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candidate to contribute to a highly translational project focused on the development of biocompatible artificial blood vessels using advanced 3D printing technologies. This multidimensional research
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textile design will be combined with advanced Additive Manufacturing (3D-Printing) techniques and specialist modelling and control algorithms for multi-body systems. This project would be most suitable
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for rehabilitation of complex joint (e.g. wrist) injuries and conditions. Bioinspired textile design will be combined with advanced Additive Manufacturing (3D-Printing) techniques and specialist modelling and control
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active feedback systems for real-time shape optimisation in defence applications. Using 3D printing technologies, the project focuses on the development of a specific device featuring shape memory alloys
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/index.aspx ) at the University of Nottingham. The student will work in world-class laboratory facilities in the CfAM engaging with interdisciplinary team with expertise in 3D printing, bio-printing for medical
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/index.aspx ) at the University of Nottingham. The student will work in world-class laboratory facilities in the CfAM engaging with interdisciplinary team with expertise in 3D printing, physics, and materials
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/index.aspx ) at the University of Nottingham. The student will work in world-class laboratory facilities in the CfAM engaging with interdisciplinary team with expertise in 3D printing, soft robotics, and
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/index.aspx ) at the University of Nottingham. The student will work in world-class laboratory facilities in the CfAM engaging with interdisciplinary team with expertise in 3D printing, physics, and materials
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to departmental teaching or research activities for a maximum of six hours per week. Title:3D printed collagen-based scaffold for targeted therapies for nerve impairments Supervisors: Dr Hanieh Khalili (Contact
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effect [4,5]. This structure will be 3D printed using reinforced polymer filaments. The choice of material will be crucial and will constitute one of the first phases of this work. The material must have