Biomolecular activity modulated by interaction with nanostructures. Nanotechnological methods are able to reliably fabricate artificial nanostructures with dimensions similar to those of large biomolecules (a few to tens of nanometers). This study focuses on the interaction of artificial nanostructures with biomolecules such as proteins and DNA, and will enable scientists to better understand biomolecular recognition and binding events, which are central to all biological processes. The underst ....Biomolecular activity modulated by interaction with nanostructures. Nanotechnological methods are able to reliably fabricate artificial nanostructures with dimensions similar to those of large biomolecules (a few to tens of nanometers). This study focuses on the interaction of artificial nanostructures with biomolecules such as proteins and DNA, and will enable scientists to better understand biomolecular recognition and binding events, which are central to all biological processes. The understanding gained can then be used to design biomimetic surfaces for use in health monitoring and medical diagnostic devices with improved sensitivity, robustness and portability, thereby providing significant benefits to the health sector.Read moreRead less
Bacterial cell behaviour in micro/nano-confined environments. The project aims to progress the understanding of the mechanisms of marine bacteria biofilm formation and surface-modulated metabolic response. We will adjust the surface characteristics of photopolymers (as ?model? surfaces) and probe the bacterial response to surfaces, passively with micro/nano-fabricated structures and Atomic Force Microscopy; and actively with optical manipulation of single cells. The results will contribute to th ....Bacterial cell behaviour in micro/nano-confined environments. The project aims to progress the understanding of the mechanisms of marine bacteria biofilm formation and surface-modulated metabolic response. We will adjust the surface characteristics of photopolymers (as ?model? surfaces) and probe the bacterial response to surfaces, passively with micro/nano-fabricated structures and Atomic Force Microscopy; and actively with optical manipulation of single cells. The results will contribute to the fundamental knowledge regarding central biological phenomena -down to single-cell processes- as well as on applied knowledge regarding the manufacturing of antimicrobial surfaces that mimic natural bactericide processes, with larger implications on biomedical practice, and environmental, civil, mining and manufacturing industrial applications.Read moreRead less