Efficiency of particle retention and filtration rate in 6 species of Northeast American bivalves

Riisgård, HU

doi:10.3354/meps045217

Cited by 341 publications

(247 citation statements)

References 15 publications

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“…A recent review by Cranford et al (2011) suggested that the constant b could be universally written as 0.58 for filter-feeding bivalves. While species-specific estimates for C. virginica are rare, they have ranged from 0.59 (Pruder et al 1976 cited in Epifanio andEwart 1977) to 0.73±0.22 (Riisgaard 1988). Using the Levenberg-Marquardt nonlinear least squares method (Press et al 2007) in Mathematica version 7, we fitted Eq.…”

Section: Methodsmentioning

confidence: 99%

“…The physiology of oyster feeding and filtration is well studied, and filtration rate is known from laboratory studies to be influenced by a variety of environmental factors such as temperature, flow rate, salinity, seston concentration, and particle size, as well as oyster size (Loosanoff 1958;Walne 1972;Shumway et al 1985;Riisgaard 1988). Although it is recognized that conditions in situ may significantly affect filtration rate (Doering and Oviatt 1986;Powell et al 1992), few studies have sought to quantify rates under field conditions.…”

Section: Introductionmentioning

confidence: 99%

“…Through this action, both phytoplankton and suspended sediment that would otherwise reduce water clarity are drawn from the water column to the benthos. The eastern oyster, Crassostrea virginica (Gmelin, 1791), is known to filter particles >5 μm in size with high efficiency (Riisgaard 1988) and can have a marked effect on light penetration in shallow, calm waters, which in turn may have positive impacts on other important adjacent habitats, such as seagrass beds (Newell and Koch 2004).…”

Section: Introductionmentioning

confidence: 99%

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Quantifying the Loss of a Marine Ecosystem Service: Filtration by the Eastern Oyster in US Estuaries

Ermgassen

Spalding

Grizzle

et al. 2012

Estuaries and Coasts

176

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The oyster habitat in the USA is a valuable resource that has suffered significant declines over the past century. While this loss of habitat is well documented, the loss of associated ecosystem services remains poorly quantified. Meanwhile, ecosystem service recovery has become a major impetus for restoration. Here we propose a model for estimating the volume of water filtered by oyster populations under field conditions and make estimates of the contribution of past (c. 1880-1910) and present (c. 2000-2010) oyster populations to improving water quality in 13 US estuaries. We find that filtration capacity of oysters has declined almost universally (12 of the 13 estuaries examined) by a median of 85 %. Whereas historically, oyster populations achieved full estuary filtration (filtering a volume equivalent or larger than the entire estuary volume within the residence time of the water) in six of the eight estuaries in the Gulf of Mexico during summer months, this is now the case for only one estuary: Apalachicola Bay, Florida. By contrast, while all five estuaries on the North Atlantic coast showed large decreases in filtration capacity, none were achieving full estuary filtration at the time of our c. 1900 historic baseline. This apparent difference from the Gulf of Mexico is explained at least in part by our North Atlantic baseline representing a shifted baseline, as surveyed populations were already much reduced by exploitation in this region.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Quantifying the Loss of a Marine Ecosystem Service: Filtration by the Eastern Oyster in US Estuaries

Ermgassen

Spalding

Grizzle

et al. 2012

Estuaries and Coasts

176

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“…Earlier studies (for review, see Hawkins & Bayne 1992) have shown that Mytilus edulis, like most suspensionfeeders, has only a limited capacity to ingest small, natural-sized ( c 1 pm) bacteria. As an exception, however, Geukensia demissa has been reported capable of filtering natural-slzed bacteria with efficiencies 18 to 30% of those of larger dietary particles (Wright et al 1982, Riisgdrd 1988). Our ingestion results are consistent with these findings.…”

Section: Diet Culturesmentioning

confidence: 99%

Ingestion and assimilation of carbon from cellulolytic bacteria and heterotrophic flagellates by the mussels Geukensia demissa and Mytilus edulis (Bivalvia, Mollusca)

Da¹,

Newell²

1996

Aquat. Microb. Ecol.

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We I4C-labeled cellulolytic bacteria and 3 species of bacterivorous nanoflagellates and fed these cultured organisms to 2 species of intertidal mussels, Geukensia demissa and Mytllus edulis. using a pulse-chase experimental design under controlled laboratory conditions. Ingestion and assimilation of C from these rmcroheterotrophs by mussels were calculated from measured rates of defecation, respiration, excretion, and tlssue incorporation. The proportion of available C ingested by G. demissa did not dlffer significantly among bacteria (39%), heterotrophic flagellates (58%), or the unicellular algae Isochrysis galbana (66%), which was used as a reference diet. In contrast, M. edulis ingested a signlflcantly lower proportion (19%) of the small bacterla ( < l pm in diameter) than the larger ( 3 to 5 pm diameter) heterotrophic flagellates (58%). The efficiency with which G. dernissa assimilated C from I. galbana (77 %) was significantly greater than that from either bacteria (42 %) or heterotrophic flagellates (44%) M edulis assimilated bacterial C with significantly lower efficiency (21 96) than C from heterotrophic flagellates (62%) These results indicate that heterotrophic flagellates can contribute to the C requirements of both G. dernlssa and M edulis, however, only G. demissa is capable of assimilating a considerable amount of C from bactena.

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“…Filtration rates (FR) can vary widely among bivalve species (Moehlenberg and Riisgaard 1979;Riisgaard 1988) and have not previously been determined for O. lurida. Here, we present the results of the first laboratory-based measurements of FR by O. lurida and propose a model of FR as it varies with oyster size and temperature.…”

Section: Introductionmentioning

confidence: 99%

Quantifying the historic contribution of Olympia oysters to filtration in Pacific Coast (USA) estuaries and the implications for restoration objectives

et al. 2013

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The Olympia oyster, Ostrea lurida Carpenter, was formerly widespread in many US Pacific coast estuaries. Following dramatic declines in the late 1800s and early 1900s, this species is now the focus of renewed restoration efforts. Restoration is undertaken for brood stock rehabilitation as well as a range of ecosystem services such as filtration; however, these ecosystem services are as yet poorly quantified. We present the first laboratory measurements of filtration rates (FR) for O. lurida, to which we fit a model of FR as a function of dry tissue weight and water temperature. We find that O. lurida has a FR at optimum temperature similar to previously established means across oyster species at 1 g dry tissue weight (DTW), but lower than many Crassostrea species. We also find that the allometric exponent relating FR to DTW in O. lurida is lower than the previously published mean across oyster species. Based on our derived filtration rates and historical data, we estimate the historic impact of filtration by O. lurida in five Pacific coast estuaries. We find that historic O. lurida populations did not have the capacity to filter the full volume of the estuary within the estuary residence time in any of the estuaries examined. This result is primarily driven by the low water temperatures and the short estuary residence times that typify the Pacific coast. We conclude that, unlike Crassostrea virginica Gmelin on the Atlantic and Gulf coasts, the Olympia oyster was not historically a dominant force in regulating seston concentrations at large scales in Pacific coast estuaries. Given the differences in the ecological role and habitat structure of these two oyster species, we recommend that analogies between them be drawn with caution. We discuss the implications of our results for developing restoration objectives.

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Efficiency of particle retention and filtration rate in 6 species of Northeast American bivalves

Cited by 341 publications

References 15 publications

Quantifying the Loss of a Marine Ecosystem Service: Filtration by the Eastern Oyster in US Estuaries

Quantifying the Loss of a Marine Ecosystem Service: Filtration by the Eastern Oyster in US Estuaries

Ingestion and assimilation of carbon from cellulolytic bacteria and heterotrophic flagellates by the mussels Geukensia demissa and Mytilus edulis (Bivalvia, Mollusca)

Quantifying the historic contribution of Olympia oysters to filtration in Pacific Coast (USA) estuaries and the implications for restoration objectives

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