Project Abstract

This project aims to conduct a comprehensive biomechanical analysis of lower limb prosthetic devices, which play a crucial role in restoring mobility and enhancing the quality of life for individuals with lower limb amputations. Prosthetic devices have undergone significant advancements in recent years, with the integration of advanced materials, sophisticated design, and sophisticated control systems. However, a thorough understanding of the biomechanical performance of these devices is essential to ensure their effectiveness, safety, and user comfort. The primary objective of this project is to develop a robust framework for evaluating the biomechanical characteristics of lower limb prosthetic devices, considering factors such as joint kinematics, kinetics, and energy expenditure. This comprehensive analysis will provide valuable insights into the biomechanical mechanisms underlying the interaction between the prosthetic device and the user, enabling the optimization of prosthetic design and the enhancement of rehabilitation outcomes. The project will employ a multi-disciplinary approach, combining expertise from fields such as biomechanics, materials science, and rehabilitation engineering. The research methodology will involve the use of state-of-the-art motion capture systems, force platforms, and advanced computational modeling techniques to analyze the biomechanical performance of various prosthetic device designs. One of the key aspects of this project is the investigation of the influence of different prosthetic components, such as the socket interface, the ankle-foot mechanism, and the knee joint, on the overall biomechanical performance of the prosthetic device. This analysis will help to identify the critical design parameters that contribute to improved gait patterns, reduced energy expenditure, and enhanced user comfort. Furthermore, the project will explore the impact of user-specific factors, such as activity level, body weight, and gait characteristics, on the biomechanical performance of prosthetic devices. This knowledge will enable the development of personalized prosthetic solutions that cater to the unique needs and requirements of individual users. The outcomes of this project will have significant implications for the field of prosthetic rehabilitation. The research findings will contribute to the development of more efficient, comfortable, and user-friendly prosthetic devices, ultimately enhancing the quality of life for individuals with lower limb amputations. The project will also provide valuable insights for clinicians and prosthetists, guiding them in the selection and optimization of prosthetic devices for their patients. Additionally, the biomechanical analysis framework developed in this project can be extended to other lower limb assistive devices, such as robotic exoskeletons and orthotic braces, further expanding the potential impact of the research. In conclusion, this comprehensive biomechanical analysis of lower limb prosthetic devices is a critical step in advancing the field of prosthetic rehabilitation. By leveraging the latest advancements in biomechanics, materials science, and computational modeling, this project aims to contribute to the development of superior prosthetic solutions that better meet the needs of individuals with lower limb amputations, ultimately improving their mobility, independence, and overall quality of life.

Project Overview