Explainable deep learning and biomechanical modeling for TMJ disorder morphological risk factors
Shuchun Sun, Pei Xu, Nathan Buchweitz, Cherice N. Hill, Farhad Ahmadi, Marshall B. Wilson, Angela Mei, Xin She, Benedikt Sagl, Elizabeth H. Slate, Janice S. Lee, Yongren Wu, Hai Yao
Shuchun Sun, Pei Xu, Nathan Buchweitz, Cherice N. Hill, Farhad Ahmadi, Marshall B. Wilson, Angela Mei, Xin She, Benedikt Sagl, Elizabeth H. Slate, Janice S. Lee, Yongren Wu, Hai Yao
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Research Article Bone biology Metabolism

Explainable deep learning and biomechanical modeling for TMJ disorder morphological risk factors

Abstract

Clarifying multifactorial musculoskeletal disorder etiologies supports risk analysis, development of targeted prevention, and treatment modalities. Deep learning enables comprehensive risk factor identification through systematic analyses of disease data sets but does not provide sufficient context for mechanistic understanding, limiting clinical applicability for etiological investigations. Conversely, multiscale biomechanical modeling can evaluate mechanistic etiology within the relevant biomechanical and physiological context. We propose a hybrid approach combining 3D explainable deep learning and multiscale biomechanical modeling; we applied this approach to investigate temporomandibular joint (TMJ) disorder etiology by systematically identifying risk factors and elucidating mechanistic relationships between risk factors and TMJ biomechanics and mechanobiology. Our 3D convolutional neural network recognized TMJ disorder patients through participant-specific morphological features in condylar, ramus, and chin. Driven by deep learning model outputs, biomechanical modeling revealed that small mandibular size and flat condylar shape were associated with increased TMJ disorder risk through increased joint force, decreased tissue nutrient availability and cell ATP production, and increased TMJ disc strain energy density. Combining explainable deep learning and multiscale biomechanical modeling addresses the “mechanism unknown” limitation undermining translational confidence in clinical applications of deep learning and increases methodological accessibility for smaller clinical data sets by providing the crucial biomechanical context.

Authors

Shuchun Sun, Pei Xu, Nathan Buchweitz, Cherice N. Hill, Farhad Ahmadi, Marshall B. Wilson, Angela Mei, Xin She, Benedikt Sagl, Elizabeth H. Slate, Janice S. Lee, Yongren Wu, Hai Yao

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Figure 4

TMJ condyle morphology and its correlation with TMJ disorders.

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TMJ condyle morphology and its correlation with TMJ disorders. (A) Salie...
(A) Saliency maps generated from deep learning models highlight the TMJ condyle as an area of interest, with variations observed in the labeling of one or both condyles among individuals. (B) Detailed assessment of the condyle’s size and shape within the study cohort, differentiating between the overall dimensions (large or small) and the flatness (steep or flat). (C) Comparative analysis of measurements from patients with TMJ disorder (n = 104 derived from 52 participants, each contributing left and right measurements) and healthy control measurements (n = 104 derived from 52 participants, each contributing left and right measurements) with a mixed effects model to account for the correlation between left and right side measurements within individuals. The results reveal that patients with TMJ disorder tend to have smaller condyle areas and a more flattened condyle shape in contrast with healthy controls. In the figure, asterisks denote the level of statistical significance, *P < 0.05, **P < 0.01, and ***P < 0.001. These insights underscore the role of condyle morphology in the context of TMJ disorders.