Adaptive Machine Learning Head Model Across Different Head Impact Types Using Unsupervised Domain Adaptation and Generative Adversarial Networks

Machine learning head models (MLHMs) are developed to estimate brain deformation from sensor-based kinematics for early detection of traumatic brain injury (TBI). However, the overfitting to simulated impacts and the decreasing accuracy caused by distributional shift of different head impact dataset...

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Bibliographic Details
Published in:IEEE sensors journal 2024-03, Vol.24 (5), p.7097-7106
Main Authors: Zhan, Xianghao, Sun, Jiawei, Liu, Yuzhe, Cecchi, Nicholas J., Le Flao, Enora, Gevaert, Olivier, Zeineh, Michael M., Camarillo, David B.
Format: Article
Language:English
Subjects:
Accuracy
Adaptation
Adaptation models
Artificial neural networks
Brain
Brain modeling
Computational modeling
Data models
Domain regularized component analysis (DRCA)
Error reduction
Generative adversarial networks
Head injuries
Kinematics
kinematics sensor informatics
Machine learning
Magnetic heads
Strain
strain and strain rate
Traumatic brain injury
traumatic brain injury (TBI)
unsupervised domain adaptation
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Summary:Machine learning head models (MLHMs) are developed to estimate brain deformation from sensor-based kinematics for early detection of traumatic brain injury (TBI). However, the overfitting to simulated impacts and the decreasing accuracy caused by distributional shift of different head impact datasets hinder the broad clinical applications of current MLHMs. We propose a new MLHM configuration that integrates unsupervised domain adaptation with a deep neural network (DNN) to predict whole-brain maximum principal strain (MPS) and MPS rate (MPSR). With 12780 simulated head impacts, we performed unsupervised domain adaptation on target head impacts from 302 college football (CF) impacts and 457 mixed martial arts (MMA) impacts using domain regularized component analysis (DRCA) and cycle-generative adversarial network (GAN)-based methods. The new model improved the MPS/MPSR estimation accuracy, with the DRCA method outperforming other domain adaptation methods in prediction accuracy: MPS mean absolute error (MAE): 0.017 (CF) and 0.020 (MMA); MPSR MAE: 4.09\,\,\text {s}^{-{1}} (CF) and 6.61\,\,\text {s}^{-{1}} (MMA). On another two hold-out test sets with 195 CF impacts and 260 boxing impacts, the DRCA model outperformed the baseline model without domain adaptation in MPS and MPSR estimation MAE. The DRCA domain adaptation approach reduces the error of MPS/MPSR estimation to be well below previously reported TBI thresholds, enabling accurate brain deformation estimation to detect TBI in future clinical applications.
ISSN:1530-437X
1558-1748
DOI:10.1109/JSEN.2023.3349213