Abstract
Bone metastasis is one of the most frequent diseases in prostate cancer; scintigraphy imaging is particularly important for the clinical diagnosis of bone metastasis. Up to date, minimal research has been conducted regarding the application of machine learning with emphasis on modern efficient convolutional neural networks (CNNs) algorithms, for the diagnosis of prostate cancer metastasis from bone scintigraphy images. The advantageous and outstanding capabilities of deep learning, machine learning's groundbreaking technological advancement, have not yet been fully investigated regarding their application in computer-aided diagnosis systems in the field of medical image analysis, such as the problem of bone metastasis classification in whole-body scans. In particular, CNNs are gaining great attention due to their ability to recognize complex visual patterns, in the same way as human perception operates. Considering all these new enhancements in the field of deep learning, a set of simpler, faster and more accurate CNN architectures, designed for classification of metastatic prostate cancer in bones, is explored. This research study has a two-fold goal: to create and also demonstrate a set of simple but robust CNN models for automatic classification of whole-body scans in two categories, malignant (bone metastasis) or healthy, using solely the scans at the input level. Through a meticulous exploration of CNN hyper-parameter selection and fine-tuning, the best architecture is selected with respect to classification accuracy. Thus a CNN model with improved classification capabilities for bone metastasis diagnosis is produced, using bone scans from prostate cancer patients. The achieved classification testing accuracy is 97.38%, whereas the average sensitivity is approximately 95.8%. Finally, the best-performing CNN method is compared to other popular and well-known CNN architectures used for medical imaging, like VGG16, ResNet50, GoogleNet and MobileNet. The classification results show that the proposed CNN-based approach outperforms the popular CNN methods in nuclear medicine for metastatic prostate cancer diagnosis in bones.
Highlights
Most common tumors, such as those of the breast, lung and prostate, frequently metastasize to the bone tissue, and so, the skeleton seems to be a site with the most significant tumor burden in cancer patients with advanced disease
This section reports on the results produced in this research study, which is devoted to the use of whole-body scans from SPECT, to perform the diagnosis of bone metastasis for patients suffering from prostate cancer
Other convolutional neural networks (CNNs) methods, including VGG16 [33], ResNet50 [38], Inception V3 [67], Xception [75], and MobileNet [76] were implemented, so as a comparative analysis could be performed between them and the method proposed in this paper
Summary
Most common tumors, such as those of the breast, lung and prostate, frequently metastasize to the bone tissue, and so, the skeleton seems to be a site with the most significant tumor burden in cancer patients with advanced disease. The metastatic prostate cancer mainly sites on the bones of the axial skeleton, causing severe lesions that can cause pain, debility and/or functional impairment [3]. As this type of cancer has great avidity for bone and could cause painful and untreatable effects, an early diagnosis is crucial for the patient. Reviews on clinical evidences and diagnostic assessments of bone metastases in men with prostate cancer can be found in [4]
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