Cells are routinely cryopreserved in dimethyl sulfoxide (DMSO), a cryoprotective agent, for medical applications. Infusion of a DMSO-laden cell suspension results in adverse patient reactions, but current DMSO extraction processes result in significant cell losses. A diffusion-based numerical model was employed to characterize DMSO extraction in fully developed channel flow containing a wash stream flowing parallel to a DMSO-laden cell suspension. DMSO was allowed to diffuse across cell membranes as well as across the channel depth. A variety of cases were considered with the ultimate goal of characterizing the optimal geometry and flow conditions to process clinical volumes of cell suspension in a reasonable time . The results were dependent on four dimensionless parameters: depth fraction of the DMSO-laden stream, Peclet number, cell volume fraction in the DMSO-laden stream, and cell membrane permeability parameter. Smaller depth fractions led to faster DMSO extraction but channel widths that were not practical. Higher Peclet numbers led to longer channels but smaller widths. For the Peclet values and channel depths considered and appropriate permeability values, diffusion across cell membranes was significantly faster than diffusion across the channel depth. Cell volume fraction influenced the cross-stream diffusion of DMSO by limiting the fluid volume fraction available in the contaminant stream but did not play a significant role in channel geometry or operating requirements. The model was validated against preliminary experiments in which DMSO was extracted from suspensions of B-lymphoblast cells. The model results suggest that a channel device with practical dimensions can remove a sufficient level of contaminant within a mesoscale volume of cells in the required time.
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October 2007
Technical Papers
Numerical Characterization of Diffusion-Based Extraction in Cell-Laden Flow Through a Microfluidic Channel
K. K. Fleming,
K. K. Fleming
Department of Mechanical Engineering,
University of Minnesota
, 1100 Mechanical Engineering, 111 Church Street, Minneapolis, Minnesota 55455
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E. K. Longmire,
E. K. Longmire
Department of Aerospace Engineering and Mechanics,
University of Minnesota
, 107 Akerman Hall, 110 Union Street SE, Minneapolis, Minnesota 55455
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A. Hubel
A. Hubel
Department of Mechanical Engineering,
e-mail: hubel001@umn.edu
University of Minnesota
, 1100 Mechanical Engineering, 111 Church Street, Minneapolis, Minnesota 55455
Search for other works by this author on:
K. K. Fleming
Department of Mechanical Engineering,
University of Minnesota
, 1100 Mechanical Engineering, 111 Church Street, Minneapolis, Minnesota 55455
E. K. Longmire
Department of Aerospace Engineering and Mechanics,
University of Minnesota
, 107 Akerman Hall, 110 Union Street SE, Minneapolis, Minnesota 55455
A. Hubel
Department of Mechanical Engineering,
University of Minnesota
, 1100 Mechanical Engineering, 111 Church Street, Minneapolis, Minnesota 55455e-mail: hubel001@umn.edu
J Biomech Eng. Oct 2007, 129(5): 703-711 (9 pages)
Published Online: December 11, 2006
Article history
Received:
June 28, 2006
Revised:
December 11, 2006
Citation
Fleming, K. K., Longmire, E. K., and Hubel, A. (December 11, 2006). "Numerical Characterization of Diffusion-Based Extraction in Cell-Laden Flow Through a Microfluidic Channel." ASME. J Biomech Eng. October 2007; 129(5): 703–711. https://doi.org/10.1115/1.2768373
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