Feasibility Study on Using Smart Templates, That Link Rectification Approaches to Particular Patient Characteristics, for Transtibial Prosthetic Socket Fitting

Not Applicable

Completed

• Conditions: Transtibial Amputation; Prosthetic
• Interventions: Device: Smart template - designed prosthetic check socket; Device: Clinician-designed prosthetic check socket

• Registration Number: NCT06597266
• Lead Sponsor: University of Southampton

Brief Summary

Prosthetic socket comfort and fit is important in ensuring individuals with amputation can get the most use from their prosthetic limb. Researchers from the University of Southampton and a spin out company Radii Devices Ltd have been developing software based upon the cutting-edge of engineering design to support clinicians in the design of the socket.

The technology uses data from previous socket designs and limb shapes to develop and train the software, developed working with Opcare Ltd, a prosthetics provider. The software suggests appropriate socket design shapes (templates) that may be optimal based on previous designs and whether they have fit and been comfortable.

The aim of this study is to assess the feasibility of sockets designed by the Radii Devices software, and a preliminary comparison against socket designed by a clinician (known as a prosthetist). Combining qualitative (semi-structured interview) and quantitative (Socket Comfort) methods, will enable understanding of the strengths and limitations and inform further development of the Radii Devices technology into full design software for prosthetists that provides optimal socket design support.

This study is funded by an Innovate UK Biomedical Catalyst grant and will be carried out over a 6 month period at Oxford, Roehampton and Bristol Opcare NHS prosthetic services. Prosthetists at these services and patients with a below-knee amputation will be eligible to apply if they are interested. Participation will be split into two stages. In Stage One participants will be asked to trial two sockets (designed using different methods) at their fitting appointment instead of the usual one. If participants would like to participate in the second stage they will be asked about their experiences of socket fit and comfort in interviews, and within a short socket comfort diary for patients.

Detailed Description

A well-fitting, comfortable prosthetic socket is an urgent priority for the 170 million people worldwide with amputation as it stops people being able to achieve their goals and participate in society. For clinics providing sockets, there is an increasing demand for prosthetic limbs, increasing costs and a shortage of prosthetists (the people who fit the limbs to the patients). The prosthetic socket connects a person's remaining limb with the rest of the prosthetic limb. When a prosthetic socket does not fit properly, it causes skin irritation, blistering and in the worst cases, ulcers. It will also lead to patients avoiding prosthetic use altogether or repeat clinic visits. These sockets are complicated to design due to differences in patient limb shape, skin properties and ability to tolerate pressure. Therefore, there is a need to support prosthetists to achieve the best socket fit they can for the patient, quicker, and with fewer complications that can lead to patients not wanting to wear their prosthetic limb.

Socket design involves a process called rectification which aims to optimise comfort, stability and mobility for the prosthesis user. To achieve this, the prosthetist will remove material or add material to shape the final socket design. Rectification is a very complicated problem; yet there is currently little guidance or evidence to support the process. This leaves the socket dependent upon the skill and experience of the individual prosthetist, who require years of training and experience. Even then getting an optimal socket fit can take up to 9 clinic visits.

The development of evidence-based socket design to improve socket fit is a primary objective of the International Society for Prosthetics \& Orthotics. Critical to this is the ability to use information about past socket designs to learn from and increase understanding of the socket design process. This need goes back many decades, with Klasson asking the following questions in 1982 which are still unsolved today:

* What is a good fit?

* What information is necessary to achieve a good fit?

* Which processing of the information is necessary to arrive at a good fit?

Since 2014, University of Southampton researchers have developed technology to meet the patient and clinic need, guided by input from prosthetics providers including Opcare, and patients. This work has so far resulted in world-leading research on analysing shape and optimising socket design and the spin out of a company (Radii Devices). As part of a collaboration with Opcare, in November 2019, a study was carried out to assess the current socket design software, understand current practice and how socket design could be supported. Five prosthetists of varying experience were recruited and key areas in which computer software can be improved were identified, including:

1. inclusion of more data to support design;

2. a more intuitive interface; and

3. the ability to adapt to individual clinician preferences.

Challenges include the complicated 3D shapes within socket design and how to get and visualise meaningful data about the design process. Researchers at the University of Southampton and Radii Devices have developed a process which uses computational geometry, data science and biomechanical engineering expertise to achieve this. The developed software learns from past socket designs to suggest optimal socket design for an individual patient. This software will be tested within this research study to compare it against Opcare's current design process. This will enable researchers to understand the strengths and weaknesses of the technology and inform the development of design software incorporating this technology in the best way to support socket design.

Study Timeline

• Study Start: 2022-10-17
• Primary Completion: 2023-11-14
• Study Completion: 2023-11-30
• Status Verified: 2024-09
• Study First Submitted: 2024-09-03
• Study First Submitted QC: 2024-09-11
• Last Update Submitted: 2024-09-11
• Study First Posted: 2024-09-19
• Last Update Posted: 2024-09-19

Recruitment & Eligibility

• Status: COMPLETED
• Sex: All
• Target Recruitment: 17

Inclusion Criteria

• aged 18 years or over
• Attend the Bristol, Oxford or Roehampton NHS Opcare prosthetic services
• Have had a transtibial amputation
• Deemed ready to cast for a new prosthesis by the clinical team as per usual care at the prosthetic centre
• Able to understand verbal and written English and provide informed consent

Exclusion Criteria

• under the age of 18
• Have had an ankle disarticulation, Knee disarticulation or transfemoral amputation
• Contraindication to be fit for a prosthetic socket
• Unwilling to trial or unable to tolerate trialling two sockets at a fitting session
• Unable to answer verbal questions (as per normal fitting appointment) on their socket fitting and comfort

Study & Design

• Study Type: INTERVENTIONAL
• Study Design: CROSSOVER

Arm && Interventions

Group	Intervention	Description
Experimental (evidence-generated socket) then Active Comparator (control socket)	Smart template - designed prosthetic check socket	Participants are first fitted with an evidence-generated prosthetic check socket (experimental), and then fitted with a prosthetist-led prosthetic check socket (active comparator)
Experimental (evidence-generated socket) then Active Comparator (control socket)	Clinician-designed prosthetic check socket	Participants are first fitted with an evidence-generated prosthetic check socket (experimental), and then fitted with a prosthetist-led prosthetic check socket (active comparator)
Active Comparator (control socket) then Experimental (evidence-generated socket)	Smart template - designed prosthetic check socket	Participants are first fitted with a prosthetist-led prosthetic check socket (active comparator), and then fitted with an evidence-generated prosthetic check socket (experimental)
Active Comparator (control socket) then Experimental (evidence-generated socket)	Clinician-designed prosthetic check socket	Participants are first fitted with a prosthetist-led prosthetic check socket (active comparator), and then fitted with an evidence-generated prosthetic check socket (experimental)

Primary Outcome Measures

Name	Time	Method
Semi-structured interview	30 minutes beginning immediately after device provision (socket fitting session), and optionally again one month after the fitting session.	To assess the feasibility of the smart templates device, by capturing participants' views and experiences of in-clinic fitting of two sockets designed in different ways, and general usability of their new prosthetic socket.; The interview will be of approximately 30 minutes duration and administered immediately after the prosthetic socket fitting session (i.e. provision of the intervention) by the researcher, and optionally again one month later at a face-to-face meeting, telephone or video call

Secondary Outcome Measures

Name	Time	Method
Socket Comfort Score (SCS)	30 minutes, i.e. at the end of the intervention provision (socket fitting session), and optionally daily over the subsequent one month	To confirm the design and operating specifications of the smart templates device intervention, before beginning a full clinical trial, a self-reported survey related to prosthetic device comfort, on a 0-10 scale where 0 and 10 represented the most uncomfortable and the most comfortable socket imaginable, respectively.; The SCS outcome measure is collected during the usual clinical pathway of prosthetic socket fitting session (i.e. at the time of provision of the intervention) by the researcher, which typically takes around 30 minutes. In this study it will be administered at fitting by the fitting-clinician, and the participant will be given the option to report it additionally daily, over the subsequent month, in a paper or electronic diary either posted back to the researchers, submitted on a webform or sent by WhatsApp.

Trial Locations

Locations (3)

Bristol Centre for Enablement; 🇬🇧 Bristol, United Kingdom

Oxford Centre for Enablement; 🇬🇧 Oxford, United Kingdom

Douglas Bader Rehabilitation Centre, Queen Mary's Hospital; 🇬🇧 Roehampton, United Kingdom