Semi-supervised and Task-Driven Data Augmentation

Chaitanya, Krishna; Karani, Neerav; Baumgartner, Christian F.; Becker, Anton S.; Donati, Olivio F.; Konukoğlu, Ender

doi:10.1007/978-3-030-20351-1_3

Cited by 125 publications

(113 citation statements)

References 34 publications

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“…Although there are works which indicate that such aggressive augmentation may deteriorate the performance of the models in brain-tumor delineation , it is still an open issue. Chaitanya et al (2019) showed that visually nonrealistic synthetic examples can improve the segmentation of cardiac MRI and noted that it is slightly counter-intuitive-it may have occurred due to the inherent structural and deformationrelated characteristics of the cardiovascular system. Finally, elastic transformations often benefit from B-splines (Huang and Cohen, 1996;Gu et al, 2014) or random deformations (Castro et al, 2018).…”

Section: Data Augmentation Using Elastic Image Transformationsmentioning

confidence: 99%

Data Augmentation for Brain-Tumor Segmentation: A Review

Nalepa

Marcinkiewicz²,

Kawulok

2019

Front. Comput. Neurosci.

245

127

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Data augmentation is a popular technique which helps improve generalization capabilities of deep neural networks, and can be perceived as implicit regularization. It plays a pivotal role in scenarios in which the amount of high-quality ground-truth data is limited, and acquiring new examples is costly and time-consuming. This is a very common problem in medical image analysis, especially tumor delineation. In this paper, we review the current advances in data-augmentation techniques applied to magnetic resonance images of brain tumors. To better understand the practical aspects of such algorithms, we investigate the papers submitted to the Multimodal Brain Tumor Segmentation Challenge (BraTS 2018 edition), as the BraTS dataset became a standard benchmark for validating existent and emerging brain-tumor detection and segmentation techniques. We verify which data augmentation approaches were exploited and what was their impact on the abilities of underlying supervised learners. Finally, we highlight the most promising research directions to follow in order to synthesize high-quality artificial brain-tumor examples which can boost the generalization abilities of deep models.

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Section: Data Augmentation Using Elastic Image Transformationsmentioning

confidence: 99%

Data Augmentation for Brain-Tumor Segmentation: A Review

Nalepa

Marcinkiewicz²,

Kawulok

2019

Front. Comput. Neurosci.

245

127

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“…In medical imaging, UDA has been studied in several fields for which multiple diverse datasets are publicly available: brain MRI [20,4], chest X-ray [7], cardiac MRI-CT [13] and others. However, very few studies investigated the use of UDA techniques in knee MRI domain and, more specifically, knee cartilage segmentation.…”

Section: Related Workmentioning

confidence: 99%

“…Comparison between the baseline and the best performing approaches. Here, means and standard deviations of volumetric DSCs are presented for the subject groups of specific KL-grades(1)(2)(3)(4) and for the full test sets. # shows the number of scans in the specific group.…”

mentioning

confidence: 99%

Improving Robustness of Deep Learning Based Knee MRI Segmentation: Mixup and Adversarial Domain Adaptation

Panfilov

Tiulpin

Klein

et al. 2019

2019 IEEE/CVF International Conference on Computer Vision Workshop (ICCVW)

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Degeneration of articular cartilage (AC) is actively studied in knee osteoarthritis (OA) research via magnetic resonance imaging (MRI). Segmentation of AC tissues from MRI data is an essential step in quantification of their damage. Deep learning (DL) based methods have shown potential in this realm and are the current state-of-the-art, however, their robustness to heterogeneity of MRI acquisition settings remains an open problem. In this study, we investigated two modern regularization techniques -mixup and adversarial unsupervised domain adaptation (UDA) -to improve the robustness of DL-based knee cartilage segmentation to new MRI acquisition settings. Our validation setup included two datasets produced by different MRI scanners and using distinct data acquisition protocols. We assessed the robustness of automatic segmentation by comparing mixup and UDA approaches to a strong baseline method at different OA severity stages and, additionally, in relation to anatomical locations. Our results showed that for moderate changes in knee MRI data acquisition settings both approaches may provide notable improvements in the robustness, which are consistent for all stages of the disease and affect the clinically important areas of the knee joint. However, mixup may be considered as a recommended approach, since it is more computationally efficient and does not require additional data from the target acquisition setup.

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“…Die diesem Konzept zugrundeliegende Idee ist, dass das Aussehen der Objekte in einem Repräsentationsraum weitestgehend kontinuierlich verteilt und die Struktur des Raums durch die initialen Klassen soweit etabliert wird, das neue Klassen eingepasst werden können. Ein anderer Ansatz für das gleiche Problem ist das erlernte Augmentieren von Daten, das heißt, die Generierung von zusätzlichen Trainingsdaten aus wenigen Beobachtungen [5].…”

Section: Transfer Learningunclassified

Maschinelles Lernen in der Radiologie

et al. 2020

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Zusammenfassung Methodisches Problem Maschinelles Lernen (ML) nimmt zunehmend Einzug in die Radiologie, um Aufgaben wie die automatische Detektion und Segmentation von diagnoserelevanten Bildmerkmalen, die Charakterisierung von Krankheits- und Behandlungsverläufen sowie Vorhersagen für individuelle Patienten durchzuführen. Radiologische Standardverfahren Die Anwendung von ML-Algorithmen ist für alle radiologischen Verfahren von der Computertomographie (CT), über die Magnetresonanztomographie (MRT) bis zum Ultraschall relevant. Verschiedene Modalitäten führen zu unterschiedlichen Herausforderungen bezüglich Standardisierung und Variabilität. Methodische Innovationen ML-Algorithmen sind zunehmend in der Lage, auch longitudinale Beobachtungen zu verarbeiten und für das Training von Vorhersagemodellen zu nutzen. Diese Entwicklung erlaubt es, umfassende Informationen für die Vorhersage individueller Verläufe heranzuziehen. Leistungsfähigkeit Die Qualität der Detektion und Segmentation von Läsionen hat in vielen Bereichen ein akzeptables Niveau erreicht, die Genauigkeit von Vorhersagemodellen muss diese aber erst erreichen, was u. a. auch mit der Verfügbarkeit repräsentativer Trainingsdaten zusammenhängt. Bewertung Die Entwicklung von ML-basierten Anwendungen in der Radiologie schreitet, trotz dass sich viele der Lösungen noch im Evaluationsstadium befinden, voran, und wird durch eine parallele Weiterentwicklung der grundlegenden Methoden und Techniken begleitet, die sukzessive in die Praxis übergehen werden. Empfehlung für die Praxis Maßgeblich für den effektiven Einsatz von ML in der Praxis sind die Validierung der Algorithmen und die Erstellung repräsentativer Datensätze, die sowohl für das Training als auch für die Validierung verwendet werden können.

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Semi-supervised and Task-Driven Data Augmentation

Cited by 125 publications

References 34 publications

Data Augmentation for Brain-Tumor Segmentation: A Review

Data Augmentation for Brain-Tumor Segmentation: A Review

Improving Robustness of Deep Learning Based Knee MRI Segmentation: Mixup and Adversarial Domain Adaptation

Maschinelles Lernen in der Radiologie

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