Filter feeders and plankton increase particle encounter rates through flow regime control

Humphries, Stuart

doi:10.1073/pnas.0809063106

Cited by 56 publications

(86 citation statements)

References 42 publications

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“…That is, a true sieving process in which all particles will be retained if greater than some minimal diameter determined by aerosol filtration theory, which takes into account particle size relative to the diameter and spacing of cylindrical wires in the mesh. In most cases, scales of relative velocity and physical length are small enough to ensure creeping flow at Reynolds number (Re) << 1, but there are cases of Re > 1 for which Humphries (2009) has shown that encounter rates of particles increase significantly above those predicted by traditional aerosol theory based on creeping (laminar) flow.…”

Section: Details Of the Capture Processmentioning

confidence: 99%

“…of the porous structure and shows to what extent particles less than the pore-size may intercept the elements, all depending on geometry, particle size and Reynolds number. Here the case of the intermediate Reynolds number range (0.1 to 50) has been studied by Palmer et al (2004) and more recently by Humphries (2009). The fraction of particles that stick when making contact is called the 'striking coefficient' (Jumars 1993).…”

Section: Filteringmentioning

confidence: 99%

“…The tentacle structures and ciliary particle capture mechanisms in bryozoans have been studied thoroughly over many years (Atkins 1932, Lutaud 1973, Gordon 1974, Ryland 1976, Winston 1977, Strathmann 1982, Strathmann & McEdward 1986, Gordon et al 1987, Nielsen 1987, 2001, 2002a,b, Mukai et al 1997, Riisgård & Manríquez 1997, Nielsen & Riisgård 1998, Riisgård et al 2004, 2009). The lateral ciliary bands of bryozoan tentacles produce feeding currents directed down into the lophophore and out between the tentacles (Figs.…”

Section: Bryozoansmentioning

confidence: 99%

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Particle capture mechanisms in suspension-feeding invertebrates

Riisgård¹,

Larsen²

2010

Mar. Ecol. Prog. Ser.

204

179

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A large number of suspension-feeding aquatic animals (e.g. bivalves, polychaetes, ascidians, bryozoans, crustaceans, sponges, echinoderms, cnidarians) have specialized in grazing on not only the 2 to 200 µm phytoplankton but frequently also the 0.5 to 2 µm free-living bacteria, or they have specialized in capturing larger prey, e.g. zooplankton organisms. We review the different particle capture mechanisms in order to illustrate the many solutions to the common problem of obtaining nourishment from a dilute suspension of microscopic food particles. Despite the many differences in morphology and living conditions, particle capture mechanisms may be divided into 2 main types. (1) Filtering or sieving (e.g. through mucus nets, stiff cilia, filter setae), which is found in passive suspension feeders that rely on external currents to bring suspended particles to the filter, and in active suspension feeders that themselves produce a feeding flow by a variety of pump systems. Here the inventiveness of nature does not lie in the capture mechanism but in the type of pump system and filter pore-size. (2) A paddle-like flow manipulating system (e.g. cilia, cirri, tentacles, hair-bearing appendages) that acts to redirect an approaching suspended particle, often along with a surrounding 'fluid parcel', to a strategic location for arrest or further transport. Examples include (1) sieving (e.g. by microvilli in sponge choanocytes, mucus nets in polychaetes, acidians, and salps among others), filter setae in crustaceans, 'ciliary sieving' by stiff laterofrontal cilia in bryozoans and phoronids; and (2) 'cirri trapping' in mussels and other bivalves with eu-laterofrontal cirri, ciliary 'catch-up' in bivalve and gastropod veliger larvae, some polychaetes, entroprocts, and cycliophores. These capture mechanisms may involve contact with a particle, and possibly mechanoreception or chemoreception, or may include redirection of particles by the interaction of multiple currents (e.g. in scallops and other bivalves without eu-laterofrontal cirri). Based on the review, we discuss the current physical and biological understanding of the capture process and suggest a number of specific problems related to particle capture, which may be solved in the future using advanced theoretical, computational and experimental techniques.

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Section: Details Of the Capture Processmentioning

confidence: 99%

Section: Filteringmentioning

confidence: 99%

Section: Bryozoansmentioning

confidence: 99%

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Particle capture mechanisms in suspension-feeding invertebrates

Riisgård¹,

Larsen²

2010

Mar. Ecol. Prog. Ser.

204

179

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“…EVR for C. sowerbyi assumes that the dominant prey encounter mechanism is direct interception and relies upon Re ranging from 0.2-2 around the tentacles. We can estimate the EVR using intermediate Re estimates (Humphries, 2009) …”

Section: Flow and Prey Encountermentioning

confidence: 99%

Fluid Interactions That Enable Stealth Predation by the Upstream-Foraging Hydromedusa Craspedacusta sowerbyi

Lucas

Colin²,

Costello³

et al. 2013

The Biological Bulletin

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Abstract. Unlike most medusae that forage with tentacles trailing behind their bells, several species forage upstream of their bells using aborally located tentacles. It has been hypothesized that these medusae forage as stealth predators by placing their tentacles in more quiescent regions of flow around their bells. Consequently, they are able to capture highly mobile, sensitive prey. We used digital particle image velocimetry (DPIV) to quantitatively characterize the flow field around Craspedacusta sowerbyi, a freshwater upstream-foraging hydromedusa, to evaluate the mechanics of its stealth predation. We found that fluid velocities were minimal in front and along the sides of the bell where the tentacles are located. As a result, the deformation rates in the regions where the tentacles are located were low, below the threshold rates required to elicit an escape response in several species of copepods. Estimates of their encounter volume rates were examined on the basis of flow past the tentacles, and trade-offs associated with tentacle characteristics were evaluated.

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“…For example, at high Reynolds number (Re), diffusive deposition is negligible, while the compression of streamlines around the feeding structure provides a potential mechanism for increased encounter of particles. 5 At low Re, inertia is negligible and the feeding structure has to manipulate the surrounding fluid to generate feeding currents that bring suspended particles closer to the feeding organ.…”

Section: Introductionmentioning

confidence: 99%

Selective particle capture by asynchronously beating cilia

Ding

Kanso

2015

Physics of Fluids

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Selective particle filtration is fundamental in many engineering and biological systems. For example, many aquatic microorganisms use filter feeding to capture food particles from the surrounding fluid, using motile cilia. One of the capture strategies is to use the same cilia to generate feeding currents and to intercept particles when the particles are on the downstream side of the cilia. Here, we develop a 3D computational model of ciliary bands interacting with flow suspended particles and calculate particle trajectories for a range of particle sizes. Consistent with experimental observations, we find optimal particle sizes that maximize capture rate. The optimal size depends nonlinearly on cilia spacing and cilia coordination, synchronous vs. asynchronous. These parameters affect the cilia-generated flow field, which in turn affects particle trajectories. The low capture rate of smaller particles is due to the particles' inability to cross the flow streamlines of neighboring cilia. Meanwhile, large particles have difficulty entering the sub-ciliary region once advected downstream, also resulting in low capture rates. The optimal range of particle sizes is enhanced when cilia beat asynchronously. These findings have potentially important implications on the design and use of biomimetic cilia in processes such as particle sorting in microfluidic devices. C 2015 AIP Publishing LLC. [http://dx

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Filter feeders and plankton increase particle encounter rates through flow regime control

Cited by 56 publications

References 42 publications

Particle capture mechanisms in suspension-feeding invertebrates

Particle capture mechanisms in suspension-feeding invertebrates

Fluid Interactions That Enable Stealth Predation by the Upstream-Foraging Hydromedusa Craspedacusta sowerbyi

Selective particle capture by asynchronously beating cilia

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