Improving Prosthetic Arms for Amputee: A Better Fit and More Functionality

NCT ID: NCT05990062

Last Updated: 2025-06-26

Basic Information

• Recruitment Status: RECRUITING
• Clinical Phase: NA
• Total Enrollment: 25 participants
• Study Classification: INTERVENTIONAL
• Study Start Date: 2025-06-01
• Study Completion Date: 2028-09-30

Brief Summary

This research and development will improve upon and investigate the potential validity of an innovative new transradial socket and harness design (the KSH system) that offers an alternative to standard hard sockets and rubber liners with a hybrid polymer and textile-based design derived from advanced athletic shoe technology. The project consists of designing, custom fitting and evaluating the function and comfort of the this new novel system. The study will take place in 3 phases; Phase 1, five experienced Veterans with transradial arm amputations will be recruited to provide guidance and to assist with the design and development. Experienced end-user Veterans and Clinical staff will work together to assist with design, develop the fitting process and working with engineers on the design of a completely digital fitting device for measuring the residual limb and locating bony prominences of the limb to inform the socket design. Phase 2, testing and assessment, the design and process validation will take place with the five Veteran upper transradial arm amputees Phase 3, an additional 20 Veterans with transradial arm amputations will be recruited and fit with the KSH system and undergo a series of evaluative tests. Veterans will perform a series of static and dynamic tasks to evaluate function, comfort and load bearing failure. The primary goal of this study is to improve upon the current preliminary prototype and to test it with a broader population of potential users to help advance the engineering and design, and to learn the potential to fit a range of Veterans with transradial amputations.

Detailed Description

Acceptance of prosthetic arms has long been a problem for clinical prosthetics, and recent studies indicate that recent advancements have done little to improve usage. Objections related to the fit and comfort of prosthetic arms remain the main reasons cited for the disuse of the devices, numbering nine of the top ten reasons cited for abandonment in a survey study. By addressing the literal point of pain for these users, the investigators hope to increase use and acceptance, allowing existing devices to have more positive impact on Veterans' lives. The breathability of composite sockets has been an acknowledged problem nearly since their development by the VA in the 1940s. Indeed, while the VA successfully developed a breathable composite socket very early on, it was quickly abandoned after it was discovered that the breathable composite recreated the problems with odor and cleanliness with leather sockets that the composites had been developed to solve. Industry leader Otto Bock discovered the same thing when it developed a porous silicone liner decades later. While VA and civilian providers were successful in replacing leather sockets with composites through the innovations in composites and other materials following World War II. Prosthetic clinics used to employ leatherworkers skilled in the art of making custom sockets and braces out of these traditional materials, but these services have disappeared along with the Veterans demanding them, and the workers capable of delivering them. By taking advantage of the benefits of the advanced materials and construction techniques that have replaced leather in the athletic shoe industry over the last seventy-five years, the investigators hope to restore much of the comfort and fit of these extinct socket designs, while at the same time delivering the improvements that have been delivered by the athletic shoe industry and advances in design and manufacturing over the same period. Lim design is working on a textile based prosthetic socket; however, the approach differs from the investigators': 1) The Lim design is not intended or currently suitable for upper limbs; 2) While a textile design, the Lim design cannot dynamically change in volume through the range of motion and constrains motion similar to any other socket once it has been adjusted; 3) The textile design of the Lim socket is nether breathable nor wicking and is designed to be used with silicone and/or gel liners, hence suffers from the same deficiencies with respect to heat and moisture management as traditional sockets. Lim Innovations and Ossur have publicly stated that they do not intend to pursue further innovations in the upper limb market. These frank admissions make it clear that the development of orphan devices for Veterans, must become the responsibility of the VA, whose goals for serving Veterans are sometimes in contrast with and not limited to the constraints of large and profitable markets. VA in collaboration with small companies can help fill this much needed void for innovation. VA has shown leadership in related domains with the research and design for ultralight wheelchairs, alternative controls for powered wheelchairs, and adaptive sports and recreation equipment, all of which eventually assisted the broader populations of Americans with disabilities. Harness discomfort is just as detrimental to acceptance as poor socket-body interface and can lead to contralateral damage to the axilla. Indeed, one recent study concluded that there was no acceptable level of force at which a body powered prosthesis could be operated pain and fatigue free with a traditional harness. While the conclusions of this study obviously contradict the staying power of the body powered prosthesis and harness system accepted by more than 90 per cent of the roughly half of users who accept a prosthesis at all, it does indicate that there is substantial improvement to be made in harnessing that could significantly improve both acceptance and comfort of the users who have been willing to tolerate the uncomfortable standard of care that has seen slow progress for decades.

Study Objectives and Hypothesis:

Specific Aim 1: Improve and develop the design and systems for fitting an innovative new transradial suspension design based on currently available technology used in athletic shoe construction.

• Design Criteria 1a: Optimize CAD documentation by revising and translating the current Autodesk Fusion 360 design to SolidWorks, aiding customization and improving design for manufacture.
• Design Criteria 1b: Verify that the currently Direct Metal Laser Sintered (DMLS) printed wrist and quick release can be efficiently and effectively CNC machined.
• Design Criteria 1c: Create fixturing and finalize CNC programming for manufacture, including the specification of manufacturing tolerances to ensure proper fit of components.
• Design Criteria 1e: Verify forearm and elbow counter parts-currently printed in Multijet Fusion (MJF)-in Selective Laser Sintering (SLS) or Fused Deposition or Fused Filament (FDM/FFF) Nylon material.
• Design Criteria 1f: Automate adaptation of the design through plugin and API development.
• Design Criteria 1g: Optimize production of 2D textile patterns with, for example, ExactFlat.
• Design Criteria 1h: Design a digital or Brannock-like fitting device for measuring the residual limb and locating bony prominences of the limb to inform the socket design.
• Design Criteria 1i: Design the device to weigh less than 2-pounds total weight. Jon is a 50-year-old Veteran with a transradial arm amputation. He has had multiple carpal tunnel release surgeries on his remaining hand. An inconsistent but long-term user of prostheses, Jon settled on body-powered arms after extensive trials of myoelectric prostheses at Walter Reed immediately following his injury in Iraq in 2005, primarily because of the discomfort and lack of range of motion in the socket. He uses them mostly for true bimanual tasks, including bicycle riding, hunting, shotgun sports, and home improvement. Jon was not selected for a trial of the DEKA arm in 2018, and instead received a Bebionic hand and hard self-suspended socket from the VA. This arm was quickly rejected: it was heavy, incapable, uncomfortable, and restrictive. Blistering and irritation to Jon's arm from sweating and friction in a silicone lined carbon fiber vacuum socket.

Specific Aim 2: Verify performance gains for the innovative KSH system that can be delivered to Veterans. The new design is expected to significantly exceed the performance of the standard-of-care prosthesis in quantitative measures.

• Hypothesis 2a (H2a): That the improved KSH will provide a higher tensile static load bearing capacity before failure than the current standard-of-care prosthesis.
• Hypothesis 2b (H2b): That the improved KSH will provide greater tensile loads in a dynamic environment. The KSH system will allow users to perform better on a rowing ergometer 10-minute test before failure than the current standard-of-care prosthesis, as measured using strokes per minute, power in Watts, distance in meters, maximal force, and time before failure.
• Hypothesis 2c (H2c): The improved KSH will provide a greater range of motion in flexion/extension than the current standard-of-care prosthesis.
• Hypothesis 2d (H3d): Participants will require less time for donning/doffing the KSH than their current standard-of-care prosthesis.

Specific Aim 3: Verify functionality of the KSH system through testing with end-users.

• Hypothesis 3a (H3a): Participants will report high usability with setup and operation of the device (>80 on the System Usability Scale (SUS)).
• Hypothesis 3b (H3b): Participants will report significantly higher Socket Comfort Scores (SCS) with the KSH than their current standard-of-care prosthesis.
• Hypothesis 3c (H3c): Lower weight will correlate with greater user satisfaction, and the KSH will be statistically and clinically significantly lighter than participants' current devices.
• Hypothesis 3d (H3d): Participants will report that they would switch to the new design or have an additional prosthesis with the new design.
• Hypothesis 3e (H3e): Participants will report significantly higher Orthotics and Prosthetics User Survey (OPUS) scores with the KSH than their current standard-of-care prosthesis.

Relevance to Veterans: According to the DoD/VA Extremity Amputation Center of Excellence there were about 3,000 Veterans with transradial amputations enrolled for VA Healthcare in FY21, out of about 62,000 Veterans with limb amputations enrolled for VA healthcare. Veterans with arm amputations from Post-911 conflicts number just over 200, and because the total number of Veterans missing arms is demographically small, this very fact has severely limited innovation in the field of prosthetic arms. Those missing at least all five fingers of a hand are among the VA's most significantly disabled Veterans, rated at 80 per cent disabled alone for the loss of a dominant hand. Many arm amputees are eligible for Special Monthly Compensation as well as vehicle and housing modifications, reflecting the degree to which these Veterans' lives are impacted by the impairment. Indeed, even among the civilian population, arm amputation is rare enough to easily meet the FDA's medical orphan criteria of fewer than 200,000 patients, though the FDA's orphan drug law specifically excludes medical devices, and the FDA has a lower device threshold of 8,000 patients, further limiting innovation. The NIH's Genetic and Rare Diseases Information Center (GARD) lists limb absence as a rare birth condition but doesn't mention the same disability acquired by trauma or through other diseases, such as cancer, which is the second most common cause despite the small total number from all causes. While the subject design can be extended to other levels of amputation, this study will focus on transradial, or below elbow amputees. This population represents approximately seventy-five per cent of the VA population of Veterans with arm amputations, a subset that is also much more likely to successfully wear a prosthetic arm. Over 90% of these users choose body powered. The design could be extended to other Veteran populations, including people with lower-limb amputations and other levels of amputation, potentially increasing the benefit by offering the same benefits to those Veterans. By targeting the portion of an orphan population that is already more likely to use the device for which improvement is sought, and by targeting the concerns that are most likely to lead to abandonment, this research stands to increase acceptance and therefore access to activities of daily living, employment and recreation that can improve quality of life for some of the VA's most impaired patients. Success could then also be translated to larger populations with similar needs. The proposed design is intended to address more than half the total population of Veterans with upper limb amputations and could with additional research and development be designed in the future for other levels of amputation, including lower limb and myoelectric upper limb use.

Conditions

Amputation, Surgical

Study Design

• Allocation Method: NON_RANDOMIZED
• Intervention Model: CROSSOVER
• Primary Study Purpose: OTHER
• Blinding Strategy: NONE

Study Groups

Verify performance gains for the innovative KSH system that can be delivered to Veterans. The new de

The investigators will perform several functional tests of the both the KSH system and the standard of care prosthesis: tensile static load bearing capacity before failure, test rowing ergometer 10-minute test before failure measured using strokes per minute, power in Watts, distance in meters, maximal force, and time before failure, range of motion in flexion/extension, and donning/doffing time.

Group Type: EXPERIMENTAL

K-Socket-Harness

Intervention Type: DEVICE

A transradial socket and harness design that offers a hybrid polymer and textile-based design derived from advanced athletic shoe technology. The KSH integrated socket, frame, and wrist, the "variable compliance prosthetic socket with breathable matrix," creates a dynamic and secure attachment with a combination of two lacing systems. The lacing systems lengthen and shorten six flexible hinges at the elbow, maintaining a secure attachment throughout the range of motion and accounting for volume changes in the soft tissue of the elbow that would otherwise restrict range of motion or cause the socket to separate from the residual limb.

Verify functionality of the KSH system through testing with end-users.

The investigators will use System Usability Scale (SUS) to assess high usability with setup and operation of the device. The investigators will assess Comfort Scores (SCS), evaluate weight and correlate it with user satisfaction. The investigators will report selection outcome between new design and current design. The investigators will asses 1) functional status, (2) health- related quality of life, and (3) satisfaction with services and (4) device scores through the Orthotics and Prosthetics User Survey (OPUS).

Group Type: EXPERIMENTAL

K-Socket-Harness

Intervention Type: DEVICE

A transradial socket and harness design that offers a hybrid polymer and textile-based design derived from advanced athletic shoe technology. The KSH integrated socket, frame, and wrist, the "variable compliance prosthetic socket with breathable matrix," creates a dynamic and secure attachment with a combination of two lacing systems. The lacing systems lengthen and shorten six flexible hinges at the elbow, maintaining a secure attachment throughout the range of motion and accounting for volume changes in the soft tissue of the elbow that would otherwise restrict range of motion or cause the socket to separate from the residual limb.

Interventions

K-Socket-Harness

A transradial socket and harness design that offers a hybrid polymer and textile-based design derived from advanced athletic shoe technology. The KSH integrated socket, frame, and wrist, the "variable compliance prosthetic socket with breathable matrix," creates a dynamic and secure attachment with a combination of two lacing systems. The lacing systems lengthen and shorten six flexible hinges at the elbow, maintaining a secure attachment throughout the range of motion and accounting for volume changes in the soft tissue of the elbow that would otherwise restrict range of motion or cause the socket to separate from the residual limb.

Intervention Type: DEVICE

Other Intervention Names

KSH System

Eligibility Criteria

Inclusion Criteria

• Unilateral transradial arm amputation
• Possession of a functioning and wearable previously fit prosthetic arm of any type
• Residual limb length of at least 4 inches from the lateral epicondyle to the distal tip
• Residual limb length less than or equal to that allowing a clearance of 1.5 inches from a fitted wrist
• Must have at least 5-years of prosthetic use experience (For Phase 1 & 2)
• Must have at least 1-year of prosthetic use experience (For Phase 3 only)

Exclusion Criteria

• Current open sores or incisions, Heterotopic ossification (HO), traumatic neuromas, or any other condition preventing the wearing of a prosthetic socket
• Residual limb length less than 4 inches
• Residual limb length greater than that allowing 1.5 inches clearance from a fitted wrist.

The investigators will make every effort to recruit Veterans. If its found that it is not possible to recruit enough Veterans, the investigators will perform a non-Veteran amendment to this protocol.

• Eligible Sex: ALL
• Accepts Healthy Volunteers: Yes

Sponsors

Stumpworx LLC

UNKNOWN

Sponsor Role: collaborator

VA Office of Research and Development

FED

Sponsor Role: lead

Responsible Party

Responsibility Role: SPONSOR

Principal Investigators

Rory A Cooper, PhD

Role: PRINCIPAL_INVESTIGATOR

VA Pittsburgh Healthcare System University Drive Division, Pittsburgh, PA

Locations

VA Pittsburgh Healthcare System University Drive Division, Pittsburgh, PA

Pittsburgh, Pennsylvania, United States

Site Status: RECRUITING

Countries

United States

Central Contacts

Elizabeth B Toth, BA

Role: CONTACT

elizabeth.toth2@va.gov

(412) 954-5382

Facility Contacts

Elizabeth B Toth, BA

Role: primary

elizabeth.toth2@va.gov

412-954-5382

References

Salminger S, Stino H, Pichler LH, Gstoettner C, Sturma A, Mayer JA, Szivak M, Aszmann OC. Current rates of prosthetic usage in upper-limb amputees - have innovations had an impact on device acceptance? Disabil Rehabil. 2022 Jul;44(14):3708-3713. doi: 10.1080/09638288.2020.1866684. Epub 2020 Dec 30.

Reference Type: BACKGROUND

PMID: 33377803 (View on PubMed)

Biddiss E, Chau T. Upper-limb prosthetics: critical factors in device abandonment. Am J Phys Med Rehabil. 2007 Dec;86(12):977-87. doi: 10.1097/PHM.0b013e3181587f6c.

Reference Type: BACKGROUND

PMID: 18090439 (View on PubMed)

Hichert M, Vardy AN, Plettenburg D. Fatigue-free operation of most body-powered prostheses not feasible for majority of users with trans-radial deficiency. Prosthet Orthot Int. 2018 Feb;42(1):84-92. doi: 10.1177/0309364617708651. Epub 2017 Jun 16.

Reference Type: BACKGROUND

PMID: 28621577 (View on PubMed)

Hanspal RS, Fisher K, Nieveen R. Prosthetic socket fit comfort score. Disabil Rehabil. 2003 Nov 18;25(22):1278-80. doi: 10.1080/09638280310001603983.

Reference Type: BACKGROUND

PMID: 14617445 (View on PubMed)

Heinemann AW, Bode RK, O'Reilly C. Development and measurement properties of the Orthotics and Prosthetics Users' Survey (OPUS): a comprehensive set of clinical outcome instruments. Prosthet Orthot Int. 2003 Dec;27(3):191-206. doi: 10.1080/03093640308726682.

Reference Type: BACKGROUND

PMID: 14727700 (View on PubMed)

Dillingham TR, Pezzin LE, MacKenzie EJ. Limb amputation and limb deficiency: epidemiology and recent trends in the United States. South Med J. 2002 Aug;95(8):875-83. doi: 10.1097/00007611-200208000-00018.

Reference Type: BACKGROUND

PMID: 12190225 (View on PubMed)

Other Identifiers

A4257-R

Identifier Type: -

Identifier Source: org_study_id