Evaluation of High-Performance, Customized, Rapidly-Manufacturable Prosthetic Feet That Provide Improved Mobility

Overview

The purpose of this research is to design a high-performance, customized, and rapidly- manufacturable passive prosthetic foot for use in the United States. We are currently testing an early stage prototype and would like user input before pursuing additional clinical testing. Participants will be asked about their current prosthesis type and use, amputation side and cause, and activity level. We will take measurements of height, weight, and length of the participant's residual limb. The participant will be asked to walk in several prosthetic foot conditions in multiple walking activities, and the visit should last approximately four hours. For each prosthetic foot, a trained prosthetist will fit the foot (either a prototype foot or a commercially available K3/K4 foot) to the prosthesis. The patient will then walk around the room until they feel comfortable. They may initially walk using a gait belt or between parallel bars based on comfort level and an evaluation by the prosthetist. Once they feel comfortable walking on level ground at a normal speed and the prosthetist feels that they will be safe performing more challenging walking activities, the participant will perform different walking activities (such as walking on flat ground at different speeds, walking up/down ramps, and walking up/down stairs). They will then be asked to tell the investigator what they like and dislike about the prosthetic foot.

The purpose of this research is to design a high-performance, customized, and rapidly- manufacturable passive prosthetic foot for use in the United States. We are currently testing an early stage prototype and would like your input before pursuing additional clinical testing. The Global Engineering and Research (GEAR) Laboratory at the Massachusetts Institute of Technology (MIT) has developed a novel design framework for creating high-performance, passive prosthetic feet. By incorporating commercial aesthetic and functional requirements, we hypothesize that we can use this design methodology to create high-performance prosthetic feet that can be customized and provided at scale in the United States. Participants will be asked about their current prosthesis type and use, amputation side and cause, and activity level. We will take measurements of height, weight, and length of the participant's residual limb. The participant will be asked to walk in several prosthetic foot conditions in multiple walking activities, and the visit should last approximately four hours. For each prosthetic foot, a trained prosthetist will fit the foot (either a prototype foot or a commercially available K3/K4 foot) to the prosthesis. The patient will then walk around the room until they feel comfortable. They may initially walk using a gait belt or between parallel bars based on comfort level and an evaluation by the prosthetist. Once they feel comfortable walking on level ground at a normal speed and the prosthetist feels that they will be safe performing more challenging walking activities, the participant will perform different walking activities (such as walking on flat ground at different speeds, walking up/down ramps, and walking up/down stairs). They will then be asked to tell the investigator what you like and dislike about the prosthetic foot. Participants may also be asked to walk while wearing inertial measurement units (IMU's), which are wearable devices similar in size to a pedometer or wrist watch. These devices will record the acceleration of the limbs, which will allow us to understand how people walk in the different prosthetic feet. We will attach the IMU's using their elastic bands, and we will attach necessary wires with hypoallergenic tape. Wearing the IMU's, the participant will walk back and forth in the room while the sensors record information about how you are walking. They may rest at any time.