Project description
Study investigates the toxicity of engineered nanoparticles on health and the environment
Nanoparticles have the potential to tackle environmental problems, but their growing use could also raise concerns about health and persistence in the environment. The EU-funded iCore project plans to develop advanced imaging technologies to investigate the physical and chemical properties of aluminium nano matrix composites in complex polymer matrices. Major focus will be placed on creating a model characterising and predicting the impact of nanomaterials on brain health. New methodologies will be provided to evaluate changes in nanomaterial morphology, chemical composition and reactivity when embedded to homogeneous matrices.
Objective
The incidental, accidental, or intentional release of manufactured nanomaterials into the environment and its exposure to humans is inevitable due to the exponential growth in invention, production, and use of them. It can have a huge impact in our health specially in the most sensible and exposed human body organs such us lungs, stomach, and brain. iCare aim to to develop a resilient and adaptive set of advanced imaging technologies to quantify physical-chemistry properties for ANMC in complex matrices. The main objective will focus on a integrated model system to characterize and predict the impact of nanomaterials on brain health to prevent the toxicity nanomaterials. The project makes accessible for industry a set of techniques and methodologies to evaluate changes in morphology, chemical composition and reactivity of nanomaterials when exposed to complex homogenous matrices mimicking environmental and biological exposure, with a particular emphasis on high-resolution imaging methodologies.
To achieve this goal the project the project brings together in the consortium 11 partners from different backgrounds such as RTOs, SMEs, industries and universities from different EU and non-eu countries and coming from different fields like nanotech, toxicology, advanced materials, advanced imaging, …
During the 48 months long of the project, the consortium will work on the development of different activities to achieve the following results: 1)new imaging methods achieving new high resolution methodologies and new super resolution imaging techniques 2)development of toxicology testing protocols and addressing current gaps in nanotoxicology, 3)development of tools and methods bringing the gap in vitro and in vivo testing, 4)efficiency of materials and product development 5)Delivery of reliable data and improved data reporting and finally development of harmonised standardised test methods that can be used in regulatory frameworks.
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HORIZON-RIA - HORIZON Research and Innovation ActionsCoordinator
4715-330 Braga
Portugal