Sustainable production of biofuels and bioderivatives from aquaculture and marine waste

IF 2.5 Q3 BIOTECHNOLOGY & APPLIED MICROBIOLOGY

Frontiers in chemical engineering Pub Date : 2023-01-04 DOI:10.3389/fceng.2022.1072761

Lynette Alvarado-Ramírez, Berenice Santiesteban-Romero, Guillaume Poss, J. E. Sosa-Hernández, Hafiz M. N. Iqbal, R. Parra-Saldívar, A. D. Bonaccorso, Elda M. Melchor-Martínez

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引用次数: 2

Abstract

The annual global fish production reached a record 178 million tonnes in 2020, which continues to increase. Today, 49% of the total fish is harvested from aquaculture, which is forecasted to reach 60% of the total fish produced by 2030. Considering that the wastes of fishing industries represent up to 75% of the whole organisms, the fish industry is generating a large amount of waste which is being neglected in most parts of the world. This negligence can be traced to the ridicule of the value of this resource as well as the many difficulties related to its valorisation. In addition, the massive expansion of the aquaculture industry is generating significant environmental consequences, including chemical and biological pollution, disease outbreaks that increase the fish mortality rate, unsustainable feeds, competition for coastal space, and an increase in the macroalgal blooms due to anthropogenic stressors, leading to a negative socio-economic and environmental impact. The establishment of integrated multi-trophic aquaculture (IMTA) has received increasing attention due to the environmental benefits of using waste products and transforming them into valuable products. There is a need to integrate and implement new technologies able to valorise the waste generated from the fish and aquaculture industry making the aquaculture sector and the fish industry more sustainable through the development of a circular economy scheme. This review wants to provide an overview of several approaches to valorise marine waste (e.g., dead fish, algae waste from marine and aquaculture, fish waste), by their transformation into biofuels (biomethane, biohydrogen, biodiesel, green diesel, bioethanol, or biomethanol) and recovering biomolecules such as proteins (collagen, fish hydrolysate protein), polysaccharides (chitosan, chitin, carrageenan, ulvan, alginate, fucoidan, and laminarin) and biosurfactants. Graphical Abstract

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从水产养殖和海洋废弃物中可持续生产生物燃料和生物杀菌剂

2020年，全球鱼类年产量达到创纪录的1.78亿吨，而且还在继续增长。如今，49%的鱼类来自水产养殖，预计到2030年将达到总产量的60%。考虑到渔业的废物占整个生物体的75%，渔业产生了大量的废物，而这些废物在世界大多数地区都被忽视了。这种疏忽可以追溯到对这种资源价值的嘲笑，以及与其定价相关的许多困难。此外，水产养殖业的大规模扩张正在产生重大的环境后果，包括化学和生物污染、增加鱼类死亡率的疾病爆发、不可持续的饲料、对沿海空间的竞争，以及人为压力导致的大型藻类水华增加，导致负面的社会经济和环境影响。由于利用废物并将其转化为有价值的产品的环境效益，综合多营养水产养殖（IMTA）的建立受到了越来越多的关注。需要整合和实施能够对鱼类和水产养殖业产生的废物进行估价的新技术，通过制定循环经济计划，使水产养殖业和鱼类行业更加可持续。这篇综述旨在概述几种将海洋废物（如死鱼、海洋和水产养殖产生的藻类废物、鱼类废物）转化为生物燃料（生物甲烷、生物氢、生物柴油、绿色柴油、生物乙醇或生物甲醇）和回收生物分子如蛋白质（胶原蛋白、鱼类水解蛋白）的方法，多糖（壳聚糖、几丁质、卡拉胶、尺骨、海藻酸盐、褐藻糖胶和昆布胶）和生物表面活性剂。图形摘要

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来源期刊

Frontiers in chemical engineering

CiteScore

3.50

自引率

0.00%

发文量

审稿时长

13 weeks