Personalised approach to restoration of arm function in people with high-level tetraplegia

Lead Research Organisation: University of Aberdeen
Department Name: Engineering

Abstract

This project aims to develop efficient methods for personalising assistive technology to restore arm function in people with high-level spinal cord injury. We will use a combination of electrical stimulation to elicit forces in muscles no longer under voluntary control, and mobile arm supports to compensate for insufficient muscle force where necessary. We will use computational models specific to an individual's functional limitations to produce patient-specific interventions. The project will be in three phases: building a model to predict the effects of electrical stimulation on a paralysed arm with arm support, development of methodologies using this model to optimise the arm support and stimulation system, and testing of stimulation controllers designed using this approach. The project brings together experts in biomechanics and musculoskeletal modelling, spinal cord injury rehabilitation and assistive technologies.

Planned Impact

Patients and carers

Spinal cord injury is a life-changing condition that impacts on a person's independence, dignity and quality of life. Patients living with paralysis of their arms are dependent on carers for many activities of daily living and have severely reduced opportunities for participation in social and work-related activities. This project aims to develop personalised interventions to give back independent movement to people who cannot use their arms following spinal cord injury. This will enable a substantial increase in the independence and participation of people with spinal cord injury through provision of a long-term assistive device. In the case of incomplete injuries, the ability to take part in exercise and rehabilitation of the upper limb may also lead to improvement in the function of the neuromuscular system. Increasing the independence and participation in this group will also lead to a reduction in the burden placed on carers by severe arm disability.

Societal benefits

There are around 40,000 people living with spinal cord injury in the UK, and over half of these have paralysis of the upper limbs, as well as the lower. SCI imposes a significant burden not only on the people who suffer them, but also on society at large. The costs of SCI to the economy in terms of lost capacity for work, the burden of care and the longer term consequences of lack of participation are significant. Designing interventions where currently there are no treatment options could reduce the burden of care and offer potentially large societal benefits.

Clinical staff and the NHS

One of the outputs of the project will be patient-specific models of the upper limb neuromuscular system. These could be used to improve treatments not just for spinal cord injury, but upper limb functional problems associated with other conditions such as stroke, multiple sclerosis and joint disease. For example, it could help therapists design targeted task-specific practice that could accelerate gains in arm function.

Industrial beneficiaries

Patient-specific models of the upper limb neuromuscular system could also be used as a virtual testing platform for the development of new devices, which will benefit device manufacturers by leading to accelerated design and testing of assistive devices. For example, it could lead to the development of robotic devices to assist upper limb function, or customised prosthetic and orthotic devices. Such devices would be of great benefit both to patients and to the commercial entities that produce them.
 
Description The aims of this project are to develop efficient methods for developing user-specific interventions for people with spinal cord injury to help them regain upper limb function. We focus on electrical stimulation to produce muscle contraction in otherwise paralysed muscles, and use a patient-specific biomechanical model to optimise the stimulation system. We have developed methods to customise the models to specific individuals, based on simple clinical measurements and optimisation. With this approach, we can also take account of additional technologies such as arm supports, and surgical interventions such as tendon transfer, to find the ideal configuration of the stimulation system for the individual. In the first part of this project, we have developed efficient methods for customising the model to make it more representative of people with spinal cord injury (meeting objective 1 of the project - see EP/R035091/1). We have now also developed personalised biomechanical models of the upper limb to optimise the systems for specific individuals (objective 2) and developed simple controllers for those optimal systems (objective 3). Our outputs are somewhat delayed by Covid (due to the participation of high-risk individuals), so data analysis is still ongoing. We hope to report on objective 4 by the end of the year. We have trained two research associates in musculoskeletal modelling as part of this grant, and disseminated knowledge of modelling approaches to the clinical community through presentation at clinical meetings.
Exploitation Route We anticipate that the findings of this research will be used by academics interested in modelling injury, who will be able to make use of our generalisable knowledge through the publications, and who can access specific code and models through our model sharing on the Github platform. We would also expect that device manufacturers would be able to make use of our finding to implement ways of customising FES control into their products, and we hope that clinicians and clinical engineers will be able to use the knowledge to configure systems for specific individuals to optimise gains in function after injury.
Sectors Digital/Communication/Information Technologies (including Software),Healthcare
 
Description Although we are only just finishing the award, we can start to identify impacts arising. This section will be updated as a clearer picture of the impacts develops. We have developed an efficient method for customisation of a computer model for use in setting up an electrical stimulation system to aid movement in people with spinal injuries. The model helps us identify the optimal configuration of an existing device such that the user achieves the best function possible. During testing, users were able to control the movement of their own arms by turning their non-paralysed muscles on and off to control their paralysed muscles, resulting in functional arm movements. This has the potential to expand the use of the technology. We have worked directly with clinicians and clinical engineers to enable them to understand better the potential and limitations of the system. We have disseminated the findings to clinical audiences, and educated the general public, including children, about the working of their own musculoskeletal systems, the technologies available for assistive devices, and the role that engineers play in providing healthcare.
First Year Of Impact 2022
Sector Healthcare
Impact Types Societal
 
Description Research Awards
Amount £30,000 (GBP)
Funding ID PPEF 321 
Organisation Private Physiotherapy Educational Foundation 
Sector Charity/Non Profit
Country United Kingdom
Start 05/2021 
End 04/2024
 
Title Upper limb biomechanical model 
Description We have improved upon previously shared models of the biomechanics of the upper limb, and developed simpler methods for customising the models to specific individuals. The models and code are shared via Github. 
Type Of Material Computer model/algorithm 
Year Produced 2020 
Provided To Others? Yes  
Impact The award is ongoing and this model will be used in the next phase of our research, and decsribed further in subsequent publications. As such, impact using the model outside of our team has not occured yet to our knowledge. 
URL https://github.com/AbdnBiomechEng/TechForParalysis
 
Description Featured Case Study in Our Future Health in Scotland R&I Workshop 
Form Of Engagement Activity Participation in an activity, workshop or similar
Part Of Official Scheme? No
Geographic Reach National
Primary Audience Industry/Business
Results and Impact The project was featured as a Case Study from Scottish Research Partnership in Engineering - Engineering for Healthcare Theme during a SRIF workshop entitled 'Our Future Health in Scotland'. The presentation comprised a short abstract and recorded video seen by delegates.
Year(s) Of Engagement Activity 2021
URL https://www.srpe.ac.uk/case-studies-all/personalised-approach-to-restoration-of-arm-function-in-peop...
 
Description Hands on exhibit at the Aberdeen Science Centre for IET Day of Engineering 
Form Of Engagement Activity Participation in an activity, workshop or similar
Part Of Official Scheme? No
Geographic Reach Regional
Primary Audience Public/other audiences
Results and Impact We held an exhibit at the Aberdeen Science Centre aiming to reach school aged children and other members of the public. The exhibit allowed participants to visualise their muscle activity using EMG sensors, and helped them understand how muscles control the movements of their arms. The heard about how we use this muscle activity to help restore movement to people with paralysis.
Year(s) Of Engagement Activity 2022
URL https://aberdeensciencecentre.org/day-filled-with-fun-activities-for-the-whole-family-at-aberdeen-sc...
 
Description Presentation to medical conference 
Form Of Engagement Activity A talk or presentation
Part Of Official Scheme? No
Geographic Reach National
Primary Audience Professional Practitioners
Results and Impact Presentation on opportunities and limitations of computational modelling of tendon transfer to a clinical audience of hand surgeons, followed by a Q&A session. Conference was Federation of European Societies for Surgery of the Hand.
Year(s) Of Engagement Activity 2021
URL https://fessh2021.com/