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Proceedings Paper

3D tracking and phase-contrast imaging by twin-beams digital holographic microscope in microfluidics
Author(s): L. Miccio; P. Memmolo; A. Finizio; M. Paturzo; F. Merola; S. Grilli; P. Ferraro
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Paper Abstract

A compact twin-beam interferometer that can be adopted as a flexible diagnostic tool in microfluidic platforms is presented. The devise has two functionalities, as explained in the follow, and can be easily integrated in microfluidic chip. The configuration allows 3D tracking of micro-particles and, at same time, furnishes Quantitative Phase-Contrast maps of tracked micro-objects by interference microscopy. Experimental demonstration of its effectiveness and compatibility with biological field is given on for in vitro cells in microfluidic environment. Nowadays, several microfluidic configuration exist and many of them are commercially available, their development is due to the possibility for manipulating droplets, handling micro and nano-objects, visualize and quantify processes occurring in small volumes and, clearly, for direct applications on lab-on-a chip devices. In microfluidic research field, optical/photonics approaches are the more suitable ones because they have various advantages as to be non-contact, full-field, non-invasive and can be packaged thanks to the development of integrable optics. Moreover, phase contrast approaches, adapted to a lab-on-a-chip configurations, give the possibility to get quantitative information with remarkable lateral and vertical resolution directly in situ without the need to dye and/or kill cells. Furthermore, numerical techniques for tracking of micro-objects needs to be developed for measuring velocity fields, trajectories patterns, motility of cancer cell and so on. Here, we present a compact holographic microscope that can ensure, by the same configuration and simultaneously, accurate 3D tracking and quantitative phase-contrast analysis. The system, simple and solid, is based on twin laser beams coming from a single laser source. Through a easy conceptual design, we show how these two different functionalities can be accomplished by the same optical setup. The working principle, the optical setup and the mathematical modeling for 3D tracking is described. Finally, the experimental proof is presented and discussed for in vitro cells in microfluidic chamber.

Paper Details

Date Published: 9 May 2012
PDF: 5 pages
Proc. SPIE 8428, Micro-Optics 2012, 842810 (9 May 2012); doi: 10.1117/12.923004
Show Author Affiliations
L. Miccio, Istituto Nazionale di Ottica (Italy)
P. Memmolo, Istituto Nazionale di Ottica (Italy)
A. Finizio, Istituto Nazionale di Ottica (Italy)
M. Paturzo, Istituto Nazionale di Ottica (Italy)
F. Merola, Istituto Nazionale di Ottica (Italy)
S. Grilli, Istituto Nazionale di Ottica (Italy)
P. Ferraro, Istituto Nazionale di Ottica (Italy)


Published in SPIE Proceedings Vol. 8428:
Micro-Optics 2012
Hugo Thienpont; Jürgen Mohr; Hans Zappe; Hirochika Nakajima, Editor(s)

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