Composition of the biofouling community associated with oyster culture in an Amazon estuary, Pará State, North Brazil

Chagas, Rafael Anaisce das; Barros, Mara Rúbia Ferreira; Santos, Wagner Cesar Rosa dos; Herrmann, Marko

doi:10.4067/s0718-19572018000100009

Cited by 8 publications

(13 citation statements)

References 23 publications

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“…A greater focus on avoiding biofouling will yield production benefits by reducing both the direct impacts of fouling organisms, and the frequency and intensity of treatments. In locations with predictable seasonal fouling patterns, spatial and temporal avoidance of biofouling may be feasible Sievers et al 2014;Holthuis et al 2015), and considerable recent effort has gone into monitoring biofouling development at farms around the world (eg Carraro et al 2012;Antoniadou et al 2013;Watts et al 2015;Casso et al 2018;das Chagas et al 2018). Modelling biofouling settlement and development is also paving the way for sophisticated avoidance strategies.…”

Section: Preventionmentioning

confidence: 99%

Biofouling in marine aquaculture: a review of recent research and developments

et al. 2019

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Biofouling in marine aquaculture is one of the main barriers to efficient and sustainable production. Owing to the growth of aquaculture globally, it is pertinent to update previous reviews to inform management and guide future research. Here, the authors highlight recent research and developments on the impacts, prevention and control of biofouling in shellfish, finfish and seaweed aquaculture, and the significant gaps that still exist in aquaculturalists' capacity to manage it. Antifouling methods are being explored and developed; these are centred on harnessing naturally occurring antifouling properties, culturing fouling-resistant genotypes, and improving farming strategies by adopting more sensitive and informative monitoring and modelling capabilities together with novel cleaning equipment. While no simple, quick-fix solutions to biofouling management in existing aquaculture industry situations have been developed, the expectation is that effective methods are likely to evolve as aquaculture develops into emerging culture scenarios, which will undoubtedly influence the path for future solutions. ARTICLE HISTORY

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Section: Preventionmentioning

confidence: 99%

Biofouling in marine aquaculture: a review of recent research and developments

et al. 2019

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“…This present study can be compared with the biofouling studies in bivalve aquaculture (oyster culture) where in initial colonies included hydroids, bryozoans, sponges, ascidians, polychaetes, bivalves, barnacles and algae. 27,28,29 In bivalve aquaculture practices the primary colonies enables the attachment of groups like crustaceans, polychaete worms or echinoderms and secondary colonization occurred after a month or few month. 27,30 In the present study, hydroids and barnacles were appeared in the initial month in the cage panel whereas hydroids, polychaete worms, amphipods, barnacles, crabs, shrimps, isopods, green mussels, Modiolus and oysters appeared in the reference panel.…”

Section: Discussionmentioning

confidence: 99%

“…27,28,29 In bivalve aquaculture practices the primary colonies enables the attachment of groups like crustaceans, polychaete worms or echinoderms and secondary colonization occurred after a month or few month. 27,30 In the present study, hydroids and barnacles were appeared in the initial month in the cage panel whereas hydroids, polychaete worms, amphipods, barnacles, crabs, shrimps, isopods, green mussels, Modiolus and oysters appeared in the reference panel. The recruitment, settlement complexities could be the reason for these differences in marine invertebrates.…”

Section: Discussionmentioning

confidence: 99%

A Study on Ecological Succession of Macrofouling Communities in Sea Cage Farm in South-West Coast of India

Mhaddolkar

Dineshbabu

Loka

et al. 2021

Int J Life Sci Pharm Res

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Development of aquaculture facilities like cages has led to rise in submerged structures which provide ample substratum to biofoulers which could greatly interfere with culture operations. An attempt was made to study the biofouling communities and succession of macro foulers on the cage culture net installed in the open sea. The main objective of the present study is to reveal the succession pattern of the biofouling communities on the panels of cage culture sites to find out seasonal settlement pattern, Dominant species and Climax community. A long-term study on the succession pattern of the cage farm experimental-net-panels revealed results as Hydroids-Gastropods-Hydroids-Barnacles-Modiolus-Green mussels. Hydroids were initial communities on the net panels and green mussels (Perna viridis) formed the climax community, also dominating on the cage culture nets. Different succession patterns were observed in two sites as well as in culture nets studied. The net panels of the cage were loaded with hydroids in the initial months and the peak fouling was during May. So frequent net cleaning was required during summer and during the spat settlement period of green mussel (September, October and November). Modiolus settlement during February month on the culture nets can be avoided by net exchange immediately after spat fall in this month. This attempt was made to study the ecological succession on the panels, in cages installed in Karwar, which is the first attempt, since the open sea cage culture was initiated in India. Looking at vast opportunities for further development in biofouling research, the aim of this investigations was to obtain the baseline information about the ecological succession pattern of biofouling organisms in fish cage sites. More research on biofouling in mariculture is essential to ensure the profitability of the aquaculture operations with environmental safety measures as a prime criteria.

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“…Os aspectos biomorfométricos das ostras (e.g., a relação peso-comprimento), são influenciados diretamente por diversos fatores, dentre eles, a espécie estudada, o ambiente (e.g., natural ou em cultivo) [47,48]. Além dessas variáveis, há outras que são importantes de se analisar, tais como: fatores abióticos (temperatura e/ou salinidade) [17,46,49,50,51,52,53,54], local a ser cultivado (ambiente marinho ou estuarino) [55,56,57], tipo de estrutura do cultivo [58,59,60,61], densidade estocada [62,63,64,65], ambientes impactados [66] e o biofouling [6,21,67,68,69,70]. De acordo com esses estudos, elevadas temperaturas incrementam a biomassa das ostras, devido a maior disponibilidade de nutrientes na água o que estar associado a um maior crescimento dos bivalves.…”

Section: Discussionunclassified

“…Neste sentido, a ostreicultura apresenta estudos desde a década de 1970 [18], que possibilitaram seu rápido desenvolvimento. Dentre esses estudos, destacam-se a dinâmica reprodutiva (e.g., indução a desova, aspectos reprodutivos), do crescimento, além das influências ambientais no desenvolvimento da ostreicultura e eventuais predadores naturais [16,19,20,21]. Entretanto, observa-se através da revisão bibliográfica efetuada, que não existe dados que possibilite a estimação da produção da biomassa (em toneladas) de ostra comercializa, pois, as estatísticas se delimitam a produção em dúzias.…”

Section: Introductionunclassified

Análise biomorfométrica da ostra-do-mangue cultivada no litoral amazônico

Chagas

Silva²,

Passos³

et al. 2019

Sci. Plena

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A ostreicultura surge no contexto mundial como uma das alternativas mais viáveis ao declínio da pesca e o fornecimento de recurso alimentício fresco. No Brasil, cultiva-se ostras do gênero Crassostrea e, no estado do Pará, cultiva-se a Crassostrea tulipa, conhecida por ostra-do-mangue. O presente estudo tem como objetivo caracterizar a biomorfometria da concha, estimar o Índice de Estabilização da Forma (IEF) da concha e o rendimento da carne comestível de C. tulipa, a partir de 1.028 ostras coletadas na ostreicultura da Associação de Agricultores, Pecuaristas e Aquicultores (ASAPAQ), situada no rio Urindeua, litoral amazônico, estado do Pará, no mês de abril de 2016. Realizou-se relações biomorfométricas entre a morfometria da concha (comprimento, largura e altura) e a biomassa (total e visceral), estimou-se o rendimento percentual da carne comestível e descreveu-se o IEF através de razões entre a morfometria da concha. Crassostrea tulipa apresenta excelentes relações biomorfométricas, gerando equações que satisfazem estimação de medidas morfométricas. Além disso, apresenta mais de 20% de rendimento da carne. A análise de IEF, indica uma tendência a estabilização da forma da concha ao atingir 60mm. Recomenda-se uma análise de IEF em ostras oriundas de ambientes naturais e sob influência da densidade de ostras e/o tipo de estrutura no qual a ostra está sendo cultivada. Este trabalho possibilita a estimação de carne de ostras comercializadas com base na mensuração da medida da altura da concha (mm) através da equação Bv = -4,29 + 1,94A.

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Composition of the biofouling community associated with oyster culture in an Amazon estuary, Pará State, North Brazil

Cited by 8 publications

References 23 publications

Biofouling in marine aquaculture: a review of recent research and developments

Biofouling in marine aquaculture: a review of recent research and developments

A Study on Ecological Succession of Macrofouling Communities in Sea Cage Farm in South-West Coast of India

Análise biomorfométrica da ostra-do-mangue cultivada no litoral amazônico

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