Deep transfer learning approaches for Monkeypox disease diagnosis
Monkeypox has become a significant global challenge as the number of cases increases daily. Those infected with the disease often display various skin symptoms and can spread the infection through contamination. Recently, Machine Learning (ML) has shown potential in image-based diagnoses, such as de...
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Veröffentlicht in: | Expert systems with applications 2023-04, Vol.216, p.119483-119483, Article 119483 |
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Zusammenfassung: | Monkeypox has become a significant global challenge as the number of cases increases daily. Those infected with the disease often display various skin symptoms and can spread the infection through contamination. Recently, Machine Learning (ML) has shown potential in image-based diagnoses, such as detecting cancer, identifying tumor cells, and identifying coronavirus disease (COVID)-19 patients. Thus, ML could potentially be used to diagnose Monkeypox as well. In this study, we developed a Monkeypox diagnosis model using Generalization and Regularization-based Transfer Learning approaches (GRA-TLA) for binary and multiclass classification. We tested our proposed approach on ten different convolutional Neural Network (CNN) models in three separate studies. The preliminary computational results showed that our proposed approach, combined with Extreme Inception (Xception), was able to distinguish between individuals with and without Monkeypox with an accuracy ranging from 77% to 88% in Studies One and Two, while Residual Network (ResNet)-101 had the best performance for multiclass classification in Study Three, with an accuracy ranging from 84% to 99%. In addition, we found that our proposed approach was computationally efficient compared to existing TL approaches in terms of the number of parameters (NP) and Floating-Point Operations per Second (FLOPs) required. We also used Local Interpretable Model-Agnostic Explanations (LIME) to explain our model’s predictions and feature extractions, providing a deeper understanding of the specific features that may indicate the onset of Monkeypox.
•Introduced optimal generalization and regularization-based transfer learning method.•Optimal CNN performance observed for both binary and multiclass classification.•Early stopping techniques reduce overfitting during the CNN model training.•GRA-TLA with Xception and ResNet101 achieved an accuracy of around 77% to 94%.•Post-image analysis with explainable AI matched with the model’s predictions. |
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ISSN: | 0957-4174 0957-4174 |
DOI: | 10.1016/j.eswa.2022.119483 |