Literature DB >> 32699564

An on-demand bench-top fabrication process for fluidic chips based on cross-diffusion through photopolymerization.

Takumi Kimoto1, Kou Suzuki1, Takashi Fukuda2, Akira Emoto3.   

Abstract

In this paper, we propose a novel approach to fabricate fluidic chips. The method utilizes molecular cross-diffusion, induced by photopolymerization under ultraviolet (UV) irradiation in a channel pattern, to form the channel structures. During channel structure formation, the photopolymer layer still contains many uncured molecules. Subsequently, a top substrate is attached to the channel structure under adequate pressure, and the entire chip is homogenously irradiated by UV light. Immediately thereafter, a sufficiently sealed fluidic chip is formed. Using this fabrication process, the channel pattern of a chip can be designed quickly by a computer as binary images, and practical chips can be produced on demand at a benchtop, instead of awaiting production in specialized factories.
Copyright © 2020 Author(s).

Year:  2020        PMID: 32699564      PMCID: PMC7354092          DOI: 10.1063/5.0014956

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


  29 in total

1.  Ultra rapid prototyping of microfluidic systems using liquid phase photopolymerization.

Authors:  Christopher Khoury; Glennys A Mensing; David J Beebe
Journal:  Lab Chip       Date:  2002-01-10       Impact factor: 6.799

Review 2.  Recent advances in lab-on-a-chip for biosensing applications.

Authors:  Josiane P Lafleur; Alexander Jönsson; Silja Senkbeil; Jörg P Kutter
Journal:  Biosens Bioelectron       Date:  2015-08-13       Impact factor: 10.618

3.  Direct rapid prototyping of PDMS from a photomask film for micropatterning of biomolecules and cells.

Authors:  Hyundoo Hwang; Gyumin Kang; Ju Hun Yeon; Yoonkey Nam; Je-Kyun Park
Journal:  Lab Chip       Date:  2008-10-20       Impact factor: 6.799

4.  Fabrication of PMMA nanofluidic electrochemical chips with integrated microelectrodes.

Authors:  Junshan Liu; Liang Wang; Wei Ouyang; Wei Wang; Jun Qin; Zheng Xu; Shenbo Xu; Dan Ge; Longchang Wang; Chong Liu; Liding Wang
Journal:  Biosens Bioelectron       Date:  2015-05-12       Impact factor: 10.618

5.  Microfluidic photoelectrocatalytic reactors for water purification with an integrated visible-light source.

Authors:  Ning Wang; Xuming Zhang; Bolei Chen; Wuzhou Song; Ngai Yui Chan; Helen L W Chan
Journal:  Lab Chip       Date:  2012-10-21       Impact factor: 6.799

Review 6.  Microfluidic: an innovative tool for efficient cell sorting.

Authors:  Julien Autebert; Benoit Coudert; François-Clément Bidard; Jean-Yves Pierga; Stéphanie Descroix; Laurent Malaquin; Jean-Louis Viovy
Journal:  Methods       Date:  2012-07-11       Impact factor: 3.608

7.  Long-term hydrolytically stable bond formation for future membrane-based deep ocean microfluidic chemical sensors.

Authors:  M Tweedie; D Sun; B Ward; P D Maguire
Journal:  Lab Chip       Date:  2019-03-27       Impact factor: 6.799

Review 8.  Microfluidic Platforms toward Rational Material Fabrication for Biomedical Applications.

Authors:  Qilong Zhao; Huanqing Cui; Yunlong Wang; Xuemin Du
Journal:  Small       Date:  2019-10-25       Impact factor: 13.281

9.  Microspheres as resistive elements in a check valve for low pressure and low flow rate conditions.

Authors:  Kevin Ou; John Jackson; Helen Burt; Mu Chiao
Journal:  Lab Chip       Date:  2012-11-07       Impact factor: 6.799

10.  Fabrication of Micro-Optics Elements with Arbitrary Surface Profiles Based on One-Step Maskless Grayscale Lithography.

Authors:  Qinyuan Deng; Yong Yang; Hongtao Gao; Yi Zhou; Yu He; Song Hu
Journal:  Micromachines (Basel)       Date:  2017-10-23       Impact factor: 2.891
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