Scientific Reports (Jul 2017)

Computationally Informed Design of a Multi-Axial Actuated Microfluidic Chip Device

  • Alessio Gizzi,
  • Sara Maria Giannitelli,
  • Marcella Trombetta,
  • Christian Cherubini,
  • Simonetta Filippi,
  • Adele De Ninno,
  • Luca Businaro,
  • Annamaria Gerardino,
  • Alberto Rainer

DOI
https://doi.org/10.1038/s41598-017-05237-9
Journal volume & issue
Vol. 7, no. 1
pp. 1 – 11

Abstract

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Abstract This paper describes the computationally informed design and experimental validation of a microfluidic chip device with multi-axial stretching capabilities. The device, based on PDMS soft-lithography, consisted of a thin porous membrane, mounted between two fluidic compartments, and tensioned via a set of vacuum-driven actuators. A finite element analysis solver implementing a set of different nonlinear elastic and hyperelastic material models was used to drive the design and optimization of chip geometry and to investigate the resulting deformation patterns under multi-axial loading. Computational results were cross-validated by experimental testing of prototypal devices featuring the in silico optimized geometry. The proposed methodology represents a suite of computationally handy simulation tools that might find application in the design and in silico mechanical characterization of a wide range of stretchable microfluidic devices.