In order to achieve the final goal of the project a step-by-step approach is followed. During the first year all the preliminary aspects regarding design, theoretical investigation, nanofabrication, chemical functionalization and optical setup have been faced. In particular, as defined in the Grant Agreement, in IIT the research work has been focused on optimization of plasmonic nanostructures characterized by a 3D design comprising a axial nanochannel. These structures ensure the localization of the enhanced electric field at the desiderated point where the single-molecule is going to be detected. Both theoretical design (deliverable 2.1) and nanofabrication procedures (deliverable 2.2) have been investigated and several results have been achieved. Moreover, as defined in the proposal, in IIT a complex computer simulation (deliverable 3.1) has been setup in order to investigate, at molecular dynamics level, the interaction between FRET couples and a biomolecule (in particular nucleic acids and amino acids chains). Also during this first twelve months, the other scientific partners, i.e. UBE and UPSud, started the investigation on nanostructure functionalization with FRET dyes (deliverable 3.3) and on optical setup for single molecule optical trapping (deliverable 4.1). Both of these activities need more time to be optimized and finalized for the project porpoise. Finally AbA worked on the definition of how the biological samples will be treated (deliverables 5.1 and 5.11).
The work performed during this first period represent valuable results for the activities started for the second year. From now on, single molecule translocation and detection experiments will be setup by using the nanostructures realized during this period. Moreover, once the most suitable FRET strategy will be defined, the functionalization strategy defined during the first year will be exploited for optical spectroscopic detection of single molecules. The movement of these latter will be controlled by means of optical trapping thanks to the work now ongoing in UBE.