A Computer-Aided Decision Support System for Detection and Localization of Cutaneous Vasculature in Dermoscopy Images Via Deep Feature Learning

Kharazmi, Pegah; Zheng, Jiannan; Lui, Harvey; Wang, Z Jane; Lee, Tim K.

doi:10.1007/s10916-017-0885-2

Cited by 34 publications

(19 citation statements)

References 28 publications

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“…These include auto-encoders, stacked auto-encoders, restricted Boltzmann machines (RBMs), deep belief networks (DBNs) and deep convolutional neural networks (CNNs). In recent years, CNN based methods have gained more popularity in vision systems as well as medical image analysis domain [48,49,50]. CNNs are biologically inspired variants of multi-layer perceptrons.…”

Section: Convolutional Neural Network (Cnns)mentioning

confidence: 99%

Medical Image Analysis using Convolutional Neural Networks: A Review

et al. 2018

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The science of solving clinical problems by analyzing images generated in clinical practice is known as medical image analysis. The aim is to extract information in an affective and efficient manner for improved clinical diagnosis. The recent advances in the field of biomedical engineering has made medical image analysis one of the top research and development area. One of the reason for this advancement is the application of machine learning techniques for the analysis of medical images. Deep learning is successfully used as a tool for machine learning, where a neural network is capable of automatically learning features. This is in contrast to those methods where traditionally hand crafted features are used. The selection and calculation of these features is a challenging task. Among deep learning techniques, deep convolutional networks are actively used for the purpose of medical image analysis. This include application areas such as segmentation, abnormality detection, disease classification, computer aided diagnosis and retrieval.

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Section: Convolutional Neural Network (Cnns)mentioning

confidence: 99%

Medical Image Analysis using Convolutional Neural Networks: A Review

et al. 2018

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“…To the best of our knowledge only few attempts have been made to detect vascular structures in dermoscopic colour images. Recently, Kharazmi et al in work [ 9 ] proposed a data-driven feature learning framework based on stacked sparse autoencoders (SSAE) for comprehensive detection of cutaneous vessels. The proposed framework demonstrated performance of 95.4% detection accuracy over a variety of vessel patterns.…”

Section: Introductionmentioning

confidence: 99%

A Deep Learning Approach to Vascular Structure Segmentation in Dermoscopy Colour Images

Jaworek-Korjakowska

2018

BioMed Research International

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Background Atypical vascular pattern is one of the most important features by differentiating between benign and malignant pigmented skin lesions. Detection and analysis of vascular structures is a necessary initial step for skin mole assessment; it is a prerequisite step to provide an accurate outcome for the widely used 7-point checklist diagnostic algorithm. Methods In this research we present a fully automated machine learning approach for segmenting vascular structures in dermoscopy colour images. The U-Net architecture is based on convolutional networks and designed for fast and precise segmentation of images. After preprocessing the images are randomly divided into 146516 patches of 64 × 64 pixels each. Results On the independent validation dataset including 74 images our implemented method showed high segmentation accuracy. For the U-Net convolutional neural network, an average DSC of 0.84, sensitivity 0.85, and specificity 0.81 has been achieved. Conclusion Vascular structures due to small size and similarity to other local structures create enormous difficulties during the segmentation and assessment process. The use of advanced segmentation methods like deep learning, especially convolutional neural networks, has the potential to improve the accuracy of advanced local structure detection.

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“…The mean accuracy, precision, recall, and Jaccard index on the test set for the combination loss function were 0.987, 0.38, 0.574, and 0.521. This compares with mean accuracy, precision, and recall for Kharazmi et al 15 . of 0.954, 0.947, and 0.917.…”

Section: Discussionmentioning

confidence: 69%

A deep learning approach to detect blood vessels in basal cell carcinoma

Maurya

Stanley

Lama

et al. 2022

Skin Research and Technology

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Purpose: Blood vessels called telangiectasia are visible in skin lesions with the aid of dermoscopy. Telangiectasia are a pivotal identifying feature of basal cell carcinoma.These vessels appear thready, serpiginous, and may also appear arborizing, that is, wide vessels branch into successively thinner vessels. Due to these intricacies, their detection is not an easy task, neither with manual annotation nor with computerized techniques. In this study, we automate the segmentation of telangiectasia in dermoscopic images with a deep learning U-Net approach. Methods:We apply a combination of image processing techniques and a deep learning-based U-Net approach to detect telangiectasia in digital basal cell carcinoma skin cancer images. We compare loss functions and optimize the performance by using a combination loss function to manage class imbalance of skin versus vessel pixels. Results:We establish a baseline method for pixel-based telangiectasia detection in skin cancer lesion images. An analysis and comparison for human observer variability in annotation is also presented. Conclusion:Our approach yields Jaccard score within the variation of human observers as it addresses a new aspect of the rapidly evolving field of deep learning: automatic identification of cancer-specific structures. Further application of DL techniques to detect dermoscopic structures and handle noisy labels is warranted.

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A Computer-Aided Decision Support System for Detection and Localization of Cutaneous Vasculature in Dermoscopy Images Via Deep Feature Learning

Cited by 34 publications

References 28 publications

Medical Image Analysis using Convolutional Neural Networks: A Review

Medical Image Analysis using Convolutional Neural Networks: A Review

A Deep Learning Approach to Vascular Structure Segmentation in Dermoscopy Colour Images

A deep learning approach to detect blood vessels in basal cell carcinoma

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