Biosensors (Dec 2022)

Single Plane Illumination Microscopy for Microfluidic Device Imaging

  • Clara Gomez-Cruz,
  • Sonia Laguna,
  • Ariadna Bachiller-Pulido,
  • Cristina Quilez,
  • Marina Cañadas-Ortega,
  • Ignacio Albert-Smet,
  • Jorge Ripoll,
  • Arrate Muñoz-Barrutia

DOI
https://doi.org/10.3390/bios12121110
Journal volume & issue
Vol. 12, no. 12
p. 1110

Abstract

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Three-dimensional imaging of live processes at a cellular level is a challenging task. It requires high-speed acquisition capabilities, low phototoxicity, and low mechanical disturbances. Three-dimensional imaging in microfluidic devices poses additional challenges as a deep penetration of the light source is required, along with a stationary setting, so the flows are not perturbed. Different types of fluorescence microscopy techniques have been used to address these limitations; particularly, confocal microscopy and light sheet fluorescence microscopy (LSFM). This manuscript proposes a novel architecture of a type of LSFM, single-plane illumination microscopy (SPIM). This custom-made microscope includes two mirror galvanometers to scan the sample vertically and reduce shadowing artifacts while avoiding unnecessary movement. In addition, two electro-tunable lenses fine-tune the focus position and reduce the scattering caused by the microfluidic devices. The microscope has been fully set up and characterized, achieving a resolution of 1.50 μm in the x-y plane and 7.93 μm in the z-direction. The proposed architecture has risen to the challenges posed when imaging microfluidic devices and live processes, as it can successfully acquire 3D volumetric images together with time-lapse recordings, and it is thus a suitable microscopic technique for live tracking miniaturized tissue and disease models.

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