Abnormal Infant Movements Classification With Deep Learning on Pose-Based Features

The pursuit of early diagnosis of cerebral palsy has been an active research area with some very promising results using tools such as the General Movements Assessment (GMA). In our previous work, we explored the feasibility of extracting pose-based features from video sequences to automatically classify infant body movement into two categories, normal and abnormal. The classification was based upon the GMA, which was carried out on the video data by an independent expert reviewer. In this paper we extend our previous work by extracting the normalised pose-based feature sets, Histograms of Joint Orientation 2D (HOJO2D) and Histograms of Joint Displacement 2D (HOJD2D), for use in new deep learning architectures. We explore the viability of using these pose-based feature sets for automated classification within a deep learning framework by carrying out extensive experiments on five new deep learning architectures. Experimental results show that the proposed fully connected neural network FCNet performed robustly across different feature sets. Furthermore, the proposed convolutional neural network architectures demonstrated excellent performance in handling features in higher dimensionality. We make the code, extracted features and associated GMA labels publicly available.

[1]  Hubert P. H. Shum,et al.  Posture reconstruction using Kinect with a probabilistic model , 2014, VRST '14.

[2]  Giovanni Cioni,et al.  Abstract booklet Publications on Prechtl’s Method on the Qualitative Assessment of General Movements in Preterm, Term and Young Infants , 2014 .

[3]  Edmond S. L. Ho,et al.  Establishing Pose Based Features Using Histograms for the Detection of Abnormal Infant Movements , 2019, 2019 41st Annual International Conference of the IEEE Engineering in Medicine and Biology Society (EMBC).

[4]  Christa Einspieler,et al.  Prechtl's assessment of general movements: a diagnostic tool for the functional assessment of the young nervous system. , 2005, Mental retardation and developmental disabilities research reviews.

[5]  Sylvain Brochard,et al.  A new deep learning-based method for the detection of gait events in children with gait disorders: Proof-of-concept and concurrent validity. , 2019, Journal of biomechanics.

[6]  Balasubramanian Raman,et al.  A Deep Learning Frame-Work for Recognizing Developmental Disorders , 2017, 2017 IEEE Winter Conference on Applications of Computer Vision (WACV).

[7]  Cewu Lu,et al.  RMPE: Regional Multi-person Pose Estimation , 2016, 2017 IEEE International Conference on Computer Vision (ICCV).

[8]  G Cioni,et al.  The qualitative assessment of general movements in preterm, term and young infants--review of the methodology. , 1997, Early human development.

[9]  Yaser Sheikh,et al.  OpenPose: Realtime Multi-Person 2D Pose Estimation Using Part Affinity Fields , 2018, IEEE Transactions on Pattern Analysis and Machine Intelligence.

[10]  Ling Shao,et al.  Action Recognition From Arbitrary Views Using Transferable Dictionary Learning , 2018, IEEE Transactions on Image Processing.

[11]  Michael Arens,et al.  Computer Vision for Medical Infant Motion Analysis: State of the Art and RGB-D Data Set , 2018, ECCV Workshops.

[12]  Emanuele Frontoni,et al.  Preterm Infants’ Pose Estimation With Spatio-Temporal Features , 2019, IEEE Transactions on Biomedical Engineering.

[13]  Deborah Gaebler-Spira,et al.  Machine Learning of Infant Spontaneous Movements for the Early Prediction of Cerebral Palsy: A Multi-Site Cohort Study , 2019, Journal of clinical medicine.

[14]  Thomas Plötz,et al.  Movement Recognition Technology as a Method of Assessing Spontaneous General Movements in High Risk Infants , 2015, Front. Neurol..

[15]  G. Clowry,et al.  Improving Outcomes in Cerebral Palsy with Early Intervention: New Translational Approaches , 2015, Front. Neurol..

[16]  Michael Arens,et al.  Learning an Infant Body Model from RGB-D Data for Accurate Full Body Motion Analysis , 2018, MICCAI.

[17]  O. M. Aamo,et al.  An Optical Flow-Based Method to Predict Infantile Cerebral Palsy , 2012, IEEE Transactions on Neural Systems and Rehabilitation Engineering.

[18]  Charles Pontonnier,et al.  Inverse dynamics based on occlusion-resistant Kinect data: Is it usable for ergonomics? , 2017, International Journal of Industrial Ergonomics.

[19]  Cordelia Schmid,et al.  Action recognition by dense trajectories , 2011, CVPR 2011.

[20]  Tom Chau,et al.  Detection of Atypical and Typical Infant Movements using Computer-based Video Analysis , 2018, 2018 40th Annual International Conference of the IEEE Engineering in Medicine and Biology Society (EMBC).

[21]  Andrew W. Fitzgibbon,et al.  Real-time human pose recognition in parts from single depth images , 2011, CVPR 2011.

[22]  Bill Triggs,et al.  Histograms of oriented gradients for human detection , 2005, 2005 IEEE Computer Society Conference on Computer Vision and Pattern Recognition (CVPR'05).

[23]  Jake K. Aggarwal,et al.  View invariant human action recognition using histograms of 3D joints , 2012, 2012 IEEE Computer Society Conference on Computer Vision and Pattern Recognition Workshops.

[24]  A. Jensenius,et al.  Early prediction of cerebral palsy by computer‐based video analysis of general movements: a feasibility study , 2010, Developmental medicine and child neurology.

[25]  Hiroshi Akima,et al.  A New Method of Interpolation and Smooth Curve Fitting Based on Local Procedures , 1970, JACM.

[26]  Nauman Aslam,et al.  Automatic Musculoskeletal and Neurological Disorder Diagnosis With Relative Joint Displacement From Human Gait , 2018, IEEE Transactions on Neural Systems and Rehabilitation Engineering.

[27]  David Picard,et al.  2D/3D Pose Estimation and Action Recognition Using Multitask Deep Learning , 2018, 2018 IEEE/CVF Conference on Computer Vision and Pattern Recognition.

[28]  Ajmal Mian,et al.  Learning Human Pose Models from Synthesized Data for Robust RGB-D Action Recognition , 2017, International Journal of Computer Vision.

[29]  Jonathan Tompson,et al.  Discovery of Latent 3D Keypoints via End-to-end Geometric Reasoning , 2018, NeurIPS.

[30]  Yan Gao,et al.  Towards Reliable, Automated General Movement Assessment for Perinatal Stroke Screening in Infants Using Wearable Accelerometers , 2019, Proc. ACM Interact. Mob. Wearable Ubiquitous Technol..

[31]  D. Zlatanovic,et al.  THE IMPORTANCE OF THE PRECHTL METHOD FOR ULTRA-EARLY PREDICTION OF NEUROLOGICAL ABNORMALITIES IN NEWBORNS AND INFANTS , 2019, Acta Medica Medianae.

[32]  Li Yao,et al.  Spatio-temporal information for human action recognition , 2016, EURASIP J. Image Video Process..

[33]  Lars Adde,et al.  Inter-observer reliability of the "Assessment of Motor Repertoire--3 to 5 Months" based on video recordings of infants. , 2009, Early human development.

[34]  M. Cowie National Institute for Health and Care Excellence. , 2015, European heart journal.

[35]  Ah Chung Tsoi,et al.  Human Action Recognition: A Dense Trajectory and Similarity Constrained Latent Support Vector Machine Approach , 2013, 2013 2nd IAPR Asian Conference on Pattern Recognition.

[36]  Xiaoyan Sun,et al.  MiCT: Mixed 3D/2D Convolutional Tube for Human Action Recognition , 2018, 2018 IEEE/CVF Conference on Computer Vision and Pattern Recognition.

[37]  Matthew J. Southgate,et al.  Fully automated image-based estimation of postural point-features in children with cerebral palsy using deep learning , 2018, Royal Society Open Science.

[38]  Jake K. Aggarwal,et al.  Human activity recognition from 3D data: A review , 2014, Pattern Recognit. Lett..

[39]  Helen Loeb,et al.  Computer vision to automatically assess infant neuromotor risk , 2019, bioRxiv.

[40]  Iasonas Kokkinos,et al.  DensePose: Dense Human Pose Estimation in the Wild , 2018, 2018 IEEE/CVF Conference on Computer Vision and Pattern Recognition.