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Mechanical control of biological function

Objetivo

Mechanical forces transmitted through specific molecular bonds drive biological function, and their understanding and control hold an uncharted potential in oncology, regenerative medicine and biomaterial design. However, this potential has not been realised, because it requires developing and integrating disparate technologies to measure and manipulate mechanical and adhesive properties from the nanometre to the metre scale. We propose to address this challenge by building an interdisciplinary research community with the aim of understanding and controlling cellular mechanics from the molecular to the organism scale. At the nanometric molecular level, we will develop cellular microenvironments enabled by peptidomimetics of cell-cell and cell-matrix ligands, with defined mechanical and adhesive properties that we will dynamically control in time and space trough photo-activation. The properties under force of the molecular bonds involved will be characterized using single-molecule atomic force microscopy and magnetic tweezers. At the cell-to-organ scale, we will combine controlled microenvironments and interfering strategies with the development of techniques to measure and control mechanical forces and adhesion in cells and tissues, and to evaluate their biological response. At the organism scale, we will establish how cellular mechanics can be controlled, by targeting specific adhesive interactions, to impair or abrogate breast tumour progression in a mouse model. At all stages and scales of the project, we will integrate experimental data with multi-scale computational modelling to establish the rules driving biological response to mechanics and adhesion. With this approach, we aim to develop specific therapeutic approaches beyond the current paradigm in breast cancer treatment. Beyond breast cancer, the general principles targeted by our technology will have high applicability in oncology, regenerative medicine and biomaterials.

Convocatoria de propuestas

H2020-FETPROACT-2016-2017

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Convocatoria de subcontratación

FETPROACT-2016

Régimen de financiación

RIA - Research and Innovation action

Coordinador

FUNDACIO INSTITUT DE BIOENGINYERIA DE CATALUNYA
Aportación neta de la UEn
€ 1 952 419,59
Dirección
CARRER BALDIRI REIXAC PLANTA 2A 10-12
08028 Barcelona
España

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Región
Este Cataluña Barcelona
Tipo de actividad
Research Organisations
Enlaces
Coste total
€ 1 952 419,59

Participantes (6)