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The aim is to discover and test candidate molecular mechanisms underlying central nervous system (CNS) (ie spinal cord and brain) regeneration. The human CNS does not regenerate after injury
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discover and test candidate molecular and cellular mechanisms underlying the switch between structural brain plasticity and degeneration in response to experience, and how this in turn modifies behaviour
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discover and test candidate molecular and cellular mechanisms underlying the switch between structural brain plasticity and degeneration in response to experience, and how this in turn modifies behaviour
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system an opportunistically attack human cells. In this respect mobile DNA elements (particularly transposons) appear key. We have developed a new genomic method to track genome rearrangements that occur
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insole architectures to redistribute plantar pressure and improve comfort. To support continuous monitoring, sensing elements will be incorporated within the insole structure to capture changes that may
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ceramic substrates providing both electrical insulation and heat dissipation. Si3N4 has very good mechanical properties such as high strength, fracture toughness and thermal shock resistance, therefore
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When light illuminates nano-sized metallic structures, the free electrons in the metal collectively oscillate, creating `plasmons'. By specifically designing the geometry and arrangement of the nano
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—where material is poured in bulk—3DCP constructs elements layer by layer via extrusion, introducing unique challenges related to interfacial bonding and structural performance. This PhD project aims
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When light illuminates nano-sized metallic structures, the free electrons in the metal collectively oscillate, creating `plasmons'. By specifically designing the geometry and arrangement of the nano
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based within the Sustainable Manufacturing Group (SMG) in the School of Engineering’s Mechanical Engineering Department. The SMG reimagines manufacturing to reduce energy consumption, decarbonise