This study evaluates the efficacy of a gait modification intervention using real-time biofeedback on reducing the knee joint loading in Alkaptonuria patients during treadmill walking. It will also assess whether the individualised adopted gait modification can be retained without feedback and during over ground walking.
Alkaptonuria (AKU) is a degenerative disease affecting the cartilage of the joints. The disease affects movement function, particularly walking/gait which is an important activity of daily living. It is believed that increased joint loading measured by the moments acting upon the joints, contributes to the degeneration of joint cartilage in Alkaptonuria, particularly in the weight bearing joints such as the knee and hips, resulting in accelerated progression of painful symptoms. Currently there is no cure for Alkaptonuria and the current management includes joint replacement surgery. Gait modification strategy interventions could be a non-invasive alternative which could delay the time to surgical interventions by reducing or altering joint loading and stalling the progression of disease. The aims of this study are 1) to determine if individualised gait modification strategies can be used to reduce the 3D knee joint loading, 2) to determine if the gait modifications can be retained without feedback during over ground walking and 3) to determine the individualised gait modification strategies adopted by AKU patients. Gait data will be measured and quantified using the non-invasive typical clinical gait analysis set up, using 3D motion capture combined with force data whereby joint angles, moments and powers can be calculated in all 3 planes of motion during treadmill walking. The intervention will involve real-time biofeedback using Motek's M-Gait treadmill. Due to the heterogeneity of the sample, each AKU patient will act as their own control. Gait data will be compared pre- and post-intervention and a validated pain score will be used to identify any patterns with knee pain and adopted gait modifications.
Study Type
INTERVENTIONAL
Allocation
NA
Purpose
BASIC_SCIENCE
Masking
NONE
Enrollment
30
An individualised gait modification intervention to reduce knee joint loading. Knee joint loading will be presented in real-time during treadmill walking. A 10% reduction of each patients baseline knee loading will be used as a target threshold along with visualisation of the history of 5 previous steps. Patients are encouraged to determine their own gait modification strategy that is most efficient for them. Previous examples of gait modifications that mechanically reduce knee loading will be presented to them.
Change from baseline 3D knee joint moment impulse after intervention
This represents the knee joint load during walking measured from kinematic and kinetic data obtained during the 3D gait analysis
Time frame: At baseline and immediately after the intervention
Change from baseline joint angles after intervention
Lower limb joint angles in degrees measured from kinematic data obtained during the 3D gait analysis
Time frame: At baseline and immediately after the intervention
Change from baseline joint moments after intervention
Lower limb joint moments in Nm/kg measured from kinematic and kinetic data obtained during the 3D gait analysis
Time frame: At baseline and immediately after the intervention
Change from baseline joint powers after intervention
Lower limb joint powers in Watts/kg measured from kinematic and kinetic data obtained during the 3D gait analysis
Time frame: At baseline and immediately after the intervention
Knee injury and Osteoarthritis Outcome Score
Validated Knee injury and Osteoarthritis Outcome Score Questionnaire. Scores between 0-100, 0 representing extreme problems and 100 representing no problems.
Time frame: Pre-intervention
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