Nature has been a source of inspiration to researchers to explore the possibility to mimic the rich multifunctionality of molecular motors, cells and microorganisms capable of move, interact, communicate and cooperate in complex biological environments and adjust their motion and behaviours in response to local stimuli and act collectively (schooling of fish, migration or sperms and bacteria in chemical gradients). Stigmergy, where the trace left in the environment by the first organism affects the motion of the following one, leading to a coherent self-organization, is observed even for very simple entities (ants, termites). Replicating this sophisticate intelligences from biology to active artificial systems could lead to emergent behaviours such as self-organization to accomplish complex tasks collectively, which single units cannot.
Engineering active nanosystems is a new and emerging area of research that comprises the design of large populations of nano- and microstructures that can harvest energy from their surroundings to move and self-organize to perform complex functions. Studying such out-of-the-equilibrium systems is intrinsically challenging and require a multidisciplinary expertise.
In this project, we study a paradigm shift from individual “passive” nanoparticles towards swarming intelligence of “active” nano-systems based on self-propelled nanobots. It will represent a step forward in systems nanotechnology, imaging, environmental applications, physics of active matter and nanomedicine (e.g. increasing the targeting efficiency from passive particles/active individual systems to swarms of different nanobots).
The main objective of this project is the production of intelligent self-powered nanosystems that cooperate, communicate and interact among themselves and with their environment presenting emergent behaviour at the nanoscale. The particular objectives can be divided in 3 aims:
1. e-Nanobots communication: To bioengineer enzyme-powered nanobots based on enzymes and nanoparticles containing different asymmetric architectures, to study their mechanism of motion and to assess their nanobot-nanobot communication via enzymatic cascades
2. Swarms of e-Nanobots: To investigate the cooperative intelligence and guidance of swarms of enanobots by chemotaxis and stigmergy phenomena
3. e-Nanobots as bio-nano-tools: To study the communication between living systems and e-nanobots and explore their use as novel tools for nanomedicine and molecular imaging