Joint object contour points and semantics for instance segmentation

Objectives: This study aimed to develop a clinical decision support system utilizing the MKG angle – derived from points M, K, and G – as a novel neural network parameter for evaluating sagittal maxillo-mandibular discrepancy. This system serves as a pre-operative screening tool for predicting the need for orthognathic surgery. Material and Methods: This retrospective study collected 494 digital lateral cephalograms. MKG angle values extracted from these cephalograms were analyzed using a Keypoint Region-based Convolutional Neural Network integrated with Detectron2 for object detection. Analysis was conducted using Keras software to facilitate decision-making regarding orthognathic surgery. The model’s output ranged from 0 to 1, with values closer to 1 indicating a stronger recommendation for orthognathic surgery. A training loss graph was used to monitor the model’s performance over epochs, while a confusion matrix evaluated the model’s accuracy and predictive capabilities. Results: The training loss value for the object detection model was 3.0510. Model performance was further evaluated using metrics such as root mean square error (RMSE) and percentage of detected joints (PDJ). The RMSE was measured at 2.68 pixels, while the PDJ, with a threshold of 0.05, achieved a value of 0.99, indicating a high level of accuracy. The developed system achieved an orthognathic surgery diagnosis accuracy of 70.41%, with a training loss value of 0.6163. The evaluation revealed instances of misdiagnosis; out of 98 cases, 29 were identified as misdiagnosed through a confusion matrix. The model’s sensitivity and specificity were measured at 72.5% and 68.97%, respectively. Conclusion: A supplementary tool for orthognathic screening, utilizing two-dimensional digital lateral cephalometry images and MKG angle as a parameter, was developed by merging a neural network model with clinical decision-making.

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Deep Learning Methods to Analyze the Forces and Torques in Joints Motion

Guo,

Chen,

2024

Applied Sciences

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This paper proposes a composite model that combines convolutional neural network models and mechanical analysis to determine the forces acting on an object. First, we establish a model using Newtonian mechanics to analyze the forces experienced by the human body during movement, particularly the forces on joints. The model calculates the mapping relationship between the object’s movement and the forces on the joints. Then, by analyzing a large number of fencing competition videos using a deep learning model, we extract video features to study the torques and forces on human joints. Our analysis of numerous images reveals that, in certain movement patterns, the peak pressure on the knee joint can be two to three times higher than in a normal state, while the driving knee can withstand peak torques of 400–600 Nm. This straightforward model can effectively capture the forces and torques on the human body during movement using a deep neural network. Furthermore, this model can also be applied to problems involving non-rigid body motion.

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Joint object contour points and semantics for instance segmentation

Cited by 3 publications

References 66 publications

Instance Segmentation of Nematode Image Based on Transformer with Skeleton Points

Instance Segmentation of Nematode Image Based on Transformer with Skeleton Points

An artificial intelligence-based screening tool for orthognathic surgery using MKG angle in lateral cephalograms

Deep Learning Methods to Analyze the Forces and Torques in Joints Motion

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