Literature DB >> 18645356

Microchannel technologies for artificial lungs: (3) open rectangular channels.

J-K Lee1, M C Kung, H H Kung, L F Mockros.   

Abstract

Lithographic techniques were used to develop patterned silicone rubber membranes that provide 15 microm high microchannels for artificial lungs. Two types of devices were fabricated as a proof-of-concept: one has a series of parallel, straight, open rectangular channels that are each 300 microm wide, separated by 200-microm walls, and 3-mm long and the other is a wide rectangular channel with support posts, also 3- mm long. Experiments with 30% hematocrit, venous, bovine blood showed average oxygen fluxes ranging from 11 x 10(-7) moles/(min x cm(2)) at a residence time of 0.04 sec to 6.5 x 10(-7) moles/(min x cm(2)) at a residence time of 0.20 sec. The average oxygen flux vs. residence time, which is due to transverse molecular diffusion, follows the same relation for all membranes tested. The corresponding increase in hemoglobin saturation ranged from 9% at the residence time of 0.04 sec to 24% at the residence time of 0.20 sec. The support-post channel membranes are attractive for designers because they can be arbitrarily wide and would be less prone to blockage.

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Year:  2008        PMID: 18645356      PMCID: PMC2702480          DOI: 10.1097/MAT.0b013e31817eda02

Source DB:  PubMed          Journal:  ASAIO J        ISSN: 1058-2916            Impact factor:   2.872


  6 in total

Review 1.  Microfluidic devices fabricated in poly(dimethylsiloxane) for biological studies.

Authors:  Samuel K Sia; George M Whitesides
Journal:  Electrophoresis       Date:  2003-11       Impact factor: 3.535

2.  Slow viscous flow in a lung alveoli model.

Authors:  J S Lee
Journal:  J Biomech       Date:  1969-05       Impact factor: 2.712

3.  Microchannel technologies for artificial lungs: (1) theory.

Authors:  J K Lee; H H Kung; L F Mockros
Journal:  ASAIO J       Date:  2008 Jul-Aug       Impact factor: 2.872

4.  Rapid Prototyping of Microfluidic Systems in Poly(dimethylsiloxane).

Authors:  D C Duffy; J C McDonald; O J Schueller; G M Whitesides
Journal:  Anal Chem       Date:  1998-12-01       Impact factor: 6.986

5.  Computational and functional evaluation of a microfluidic blood flow device.

Authors:  Richard J Gilbert; Hyesung Park; Marco Rasponi; Alberto Redaelli; Barry Gellman; Kurt A Dasse; Todd Thorsen
Journal:  ASAIO J       Date:  2007 Jul-Aug       Impact factor: 2.872

6.  Microchannel technologies for artificial lungs: (2) screen-filled wide rectangular channels.

Authors:  M C Kung; J-K Lee; H H Kung; L F Mockros
Journal:  ASAIO J       Date:  2008 Jul-Aug       Impact factor: 2.872
  6 in total
  12 in total

1.  Engineering tissue with BioMEMS.

Authors:  Jeffrey T Borenstein; Gordana Vunjak-Novakovic
Journal:  IEEE Pulse       Date:  2011-11       Impact factor: 0.924

2.  Stem cells and cell therapies in lung biology and diseases: conference report.

Authors:  Daniel J Weiss; Jason H T Bates; Thomas Gilbert; W Conrad Liles; Carolyn Lutzko; Jay Rajagopal; Darwin Prockop
Journal:  Ann Am Thorac Soc       Date:  2013-10

3.  Liquid Flooded Flow-Focusing Microfluidic Device for in situ Generation of Monodisperse Microbubbles.

Authors:  Ali Haider Dhanaliwala; Johnny L Chen; Shiying Wang; John A Hossack
Journal:  Microfluid Nanofluidics       Date:  2012-10-06       Impact factor: 2.529

4.  Gas Transfer in Cellularized Collagen-Membrane Gas Exchange Devices.

Authors:  Justin H Lo; Erik K Bassett; Elliot J N Penson; David M Hoganson; Joseph P Vacanti
Journal:  Tissue Eng Part A       Date:  2015-07-16       Impact factor: 3.845

5.  Production rate and diameter analysis of spherical monodisperse microbubbles from two-dimensional, expanding-nozzle flow-focusing microfluidic devices.

Authors:  Shiying Wang; Ali H Dhanaliwala; Johnny L Chen; John A Hossack
Journal:  Biomicrofluidics       Date:  2013-01-16       Impact factor: 2.800

6.  Development of a biomimetic microfluidic oxygen transfer device.

Authors:  A A Gimbel; E Flores; A Koo; G García-Cardeña; J T Borenstein
Journal:  Lab Chip       Date:  2016-08-16       Impact factor: 6.799

7.  Microfluidic Valves Made From Polymerized Polyethylene Glycol Diacrylate.

Authors:  Chad I Rogers; Joseph B Oxborrow; Ryan R Anderson; Long-Fang Tsai; Gregory P Nordin; Adam T Woolley
Journal:  Sens Actuators B Chem       Date:  2014-02-01       Impact factor: 7.460

8.  A small-scale, rolled-membrane microfluidic artificial lung designed towards future large area manufacturing.

Authors:  A J Thompson; L H Marks; M J Goudie; A Rojas-Pena; H Handa; J A Potkay
Journal:  Biomicrofluidics       Date:  2017-04-05       Impact factor: 2.800

9.  An ultra-thin, all PDMS-based microfluidic lung assist device with high oxygenation capacity.

Authors:  Mohammadhossein Dabaghi; Neda Saraei; Gerhard Fusch; Niels Rochow; John L Brash; Christoph Fusch; P Ravi Selvaganapathy
Journal:  Biomicrofluidics       Date:  2019-06-27       Impact factor: 2.800

10.  Steel reinforced composite silicone membranes and its integration to microfluidic oxygenators for high performance gas exchange.

Authors:  Harpreet Matharoo; Mohammadhossein Dabaghi; Niels Rochow; Gerhard Fusch; Neda Saraei; Mohammed Tauhiduzzaman; Stephen Veldhuis; John Brash; Christoph Fusch; P Ravi Selvaganapathy
Journal:  Biomicrofluidics       Date:  2018-01-11       Impact factor: 2.800
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