Cancer is considered as the second leading cause of death worldwide. There were an estimated 14.1 million cancer cases around the world in 2012. The number is expected to increase to 24 million by 2035. It is important to develop methodologies that improve understanding of disease condition and progression. Physicochemical forces drive proliferation, differentiation, and migration of cells in live tissue. Significant alteration of these forces or heterogeneity within the tissue implicates a role of nanomechanics in cancer diagnosis. Over the past few years, single cell biology has been performed using micro/nano robotics for exploration of the nanomechanical and electrophysiological properties of cells. However, most of the research so far has been empirical and the understanding of the mechanisms and thus possible for cancer therapy are limited. Therefore, a systematic approach to address this challenge using advanced micro/robotics techniques is timely and important to a wide range of the technologies where micro/nano manipulation and measurement are in demand. The MNR4SCell project focuses on the staff exchange between the 12 world recognised institutions of EU and China, and the share of knowledge and ideas, and further the development of the leading edge technologies for the design, modelling, and control of micro/nano robotics and their applications in single cancer cell measurement, characterisation, manipulation, and surgery. This project meets the objectives and requirements of the Marie Skłodowska-Curie Actions: Research and Innovation Staff Exchange (RISE).
The ultimate goal of MNR4SCell is to establish long-term international and multidisciplinary research collaboration between Europe and China in the challenging field of micro/nano robotics for single cancer cells in the characterisation, diagnosis and targeted therapy. The synergistic approach and knowledge established by MNR4SCell will serve as the building blocks of the micro/nano robotics and biomedical applications, and thus keep the consortium’s leading position in the world for potential major scientific and technological breakthroughs in nanotechnology and cancer therapy.
This project is divided into six inter-related work packages and through their integration it will lead to the accomplishment of all the project objectives within the 48 month project duration.
This project has received funding from the European Union's Horizon 2020 research and innovation programme under grant agreement No 734174.