Unsupervised brain lesion segmentation from MRI using a convolutional autoencoder

Atlason, Hans E.; Löve, Áskell; Sigurðsson, Sigurður; Guðnason, Vilmundur; Ellingsen, Lotta M.

doi:10.1117/12.2512953

Cited by 36 publications

(27 citation statements)

References 18 publications

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“…Deep learning image segmentation tasks can be categorised into unsupervised and supervised methods [101], as discussed below. A number of metrics are commonly used to quantify the performance of segmentation models such as the Dice score, positive predictive value (PPV), true positive rate (TPR) and absolute volume difference (AVD) [102].…”

Section: Segmentationmentioning

confidence: 99%

Enterprise imaging and big data: A review from a medical physics perspective

et al. 2021

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In recent years enterprise imaging (EI) solutions have become a core component of healthcare initiatives, while a simultaneous rise in big data has opened up a number of possibilities in how we can analyze and derive insights from large amounts of medical data. Together they afford us a range of opportunities that can transform healthcare in many fields. This paper provides a review of recent developments in EI and big data in the context of medical physics. It summarizes the key aspects of EI and big data in practice, with discussion and consideration of the steps necessary to implement an EI strategy. It examines the benefits that a healthcare service can achieve through the implementation of an EI solution by looking at it through the lenses of: compliance, improving patient care, maximizing revenue, optimizing workflows, and applications of artificial intelligence that support enterprise imaging. It also addresses some of the key challenges in enterprise imaging, with discussion and examples presented for those in systems integration, governance, and data security and privacy.

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Section: Segmentationmentioning

confidence: 99%

Enterprise imaging and big data: A review from a medical physics perspective

et al. 2021

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“…EDDNs learn to reconstruct training images from healthy individuals only by first compressing (encoding) them into a low-dimensional representation (latent features) and then decompressing that representation to minimize the reconstruction error between the input data and its reconstruction. Some methods [22,23,24,25,26] delineate anomalies by thresholding the resulting reconstruction errors, i.e., the residual image between the input image vs its reconstruction. Other methods [6,27] train a one-class classifier from latent features to classify if an image (or region of interest) has some anomaly [27,28].…”

Section: Related Workmentioning

confidence: 99%

Investigating the impact of supervoxel segmentation for unsupervised abnormal brain asymmetry detection

Martins

Telea

Falcão

2020

Computerized Medical Imaging and Graphics

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Several brain disorders are associated with abnormal brain asymmetries (asymmetric anomalies). Several computerbased methods aim to detect such anomalies automatically. Recent advances in this area use automatic unsupervised techniques that extract pairs of symmetric supervoxels in the hemispheres, model normal brain asymmetries for each pair from healthy subjects, and treat outliers as anomalies. Yet, there is no deep understanding of the impact of the supervoxel segmentation quality for abnormal asymmetry detection, especially for small anomalies, nor of the added value of using a specialized model for each supervoxel pair instead of a single global appearance model. We aim to answer these questions by a detailed evaluation of different scenarios for supervoxel segmentation and classification for detecting abnormal brain asymmetries. Experimental results on 3D MR-T1 brain images of stroke patients confirm the importance of high-quality supervoxels fit anomalies and the use of a specific classifier for each supervoxel. Next, we present a refinement of the detection method that reduces the number of false-positive supervoxels, thereby making the detection method easier to use for visual inspection and analysis of the found anomalies.

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“…It was also used for diagnosing Parkinson disease [59] , [60] . Additionally, AEN was used for diagnosing osteoporosis disease [61] , type 2 diabetes [62] , prostate [63] , brain [64] (as being recognition related), and even different cancer types [65] , [66] , [67] .…”

Section: Introductionmentioning

confidence: 99%

Diagnosis of heart diseases by a secure Internet of Health Things system based on Autoencoder Deep Neural Network

Deperlioğlu

Köse

Gupta

et al. 2020

Computer Communications

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Objective of this study is to introduce a secure IoHT system, which acts as a clinical decision support system with the diagnosis of cardiovascular diseases. In this sense, it was emphasized that the accuracy rate of diagnosis (classification) can be improved via deep learning algorithms, by needing no hybrid-complex models, and a secure data processing can be achieved with a multi-authentication and Tangle based approach. In detail, heart sounds were classified with Autoencoder Neural Networks (AEN) and the IoHT system was built for supporting doctors in real-time. For developing the diagnosis infrastructure by the AEN, PASCAL B-Training and Physiobank-PhysioNet A-Training heart sound datasets were used accordingly. For the PASCAL dataset, the AEN provided a diagnosis-classification performance with the accuracy of 100%, sensitivity of 100%, and the specificity of 100% whereas the rates were respectively 99.8%, 99.65%, and 99.13% for the PhysioNet dataset. It was seen that the findings by the developed AEN based solution were better than the alternative solutions from the literature. Additionally, usability of the whole IoHT system was found positive by the doctors, and according to the 479 real-case applications, the system was able to achieve accuracy rates of 96.03% for normal heart sounds, 91.91% for extrasystole, and 90.11% for murmur. In terms of security approach, the system was also robust against several attacking methods including synthetic data impute as well as trying to penetrating to the system via central system or mobile devices.

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Unsupervised brain lesion segmentation from MRI using a convolutional autoencoder

Cited by 36 publications

References 18 publications

Enterprise imaging and big data: A review from a medical physics perspective

Enterprise imaging and big data: A review from a medical physics perspective

Investigating the impact of supervoxel segmentation for unsupervised abnormal brain asymmetry detection

Diagnosis of heart diseases by a secure Internet of Health Things system based on Autoencoder Deep Neural Network

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