Time-lapse contact microscopy of cell cultures based on non-coherent illumination.

Marion Gabriel,Stéphane Gétin,Stéphanie Bigault,Vincent Haguet,Nathalie Picollet-D’Hahan,François Perraut,Xavier Gidrol,Dorothée Balle,Marc R Block,Cyrille Pornin,François Chatelain

doi:10.1038/srep14532

Abstract

Video microscopy offers outstanding capabilities to investigate the dynamics of biological and pathological mechanisms in optimal culture conditions. Contact imaging is one of the simplest imaging architectures to digitally record images of cells due to the absence of any objective between the sample and the image sensor. However, in the framework of in-line holography, other optical components, e.g., an optical filter or a pinhole, are placed underneath the light source in order to illuminate the cells with a coherent or quasi-coherent incident light. In this study, we demonstrate that contact imaging with an incident light of both limited temporal and spatial coherences can be achieved with sufficiently high quality for most applications in cell biology, including monitoring of cell sedimentation, rolling, adhesion, spreading, proliferation, motility, death and detachment. Patterns of cells were recorded at various distances between 0 and 1000 μm from the pixel array of the image sensors. Cells in suspension, just deposited or at mitosis focalise light into photonic nanojets which can be visualised by contact imaging. Light refraction by cells significantly varies during the adhesion process, the cell cycle and among the cell population in connection with every modification in the tridimensional morphology of a cell.

Highlights

Video microscopy offers outstanding capabilities to investigate the dynamics of biological and pathological mechanisms in optimal culture conditions
To investigate the effect of refraction by cells on the formed holograms, a contact imaging architecture was achieved using a white 5 mm Light Emitting Diode (LED) as the light source, human cells adhered on tissue culture-coated glass substrates of various thicknesses, and a Charge-Coupled Device (CCD) or a Complementary Metal Oxide Semiconductor (CMOS) image sensor remotely controlled by their respective electronic devices (Fig. 1a)
The emitted white light was mainly composed of a 465 nm blue peak supplied by GaN layers in the LED chip and a 565 nm green-yellow peak very likely produced by cerium-doped yttrium aluminium garnet (YAG:Ce) phosphor pigments

Summary

Introduction

Video microscopy offers outstanding capabilities to investigate the dynamics of biological and pathological mechanisms in optimal culture conditions. There is currently a growing need of time-lapse investigation for better characterisation of cell populations, e.g., to study cell proliferation, morphology evolution, long-period cytotoxicity, cell variability, cell-cell interaction, cell-substrate interaction, motility or chemotaxis. This trend is supported by the strong desire, in cancer and infectious disease research, to move to live-cell applications which are considered by many biologists as being far more biologically relevant than fixed-cell assays[1]. Limiting the environmental changes for the cells decreases the risk of bacterial or fungi contamination

Methods

Results

Discussion

Conclusion