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Trial registered on ANZCTR

Registration number

ACTRN12618000558224

Ethics application status

Approved

Date submitted

23/03/2018

Date registered

13/04/2018

Date last updated

16/07/2021

Date data sharing statement initially provided

22/03/2019

Type of registration

Prospectively registered

Titles & IDs

Public title

Personalised 3D printed ankle-foot orthoses for children and adolescents with Charcot-Marie-Tooth disease (printhotics™ trial)

Scientific title

Effect of personalised 3D printed vs. traditional handmade ankle-foot orthoses on walking ability for children with Charcot-Marie-Tooth disease: a pilot crossover randomised controlled trial (printhotics™ trial)

Secondary ID [1]

Nil known

Universal Trial Number (UTN)

Trial acronym

Linked study record

Health condition

Health condition(s) or problem(s) studied:

Charcot-Marie-Tooth disease

Condition category

Condition code

Human Genetics and Inherited Disorders

Other human genetics and inherited disorders

Musculoskeletal

Other muscular and skeletal disorders

Neurological

Other neurological disorders

Intervention/exposure

Study type

Interventional

Description of intervention(s) / exposure

The three ankle-foot orthosis (AFO) designs will be evaluated, traditional AFO, replicated 3D printed AFO (same design as traditional AFO) and optimised 3D printed AFO (design only achieved through 3D printing), and compared to a shoe only condition. Each AFO design will be worn on both legs. Traditional AFOs will be manufactured by an Orthotist from a plaster cast of the participants lower limb followed by thermoplastic vaccum forming. The positive plaster cast mould will then be digitised using a 3D surface scanner to create a 3D model. Computer aided models of a replicated AFO and optimised AFO will then be generated from the 3D model and manufactured using a 3D printer. 3D gait analysis and inshoe pedobarography data will be collected to assess differences in walking in the gait lab of the Paedatric Gait Analysis Service of NSW by a Biomedical Engineer with over 6 years experience in clinical gait analysis. The participant will also be asked to complete a patient satisfaction questionnaire on each AFO condition. The testing order of the four conditions will be randomised for each participant. Each condition will take approximately 30 minutes to test with a 5 minute break in between.

Intervention code [1]

Treatment: Devices

Comparator / control treatment

Each device will be worn in the same shoe for testing and compared to the shoe only condition (Dunlop Volley). This shoe has thin and flexible rubber soles, light weight construction and minimal cushioning and supportive features are considered to have minimal effect on foot function.

Control group

Active

Outcomes

Primary outcome [1]

Effect on foot drop measured by 3D gait analysis

Timepoint [1]

6 weeks from enrollment and 5 minutes post placement of each AFO

Secondary outcome [1]

Walking speed measured by 3D gait analysis

Timepoint [1]

6 weeks from enrollment and 5 minutes post placement of each AFO

Secondary outcome [2]

Stride length measured by 3D gait analysis

Timepoint [2]

6 weeks from enrollment and 5 minutes post placement of each AFO

Secondary outcome [3]

Cadence measure by 3D gait analysis

Timepoint [3]

6 weeks from enrollment and 5 minutes post placement of each AFO

Secondary outcome [4]

Plantar pressure measured using inshoe pedobarograpahy

Timepoint [4]

6 weeks from enrollment and 5 minutes post placement of each AFO

Secondary outcome [5]

Patient satisfaction measured using a child version of the Client Satisfaction with Device module of the Orthotics and Prosthetic Users’ Survey

Timepoint [5]

6 weeks from enrollment and 30 minutes post placement of each AFO

Secondary outcome [6]

Gait profile score measured by 3D gait analysis

Timepoint [6]

6 weeks from enrollment and 5 minutes post placement of each AFO

Secondary outcome [7]

Ankle gait variable score measured by 3D gait analysis

Timepoint [7]

6 weeks from enrollment and 5 minutes post placement of each AFO

Secondary outcome [8]

Maximum ankle dorsiflexion in stance

Timepoint [8]

6 weeks from enrollment and 5 minutes post placement of each AFO

Secondary outcome [9]

Timing of maximum ankle dorsiflexion in stance as a percentage of the gait cycle

Timepoint [9]

6 weeks from enrollment and 5 minutes post placement of each AFO

Secondary outcome [10]

Maximum ankle plantarflexion at push-off

Timepoint [10]

6 weeks from enrollment and 5 minutes post placement of each AFO

Secondary outcome [11]

Maximum ankle dorsiflexion in swing

Timepoint [11]

6 weeks from enrollment and 5 minutes post placement of each AFO

Secondary outcome [12]

Maximum ankle dorsiflexion in the last 1/3rd swing

Timepoint [12]

6 weeks from enrollment and 5 minutes post placement of each AFO

Secondary outcome [13]

Ankle dorsiflexion at initial contact

Timepoint [13]

6 weeks from enrollment and 5 minutes post placement of each AFO

Secondary outcome [14]

Foot progression angle at 25%

Timepoint [14]

6 weeks from enrollment and 5 minutes post placement of each AFO

Secondary outcome [15]

Thigh-foot angle at 25%

Timepoint [15]

6 weeks from enrollment and 5 minutes post placement of each AFO

Secondary outcome [16]

Maximum ankle dorsiflexor moment in loading response

Timepoint [16]

6 weeks from enrollment and 5 minutes post placement of each AFO

Secondary outcome [17]

Maximum ankle plantarflexor moment

Timepoint [17]

6 weeks from enrollment and 5 minutes post placement of each AFO

Secondary outcome [18]

Maximum ankle power at push-off

Timepoint [18]

6 weeks from enrollment and 5 minutes post placement of each AFO

Secondary outcome [19]

Maximum ankle power generation in mid-stance

Timepoint [19]

6 weeks from enrollment and 5 minutes post placement of each AFO

Secondary outcome [20]

Knee flexion at initial contact

Timepoint [20]

6 weeks from enrollment and 5 minutes post placement of each AFO

Secondary outcome [21]

Maximum knee flexion in loading response

Timepoint [21]

6 weeks from enrollment and 5 minutes post placement of each AFO

Secondary outcome [22]

Minimum knee flexion in stance

Timepoint [22]

6 weeks from enrollment and 5 minutes post placement of each AFO

Secondary outcome [23]

Maximum knee flexion in swing

Timepoint [23]

6 weeks from enrollment and 5 minutes post placement of each AFO

Secondary outcome [24]

Maximum knee flexor moment in single-support

Timepoint [24]

6 weeks from enrollment and 5 minutes post placement of each AFO

Secondary outcome [25]

Maximum knee extensor moment in stance

Timepoint [25]

6 weeks from enrollment and 5 minutes post placement of each AFO

Secondary outcome [26]

Mean sagittal plane knee moment in stance

Timepoint [26]

6 weeks from enrollment and 5 minutes post placement of each AFO

Secondary outcome [27]

Minimum hip flexion

Timepoint [27]

6 weeks from enrollment and 5 minutes post placement of each AFO

Secondary outcome [28]

Maximum hip flexion in swing

Timepoint [28]

6 weeks from enrollment and 5 minutes post placement of each AFO

Secondary outcome [29]

Hip flexion range of motion during swing (max in swing - initial contact)

Timepoint [29]

6 weeks from enrollment and 5 minutes post placement of each AFO

Secondary outcome [30]

Maximum hip adduction in stance

Timepoint [30]

6 weeks from enrollment and 5 minutes post placement of each AFO

Secondary outcome [31]

Maximum hip adduction in swing

Timepoint [31]

6 weeks from enrollment and 5 minutes post placement of each AFO

Secondary outcome [32]

Hip rotation in at 25%

Timepoint [32]

6 weeks from enrollment and 5 minutes post placement of each AFO

Secondary outcome [33]

Maximum hip abductor moment in terminal stance

Timepoint [33]

6 weeks from enrollment and 5 minutes post placement of each AFO

Secondary outcome [34]

Maximum pelvic tilt

Timepoint [34]

6 weeks from enrollment and 5 minutes post placement of each AFO

Secondary outcome [35]

Maximum pelvic obliquity in swing

Timepoint [35]

6 weeks from enrollment and 5 minutes post placement of each AFO

Secondary outcome [36]

Pelvic obliquity range of motion in swing

Timepoint [36]

6 weeks from enrollment and 5 minutes post placement of each AFO

Secondary outcome [37]

Pelvic rotation at 25%

Timepoint [37]

6 weeks from enrollment and 5 minutes post placement of each AFO

Eligibility

Key inclusion criteria

Children aged 5-16 years with a confirmed diagnosis of Charcot-Marie-Tooth disease, currently using or functionally indicated (foot drop during gait by observation) for bilateral ankle-foot orthoses.

Minimum age

5 Years

Maximum age

16 Years

Sex

Both males and females

Can healthy volunteers participate?

Key exclusion criteria

Inability to give informed consent, understand English, a diagnosis other than Charcot-Marie-Tooth disease (CMT), unable to walk 100 metres in shoes.

Study design

Purpose of the study

Treatment

Allocation to intervention

Non-randomised trial

Procedure for enrolling a subject and allocating the treatment (allocation concealment procedures)

Allocation is not concealed.

Methods used to generate the sequence in which subjects will be randomised (sequence generation)

Data on the shoe condition will be collected first. The testing order of the three AFO conditions will then be randomised for each participant allowing all possible sequences to be completed twice. This will be completed prior to data collection by the co-ordinating investigator.

Masking / blinding

Open (masking not used)

Who is / are masked / blinded?

Intervention assignment

Crossover

Other design features

All participants will receive each test condition on both legs.

Phase

Not Applicable

Type of endpoint/s

Statistical methods / analysis

Recruitment

Recruitment status

Completed

Date of first participant enrolment

Anticipated

16/04/2018

Actual

10/07/2018

Date of last participant enrolment

Anticipated

15/04/2019

Actual

13/06/2019

Date of last data collection

Anticipated

27/05/2019

Actual

28/07/2019

Sample size

Target

Accrual to date

Final

Recruitment in Australia

Recruitment state(s)

NSW

Recruitment hospital [1]

The Children's Hospital at Westmead - Westmead

Recruitment postcode(s) [1]

2145 - Westmead

Funding & Sponsors

Funding source category [1]

Government body

Name [1]

Department of Education and Training

Address [1]

Department of Education and Training
GPO Box 9880
Canberra ACT 2601

Country [1]

Australia

Funding source category [2]

Charities/Societies/Foundations

Name [2]

Charcot-Marie-Tooth Association of Australia

Address [2]

Building 22
Concord Hospital
Hospital Rd
Concord NSW 2139

Country [2]

Australia

Funding source category [3]

University

Name [3]

University of Sydney

Address [3]

Commercial Development & Industry Partnerships (Industry and Community Engagement Seed Fund)
Level 6 Jane Foss Russell Building (G02)
City Road
University of Sydney NSW 2006

Country [3]

Australia

Primary sponsor type

Individual

Name

Professor Joshua Burns

Address

The Children's Hospital at Westmead
Locked Bag 4001
Westmead 2145 NSW

Country

Australia

Secondary sponsor category [1]

None

Name [1]

Address [1]

Country [1]

Ethics approval

Ethics application status

Approved

Ethics committee name [1]

Sydney Childrens Hospitals Network Human Research Ethics Committee

Ethics committee address [1]

Research Ethics Manager
Research Office
The Children's Hospital at Westmead
Locked Bag 4001
Westmead, 2145, NSW

Ethics committee country [1]

Australia

Date submitted for ethics approval [1]

29/03/2018

Approval date [1]

04/06/2018

Ethics approval number [1]

Summary

Brief summary

The aim of this project is to evaluate 3D printed AFOs compared to traditional handmade AFOs in children and adolescents with Charcot-Marie-Tooth disease (CMT) during walking. Three AFO designs will be evaluated traditional AFO, replicated 3D printed AFO and optimised 3D printed AFO and compared to a shoe only condition. Traditional AFOs will be handmade by an Orthotist from plaster casting methods of the participant’s lower limb followed by thermoplastic vaccum forming. The positive plaster cast mould will then be digitised using a 3D surface scanner to create a 3D model. Computer aided models of a replicated AFO and optimised AFO will then be generated from the 3D model and manufactured using the state of the art 3D printer. 3D gait analysis and inshoe plantar pressure data will be collected to assess differences in walking.

Trial website

Trial related presentations / publications

Public notes

Contacts

Principal investigator

Name

Prof Joshua Burns

Address

The Children's Hospital at Westmead
Locked Bag 4001
Westmead, 2145, NSW

Country

Australia

Phone

+61290367302

Fax

[email protected]

Contact person for public queries

Name

Elizabeth Wojciechowski

Address

The Children's Hospital at Westmead
Locked Bag 4001
Westmead, 2145, NSW

Country

Australia

Phone

+61298452985

Fax

[email protected]

Contact person for scientific queries

Name

Elizabeth Wojciechowski

Address

The Children's Hospital at Westmead
Locked Bag 4001
Westmead, 2145, NSW

Country

Australia

Phone

+61298452985

Fax

[email protected]

Data sharing statement

Will individual participant data (IPD) for this trial be available (including data dictionaries)?

No/undecided IPD sharing reason/comment

To protect intellectual property associated with this trial.

What supporting documents are/will be available?

No Supporting Document Provided

Results publications and other study-related documents

Documents added manually

No documents have been uploaded by study researchers.

Documents added automatically

No additional documents have been identified.

Trial Review

Documents added manually

Documents added automatically