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of osteoarthritis). This project aims the following main objectives: Define patient-specific key functional and mechanical requirements for large osteochondral scaffolds. Produce biocompatible porous 3D structures
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make them excellent candidates for topical wound healing treatment, the potential application of foldamers as biomaterials has not yet been explored. Moreover, 3D scaffolds obtained from supramolecular
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of osteoarthritis). This project aims the following main objectives: Define patient-specific key functional and mechanical requirements for large osteochondral scaffolds. Produce biocompatible porous 3D structures
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fibrous scaffolds that replicate the native ECM network, we can systematically investigate how different cell types respond to defined microenvironments. Your tasks Fabricating hydrogel-based fibrous
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proven the potential of targeted radionuclide therapy, novel ligand scaffolds are needed to expand its reach across cancer types. This PhD project focuses on developing innovative small molecules targeting
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is to advance the field of bone tissue engineering by developing and characterizing artificial bone scaffolds using state-of-the-art 3D printing technology and advanced biomaterial inks. Scaffolds
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collaboration with XapHe , this doctoral project will integrate peptide-based delivery systems carrying osteoanabolic bio-cargoes into novel polymer matrices, paving the way toward intelligent scaffolds
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mechanical and biological properties. This cutting-edge technology allows for the layer-by-layer construction of biocompatible scaffolds that closely mimic native tissue microarchitecture, crucial
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) establish a continuous cell line of a commercially important food fish, ii) develop a cell-specific algae-derived medium and scaffold/microcarrier, and iii) scale up (bench-scale) the cultivation process
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contributing to the design of innovative molecular scaffolds. • Ability to work both independently and within a multidisciplinary research team. • Proven ability in conducting independent research, funding