Only few theoretical studies with weak experimental evidence are reported in literature for target-aptamer characterization (virtually and experimentally). The Progress beyond the state of the art obtained by this project was the investigation of target-aptamer interface in terms of geometry, chemical bonds, shape complementarity, affinity constant, thermodynamic and kinetic experimental magnitudes.
This project delivered databases experimentally proved to predict aptasensors performances. In literature, there are NO database available in biosensors area. The project produced different databases of aptamer receptors (also chemically modified) binding ligands in different chemical environments.
The synthesis schemes for increasing signal and stability are well studied with many works increasing every year especially using aptamers. This project released methods to reduce synthesis steps and reagents as much as possible for coupling functionalized aptamers with dynamic or static nanoparticles and electrode surfaces and inks (graphite, silver, gold, platinum).
This project Improved electrochemical portable analytical techniques (sensitivity, selectivity, robustness, drift, stability, reproducibility and long term stability) focusing on miniaturization, wearable, continuous monitoring, in-situ analysis, reagentless, low cost and fast analytical response.
This project implemented small density array of aptasensors for multianalyte detection coupled with multivariate analysis.
The results of the project and potential impacts of them are:
Reinforcing the understanding of the virtual and experimental matching by using large datasets. The Application of advanced chemometric data post-processing to correlate experimental to simulated results was the main improvement achieved by the project.
Producing small density array of rationally designed aptasensors for real samples analysis. This is the major challenge of the analytical chemistry. The impact of this deliverable confirmed the proof of concept of working with rationally designed aptamer and supported the field of virtual assisted bioanalysis.