Exploiting Epistemic Uncertainty of Anatomy Segmentation for Anomaly Detection in Retinal OCT

Seeböck, Philipp; Orlando, José Ignacio; Schlegl, Thomas; Waldstein, Sebastian M.; Bogunović, Hrvoje; Klimscha, Sophie; Langs, Georg; Schmidt‐Erfurth, Ursula

doi:10.1109/tmi.2019.2919951

Cited by 113 publications

(73 citation statements)

References 47 publications

(101 reference statements)

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“…Quantifying uncertainty Variance-based uncertainty quantification using dropout networks is applied to both detection tasks [28,36,50] and segmentation tasks [21,24,34,41,48]. While this metric is most common, alternatives to quantify uncertainty exist, such as the predictive entropy or mutual information [11,18].…”

Section: Related Workmentioning

confidence: 99%

Leveraging the Bhattacharyya coefficient for uncertainty quantification in deep neural networks

Molle

Verbelen

Vankeirsbilck

et al. 2021

Neural Comput & Applic

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Modern deep learning models achieve state-of-the-art results for many tasks in computer vision, such as image classification and segmentation. However, its adoption into high-risk applications, e.g. automated medical diagnosis systems, happens at a slow pace. One of the main reasons for this is that regular neural networks do not capture uncertainty. To assess uncertainty in classification, several techniques have been proposed casting neural network approaches in a Bayesian setting. Amongst these techniques, Monte Carlo dropout is by far the most popular. This particular technique estimates the moments of the output distribution through sampling with different dropout masks. The output uncertainty of a neural network is then approximated as the sample variance. In this paper, we highlight the limitations of such a variance-based uncertainty metric and propose an novel approach. Our approach is based on the overlap between output distributions of different classes. We show that our technique leads to a better approximation of the inter-class output confusion. We illustrate the advantages of our method using benchmark datasets. In addition, we apply our metric to skin lesion classification—a real-world use case—and show that this yields promising results.

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Section: Related Workmentioning

confidence: 99%

Leveraging the Bhattacharyya coefficient for uncertainty quantification in deep neural networks

Molle

Verbelen

Vankeirsbilck

et al. 2021

Neural Comput & Applic

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“…In the medical imaging domain, deep learning (DL) techniques have been used to improve the performance of image analysis significantly [9] [10]. For example, DL has been successfully applied to microscopy images [11], brain tumor classification [12], MRI images [13], and retinal photographs [14].…”

Section: Introductionmentioning

confidence: 99%

Deep Learning Approaches for Detecting COVID-19 From Chest X-Ray Images: A Survey

et al. 2021

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Chest X-ray (CXR) imaging is a standard and crucial examination method used for suspected cases of coronavirus disease (COVID-19). In profoundly affected or limited resource areas, CXR imaging is preferable owing to its availability, low cost, and rapid results. However, given the rapidly spreading nature of COVID-19, such tests could limit the efficiency of pandemic control and prevention. In response to this issue, artificial intelligence methods such as deep learning are promising options for automatic diagnosis because they have achieved state-of-the-art performance in the analysis of visual information and a wide range of medical images. This paper reviews and critically assesses the preprint and published reports between March and May 2020 for the diagnosis of COVID-19 via CXR images using convolutional neural networks and other deep learning architectures. Despite the encouraging results, there is an urgent need for public, comprehensive, and diverse datasets. Further investigations in terms of explainable and justifiable decisions are also required for more robust, transparent, and accurate predictions. INDEX TERMS Chest x-ray, coronavirus, COVID-19, deep learning, radiological imaging.

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“…Since the significance of anomalous data, many researchers proposed anomaly detection methods from different application domains and categories. Anomaly detection has been applied in Cyber‐Intrusion Detection, 3 Fraud Detection, 4,5,6 Medical Anomaly Detection, 7 Industrial Damage Detection, 8 Image Processing, 9 Textual Anomaly Detection, 10 Sensor Networks 11 , etc. From the aspect of machine learning, various anomaly detection methods can be classified as supervised, semi‐supervised and unsupervised anomaly detection 2 …”

Section: Introductionmentioning

confidence: 99%

“…In supervised anomaly detection technologies, support vector machines (SVM) 12 and artificial neural networks 13 perform well, especially for multiclassification detection problems. Semi‐supervised anomaly detection technologies are well‐known for nice outcomes only with normal labeled samples, mainly containing One‐class SVMs 14 and autoencoders 7 . However, the inconvenience of obtaining labeled samples acts as a block of common usage of supervised and semi‐supervised methods.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

An improved agglomerative hierarchical clustering anomaly detection method for scientific data

Shi

Zhao

Zhong

et al. 2020

Concurrency and Computation

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Anomaly detection tries to find out the data that disobeys the rule of majority data or expected patterns. The traditional hierarchical clustering algorithms have been adopted to detect anomaly, but have the disadvantages of low effectiveness and unstability. So we propose an improved agglomerative hierarchical clustering method for anomaly detection. It dynamically adjusts the optimum clustering number according to the self-defined criterion to save the trouble of manually picking clustering number, and determines the optimum clustering distance mode according to cophenetic correlation coefficient to reduce the procedure of manually testing the suitable distance mode in each iteration. The performances of proposed method are verified on tensile test, HTRU2 and credit card dataset. Compared with the traditional methods, our method possesses the most comprehensive performance (the highest F-measure with less iterations), which shows effectiveness of anomaly detection. And compared with the traditional methods (single, complete, average, and centroid mode), our method achieves the best performance on tensile test and HTRU2 dataset, showing stronger generalization. Compared with other methods (Decision + Gradient Boosted Tree, Decision Trees + Decision Stump, etc) on credit card dataset, our method obtains similar accuracy, and ranks in the top level in the aspect of sensitivity.

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Exploiting Epistemic Uncertainty of Anatomy Segmentation for Anomaly Detection in Retinal OCT

Cited by 113 publications

References 47 publications

Leveraging the Bhattacharyya coefficient for uncertainty quantification in deep neural networks

Leveraging the Bhattacharyya coefficient for uncertainty quantification in deep neural networks

Deep Learning Approaches for Detecting COVID-19 From Chest X-Ray Images: A Survey

An improved agglomerative hierarchical clustering anomaly detection method for scientific data

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