CAM and non-CAM substrates in this study demonstrated distinct degradation kinetics (yields and degradation rates). We demonstrate that regardless of the inoculum type, CAM crops show higher hydrolysis rates for VFA production. Moreover, yields of VFAs from three CAM crops (0.41 ± 0.01 – 0.48 ± 0.02 g/g_vs) were higher than for the three non-CAM crops (0.21 ± 0.01 – 0.38 ± 0.01 g/g_vs) when AD sludge was used as the inoculum. This superior performance appeared to correlate with a higher abundance of soluble material and lower structural carbohydrate content in CAM biomass.

Conclusions

At industrial scale, the observed kinetic advantages of VFA production from CAM-plant feedstocks could translate into process enhancements that would greatly improve the cost-competitiveness of anaerobic biorefinery. Assuming comparable biomass productivities of CAM and non-CAM crops, this high yield could allow higher VFA production per unit of cultivated land, improving the environmental credentials of CAM biorefinery.

Graphical abstract

Abstract Image

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循环碳范例的生物炼制：利用旱地CAM作物生产厌氧挥发性脂肪酸的过程有益。

背景：生物质厌氧消化（AD）或产酸发酵（AF）可以产生沼气燃料或C2 - C8挥发性脂肪酸（VFAs）作为合成其他石化产品的原料。典型的AD原料需要大量的土地，而这些土地本来可以用于粮食生产。与这些传统的生物能源作物不同，使用天冬肽酸代谢途径（CAM）的植物，如仙人掌和多肉植物，可以种植在不能支持传统农业的退化或半干旱土地上。这可以使重要的生物炼制原料的来源对现有农业或生物多样性的影响最小。几种经济上重要的CAM作物（如菠萝、龙舌兰、刺梨）在全球范围内种植，废弃的生物质可以作为生物炼制原料。结果：本研究采用两种不同的接种剂：AD污泥和瘤胃液，研究了这种新型原料类（CAM植物）对传统生物能源作物的发酵动力学。在甲烷生成抑制剂（溴乙烷磺酸盐）的影响下进行发酵，以分离产酸发酵过程。在本研究中，CAM和非CAM底物表现出不同的降解动力学（产量和降解率）。我们证明，无论接种类型如何，CAM作物都显示出更高的VFA水解率。以AD污泥为接种物时，3种CAM作物的VFAs产量（0.41±0.01 ~ 0.48±0.02 g/gvs）均高于3种非CAM作物（0.21±0.01 ~ 0.38±0.01 g/gvs）。这种优异的性能似乎与CAM生物质中较高的可溶性物质丰度和较低的结构碳水化合物含量有关。结论：在工业规模上，观察到的从cam工厂原料生产VFA的动力学优势可以转化为工艺改进，这将大大提高厌氧生物炼制的成本竞争力。假设CAM和非CAM作物的生物量生产力相当，这种高产量可以使单位耕地的VFA产量更高，从而改善CAM生物炼制的环境证书。

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来源期刊

Biotechnology for Biofuels 工程技术-生物工程与应用微生物

自引率

0.00%

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审稿时长

2.7 months

期刊介绍： Biotechnology for Biofuels is an open access peer-reviewed journal featuring high-quality studies describing technological and operational advances in the production of biofuels, chemicals and other bioproducts. The journal emphasizes understanding and advancing the application of biotechnology and synergistic operations to improve plants and biological conversion systems for the biological production of these products from biomass, intermediates derived from biomass, or CO2, as well as upstream or downstream operations that are integral to biological conversion of biomass. Biotechnology for Biofuels focuses on the following areas: • Development of terrestrial plant feedstocks • Development of algal feedstocks • Biomass pretreatment, fractionation and extraction for biological conversion • Enzyme engineering, production and analysis • Bacterial genetics, physiology and metabolic engineering • Fungal/yeast genetics, physiology and metabolic engineering • Fermentation, biocatalytic conversion and reaction dynamics • Biological production of chemicals and bioproducts from biomass • Anaerobic digestion, biohydrogen and bioelectricity • Bioprocess integration, techno-economic analysis, modelling and policy • Life cycle assessment and environmental impact analysis