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dc.contributor.advisorZeugolis, Dimitrios
dc.contributor.authorAzeem, Ayesha
dc.date.accessioned2017-02-24T15:52:06Z
dc.date.available2017-02-24T15:52:06Z
dc.date.issued2017-02-24
dc.identifier.urihttp://hdl.handle.net/10379/6365
dc.description.abstractCurrently, over 1.7 billion people suffer from a musculoskeletal disorder; over 200 million operations take place annually; and in excess of 1 million new clinical cases are reported per year. Further, the annual healthcare expenditure exceeds US$ 950 billion Orthopaedic pathologies, such as osteoarthritis, tendinopathies, fractures, osteoporosis, intervertebral disc degeneration, low back pain, tumours and congenital deformities are among the largest group of debilitating diseases today. Therefore, the need for innovative regenerative strategies that are free from dysfunctional tissue healing remains ever relevant. Despite significant advances in the field, current biomaterial-based products for musculoskeletal repair and regeneration do not mimic the complex hierarchical structure and osteoinductive signals of the host native bone microenvironment. Herein, it is hypothesised that nano-textured biomaterials functionalised with carbohydrates moieties, by mimicking the native bone hierarchy and composition, would control osteoblast response in vitro and promote functional bone regeneration in vivo. Starting with nano-imprinting, this work revealed that topographical features in the middle nano-range (~306 nm) and low micron-range (~2,046 nm) induce cellular and matrix alignment and upregulation of osteogenic markers in vitro. However, these topographical features did not induce directional cell growth and neotissue formation in vivo. These data suggest that topographical features in two-dimensional scaffold (surface) can be utilised to maintain cell phenotype during in vitro cell expansion, enhancing that way clinical translation and commercialisation of cell-based therapies. With respect to electro-spinning, as low as 0.01 % functionalisation of electro-spun scaffolds with non-sulphated polysaccharides not only did not compromise the mechanical properties of the produced scaffolds, but also didn’t supress osteoblast adhesion, growth, proliferation and early in vitro osteogenesis. These data suggest that functionalisation of three-dimensional implantable devices with carbohydrates moieties (in this case non-sulphated polysaccharides) could promote functional bone repair and regeneration.en_IE
dc.rightsAttribution-NonCommercial-NoDerivs 3.0 Ireland
dc.rights.urihttps://creativecommons.org/licenses/by-nc-nd/3.0/ie/
dc.subjectMechanical engineeringen_IE
dc.subjectBiomedical engineeringen_IE
dc.subjectNanoimprintingen_IE
dc.subjectElectrospinningen_IE
dc.subjectOsteoblastsen_IE
dc.subjectTopographyen_IE
dc.subjectBiomimetic Nano-biomaterialsen_IE
dc.subjectBone regenerationen_IE
dc.titleBiomimetic nano-biomaterials for bone repair and regenerationen_IE
dc.typeThesisen_IE
dc.contributor.funderEnterprise Ireland; Proxy Biomedicalen_IE
dc.local.noteBone regeneration using biomimetic biomaterials. Human osteoblasts were used to monitor their behaviour on scaffolds created using techniques such as nanoimprinting and electrospinning. These techniques were used to create scaffolds mimicking the natural niche of bone, followed by their use to guide bone tissue formation.en_IE
dc.local.finalYesen_IE
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Attribution-NonCommercial-NoDerivs 3.0 Ireland
Except where otherwise noted, this item's license is described as Attribution-NonCommercial-NoDerivs 3.0 Ireland