Literature DB >> 18383190

Sheathless focusing of microbeads and blood cells based on hydrophoresis.

Sungyoung Choi1, Seungjeong Song, Chulhee Choi, Je-Kyun Park.   

Abstract

This paper presents a microfluidic device for sheathless focusing of microbeads and blood cells based on a hydrophoretic platform comprising a V-shaped obstacle array (VOA). The VOA generates lateral pressure gradients that induce helical recirculations. Following the focusing flow particles passing through the VOA are focused in the center of the channel. In the device, the focusing pattern can be modulated by varying the gap height of the VOA. To achieve complete focusing within 4.4% coefficient of variation, the relative size differences between the gap and the particle were 3 and 4 microm for 10 and 15 microm beads, respectively. Red blood cells were used to study the hydrophoretic focusing pattern of biconcave, disk-shaped particles.

Mesh:

Year:  2008        PMID: 18383190     DOI: 10.1002/smll.200700308

Source DB:  PubMed          Journal:  Small        ISSN: 1613-6810            Impact factor:   13.281


  19 in total

1.  Three-dimensional cellular focusing utilizing a combination of insulator-based and metallic dielectrophoresis.

Authors:  Ching-Te Huang; Cheng-Hsin Weng; Chun-Ping Jen
Journal:  Biomicrofluidics       Date:  2011-10-03       Impact factor: 2.800

2.  A method for reducing pressure-induced deformation in silicone microfluidics.

Authors:  David W Inglis
Journal:  Biomicrofluidics       Date:  2010-06-17       Impact factor: 2.800

3.  Hydrodynamic self-focusing in a parallel microfluidic device through cross-filtration.

Authors:  S Torino; M Iodice; I Rendina; G Coppola; E Schonbrun
Journal:  Biomicrofluidics       Date:  2015-11-20       Impact factor: 2.800

4.  A hydrodynamic focusing microchannel based on micro-weir shear lift force.

Authors:  Ruey-Jen Yang; Hui-Hsiung Hou; Yao-Nan Wang; Che-Hsin Lin; Lung-Ming Fu
Journal:  Biomicrofluidics       Date:  2012-08-06       Impact factor: 2.800

5.  Electrokinetic focusing and filtration of cells in a serpentine microchannel.

Authors:  Christopher Church; Junjie Zhu; Gaoyan Wang; Tzuen-Rong J Tzeng; Xiangchun Xuan
Journal:  Biomicrofluidics       Date:  2009-11-24       Impact factor: 2.800

6.  Making a hydrophoretic focuser tunable using a diaphragm.

Authors:  Sheng Yan; Jun Zhang; Huaying Chen; Gursel Alici; Haiping Du; Yonggang Zhu; Weihua Li
Journal:  Biomicrofluidics       Date:  2014-12-04       Impact factor: 2.800

7.  Hydrodynamic particle focusing design using fluid-particle interaction.

Authors:  Teng Zhou; Zhenyu Liu; Yihui Wu; Yongbo Deng; Yongshun Liu; Geng Liu
Journal:  Biomicrofluidics       Date:  2013-09-11       Impact factor: 2.800

8.  Microfluidic cell concentrator with a reduced-deviation-flow herringbone structure.

Authors:  Ji-Chul Hyun; Jongchan Choi; Yu-Gyung Jung; Sung Yang
Journal:  Biomicrofluidics       Date:  2017-09-27       Impact factor: 2.800

9.  Sub-micrometer-precision, three-dimensional (3D) hydrodynamic focusing via "microfluidic drifting".

Authors:  Ahmad Ahsan Nawaz; Xiangjun Zhang; Xiaole Mao; Joseph Rufo; Sz-Chin Steven Lin; Feng Guo; Yanhui Zhao; Michael Lapsley; Peng Li; J Philip McCoy; Stewart J Levine; Tony Jun Huang
Journal:  Lab Chip       Date:  2013-11-28       Impact factor: 6.799

10.  Single stream inertial focusing in a straight microchannel.

Authors:  Xiao Wang; Matthew Zandi; Chia-Chi Ho; Necati Kaval; Ian Papautsky
Journal:  Lab Chip       Date:  2015-04-21       Impact factor: 6.799
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