3D sheath flow using hydrodynamic position control of the sample flow

Hironobu Sato; Yutaka Sasamoto; Daisuke Yagyu; Tetsushi Sekiguchi; Shuichi Shoji

doi:10.1088/0960-1317/17/11/006

3D sheath flow using hydrodynamic position control of the sample flow

Hironobu Sato^*, Yutaka Sasamoto, Daisuke Yagyu, Tetsushi Sekiguchi, Shuichi Shoji

^*この研究の対応する著者

研究成果: Article › 査読

12 被引用数 (Scopus)

抄録

3D sheath flow was realized using hydrodynamic position control of the sample flow. The symmetric microgrooves formed on the channel walls were utilized to generate local directional streams. The sample introduced into the grooved area was shifted to the center region of the microchannel, and 3D sheath flow was formed passively. Using CFD (computational fluid dynamics) simulation, the flow shift area was designed to achieve 3D sheath flow no longer than 500 νm in channel length. Sample flow shift behavior was observed by using a confocal microscope. Since the structure of the inlets was very simple, it was possible to fabricate an in-plane multi-sample 3D sheath flow device. As a demonstration, a two-sample 3D sheath flow device was fabricated. The separated two-sample 3D sheath flow configuration was clearly observed.

本文言語	English
ページ（範囲）	2211-2216
ページ数	6
ジャーナル	Journal of Micromechanics and Microengineering
巻	17
号	11
DOI	https://doi.org/10.1088/0960-1317/17/11/006
出版ステータス	Published - 2007 11月 1

ASJC Scopus subject areas

電子材料、光学材料、および磁性材料
材料力学
機械工学
電子工学および電気工学

文献へのアクセス

10.1088/0960-1317/17/11/006

他のファイルとリンク

引用スタイル

@article{81cacc8d74c84e96ba90b5b851c10e2b,

title = "3D sheath flow using hydrodynamic position control of the sample flow",

abstract = "3D sheath flow was realized using hydrodynamic position control of the sample flow. The symmetric microgrooves formed on the channel walls were utilized to generate local directional streams. The sample introduced into the grooved area was shifted to the center region of the microchannel, and 3D sheath flow was formed passively. Using CFD (computational fluid dynamics) simulation, the flow shift area was designed to achieve 3D sheath flow no longer than 500 νm in channel length. Sample flow shift behavior was observed by using a confocal microscope. Since the structure of the inlets was very simple, it was possible to fabricate an in-plane multi-sample 3D sheath flow device. As a demonstration, a two-sample 3D sheath flow device was fabricated. The separated two-sample 3D sheath flow configuration was clearly observed.",

author = "Hironobu Sato and Yutaka Sasamoto and Daisuke Yagyu and Tetsushi Sekiguchi and Shuichi Shoji",

year = "2007",

month = nov,

day = "1",

doi = "10.1088/0960-1317/17/11/006",

language = "English",

volume = "17",

pages = "2211--2216",

journal = "Journal of Micromechanics and Microengineering",

issn = "0960-1317",

publisher = "IOP Publishing Ltd.",

number = "11",

}

TY - JOUR

T1 - 3D sheath flow using hydrodynamic position control of the sample flow

AU - Sato, Hironobu

AU - Sasamoto, Yutaka

AU - Yagyu, Daisuke

AU - Sekiguchi, Tetsushi

AU - Shoji, Shuichi

PY - 2007/11/1

Y1 - 2007/11/1

N2 - 3D sheath flow was realized using hydrodynamic position control of the sample flow. The symmetric microgrooves formed on the channel walls were utilized to generate local directional streams. The sample introduced into the grooved area was shifted to the center region of the microchannel, and 3D sheath flow was formed passively. Using CFD (computational fluid dynamics) simulation, the flow shift area was designed to achieve 3D sheath flow no longer than 500 νm in channel length. Sample flow shift behavior was observed by using a confocal microscope. Since the structure of the inlets was very simple, it was possible to fabricate an in-plane multi-sample 3D sheath flow device. As a demonstration, a two-sample 3D sheath flow device was fabricated. The separated two-sample 3D sheath flow configuration was clearly observed.

AB - 3D sheath flow was realized using hydrodynamic position control of the sample flow. The symmetric microgrooves formed on the channel walls were utilized to generate local directional streams. The sample introduced into the grooved area was shifted to the center region of the microchannel, and 3D sheath flow was formed passively. Using CFD (computational fluid dynamics) simulation, the flow shift area was designed to achieve 3D sheath flow no longer than 500 νm in channel length. Sample flow shift behavior was observed by using a confocal microscope. Since the structure of the inlets was very simple, it was possible to fabricate an in-plane multi-sample 3D sheath flow device. As a demonstration, a two-sample 3D sheath flow device was fabricated. The separated two-sample 3D sheath flow configuration was clearly observed.

UR - http://www.scopus.com/inward/record.url?scp=35648929980&partnerID=8YFLogxK

UR - http://www.scopus.com/inward/citedby.url?scp=35648929980&partnerID=8YFLogxK

U2 - 10.1088/0960-1317/17/11/006

DO - 10.1088/0960-1317/17/11/006

M3 - Article

AN - SCOPUS:35648929980

SN - 0960-1317

VL - 17

SP - 2211

EP - 2216

JO - Journal of Micromechanics and Microengineering

JF - Journal of Micromechanics and Microengineering

IS - 11

ER -

3D sheath flow using hydrodynamic position control of the sample flow

抄録

ASJC Scopus subject areas

文献へのアクセス

他のファイルとリンク

フィンガープリント

引用スタイル