Optimising the spring in your step to enhance footwear design. This project aims to examine how the nervous system adjusts the mechanical function of our feet across a spectrum of speeds, from slow running through to maximal effort sprinting. The proposed research will explore how the nervous system controls the function of the foot to meet the ever-varying demands of locomotion in the real-world. Expected outcomes of this project are to determine if running shoes help or hinder the natural spri ....Optimising the spring in your step to enhance footwear design. This project aims to examine how the nervous system adjusts the mechanical function of our feet across a spectrum of speeds, from slow running through to maximal effort sprinting. The proposed research will explore how the nervous system controls the function of the foot to meet the ever-varying demands of locomotion in the real-world. Expected outcomes of this project are to determine if running shoes help or hinder the natural spring-like function of the foot. It will explain a conceptually novel design allowing shoes to support our feet, whilst harnessing the energetic benefits of the foot's spring-like function. This research has the potential to revolutionise athletic footwear design and has direct implications for enhanced performance in running athletes.Read moreRead less
Influence of athletic footwear on lower limb biomechanics of pubertal girls. This project aims to determine whether athletic footwear with appropriate design features can help improve neuromuscular control and, in doing so, reduce the potentially deleterious forces on the knee and lower limb structures of pubertal girls. As girls reach puberty, they become less able to control the movement patterns of their lower limbs, particularly in high-demand tasks like running and jumping. Better-designed ....Influence of athletic footwear on lower limb biomechanics of pubertal girls. This project aims to determine whether athletic footwear with appropriate design features can help improve neuromuscular control and, in doing so, reduce the potentially deleterious forces on the knee and lower limb structures of pubertal girls. As girls reach puberty, they become less able to control the movement patterns of their lower limbs, particularly in high-demand tasks like running and jumping. Better-designed footwear for pubertal girls may improve movement patterns, decrease the likelihood of musculoskeletal injury and improve physical activity participation rates. Project outcomes may lead to the development of such footwear, and are also anticipated to expand our understanding of female developmental biomechanics.Read moreRead less
Athletic footwear for reducing knee loads in girls and women. This project aims to develop a novel athletic shoe that can reduce harmful knee loads during sport in adolescent girls and young women. As girls reach puberty, they become less able to control the movement patterns of their knees and lower limbs - particularly in high-demand tasks like jumping. The project will develop a new ASICS shoe that will be ‘field-tested’ during sporting activity with high ACL injury risk (netball) to evaluate ....Athletic footwear for reducing knee loads in girls and women. This project aims to develop a novel athletic shoe that can reduce harmful knee loads during sport in adolescent girls and young women. As girls reach puberty, they become less able to control the movement patterns of their knees and lower limbs - particularly in high-demand tasks like jumping. The project will develop a new ASICS shoe that will be ‘field-tested’ during sporting activity with high ACL injury risk (netball) to evaluate its effect on tibial shock (in-field surrogate measure of knee load) and player comfort compared to a conventional shoe. Expected outcomes include reduced healthcare costs associated with the treatment of serious knee injury, including surgical reconstruction and early-onset knee osteoarthritis.Read moreRead less
Structural and neural determinants of stress and strain in human muscle. This project aims to further our understanding of the biomechanical stress and strains experienced by contracting human muscles. Using innovative imaging techniques such as microendoscopy and supersonic shear imaging, we expect to generate new significant evidence on the structural and neural factors that lead to areas of high stress in human muscles. Outcomes of this project include not only a new understanding of muscle d ....Structural and neural determinants of stress and strain in human muscle. This project aims to further our understanding of the biomechanical stress and strains experienced by contracting human muscles. Using innovative imaging techniques such as microendoscopy and supersonic shear imaging, we expect to generate new significant evidence on the structural and neural factors that lead to areas of high stress in human muscles. Outcomes of this project include not only a new understanding of muscle design on multi-scale level, but also of muscle function and adaptation. This should provide significant benefits in better predicting muscle injury and prescribing safe exercise, knowledge that would benefit biomechanical engineers and sport and exercise professionals.Read moreRead less
Dynamics of Locomotion: Visualisation in skill acquisition & rehabilitation. How does visual information and attention determine the control and coordination of locomotion? Using large-screen projection of computer graphics and immersive virtual reality, we will examine the influence of visual information on driver training, gait in the elderly, cardiorespiratory control, and the attentional interference of mobile phones on driving. Experiments will be based on principles from dynamical and comp ....Dynamics of Locomotion: Visualisation in skill acquisition & rehabilitation. How does visual information and attention determine the control and coordination of locomotion? Using large-screen projection of computer graphics and immersive virtual reality, we will examine the influence of visual information on driver training, gait in the elderly, cardiorespiratory control, and the attentional interference of mobile phones on driving. Experiments will be based on principles from dynamical and complex systems theory and will inform the design of innovative algorithms for autonomous mobile robots. Expected outcomes include improved road safety, new methods for the rehabilitation of those with gait disorders, and a deeper understanding of the physiological response to virtual exercise.Read moreRead less