Your search keyword '"Microfiltration model"' showing total 4 results

1. Co-current crossflow microfiltration in a microchannel

Author

Michael I Hill, Cees J.M. van Rijn, Daniela Guisado, Mónica Faria, Levy I Amar, and Edward F. Leonard

Subjects

Microfiltration model, Materials science, Erythrocytes, Sieve, Microfiltration, Microfluidics, Biomedical Engineering, 02 engineering and technology, 01 natural sciences, Microsieve, law.invention, Nanopores, Plasma, law, Pressure, Molecular Biology, Filtration, Backflow, VLAG, Pressure drop, Cross-flow, Steady state, Microchannel, 010401 analytical chemistry, Organic Chemistry, Water, Membranes, Artificial, Mechanics, Equipment Design, Models, Theoretical, 021001 nanoscience & nanotechnology, Organische Chemie, Constant transmembrane pressure, 0104 chemical sciences, Membrane, Blood, Current (fluid), 0210 nano-technology

Abstract

Steady state crossflow microfiltration (CMF) is an important and often necessary means of particle separation and concentration for both industrial and biomedical processes. The factors controlling the performance of CMF have been extensively reviewed. A major factor is transmembrane pressure (TMP). Because microchannels have small height, they tend to have high pressure gradients in the feed-flow direction. In the extreme, these gradients may even reverse the pressure across the membrane (inciting backflow). It is therefore desirable to compensate for the effect of feed-flow on the TMP, aiming at constant transmembrane pressure (cTMP) at a value which maximizes filtrate flux. This is especially critical during filtration of deformable particles (e.g. erythrocytes) through low intrinsic resistance membranes. Filtration flux is generally taken to be directly proportional to TMP, with pressure drop along the channel decreasing in the flow direction. A co-current flow of filtrate in a suitably designed filtrate collecting channel is shown to allow the TMP to remain constant and permit the sieving surface to perform optimally, permitting up to twice as much filtration over that of a naïve configuration. Manipulation of the filtrate channel may be even more beneficial if it prevents backflow that might otherwise occur at the end of a sufficiently long channel. Experiments with erythrocyte suspensions, reported here, validate these concepts.

Published

2019

2. Erythrocyte fouling on micro-engineered membranes

Author

Amar, Levy I., Guisado, Daniela, Faria, Monica, Jones, James P., van Rijn, Cees J. M., Hill, Michael I., and Leonard, Edward F.

Published

2018

3. Erythrocyte fouling on micro-engineered membranes

Author

Cees J.M. van Rijn, James Jones, Mónica Faria, Edward F. Leonard, Daniela Guisado, Levy I Amar, and Michael I Hill

Subjects

Microfiltration model, Photolithography, Erythrocytes, Materials science, Sieve, Microfiltration, Microfluidics, Biomedical Engineering, 02 engineering and technology, Microsieve, 01 natural sciences, Cross-flow filtration, law.invention, Nanopores, law, Lab-On-A-Chip Devices, Monolayer, Pressure, Humans, Porosity, Molecular Biology, Filtration, VLAG, Cross-flow, Microchannel, Fouling, Organic Chemistry, 010401 analytical chemistry, Water, Membranes, Artificial, Equipment Design, 021001 nanoscience & nanotechnology, Organische Chemie, 0104 chemical sciences, Blood, Membrane, Chemical engineering, 0210 nano-technology

Abstract

Crossflow microfiltration of plasma from blood through microsieves in a microchannel is potentially useful in many biomedical applications, including clinically as a wearable water removal device under development by the authors. We report experiments that correlate filtration rates, transmembrane pressures (TMP) and shear rates during filtration through a microscopically high channel bounded by a low intrinsic resistance photolithographically-produced porous semiconductor membrane. These experiments allowed observation of erythrocyte behavior at the filtering surface and showed how their unique deformability properties dominated filtration resistance. At low filtration rates (corresponding to low TMP), they rolled along the filter surface, but at higher filtration rates (corresponding to higher TMP), they anchored themselves to the filter membrane, forming a self-assembled, incomplete monolayer. The incompleteness of the layer was an essential feature of the monolayer’s ability to support sustainable filtration. Maximum steady-state filtration flux was a function of wall shear rate, as predicted by conventional crossflow filtration theory, but, contrary to theories based on convective diffusion, showed weak dependence of filtration on erythrocyte concentration. Post-filtration scanning electron micrographs revealed significant capture and deformation of erythrocytes in all filter pores in the range 0.25 to 2 μm diameter. We report filtration rates through these filters and describe a largely unrecognized mechanism that allows stable filtration in the presence of substantial cell layers.

Published

2018

4. Co-current crossflow microfiltration in a microchannel.

Author

Amar, Levy I., Hill, Michael I., Faria, Monica, Guisado, Daniela, van Rijn, Cees J. M., and Leonard, Edward F.

Abstract

Steady state crossflow microfiltration (CMF) is an important and often necessary means of particle separation and concentration for both industrial and biomedical processes. The factors controlling the performance of CMF have been extensively reviewed. A major factor is transmembrane pressure (TMP). Because microchannels have small height, they tend to have high pressure gradients in the feed-flow direction. In the extreme, these gradients may even reverse the pressure across the membrane (inciting backflow). It is therefore desirable to compensate for the effect of feed-flow on the TMP, aiming at constant transmembrane pressure (cTMP) at a value which maximizes filtrate flux. This is especially critical during filtration of deformable particles (e.g. erythrocytes) through low intrinsic resistance membranes. Filtration flux is generally taken to be directly proportional to TMP, with pressure drop along the channel decreasing in the flow direction. A co-current flow of filtrate in a suitably designed filtrate collecting channel is shown to allow the TMP to remain constant and permit the sieving surface to perform optimally, permitting up to twice as much filtration over that of a naïve configuration. Manipulation of the filtrate channel may be even more beneficial if it prevents backflow that might otherwise occur at the end of a sufficiently long channel. Experiments with erythrocyte suspensions, reported here, validate these concepts. [ABSTRACT FROM AUTHOR]

Published

2019