Mario Broeckx scite author profile

Mario Broeckx

5Publications

7Citation Statements Received

9Citation Statements Given

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Thomas More Kempen

Publications

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Dynamic 3D scanning as a markerless method to calculate multi-segment foot kinematics during stance phase: Methodology and first application

Herrewegen¹,

Cuppens²,

Broeckx³

et al. 2014

Journal of Biomechanics

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Multi-segmental foot kinematics have been analyzed by means of optical marker-sets or by means of inertial sensors, but never by markerless dynamic 3D scanning (D3DScanning). The use of D3DScans implies a radically different approach for the construction of the multi-segment foot model: the foot anatomy is identified via the surface shape instead of distinct landmark points. We propose a 4-segment foot model consisting of the shank (Sha), calcaneus (Cal), metatarsus (Met) and hallux (Hal). These segments are manually selected on a static scan. To track the segments in the dynamic scan, the segments of the static scan are matched on each frame of the dynamic scan using the iterative closest point (ICP) fitting algorithm. Joint rotations are calculated between Sha-Cal, Cal-Met, and Met-Hal. Due to the lower quality scans at heel strike and toe off, the first and last 10% of the stance phase is excluded. The application of the method to 5 healthy subjects, 6 trials each, shows a good repeatability (intra-subject standard deviations between 1° and 2.5°) for Sha-Cal and Cal-Met joints, and inferior results for the Met-Hal joint (>3°). The repeatability seems to be subject-dependent. For the validation, a qualitative comparison with joint kinematics from a corresponding established marker-based multi-segment foot model is made. This shows very consistent patterns of rotation. The ease of subject preparation and also the effective and easy to interpret visual output, make the present technique very attractive for functional analysis of the foot, enhancing usability in clinical practice.

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Comparison of biomechanical foot analyses between nine Flemish foot‐experts

Knippels

Saey

Herrewegen

et al. 2014

Journal of Foot and Ankle Research

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Development of a model to analyse foot biomechanics using dynamic 3D surface scanning

Herrewegen¹,

Cuppens²,

Broeckx³

et al. 2012

Computer Methods in Biomechanics and Biomedical Engineering

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Eigenfoot decomposition of plantar pressure images and case study of feature prediction of two modalities

Cuppens

Saey

Raeve

et al. 2015

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The registration of plantar pressure images is a widely used technique to support human gait analysis. In plantar pressure images, most of the time conventionally derived features are used for further processing. Recently, automatic feature extraction based on PCA and kPCA is being used, to increase the information that can be extracted from this data. In this paper, we describe our work flow and a case study on the application of predicting two pressure features and a non-pressure feature out of the automatically derived PCA features. This includes the normalization of the pressure images, the PCA based feature extraction, and building and testing the regression model based on a linear and kernel SVM.

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Digital Design of Aids for Activities of Daily Living

Saey

Cuppens

Delien

et al. 2020

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Mario Broeckx

Dynamic 3D scanning as a markerless method to calculate multi-segment foot kinematics during stance phase: Methodology and first application

Comparison of biomechanical foot analyses between nine Flemish foot‐experts

Development of a model to analyse foot biomechanics using dynamic 3D surface scanning

Eigenfoot decomposition of plantar pressure images and case study of feature prediction of two modalities

Digital Design of Aids for Activities of Daily Living

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