Defining and averting syndemic pathways in aquaculture: a major global food sector

被引：3

作者：

Stentiford, Grant D. ^{[1
,2
]}

Tyler, Charles R. ^{[2
,3
]}

Ellis, Robert P. ^{[2
,3
]}

Bean, Tim P. ^{[4
]}

Mackenzie, Simon ^{[5
]}

Brugere, Cecile ^{[6
]}

Holt, Corey C. ^{[7
]}

Peeler, Edmund J. ^{[1
,8
]}

Christison, Kevin W. ^{[9
]}

Rushton, Jonathan ^{[8
]}

Bass, David ^{[1
,2
]}

机构：

[1] Ctr Environm Fisheries & Aquaculture Sci CEFAS, Weymouth Lab, Weymouth, England

[2] Univ Exeter, Ctr Sustainable Aquaculture Futures, Exeter, Devon, England

[3] Univ Exeter, Biosci, Exeter, England

[4] Univ Edinburgh, Roslin Inst, Edinburgh, Scotland

[5] Univ Stirling, Inst Aquaculture, Stirling, Scotland

[6] Soulfish Res & Consultancy, York, England

[7] Univ British Columbia, Dept Bot, Vancouver, BC, Canada

[8] Univ Liverpool, Ctr Excellence Sustainable Food Syst, Liverpool, England

[9] Dept Forestry Fisheries & Environm, Pretoria, South Africa

来源：

FRONTIERS IN SUSTAINABLE FOOD SYSTEMS | 2023年 / 7卷

基金：

英国生物技术与生命科学研究理事会;

关键词：

aquaculture; food; disease; sustainable; health; ANIMAL DISEASES; HEALTH; COVID-19; IMPACTS; BURDEN; SALMON; SHRIMP;

D O I：

10.3389/fsufs.2023.1281447

中图分类号：

TS2 [食品工业];

学科分类号：

0832 ;

摘要：

Aquaculture now provides half of all aquatic protein consumed globally-with most current and future production occurring in low- and middle-income countries (LMICs). Concerns over the availability and application of effective policies to deliver safe and sustainable future supply have the potential to hamper further development of the sector. Creating healthy systems must extend beyond the simple exclusion of disease agents to tackle the host, environmental, and human drivers of poor outcomes and build new policies that incorporate these broader drivers. Syndemic theory provides a potential framework for operationalizing this One Health approach.

引用

页数：5

共 62 条

[1] The Cost of Lice: Quantifying the Impacts of Parasitic Sea Lice on Farmed Salmon [J].

Abolofia, Jay ;

Wilen, James E. ;

Asche, Frank .

MARINE RESOURCE ECONOMICS, 2017, 32 (03) :329-349

[2] The Pathobiome in Animal and Plant Diseases [J].

Bass, David ;

Stentiford, Grant D. ;

Wang, Han-Ching ;

Koskella, Britt ;

Tyler, Charles R. .

TRENDS IN ECOLOGY & EVOLUTION, 2019, 34 (11) :996-1008

[3]

Bateman KS, 2020, MARINE DISEASE ECOLOGY, P3, DOI 10.1093/oso/9780198821632.003.0001

[4] Monitoring and managing microbes in aquaculture - Towards a sustainable industry [J].

Bentzon-Tilia, Mikkel ;

Sonnenschein, Eva C. ;

Gram, Lone .

MICROBIAL BIOTECHNOLOGY, 2016, 9 (05) :576-584

[5] Collateral diseases: Aquaculture impacts on wildlife infections [J].

Bouwmeester, Mark M. ;

Goedknegt, M. Anouk ;

Poulin, Robert ;

Thieltges, David W. .

JOURNAL OF APPLIED ECOLOGY, 2021, 58 (03) :453-464

[6] People matter in animal disease surveillance: Challenges and opportunities for the aquaculture sector [J].

Brugere, Cecile ;

Onuigbo, Dennis Mark ;

Morgan, Kenton Ll. .

AQUACULTURE, 2017, 467 :158-169

[7] Understanding the Dynamic of POMS Infection and the Role of Microbiota Composition in the Survival of Pacific Oysters, Crassostrea gigas [J].

Delisle, Lizenn ;

Laroche, Olivier ;

Hilton, Zoe ;

Burguin, Jean-Francois ;

Rolton, Anne ;

Berry, Jolene ;

Pochon, Xavier ;

Boudry, Pierre ;

Vignier, Julien .

MICROBIOLOGY SPECTRUM, 2022, 10 (06)

[8]

Dohoo IR., 2009, Veterinary epidemiologic research

[9]

FAO, 2012, Food and agriculture organization of the united nations (FAO), FAO statistical databases

[10]

Faruk M. A. R., 2004, Pakistan Journal of Biological Sciences, V7, P2086, DOI 10.3923/pjbs.2004.2086.2091

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