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access icon free Early-stage microfluidic network design framework using graph sparsificiation based optimisation

  • Author(s): Shunjie Dong 1 ; Weiqing Ji 2 ; Hailong Yao 2 ; Cheng Zhuo 1
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  • Source: Volume 55, Issue 19, 19 September 2019, p. 1034 – 1037
    DOI:  10.1049/el.2019.1656 , Print ISSN 0013-5194, Online ISSN 1350-911X
© The Institution of Engineering and Technology
Received 06/06/2019, Published 01/08/2019

Microfluidics has emerged as an effective technology for miniaturised manipulation and biochemical analysis. Recently, several physical design solutions for functional microfluidic chips have been presented. However, the commonly designed grid structure happens to be redundant with unnecessary channels, causing significant waste of expensive sample fluid. In this work, the authors propose an early stage microfluidic network design framework to sparsify the network topology and optimise network area overhead. Simulation results show that the proposed framework can generate the network to meet design constraints and reduce design overhead by almost 79.2% compared with prior works.

Inspec keywords: microfluidics; optimisation; microchannel flow; network topology; lab-on-a-chip; integrated circuit design; bioMEMS

Other keywords: early stage microfluidic network design framework; network topology; miniaturised manipulation; grid structure; physical design solutions; expensive sample fluid; functional microfluidic chips; graph sparsificiation based optimisation; biochemical analysis

Subjects: Biomedical measurement and imaging; Applied fluid mechanics; Design and modelling of MEMS and NEMS devices; Micromechanical and nanomechanical devices and systems

References

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      • 6. Wang, Q., Ru, Y., Yao, H., et al: ‘Sequence-pair-based placement and routing for flow-based microfluidic biochips’. IEEE Asia and South Pacific Design Automation Conf. (ASP-DAC), Macau, China, January 2016, pp. 587592.
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