NCT02229331

Brief Summary

Haemophilia is a rare X chromosome-linked coagulation disorder resulting from a congenital deficiency or absence of circulating factor VIII (Haemophilia A) or factor IX (Haemophilia B).As a consequence, patients with haemophilia are unable to generate adequate thrombin resulting in abnormal bleeding. Approximately 80-90% of bleeding episodes occur in the musculoskeletal system, especially in the large synovial joints and muscles. Repeated haemarthrosis induce joint cartilage damage and irreversible degenerative joint disease. Regular intravenous administration of coagulation factor concentrates starting after the first joint bleed and/or before the age of 2 ('primary' prophylaxis) is now the evidence-based, first-choice treatment in children with severe haemophilia. This primary prophylaxis has radically decreased the incidence of arthropathy in patients with haemophilia. Despite the positive effect of primary prophylaxis on arthropathy at several joints, the ankle joint seems to be an exception to the rule, as patients with haemophilia treated with primary prophylaxis still experience ankle arthropathy. As such, the ankle now is the main affected joint in patients with haemophilia under the age of 20. This makes the scientific community facing a new challenge. Determining aetiologic/contributing factors associated to the ankle arthropathy pathophysiological cascade in children with haemophilia (CwH) is therefore a primary objective in the haemophilic research community nowadays. Loading of the ankle is crucial as the ankle plantar flexors provide the main propulsive power during gait, the tibiotalar joint caries a complex distribution of joint stresses as a consequence of talar morphology and kinematics and, from a biomechanical and biochemical viewpoint, differs significantly from other major lower limb joints. Previous biomechanical studies focused on kinematic and strength measures, however, they omitted to incorporate fundamental measures of joint loading (joint kinetics) and joint structural integrity (JSI, assessment of soft tissue and osteochondral integrity through MRI). This makes it impossible to draw firm conclusions on biomechanical contributing factors. Furthermore, few, low-quality studies focused on conservative treatment strategies (e.g. strength training, mobilisation, proprioceptive training) in patients with ankle arthropathy. In a minority of the cases, important adverse effects (joint bleeding during strength and proprioception training) have been reported. Because of the low quality of the intervention studies and the lack of biomechanical studies focusing on joint loading and joint integrity, it is impossible to pinpoint the aetiology of these side effects. One assumption might be that side effects originate from inappropriate conservative approaches as a consequence of lacking knowledge on joint loading and joint integrity. An innovative approach within the domain of ankle arthropathy in CwH is therefore to study foot and lower limb kinetics during gait. The quantification of foot joints kinetics encompasses considerable challenges and, until recently, only simplified single-segment foot models have been used. Those models typically underestimate the mechanical contribution of the different foot joints and, of equal importance, overestimate the kinetic contribution of the tibiotalar joint. To overcome the above mentioned shortcomings, a valid 3D Multisegment Foot Kinetic Model (3DMFKM) should be developed and introduced within the population of CwH. This is important as it allows to quantify increased loading at the tibiotalar joint (or other joints) that may help to explain this ankle arthropathy in these patients. This will have been missed by previous research due to the consideration of the foot as one entire segment. Providing a classification system based on these kinetic data would, in a second stage, be a pertinent and valuable approach as this provides a rationale for designing randomized controlled trials. In this perspective, it is also recommended to assess the relationship with other biomechanical and anatomical determinants, especially if one aims at developing optimal management and rehabilitation strategies.

Trial Health

100
On Track

Trial Health Score

Automated assessment based on enrollment pace, timeline, and geographic reach

Enrollment
37

participants targeted

Target at P25-P50 for all trials

Timeline
Completed

Started Sep 2014

Longer than P75 for all trials

Status
completed

Health score is calculated from publicly available data and should be used for screening purposes only.

Trial Relationships

Click on a node to explore related trials.

Study Timeline

Key milestones and dates

First Submitted

Initial submission to the registry

August 26, 2014

Completed
6 days until next milestone

First Posted

Study publicly available on registry

September 1, 2014

Completed
8 days until next milestone

Study Start

First participant enrolled

September 9, 2014

Completed
3.7 years until next milestone

Primary Completion

Last participant's last visit for primary outcome

May 16, 2018

Completed
3.3 years until next milestone

Study Completion

Last participant's last visit for all outcomes

September 16, 2021

Completed
Last Updated

May 18, 2023

Status Verified

May 1, 2023

Enrollment Period

3.7 years

First QC Date

August 26, 2014

Last Update Submit

May 16, 2023

Conditions

HaemophiliaArthropathy

Keywords

haemophiliaarthropathypediatricsanklebiomechanics

Outcome Measures

Primary Outcomes (1)

  • Kinetic Joint Classification System outcome measure

    Kinetic Joint classification system encompasses a classification system based on mechanical loading profiles of foot joints measured during barefoot walking

    month 24

Secondary Outcomes (2)

  • Instrumentation implementation outcome measure

    month 12

  • MRI and Haemophilia Joint Health Score correlation outcome measure

    month 24

Study Arms (1)

gait analysis

gait analysis

Other: Gait analysis

Interventions

Gait analysisOTHER
gait analysis

Eligibility Criteria

Age6 Years - 18 Years
Sexmale
Healthy VolunteersYes
Age GroupsChild (0-17), Adult (18-64)
Sampling MethodProbability Sample
Study Population

Children with haemophilia

You may qualify if:

  • Aged range 6-18 years
  • All levels of severity of haemophilia A or B, and on all types of treatment.

You may not qualify if:

  • Excluded will be those with an acute bleed within 12 weeks prior to testing and those with an uncontrolled high titre inhibitor.

Contact the study team to confirm eligibility.

Sponsors & Collaborators

MeSH Terms

Conditions

Hemophilia AJoint Diseases

Interventions

Gait Analysis

Condition Hierarchy (Ancestors)

Blood Coagulation Disorders, InheritedBlood Coagulation DisordersHematologic DiseasesHemic and Lymphatic DiseasesCoagulation Protein DisordersHemorrhagic DisordersGenetic Diseases, InbornCongenital, Hereditary, and Neonatal Diseases and AbnormalitiesMusculoskeletal Diseases

Intervention Hierarchy (Ancestors)

GaitPhysical ExaminationDiagnostic Techniques and ProceduresDiagnosisPhysical Functional PerformancePhysical FitnessHealthPopulation Characteristics

Study Design

Study Type
observational
Observational Model
COHORT
Time Perspective
CROSS SECTIONAL
Sponsor Type
OTHER
Responsible Party
PRINCIPAL INVESTIGATOR
PI Title
Dr

Study Record Dates

First Submitted

August 26, 2014

First Posted

September 1, 2014

Study Start

September 9, 2014

Primary Completion

May 16, 2018

Study Completion

September 16, 2021

Last Updated

May 18, 2023

Record last verified: 2023-05