Abstract
BackgroundAlthough deep neural networks (DNNs) are showing state of the art performance in clinical gait analysis, they are considered to be black-box algorithms. In other words, there is a lack of direct understanding of a DNN’s ability to identify relevant features, hindering clinical acceptance. Interpretability methods have been developed to ameliorate this concern by providing a way to explain DNN predictions.MethodsThis paper proposes the use of an interpretability method to explain DNN decisions for classifying the movement that precedes freezing of gait (FOG), one of the most debilitating symptoms of Parkinson’s disease (PD). The proposed two-stage pipeline consists of (1) a convolutional neural network (CNN) to model the reduction of movement present before a FOG episode, and (2) layer-wise relevance propagation (LRP) to visualize the underlying features that the CNN perceives as important to model the pathology. The CNN was trained with the sagittal plane kinematics from a motion capture dataset of fourteen PD patients with FOG. The robustness of the model predictions and learned features was further assessed on fourteen PD patients without FOG and fourteen age-matched healthy controls.ResultsThe CNN proved highly accurate in modelling the movement that precedes FOG, with 86.8% of the strides being correctly identified. However, the CNN model was unable to model the movement for one of the seven patients that froze during the protocol. The LRP interpretability case study shows that (1) the kinematic features perceived as most relevant by the CNN are the reduced peak knee flexion and the fixed ankle dorsiflexion during the swing phase, (2) very little relevance for FOG is observed in the PD patients without FOG and the healthy control subjects, and (3) the poor predictive performance of one subject is attributed to the patient’s unique and severely flexed gait signature.ConclusionsThe proposed pipeline can aid clinicians in explaining DNN decisions in clinical gait analysis and aid machine learning practitioners in assessing the generalization of their models by ensuring that the predictions are based on meaningful kinematic features.
Highlights
Deep neural networks (DNNs) are showing state of the art performance in clinical gait analysis, they are considered to be black-box algorithms
The convolutional neural network (CNN) proved the most robust (p = 2.40e-07), with only 26 strides falsely classified for the Parkinson’s disease (PD) patients without freezing of gait (FOG) and only a single stride falsely classified for the healthy control subjects
To tackle the problem of explainable freezing of gait (FOG) prediction, this paper proposed a two-stage pipeline of: (1) a convolutional neural network (CNN) to model the dramatic reduction of movement present before a FOG episode, and (2) layer-wise relevance propagation (LRP) to visualize the underlying features that the CNN perceives as important to model the pathology
Summary
Deep neural networks (DNNs) are showing state of the art performance in clinical gait analysis, they are considered to be black-box algorithms. FOG is common in PD, with approximately 70% of Parkinson’s disease patients developing FOG over the duration of the disease [4, 5]. FOG is clinically defined as a “brief, episodic absence or marked reduction of forward progression of the feet despite the intention to walk” [6]. PD patients describe freezing of gait as “the feeling that their feet are glued to the ground” [7]. Freezing episodes are most frequently provoked when traversing small spaces, during turning and gait initiation, and while dual-tasking [14, 15]. Especially in gait laboratories, it is common that FOG does not occur, despite providing adequate FOG-provoking conditions [15]
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