Hybrid classical–quantum Convolutional Neural Network for stenosis detection in X-ray coronary angiography

Hybrid classical–quantum Convolutional Neural Network for stenosis detection in X-ray coronary angiography

Despite advances in Deep Learning, the Convolutional Neural Networks methods still manifest limitations in medical applications because datasets are usually restricted in the number of samples or include poorly contrasted images. Such a case is found in stenosis detection using X-rays coronary angio...

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Veröffentlicht in:Expert systems with applications 2022-03, Vol.189, p.116112, Article 116112
Hauptverfasser: Ovalle-Magallanes, Emmanuel, Avina-Cervantes, Juan Gabriel, Cruz-Aceves, Ivan, Ruiz-Pinales, Jose
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Sprache:eng
Schlagworte:
Angiography
Artificial neural networks
Circuits
Coronary angiography
Datasets
Deep learning
Hybrid Convolutional Neural Network
Hyperbolic functions
Hyperspheres
Medical imaging
Neural networks
Performance enhancement
Quantum computing
Stenosis detection
X-ray imaging
X-rays
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creator Ovalle-Magallanes, Emmanuel
Avina-Cervantes, Juan Gabriel
Cruz-Aceves, Ivan
Ruiz-Pinales, Jose
description Despite advances in Deep Learning, the Convolutional Neural Networks methods still manifest limitations in medical applications because datasets are usually restricted in the number of samples or include poorly contrasted images. Such a case is found in stenosis detection using X-rays coronary angiography. In this study, the emerging field of quantum computing is applied in the context of hybrid neural networks. So, a hybrid transfer-learning paradigm is used for stenosis detection, where a quantum network drives and improves the performance of a pre-trained classical network. An intermediate layer between the classical and quantum network post-processes the classical features by mapping them into a hypersphere of fixed radius through a hyperbolic tangent function. Next, these normalized features are processed in the quantum network, and through a SoftMax function, the class probabilities are obtained: stenosis and non-stenosis. Furthermore, a distributed variational quantum circuit is implemented to split the data into multiple quantum circuits within the quantum network, improving the training time without compromising the stenosis detection performance. The proposed method is evaluated on a small X-ray coronary angiography dataset containing 250 image patches (50%–50% of positive and negative stenosis cases). The hybrid classical–quantum network significantly outperformed the classical network. Evaluation results showed a boost concerning the classical transfer learning paradigm in the accuracy of 9%, recall of 20%, and F1-score of 11%, reaching 91.8033%, 94.9153%, and 91.8033%, respectively. •A quantum network boosts the performance of classical neural architecture.•An L2 hyperbolic tangent layer bounds the features between classical and quantum stages.•The X-ray angiography images are analyzed to develop a robust stenosis detector system.•Transfer learning and quantum network substantially improved stenosis detection.•An efficient hybrid classical–quantum architecture is focused on stenosis detection.
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subjects Angiography
Artificial neural networks
Circuits
Coronary angiography
Datasets
Deep learning
Hybrid Convolutional Neural Network
Hyperbolic functions
Hyperspheres
Medical imaging
Neural networks
Performance enhancement
Quantum computing
Stenosis detection
X-ray imaging
X-rays
title Hybrid classical–quantum Convolutional Neural Network for stenosis detection in X-ray coronary angiography
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