Abstract EN:

Small animal imaging is a powerful tool largely used in preclinical studies. Luminescence-based techniques allow an external detection of light from visible or infrared spectrum and constitute a rapidly expanding field. These innovative techniques are still under development and the field of applications could be extended. This work consists in two projects that were conducted in order to bring about some solutions to these issues. A first development was based on the real time capacity of luminescence imaging. Because of their sensitivity, cooled CCD cameras are largely used to detect the very small amount of light produced by bioluminescence reactions or by fluorescence probes. However, these systems generally require an exposure time of several seconds to overcome the readout noise. We report here the development and the validation of a photon counting-based system combined with a video monitoring function. The biological signal of interest, recorded by a third generation cooled intensified CCD camera, is spatially and temporally registered with the tracking video. Performing molecular imaging studies without the use of anaesthetics and in freely moving animals would limit the interference with signalization processes. Another aspect of luminescence imaging improvements was investigated in this thesis. A major limitation of this technique is the lack of quantification in planar imaging. Most of current systems are not compatible with real time imaging because of their acquisition process. We designed and realized an innovative device based on the use of a conical mirror enclosing the sample and thus allowing to record an anamorphic image of the sample.