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of the metabolic microenvironment. He/she will contribute to the design of miniaturized microphysiological devices enabling continuous-flow culture of organoids encapsulated in biomimetic matrices, compatible with
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and nano-robots (e.g., conformational switching, cargo encapsulation and release). - Quantitative analysis of assembly efficiency, mechanical stability, and functional performance in vitro and, where
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researcher will be responsible for developing "cage-type" materials. These materials will be synthesized using green chemistry (without organic solvents), and active molecules will be encapsulated within them
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within a confined environment featuring surface irregularities, thereby mimicking the migration of non-adhesive immune cells. The system will consist of encapsulating within giant liposomes: a) cell
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operations of chemical (mixing process in deep bed reaction systems), petroleum (oil-water separation systems), and biomedical industries (drug delivery encapsulating system) as well as in environmental
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perforation, and the partial encapsulation or/and amorphisation of the 2D materials. The originality of our project is to design the spatial organisation and density distribution of phonon scattering centers