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
The role of muscle and tendon mechanics in human muscle damage. This project aims to examine what sort of forceful stretch is required to cause exercise induced muscle damage (EIMD) in humans and how muscles adapt to limit future damage. Specifically, the project aims to examine how the elastic properties of tendons might reduce muscle damage by buffering stretch in muscle fibres. Using cutting-edge ultrasound imaging technology, human muscle strain in different regions of muscle will be examine ....The role of muscle and tendon mechanics in human muscle damage. This project aims to examine what sort of forceful stretch is required to cause exercise induced muscle damage (EIMD) in humans and how muscles adapt to limit future damage. Specifically, the project aims to examine how the elastic properties of tendons might reduce muscle damage by buffering stretch in muscle fibres. Using cutting-edge ultrasound imaging technology, human muscle strain in different regions of muscle will be examined to quantify the temporal relationship between muscle power absorption and EIMD. The importance of muscle and tendon mechanical properties in buffering the muscle from potential damage will be gauged. This could be a critical mechanism for preventing EIMD in exercising humans.Read moreRead less