Literature DB >> 22662066

Sealing SU-8 microfluidic channels using PDMS.

Zhiyi Zhang, Ping Zhao, Gaozhi Xiao, Benjamin R Watts, Changqing Xu.   

Abstract

A simple method of irreversibly sealing SU-8 microfluidic channels using PDMS is reported in this paper. The method is based on inducing a chemical reaction between PDMS and SU-8 by first generating amino groups on PDMS surface using N(2) plasma treatment, then allowing the amino groups to react with the residual epoxy groups on SU-8 surface at an elevated temperature. The N(2) plasma treatment of PDMS can be conducted using an ordinary plasma chamber and high purity N(2), while the residual epoxy groups on SU-8 surface can be preserved by post-exposure baking SU-8 at a temperature no higher than 95 °C. The resultant chemical bonding between PDMS and SU-8 using the method create an interface that can withstand a stress that is greater than the bulk strength of PDMS. The bond is permanent and is long-term resistant to water. The method was applied in fabricating SU-8 microfluidi-photonic integrated devices, and the obtained devices were tested to show desirable performance.

Entities:  

Year:  2011        PMID: 22662066      PMCID: PMC3364813          DOI: 10.1063/1.3659016

Source DB:  PubMed          Journal:  Biomicrofluidics        ISSN: 1932-1058            Impact factor:   2.800


  7 in total

1.  Components for integrated poly(dimethylsiloxane) microfluidic systems.

Authors:  Jessamine M K Ng; Irina Gitlin; Abraham D Stroock; George M Whitesides
Journal:  Electrophoresis       Date:  2002-10       Impact factor: 3.535

2.  Measurements of scattered light on a microchip flow cytometer with integrated polymer based optical elements.

Authors:  Z Wang; J El-Ali; M Engelund; T Gotsaed; I R Perch-Nielsen; K B Mogensen; D Snakenborg; J P Kutter; A Wolff
Journal:  Lab Chip       Date:  2004-04-20       Impact factor: 6.799

3.  A SU-8/PDMS hybrid microfluidic device with integrated optical fibers for online monitoring of lactate.

Authors:  Min-Hsien Wu; Haoyuan Cai; Xia Xu; Jill P G Urban; Zhan-Feng Cui; Zheng Cui
Journal:  Biomed Microdevices       Date:  2005-12       Impact factor: 2.838

4.  Generation of hydrophilic poly(dimethylsiloxane) for high-performance microchip electrophoresis.

Authors:  Jonathan A Vickers; Meghan M Caulum; Charles S Henry
Journal:  Anal Chem       Date:  2006-11-01       Impact factor: 6.986

5.  Fabrication of SU-8 based microchip electrophoresis with integrated electrochemical detection for neurotransmitters.

Authors:  Mario Castaño-Alvarez; M Teresa Fernández-Abedul; Agustín Costa-García; María Agirregabiria; Luis J Fernández; Jesús Miguel Ruano-López; Borja Barredo-Presa
Journal:  Talanta       Date:  2009-06-25       Impact factor: 6.057

6.  Self-assembled epoxy-modified polymer coating on a poly(dimethylsiloxane) microchip for EOF inhibition and biopolymers separation.

Authors:  Dapeng Wu; Jianhua Qin; Bingcheng Lin
Journal:  Lab Chip       Date:  2007-08-28       Impact factor: 6.799

7.  Formation and characterization of an ideal excitation beam geometry in an optofluidic device.

Authors:  Benjamin R Watts; Thomas Kowpak; Zhiyi Zhang; Chang-Qing Xu; Shiping Zhu
Journal:  Biomed Opt Express       Date:  2010-09-14       Impact factor: 3.732
  7 in total
  13 in total

1.  A nanofilter for fluidic devices by pillar-assisted self-assembly microparticles.

Authors:  Tamer AbdelFatah; Mahsa Jalali; Sara Mahshid
Journal:  Biomicrofluidics       Date:  2018-11-19       Impact factor: 2.800

2.  Development of vertical SU-8 microneedles for transdermal drug delivery by double drawing lithography technology.

Authors:  Zhuolin Xiang; Hao Wang; Aakanksha Pant; Giorgia Pastorin; Chengkuo Lee
Journal:  Biomicrofluidics       Date:  2013-12-06       Impact factor: 2.800

3.  A reproducible method for μm precision alignment of PDMS microchannels with on-chip electrodes using a mask aligner.

Authors:  J Cottet; C Vaillier; F Buret; M Frénéa-Robin; P Renaud
Journal:  Biomicrofluidics       Date:  2017-12-20       Impact factor: 2.800

4.  Development of low-fluorescence thick photoresist for high-aspect-ratio microstructure in bio-application.

Authors:  H Tamai; K Maruo; H Ueno; K Terao; H Kotera; T Suzuki
Journal:  Biomicrofluidics       Date:  2015-04-13       Impact factor: 2.800

5.  Integration of optical components on-chip for scattering and fluorescence detection in an optofluidic device.

Authors:  Benjamin R Watts; Zhiyi Zhang; Chang-Qing Xu; Xudong Cao; Min Lin
Journal:  Biomed Opt Express       Date:  2012-10-10       Impact factor: 3.732

6.  SU-8 free-standing microfluidic probes.

Authors:  A A Kim; K Kustanovich; D Baratian; A Ainla; M Shaali; G D M Jeffries; A Jesorka
Journal:  Biomicrofluidics       Date:  2017-02-14       Impact factor: 2.800

Review 7.  Optofluidic Device Based Microflow Cytometers for Particle/Cell Detection: A Review.

Authors:  Yushan Zhang; Benjamin R Watts; Tianyi Guo; Zhiyi Zhang; Changqing Xu; Qiyin Fang
Journal:  Micromachines (Basel)       Date:  2016-04-15       Impact factor: 2.891

8.  Application of Vertical Electrodes in Microfluidic Channels for Impedance Analysis.

Authors:  Qiang Li; Yong J Yuan
Journal:  Micromachines (Basel)       Date:  2016-05-25       Impact factor: 2.891

9.  A method for detecting forward scattering signals on-chip with a photonic-microfluidic integrated device.

Authors:  Benjamin R Watts; Zhiyi Zhang; Chang-Qing Xu; Xudong Cao; Min Lin
Journal:  Biomed Opt Express       Date:  2013-06-07       Impact factor: 3.732

10.  A portable system for processing donated whole blood into high quality components without centrifugation.

Authors:  Sean C Gifford; Briony C Strachan; Hui Xia; Eszter Vörös; Kian Torabian; Taylor A Tomasino; Gary D Griffin; Benjamin Lichtiger; Fleur M Aung; Sergey S Shevkoplyas
Journal:  PLoS One       Date:  2018-01-18       Impact factor: 3.240
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