Regenerative Peripheral Nerve Interface for Control of Lower Limb Prostheses

Description

Background: While many prosthetic devices have been developed for functional restoration after major lower extremity amputation, there is no stable interface to provide reliable, long-term volitional control of an advanced robotic limb capable of multiple degrees of freedom. Moreover, there is no existing interface that provides useful sensory feedback that in turn enhances the functional capabilities of the prosthesis. To address these limitations, the investigators propose use of a novel biologic interface known as the Regenerative Peripheral Nerve Interface (RPNI). An RPNI consists of a peripheral nerve that is implanted into a free muscle graft. As the nerve grows, it reinnervates the free muscle graft which undergoes a predictable sequence of revascularization and regeneration. The RPNI leverages these biological processes to provide three essential benefits to people with amputation: 1) intuitive motor control, 2) sensory feedback, and 3) reduction of post-amputation pain.

Objective/Hypotheses: The objective of this application is to (1) determine the extent to which the RPNIs enable generation of high-fidelity motor control signals for a powered knee-ankle prosthesis and (2) demonstrate that meaningful sensory feedback can be generated from stimulation of sciatic nerve RPNIs.

Specific Aims: The specific aims are to: (1) Evaluate the amplitude, movement specificity and stability of sciatic nerve RPNI electromyography (EMG) signals up to one year post RPNI surgery, (2) Assess functional movement performance using sciatic nerve RPNI signals for control of a physical motorized prosthetic leg with multiple degrees of freedom, and (3) Determine whether stimulation of sciatic nerve RPNIs provides meaningful sensory feedback.

Study design: This project is the first clinical investigation of RPNIs in people with lower-limb amputation. The study will recruit 3 individuals with transfemoral amputation. RPNIs will be surgically constructed on the sciatic nerve and intramuscular electrodes will be implanted into these RPNIs and residual muscles. Experiments will then be conducted at regular intervals up to one year post RPNI surgery. These experiments will measure the EMG signals generated by RPNIs in response to volitional movement of the phantom limb. These signals will then be used to control a two-joint powered prosthesis during cyclic and unpredictable movements. Functional movement, pain, and other patient-reported outcomes will be collected for data analysis. Additionally, RPNIs will be electrically stimulated to elicit sensation. Stimulation will also be provided during the performance of functional tasks.

At the completion of data collection, participants will undergo electrode explantation and complete a postoperative visit to assess recovery, pain and any associated adverse events.