A high-performance micromixer using three-dimensional Tesla structures for bio-applications

•A new high-performance micromixer via 3D Tesla structures was designed, fabricated and tested.•The mixing efficiency was up to 0.94 at the volumetric flow rate 0.015–15μL/s.•The immunofluorescence experiments showed the mixing efficacy of this micromixer. Micromixers have been commonly utilized in...

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Bibliographic Details
Published in:Chemical engineering journal (Lausanne, Switzerland : 1996) Switzerland : 1996), 2015-03, Vol.263, p.444-451
Main Authors: Yang, An-Shik, Chuang, Feng-Chao, Chen, Chi-Kuan, Lee, Mei-Hui, Chen, Shih-Wei, Su, Tsai-Lung, Yang, Yung-Chun
Format: Article
Language:English
Subjects:
Antigens
Cancer
Cellular
CFD simulation
Computational fluid dynamics
Devices
Microfluidic
Microfluidics
Micromixer
Pressure drop
Tesla structure
Three dimensional
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Summary:•A new high-performance micromixer via 3D Tesla structures was designed, fabricated and tested.•The mixing efficiency was up to 0.94 at the volumetric flow rate 0.015–15μL/s.•The immunofluorescence experiments showed the mixing efficacy of this micromixer. Micromixers have been commonly utilized in the areas of biotechnical engineering, analytical chemistry, medical industry, and high-throughput synthesis because biological processes generally involve complicated chemical reactions that require useful reactant mixing for initiation. This paper reports the design, simulation, fabrication and test of a new high-performance micromixer via three-dimensional (3D) Tesla structures to realize the effective mixing process in the microfluidic devices for bio-applications. Both computational fluid dynamics (CFD) calculations and experiments were conducted to study the flow and mixing characteristics in the development of 3D Tesla micromixers. The predicted and measured results of the proposed micromixer have illustrated excellent mixing performance for Reynolds numbers (Re) ranging from 0.1 to 100 (0.015–15μL/s) with its pressure drop less than 1054Pa at Re=100. We also showed the successful application of the proposed mixer to the immunofluorescence analysis of the EGF receptor L858R mutant specific rabbit mAb (as a cancer biomarker) recognized by anti-rabbit IgG-CFL555 and H1975 cells, revealing the mixing effectiveness of this microfluidic device in the binding reaction of antibodies for detecting antigens of lung cancer cellular surface.
ISSN:1385-8947
1873-3212
DOI:10.1016/j.cej.2014.11.034