水产养殖中的循环生物经济

IF 8.8 1区 农林科学 Q1 FISHERIES
Johan A. J. Verreth, Koushik Roy, Giovanni M. Turchini
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Even novel planetary health threats such as microplastics are emerging.<span><sup>12, 13</sup></span> Obviously, the current bio-economy needs to be revisited to remain within ‘safe operating space for the future of mankind’. A change to a circular bio-based economy focusing on resource use efficiency and minimizing environmental impacts might be one of the most prospective strategies to achieve that goal.</p><p>Muscat et al.<span><sup>14</sup></span> presented five principles to transform agro-food systems into a circular bio-economy, for example, safeguarding the health of agro-ecosystems, avoiding waste, prioritizing the use of biomass to avoid a food–feed–fuel competition, recycling by-products and using renewable energy. Products and/or production systems are designed in such a way that they minimize their impact on the environment during their whole lifetime. European Commission, Directorate-General for Maritime Affairs and Fisheries, et al.<span><sup>15</sup></span> and Colombo and Turchini<span><sup>16</sup></span> transferred this idea to the area of fisheries and aquaculture and presented a framework for a circular economy, focusing on the conceptualization and design of new appropriate production systems, evaluating the possible reuse of wastes and by-products from fisheries/aquaculture, reducing the impact of equipment and products from the sector and exploring possibilities to recycle. It all relates to the so-called three Rs, for example, reduce, reuse, recycle.</p><p><i>Reviews in Aquaculture</i> contributed already to the discourse on circularity in aquaculture. Roy et al.<span><sup>17</sup></span> provided a virtual topical collection of 13 review articles published by <i>Reviews in Aquaculture</i> between 2020 and 2021, which together reflected some of the contemporary puzzles of circularity in aquaculture. Following a virtual special issue (here), the journal decided to initiate a physical special issue entitled ‘Circular Bio-economy Framework in Aquaculture’, which we proudly present today.</p><p>The special issue was organized around the four key processes in circularity, for example, designing new (circular) aquacultural production systems, reducing the impact of aquaculture, re-using wastes and by-products from aquaculture and recycling materials and biomasses. In our call for papers, we invited state-of-the-art reviews on themes, fitting in each of the above processes.</p><p>With regard to <i>Conceptualizing and/or designing circular production systems</i>, we called for ‘Circular production systems, such as aquaponics, integrated multi-trophic aquaculture systems, etc.’. For this topic, four interesting reviews emerged, one relevant for marine aquaculture,<span><sup>18</sup></span> two relevant for inland aquaculture<span><sup>19</sup></span> and one for both.<span><sup>20, 21</sup></span> Some lesser known approaches were taken to the forefront by Garibay-Valtez et al.,<span><sup>20</sup></span> Lothmann and Sewilam,<span><sup>18</sup></span> and Zhao et al.,<span><sup>21</sup></span> while promising solutions were revisited from a wider industry perspective by Marousek et al.<span><sup>19</sup></span></p><p>With regard to <i>Reduce</i>, the call stipulated ‘Reducing emissions and footprints of aquaculture’ which was complemented by Arantzamendia et al.<span><sup>22</sup></span> exploring the feasibility of bio-based solutions for innovations in materials used in aquaculture as a possible emerging new science field. Within this process, the call further stipulated ‘Connecting aquaculture research to side streams (pharmaceutical, biofuel, etc.)’, as a possible theme. The review by Yun et al.<span><sup>23</sup></span> presented how seaweed-farming waste streams could be industrially lucrative. An interesting review<span><sup>24</sup></span> contributed to the process of ‘reduce’ by reviewing marine resources that would reduce the land-use dependency of aquaculture.</p><p>With regard to <i>Reuse</i>, themes mentioned were ‘valorization of aquaculture and non-aquaculture waste streams for aquaculture’ and ‘Improving food safety issues of products emanating from circular aquaculture’. Two reviews, one focusing on nutrient reuse at farm level<span><sup>25</sup></span> and another one focusing on re-using nutrients locked in biomasses at the farm-to-fork level,<span><sup>26</sup></span> showed several possible routes of upcycling ecosystem nutrients into the human food chain. 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Wang et al.<span><sup>32</sup></span> showed the potential of transforming industrial gas emissions into edible biomass, through aquaculture. van Riel et al.<span><sup>29</sup></span> tackled the issue of ‘food-feed competition’ against the background of the expected aquaculture expansion. Ogburn et al.<span><sup>30</sup></span> showed that substrate-based production systems could be another winner to recycle the bulk of semi-refined agri-food by-products into edible biomass. Sunish and co-authors<span><sup>31</sup></span> gave a perspective of naturally occurring, in situ saprophytic microbes strengthening farmed aquatic animal health.</p><p>There were also topics where the editors could not receive enough submissions for. 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Food production is considered as one of the most significant causes of environmental change.<span><sup>6, 7</sup></span> The planetary boundaries framework<span><sup>8, 9</sup></span> offers a tool to explore to which extent we are still operating within the carrying capacity of our planet. In its most recent update,<span><sup>10, 11</sup></span> six out of the nine boundaries were transgressed already. Even novel planetary health threats such as microplastics are emerging.<span><sup>12, 13</sup></span> Obviously, the current bio-economy needs to be revisited to remain within ‘safe operating space for the future of mankind’. 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European Commission, Directorate-General for Maritime Affairs and Fisheries, et al.<span><sup>15</sup></span> and Colombo and Turchini<span><sup>16</sup></span> transferred this idea to the area of fisheries and aquaculture and presented a framework for a circular economy, focusing on the conceptualization and design of new appropriate production systems, evaluating the possible reuse of wastes and by-products from fisheries/aquaculture, reducing the impact of equipment and products from the sector and exploring possibilities to recycle. It all relates to the so-called three Rs, for example, reduce, reuse, recycle.</p><p><i>Reviews in Aquaculture</i> contributed already to the discourse on circularity in aquaculture. Roy et al.<span><sup>17</sup></span> provided a virtual topical collection of 13 review articles published by <i>Reviews in Aquaculture</i> between 2020 and 2021, which together reflected some of the contemporary puzzles of circularity in aquaculture. Following a virtual special issue (here), the journal decided to initiate a physical special issue entitled ‘Circular Bio-economy Framework in Aquaculture’, which we proudly present today.</p><p>The special issue was organized around the four key processes in circularity, for example, designing new (circular) aquacultural production systems, reducing the impact of aquaculture, re-using wastes and by-products from aquaculture and recycling materials and biomasses. In our call for papers, we invited state-of-the-art reviews on themes, fitting in each of the above processes.</p><p>With regard to <i>Conceptualizing and/or designing circular production systems</i>, we called for ‘Circular production systems, such as aquaponics, integrated multi-trophic aquaculture systems, etc.’. 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Within this process, the call further stipulated ‘Connecting aquaculture research to side streams (pharmaceutical, biofuel, etc.)’, as a possible theme. The review by Yun et al.<span><sup>23</sup></span> presented how seaweed-farming waste streams could be industrially lucrative. An interesting review<span><sup>24</sup></span> contributed to the process of ‘reduce’ by reviewing marine resources that would reduce the land-use dependency of aquaculture.</p><p>With regard to <i>Reuse</i>, themes mentioned were ‘valorization of aquaculture and non-aquaculture waste streams for aquaculture’ and ‘Improving food safety issues of products emanating from circular aquaculture’. Two reviews, one focusing on nutrient reuse at farm level<span><sup>25</sup></span> and another one focusing on re-using nutrients locked in biomasses at the farm-to-fork level,<span><sup>26</sup></span> showed several possible routes of upcycling ecosystem nutrients into the human food chain. 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Wang et al.<span><sup>32</sup></span> showed the potential of transforming industrial gas emissions into edible biomass, through aquaculture. van Riel et al.<span><sup>29</sup></span> tackled the issue of ‘food-feed competition’ against the background of the expected aquaculture expansion. Ogburn et al.<span><sup>30</sup></span> showed that substrate-based production systems could be another winner to recycle the bulk of semi-refined agri-food by-products into edible biomass. Sunish and co-authors<span><sup>31</sup></span> gave a perspective of naturally occurring, in situ saprophytic microbes strengthening farmed aquatic animal health.</p><p>There were also topics where the editors could not receive enough submissions for. 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引用次数: 0

摘要

我们生产食物的方式受到越来越多的审查和评估,以确定其对全球环境变化的可能贡献。关于农业(包括水产养殖)对世界自然资源的负面影响的科学证据越来越多。粮食生产被认为是环境变化的最重要原因之一。行星边界框架提供了一种工具来探索我们在多大程度上仍在地球的承载能力范围内活动。在最近的一次更新中,9个边界中有6个已经被越过。甚至像微塑料这样的新型地球健康威胁也在出现。12,13显然,当前的生物经济需要重新审视,以保持在“人类未来的安全运行空间”之内。向注重资源利用效率和尽量减少环境影响的循环生物经济转变,可能是实现这一目标的最具前景的战略之一。Muscat等人14提出了将农业-粮食系统转变为循环生物经济的五项原则,例如,保障农业生态系统的健康,避免浪费,优先使用生物质以避免食品-饲料-燃料竞争,回收副产品和使用可再生能源。产品和/或生产系统的设计使其在整个生命周期内对环境的影响最小化。欧洲委员会、海事和渔业总局等15以及科伦坡和图尔奇尼16将这一想法转移到渔业和水产养殖领域,并提出了一个循环经济框架,重点是新的适当生产系统的概念化和设计,评估渔业/水产养殖废物和副产品的可能再利用,减少该部门设备和产品的影响,并探索回收的可能性。这一切都与所谓的3r有关,例如,减少(reduce)、再利用(reuse)、再循环(recycle)。《水产养殖评论》已经对关于水产养殖循环的论述作出了贡献。Roy等人17提供了2020年至2021年间发表在《水产养殖评论》上的13篇评论文章的虚拟专题合集,这些文章共同反映了水产养殖中的一些当代循环性难题。继虚拟特刊(在这里)之后,该杂志决定发起一个名为“水产养殖中的循环生物经济框架”的实体特刊,我们今天自豪地提出这个特刊。本期特刊围绕循环的四个关键过程组织,例如,设计新的(循环)水产养殖生产系统、减少水产养殖的影响、重新利用水产养殖的废物和副产品以及回收材料和生物质。在我们的论文征集中,我们邀请了最先进的主题评论,适合上述每个过程。关于概念化和/或设计循环生产系统,我们呼吁“循环生产系统,如鱼菜共生、综合多营养水产养殖系统等”。针对这一主题,出现了四篇有趣的综述,一篇与海洋水产养殖有关,两篇与内陆水产养殖有关,一篇与两者都有关。20,21一些鲜为人知的方法被Garibay-Valtez等人,20 Lothmann和Sewilam,18以及Zhao等人,21带到了最前沿,而Marousek等人则从更广泛的行业角度重新审视了有希望的解决方案。该呼吁规定了“减少水产养殖的排放和足迹”,并由Arantzamendia等人补充。22探讨了水产养殖中使用的材料创新的生物基解决方案的可行性,作为一个可能出现的新科学领域。在这一过程中,呼吁进一步规定了“将水产养殖研究与侧流(制药、生物燃料等)联系起来”作为一个可能的主题。Yun等人23的综述展示了海藻养殖废物流如何在工业上有利可图。一项有趣的审查24通过审查海洋资源来减少对水产养殖的土地利用依赖,从而促进了“减少”过程。关于再利用,提到的主题是“水产养殖和用于水产养殖的非水产养殖废物流的价值”和“改善循环水产养殖产生的产品的食品安全问题”。两篇综述,一篇侧重于农场层面的养分再利用(25),另一篇侧重于从农场到餐桌层面的生物质中锁定的养分再利用(26),展示了几种将生态系统养分升级到人类食物链的可能途径。后一篇论文还回顾了消费者接受度、产品质量、保质期和某些池塘和RAS养殖鱼的再制造的复杂性。第三项审查27探讨了在渔业和水产养殖中重新利用废水的可能性。回收过程收到的意见书最多。 会议的主题是“基于植物和微生物的解决方案”和“水产养殖和循环饲料中的食物-饲料冲突”。总共有五篇评论发表在这个板块下,11,28-31,很好地总结了水产养殖从几十年前到现在是如何依赖于再生生物质的。Colombo等人28概述了养殖蓝色食品是如何被喂养的,以及循环概念是如何逐渐融入水产饲料的,从而导致了循环饲料的潜在候选。Wang等人32展示了通过水产养殖将工业气体排放转化为可食用生物质的潜力。van Riel等人29在预期水产养殖扩张的背景下解决了“食品-饲料竞争”问题。Ogburn等人30表明,基于基质的生产系统可能是将大部分半精炼农业食品副产品回收为可食用生物质的另一个赢家。苏尼什和他的合著者31提出了一种观点,认为自然存在的原位腐生微生物可以增强养殖水生动物的健康。还有一些题目是编辑们收不到足够的投稿的。主题涉及“基于系统的思维和建模”和“潜在循环水产养殖模式的能源和能量分析”。本期特刊介绍了15篇综述论文,它们共同证明了循环方法和生物基解决方案在水产养殖研究界得到了很好的采用。现在,它正在等待这些创新在行业中的广泛应用。编辑们诚挚地感谢匿名同行审稿人的巨大帮助,他们帮助我们实现了这一期特刊。编辑们希望这些文章能引起读者的深思。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Circular bio-economy in aquaculture

The way we produce our food is increasingly scrutinized and evaluated on its possible contribution to the global environmental changes the world is currently witnessing. Scientific evidence about the negative effects of agriculture (including aquaculture) on the world's natural resources1-5 is mounting. Food production is considered as one of the most significant causes of environmental change.6, 7 The planetary boundaries framework8, 9 offers a tool to explore to which extent we are still operating within the carrying capacity of our planet. In its most recent update,10, 11 six out of the nine boundaries were transgressed already. Even novel planetary health threats such as microplastics are emerging.12, 13 Obviously, the current bio-economy needs to be revisited to remain within ‘safe operating space for the future of mankind’. A change to a circular bio-based economy focusing on resource use efficiency and minimizing environmental impacts might be one of the most prospective strategies to achieve that goal.

Muscat et al.14 presented five principles to transform agro-food systems into a circular bio-economy, for example, safeguarding the health of agro-ecosystems, avoiding waste, prioritizing the use of biomass to avoid a food–feed–fuel competition, recycling by-products and using renewable energy. Products and/or production systems are designed in such a way that they minimize their impact on the environment during their whole lifetime. European Commission, Directorate-General for Maritime Affairs and Fisheries, et al.15 and Colombo and Turchini16 transferred this idea to the area of fisheries and aquaculture and presented a framework for a circular economy, focusing on the conceptualization and design of new appropriate production systems, evaluating the possible reuse of wastes and by-products from fisheries/aquaculture, reducing the impact of equipment and products from the sector and exploring possibilities to recycle. It all relates to the so-called three Rs, for example, reduce, reuse, recycle.

Reviews in Aquaculture contributed already to the discourse on circularity in aquaculture. Roy et al.17 provided a virtual topical collection of 13 review articles published by Reviews in Aquaculture between 2020 and 2021, which together reflected some of the contemporary puzzles of circularity in aquaculture. Following a virtual special issue (here), the journal decided to initiate a physical special issue entitled ‘Circular Bio-economy Framework in Aquaculture’, which we proudly present today.

The special issue was organized around the four key processes in circularity, for example, designing new (circular) aquacultural production systems, reducing the impact of aquaculture, re-using wastes and by-products from aquaculture and recycling materials and biomasses. In our call for papers, we invited state-of-the-art reviews on themes, fitting in each of the above processes.

With regard to Conceptualizing and/or designing circular production systems, we called for ‘Circular production systems, such as aquaponics, integrated multi-trophic aquaculture systems, etc.’. For this topic, four interesting reviews emerged, one relevant for marine aquaculture,18 two relevant for inland aquaculture19 and one for both.20, 21 Some lesser known approaches were taken to the forefront by Garibay-Valtez et al.,20 Lothmann and Sewilam,18 and Zhao et al.,21 while promising solutions were revisited from a wider industry perspective by Marousek et al.19

With regard to Reduce, the call stipulated ‘Reducing emissions and footprints of aquaculture’ which was complemented by Arantzamendia et al.22 exploring the feasibility of bio-based solutions for innovations in materials used in aquaculture as a possible emerging new science field. Within this process, the call further stipulated ‘Connecting aquaculture research to side streams (pharmaceutical, biofuel, etc.)’, as a possible theme. The review by Yun et al.23 presented how seaweed-farming waste streams could be industrially lucrative. An interesting review24 contributed to the process of ‘reduce’ by reviewing marine resources that would reduce the land-use dependency of aquaculture.

With regard to Reuse, themes mentioned were ‘valorization of aquaculture and non-aquaculture waste streams for aquaculture’ and ‘Improving food safety issues of products emanating from circular aquaculture’. Two reviews, one focusing on nutrient reuse at farm level25 and another one focusing on re-using nutrients locked in biomasses at the farm-to-fork level,26 showed several possible routes of upcycling ecosystem nutrients into the human food chain. The latter paper reviewed also intricacies of consumer acceptance, product quality, shelf life and re-manufacturing of certain pond and RAS farmed fish. A third review27 explored the possibilities of re-using the wastewater in fisheries and aquaculture.

The process of Recycling received most submissions. The call themes were ‘Plant and microbial-based solutions’ and ‘Food-feed conflicts in aquaculture and circular feeds’. Altogether five reviews were published under this block,11, 28-31 nicely summarizing how aquaculture relied on recycling biomass, from decades ago till now. Colombo et al.28 provided an overview on how farmed blue foods have been fed and how the circularity concepts were gradually integrated in aquafeed, leading to potential candidates for circular feeds. Wang et al.32 showed the potential of transforming industrial gas emissions into edible biomass, through aquaculture. van Riel et al.29 tackled the issue of ‘food-feed competition’ against the background of the expected aquaculture expansion. Ogburn et al.30 showed that substrate-based production systems could be another winner to recycle the bulk of semi-refined agri-food by-products into edible biomass. Sunish and co-authors31 gave a perspective of naturally occurring, in situ saprophytic microbes strengthening farmed aquatic animal health.

There were also topics where the editors could not receive enough submissions for. The topics were related to ‘Systems-based thinking and modeling’ and ‘Energy and emergy analysis on potential circular aquaculture models’.

The special issue presents 15 review papers that together prove that circular approaches and bio-based solutions are well adopted in the aquaculture research community. It is now waiting for a widespread application of these innovations in the industry.

The editors cordially acknowledge the immense help of anonymous peer reviewers who have helped us to materialize this special issue. The editors hope readers would find the articles thought-provoking.

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来源期刊
CiteScore
24.80
自引率
5.80%
发文量
109
审稿时长
>12 weeks
期刊介绍: Reviews in Aquaculture is a journal that aims to provide a platform for reviews on various aspects of aquaculture science, techniques, policies, and planning. The journal publishes fully peer-reviewed review articles on topics including global, regional, and national production and market trends in aquaculture, advancements in aquaculture practices and technology, interactions between aquaculture and the environment, indigenous and alien species in aquaculture, genetics and its relation to aquaculture, as well as aquaculture product quality and traceability. The journal is indexed and abstracted in several databases including AgBiotech News & Information (CABI), AgBiotechNet, Agricultural Engineering Abstracts, Environment Index (EBSCO Publishing), SCOPUS (Elsevier), and Web of Science (Clarivate Analytics) among others.
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