Periodic Reporting for period 1 - TiFuN (Tiny Functional Au Nanorods: Novel NIR-Photothermal Nanoprobes for Single-Molecule Tracking at Confined Cellular Environment)
Reporting period: 2015-04-01 to 2017-03-31
This project aimed at developing an alternative approach to fluorescence for single biomolecule detection and tracking. It was based on the development of a photothermal imaging setup working at the biological optical window, and on the synthesis, functionalization and conjugation of tiny gold nanorods for biolabeling. Because they present strong optical absorption tunable from the red to the near IR, gold nanorods could be detected with high signal-to-noise and signal-to-background ratios at the single particle levels and in biological samples.
We anticipated that small bio-conjugated nanorods will constitute the next generation photothermal probe to study complex molecular dynamics in biological systems owing to their small size, tunable NIR-absorption, absolute photostability, and chemical suitability for surface functionalization and bioconjugation.
Ultimately the project aimed at opening a new way to study dynamics of biomolecules in confined cellular regions such as neurotransmitter receptors in synapses or integrin proteins in adhesion sites. This helps to reveal the molecular mechanisms of synaptic transmission, which are at the basis of synaptic plasticity and their deregulations are involved in pathologies including cognitive disorder. It also allows to study the nanoscale organization and dynamics of cell adhesion sites and actin networks which control critical cellular functions.
This opens a new way to study dynamics of biomolecules in confined cellular regions and decipher complex molecular mechanisms such as those occurring with neurotransmitter receptors in synapses or integrin proteins in adhesion sites. This will help to reveal the molecular mechanisms of synaptic transmission, which are at the basis of synaptic plasticity and their deregulations are involved in pathologies including cognitive disorder. It will also allow to study the nanoscale organization and dynamics of cell adhesion sites and actin networks which control critical cellular functions responsible of cancer cell proliferation.