Literature DB >> 15672129

Microfluidic channel fabrication in dry film resist for production and prototyping of hybrid chips.

P Vulto1, N Glade, L Altomare, J Bablet, L Del Tin, G Medoro, I Chartier, N Manaresi, M Tartagni, R Guerrieri.   

Abstract

Microfluidic networks are patterned in a dry film resist (Ordyl SY300/550) that is sandwiched in between two substrates. The technique enables fabrication of complex biochips with active elements both in the bottom and the top substrate (hybrid chips). The resist can be double bonded at relatively low temperatures without the use of extra adhesives. A postbake transfers the resist into a rigid structure. The resist is qualified in terms of resolution, biocompatibility and fluidic sealing. Fabrication in both a fully equipped cleanroom setting as well as a minimally equipped laboratory is described. The technique is applied for dielectrophoresis-based cell separation systems and a fuel cell reaction chamber with micropillars. The dry film resist can be considered a cheap and fast alternative to SU-8.

Year:  2004        PMID: 15672129     DOI: 10.1039/b411885e

Source DB:  PubMed          Journal:  Lab Chip        ISSN: 1473-0189            Impact factor:   6.799


  14 in total

1.  Trapping single human osteoblast-like cells from a heterogeneous population using a dielectrophoretic microfluidic device.

Authors:  Rupert S W Thomas; Peter D Mitchell; Richard O C Oreffo; Hywel Morgan
Journal:  Biomicrofluidics       Date:  2010-06-29       Impact factor: 2.800

2.  Print-to-Pattern Dry Film Photoresist Lithography.

Authors:  Shaun P Garland; Terrence M Murphy; Tingrui Pan
Journal:  J Micromech Microeng       Date:  2014-05-01       Impact factor: 1.881

3.  M³: Microscope-based maskless micropatterning with dry film photoresist.

Authors:  Steven Y Leigh; Aashay Tattu; Joseph S B Mitchell; Emilia Entcheva
Journal:  Biomed Microdevices       Date:  2011-04       Impact factor: 2.838

4.  Review article-dielectrophoresis: status of the theory, technology, and applications.

Authors:  Ronald Pethig
Journal:  Biomicrofluidics       Date:  2010-06-29       Impact factor: 2.800

Review 5.  From cleanroom to desktop: emerging micro-nanofabrication technology for biomedical applications.

Authors:  Tingrui Pan; Wei Wang
Journal:  Ann Biomed Eng       Date:  2010-12-14       Impact factor: 3.934

6.  Detection of Dissolved Lactose Employing an Optofluidic Micro-System.

Authors:  Emanuel Weber; Franz Keplinger; Michael J Vellekoop
Journal:  Diagnostics (Basel)       Date:  2012-12-06

7.  High-Throughput Fabrication of Flexible and Transparent All-Carbon Nanotube Electronics.

Authors:  Yong-Yang Chen; Yun Sun; Qian-Bing Zhu; Bing-Wei Wang; Xin Yan; Song Qiu; Qing-Wen Li; Peng-Xiang Hou; Chang Liu; Dong-Ming Sun; Hui-Ming Cheng
Journal:  Adv Sci (Weinh)       Date:  2018-02-20       Impact factor: 16.806

8.  Microfluidic Overhauser DNP chip for signal-enhanced compact NMR.

Authors:  Sebastian Z Kiss; Neil MacKinnon; Jan G Korvink
Journal:  Sci Rep       Date:  2021-02-25       Impact factor: 4.379

9.  Dry Film Resist Laminated Microfluidic System for Electrical Impedance Measurements.

Authors:  Yuan Cao; Julia Floehr; Sven Ingebrandt; Uwe Schnakenberg
Journal:  Micromachines (Basel)       Date:  2021-05-29       Impact factor: 2.891

10.  A Versatile Microarray Platform for Capturing Rare Cells.

Authors:  Falko Brinkmann; Michael Hirtz; Anna Haller; Tobias M Gorges; Michael J Vellekoop; Sabine Riethdorf; Volkmar Müller; Klaus Pantel; Harald Fuchs
Journal:  Sci Rep       Date:  2015-10-23       Impact factor: 4.379
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