CuffForce: Reliability of Force Measurement Within the Carbon Fiber Orthosis Proximal Cuff

Sponsor

University of Iowa (Other)

Overall Status

Not yet recruiting

CT.gov ID

NCT06127264

Collaborator

(none)

Enrollment

Arms

Anticipated Duration (Months)

Study Details

Study Description

Brief Summary

The primary purpose of this research study is to determine if forces within carbon fiber custom dynamic orthoses (CDOs) can be reliability assessed using Loadpad and Loadsol force measuring sensors (Novel GMBH, St. Paul, MN). An improved understanding of the forces acting within orthoses may help to guide future orthosis related research studies, provision methods, and patient education.

Study participants will consist of healthy, able-bodied adult participants using generic sized CDOs, which consist of a proximal cuff that wraps around the leg just below the knee, a posterior carbon fiber strut that runs the length of the leg and bends to store and return energy, and a semi-rigid footplate that acts as a lever arm to bend the posterior strut. Participants will be asked to fasten the proximal cuff to a self-selected cuff tightness 'SSCT', as well as three different predefined force levels; 'Loose' where the proximal cuff is loosely fastened around the participants leg, 'Moderate' where the proximal cuff is fastened with moderate tightness, and 'Tight' where the proximal cuff is tightly fastened around the participants leg. Forces acting on the leg, within the proximal cuff, will be measured using wireless Loadpad sensors and forces acting on the foot will be measured using wireless Loadsol insoles. Testing will include collection of force data as participants sit quietly, stand quietly, and walk and completion of questionnaires. Testing in the predetermined force levels (Loose, Moderate, Tight) will occur in a randomized order.

Condition or Disease	Intervention/Treatment	Phase
Healthy	Device: Carbon Fiber Custom Dynamic Orthosis (CDO)	N/A

Detailed Description

Ankle foot orthoses (AFOs) are medical devices often used to support the foot and ankle during daily activities. Carbon fiber custom dynamic orthoses (CDOs), one subset of AFOs, that consist of a proximal cuff that wraps around the leg just below the knee, a posterior carbon fiber strut that runs the length of the leg and bends to store and return energy during gait, a semi-rigid carbon fiber footplate that acts as a lever arm to bend the posterior strut, and in some cases a foam heel wedge placed between the footplate and the shoe. Different CDO design characteristics, such as posterior strut stiffness, device alignment, and heel cushion height and stiffness have been studied in the past. While different design characteristics have been studied previously, there is little information available concerning the proximal cuff and how it impacts patient outcomes. Different types of AFOs and CDOs have been used in an effort to offload the limb for years. Both CDOs and patellar tendon bearing (PTB) style AFOs have been shown to reduce forces acting on the plantar surface of the foot. While multiple studies have indicated the importance of fastening the proximal cuff, few have actually investigated the forces acting within the proximal cuff. A loose proximal cuff has been associated with pistoning of the limb, where the limb translates down within the proximal cuff during loading, potentially increasing forces acting on the foot and reducing the offloading effects of the orthosis. Only one study investigated the effects of altering forces within the proximal cuff by adding more padding to the proximal cuff, which was shown to improve limb offloading.

A better understanding of the forces acting within the proximal cuff, and how these effect patient outcomes would help to guide future AFO related research studies, provision, and patient education. At this point in time there is little guidance available to inform patients how tightly they need to secure the proximal cuff when wearing an AFO, many clinicians recommend tightening it so that it's secure, but not uncomfortable. The ability to measure forces within the proximal cuff and an idea of the range of forces seen in a clinical setting will act as a first step to better understanding how forces acting within the proximal cuff impact patient outcomes.

Study Design

Study Type:

Interventional

Anticipated Enrollment :

20 participants

Allocation:

Randomized

Intervention Model:

Crossover Assignment

Intervention Model Description:

Participants will be asked to fasten the proximal cuff to a self-selected cuff tightness 'SSCT', as well as three different predefined force levels; Loose, Moderate, and Tight. Testing will occur without a CDO (NoCDO) and with each cuff tightness (SSCT, Loose, Moderate, Tight). Forces acting on the leg will be measured using wireless Loadpad sensors and forces acting on the plantar surface of the foot will be measured using wireless Loadsol insoles. Testing will include collection of force data as participants sit quietly, stand quietly, and walk and completion of questionnaires. Testing in the predetermined force levels (Loose, Moderate, Tight) will occur in a randomized order.Participants will be asked to fasten the proximal cuff to a self-selected cuff tightness 'SSCT', as well as three different predefined force levels; Loose, Moderate, and Tight. Testing will occur without a CDO (NoCDO) and with each cuff tightness (SSCT, Loose, Moderate, Tight). Forces acting on the leg will be measured using wireless Loadpad sensors and forces acting on the plantar surface of the foot will be measured using wireless Loadsol insoles. Testing will include collection of force data as participants sit quietly, stand quietly, and walk and completion of questionnaires. Testing in the predetermined force levels (Loose, Moderate, Tight) will occur in a randomized order.

Masking:

Single (Participant)

Masking Description:

Participants will be blinded, to the greatest extent possible, to the different CDO proximal cuff tightness's.

Primary Purpose:

Other

Official Title:

Reliability of Force Measurement Within the Carbon Fiber Orthosis Proximal Cuff

Anticipated Study Start Date :

Jan 1, 2024

Anticipated Primary Completion Date :

Jan 1, 2025

Anticipated Study Completion Date :

May 1, 2025

Arms and Interventions

Arm	Intervention/Treatment
No Intervention: NoCDO Participants will complete study activities without wearing a CDO
Experimental: SSCT Participants will complete study activities while wearing a CDO fastened to their self-selected proximal cuff tightness	Device: Carbon Fiber Custom Dynamic Orthosis (CDO) The carbon fiber custom dynamic orthosis (CDO) will consist of a semi-rigid carbon fiber footplate, a carbon fiber posterior strut, and a proximal cuff that wraps around the leg below the knee that is fastened to different tightness's Other Names: Ankle Foot Orthosis (AFO)
Experimental: Loose Participants will complete study activities while wearing a CDO fastened to a loose proximal cuff tightness	Device: Carbon Fiber Custom Dynamic Orthosis (CDO) The carbon fiber custom dynamic orthosis (CDO) will consist of a semi-rigid carbon fiber footplate, a carbon fiber posterior strut, and a proximal cuff that wraps around the leg below the knee that is fastened to different tightness's Other Names: Ankle Foot Orthosis (AFO)
Experimental: Moderate Participants will complete study activities while wearing a CDO fastened to a moderate proximal cuff tightness	Device: Carbon Fiber Custom Dynamic Orthosis (CDO) The carbon fiber custom dynamic orthosis (CDO) will consist of a semi-rigid carbon fiber footplate, a carbon fiber posterior strut, and a proximal cuff that wraps around the leg below the knee that is fastened to different tightness's Other Names: Ankle Foot Orthosis (AFO)
Experimental: Tight Participants will complete study activities while wearing a CDO fastened to a tight proximal cuff tightness	Device: Carbon Fiber Custom Dynamic Orthosis (CDO) The carbon fiber custom dynamic orthosis (CDO) will consist of a semi-rigid carbon fiber footplate, a carbon fiber posterior strut, and a proximal cuff that wraps around the leg below the knee that is fastened to different tightness's Other Names: Ankle Foot Orthosis (AFO)

Outcome Measures

Primary Outcome Measures

Proximal Cuff Force [Baseline]
Proximal cuff forces (N) will be measured as participants sit, stand, and walk without a CDO and in each CDO condition.
Peak Plantar Force [Baseline]
Plantar forces (N) will be measured across the total foot, the hindfoot, midfoot, and forefoot as participants sit, stand, and walk without a CDO and in each CDO condition.
Plantar Force Impulse [Baseline]
Plantar force impulse (Ns) across the total foot, the hindfoot, midfoot, and forefoot will be calculated using the integral of the force over the stance phase as participants sit, stand, and walk without a CDO and in each CDO condition.
Numerical Pain Rating Scale [Baseline]
Pain will be assessed using a standard 11-point numerical pain rating scale, in which 0 = no pain and 10 = worst pain imaginable
Modified Socket Comfort Score (Comfort) [Baseline]
Comfort scores range from 0 = most uncomfortable to 10 = most comfortable

Secondary Outcome Measures

Modified Socket Comfort Score (Smoothness) [Baseline]
Smoothness scores range from 0 = least smooth to 10 = most smooth

Eligibility Criteria

Criteria

Ages Eligible for Study:

18 Years to 65 Years

Sexes Eligible for Study:

All

Accepts Healthy Volunteers:

Yes

Inclusion Criteria

Between the ages of 18 and 65
Healthy without current complaint of lower extremity pain, spine pain, open wounds or active infections, or medical or neuromusculoskeletal disorders that have limited their participation in work or exercise in the last 6 months
Able to hop without pain
Able to perform a full squat without pain
Ability to read and write in English and provide written informed consent Exclusion Criteria
Diagnosed with a moderate or severe brain injury
Lower extremity injury resulting in surgery or limiting function for greater than 6 weeks
Injuries that would limit performance in this study
Diagnosed with a physical or psychological condition that would preclude functional testing (e.g. cardiac condition, clotting disorder, pulmonary condition)
Visual or hearing impairments that limit walking ability or limit the ability to comply with instructions given during testing
Require use of an assistive device
Unhealed wounds (cuts/abrasions) that would prevent AFO use
BMI > 35
Pregnancy

Contacts and Locations

Locations

No locations specified.

Sponsors and Collaborators

University of Iowa

Investigators

Principal Investigator: Jason Anderson, PT,PhD, University of Iowa

Study Documents (Full-Text)

Study Protocol and Statistical Analysis Plan - Oct 17, 2023

More Information

Publications

None provided.

Responsible Party:

Jason Wilken, Director of Collaborative Research and Development, Associate Professor, University of Iowa

ClinicalTrials.gov Identifier:

NCT06127264

Other Study ID Numbers:

202212359

First Posted:

Nov 13, 2023

Last Update Posted:

Nov 13, 2023

Last Verified:

Nov 1, 2023

Individual Participant Data (IPD) Sharing Statement:

Plan to Share IPD:

Studies a U.S. FDA-regulated Drug Product:

Studies a U.S. FDA-regulated Device Product:

Yes

Product Manufactured in and Exported from the U.S.:

Keywords provided by Jason Wilken, Director of Collaborative Research and Development, Associate Professor, University of Iowa

Ankle Foot Orthosis

Carbon Fiber Orthosis

Plantar Force

Additional relevant MeSH terms:

Carbon Fiber

Study Results

No Results Posted as of Nov 13, 2023