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dc.contributor.authorMartin, Neil Richard Williamen_GB
dc.date.accessioned2013-06-20T08:47:19Z
dc.date.available2013-06-20T08:47:19Z
dc.date.issued2012-11
dc.identifier.citationMartin, N.R.W. (2012) 'A tissue engineered human skeletal muscle model for use in exercise sciences' PhD thesis. University of Bedfordshire.en_GB
dc.identifier.urihttp://hdl.handle.net/10547/294280
dc.descriptionA thesis submitted to the University of Bedfordshire, in partial fulfilment of the requirements for the degree of Doctor of Philosophyen_GB
dc.description.abstractSkeletal muscles are composed of thousands of muscle fibres (muscle cells), densely packed together in parallel and surrounded by connective tissue sheaths. These fibres are multinuclear in nature, which allows for the control and regulation of the highly organised, protein rich cellular interior. The primary function of skeletal muscle is to produce force, which allows for movement to occur or posture to be maintained, and the regulation of this function is in turn reliant on the expression of specific genes and proteins. Skeletal muscle exhibits a high degree of plasticity, and can adapt in response to stimuli such as increased/decreased use, metabolic perturbations or changes in the systemic environment which often occur as a result of exercise, ageing, disuse or disease. Examining responses and adaptations in skeletal muscle in vivo are challenging due to experimental restrictions, and studies are limited by ethical issues surrounding experimentation on human beings and indeed on animals following the principals of refinement, reduction and replacement. Thus in vitro studies are often conducted in order to further understand mechanisms involved in adaptation. However, the environment to which skeletal muscle cells are exposed to in vitro is far removed from that in the body, and the resulting cellular architecture is often abnormal in morphology. Tissue engineered skeletal muscle has shown much promise in rectifying these issues, as cells can be grown on/within a matrix which is biologically relevant and engineered to grow in a uniaxial manner in parallel to one another. However, this field is in its relative infancy, and to date little data exists with regards the behaviour and characteristics of human muscle derived cells (MDCs) in tissue engineered constructs. In this thesis, human skeletal MDCs were obtained, characterised and subsequently cultured in a suitable model for tissue engineering purposes. MDCs were seeded on to a fibrin based hydrogel, which self-assembled over time to form a cylindrically shaped construct held in place between two anchor points. In ii this model, the cells were shown to align uniaxially and in parallel to one another in a fascicular like structure. The model was improved in terms of biomimicity and maturation by both increasing the seeding density of the MDCs, and by increasing the ratio of myogenic to non-myogenic cells. These models appear to promote the development of a slow muscle, as evidenced by the favourably high levels of MYH7 transcription in comparison to other isoforms, and showed suggestions of sarcomeric organisation as indicated by the classically striated pattern of protein organisation when myosin heavy chain immunostaining was conducted. The work conducted in the final chapter of this thesis focussed on developing a system capable of assessing and quantifying the force produced by these tissue engineered human skeletal muscle constructs when electrically stimulated. Further work in this area should aim to determine these functional characteristics and thereafter use the model for physiological, cellular and molecular studies in exercise science.
dc.language.isoenen
dc.publisherUniversity of Bedfordshireen_GB
dc.subjectB100 Anatomy, Physiology and Pathologyen_GB
dc.subjectmuscleen_GB
dc.subjectskeletal muscleen_GB
dc.subjecthuman muscle derived cellsen_GB
dc.subjecttissue engineeringen_GB
dc.titleA tissue engineered human skeletal muscle model for use in exercise sciencesen
dc.typeThesis or dissertationen
dc.type.qualificationnamePhDen_GB
dc.type.qualificationlevelPhDen
dc.publisher.institutionUniversity of Bedfordshireen_GB
html.description.abstractSkeletal muscles are composed of thousands of muscle fibres (muscle cells), densely packed together in parallel and surrounded by connective tissue sheaths. These fibres are multinuclear in nature, which allows for the control and regulation of the highly organised, protein rich cellular interior. The primary function of skeletal muscle is to produce force, which allows for movement to occur or posture to be maintained, and the regulation of this function is in turn reliant on the expression of specific genes and proteins. Skeletal muscle exhibits a high degree of plasticity, and can adapt in response to stimuli such as increased/decreased use, metabolic perturbations or changes in the systemic environment which often occur as a result of exercise, ageing, disuse or disease. Examining responses and adaptations in skeletal muscle in vivo are challenging due to experimental restrictions, and studies are limited by ethical issues surrounding experimentation on human beings and indeed on animals following the principals of refinement, reduction and replacement. Thus in vitro studies are often conducted in order to further understand mechanisms involved in adaptation. However, the environment to which skeletal muscle cells are exposed to in vitro is far removed from that in the body, and the resulting cellular architecture is often abnormal in morphology. Tissue engineered skeletal muscle has shown much promise in rectifying these issues, as cells can be grown on/within a matrix which is biologically relevant and engineered to grow in a uniaxial manner in parallel to one another. However, this field is in its relative infancy, and to date little data exists with regards the behaviour and characteristics of human muscle derived cells (MDCs) in tissue engineered constructs. In this thesis, human skeletal MDCs were obtained, characterised and subsequently cultured in a suitable model for tissue engineering purposes. MDCs were seeded on to a fibrin based hydrogel, which self-assembled over time to form a cylindrically shaped construct held in place between two anchor points. In ii this model, the cells were shown to align uniaxially and in parallel to one another in a fascicular like structure. The model was improved in terms of biomimicity and maturation by both increasing the seeding density of the MDCs, and by increasing the ratio of myogenic to non-myogenic cells. These models appear to promote the development of a slow muscle, as evidenced by the favourably high levels of MYH7 transcription in comparison to other isoforms, and showed suggestions of sarcomeric organisation as indicated by the classically striated pattern of protein organisation when myosin heavy chain immunostaining was conducted. The work conducted in the final chapter of this thesis focussed on developing a system capable of assessing and quantifying the force produced by these tissue engineered human skeletal muscle constructs when electrically stimulated. Further work in this area should aim to determine these functional characteristics and thereafter use the model for physiological, cellular and molecular studies in exercise science.


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