Your search keyword '"Rieke, Nicola"' showing total 288 results

1. Confidence intervals uncovered: Are we ready for real-world medical imaging AI?

Author

Christodoulou, Evangelia, Reinke, Annika, Houhou, Rola, Kalinowski, Piotr, Erkan, Selen, Sudre, Carole H., Burgos, Ninon, Boutaj, Sofiène, Loizillon, Sophie, Solal, Maëlys, Rieke, Nicola, Cheplygina, Veronika, Antonelli, Michela, Mayer, Leon D., Tizabi, Minu D., Cardoso, M. Jorge, Simpson, Amber, Jäger, Paul F., Kopp-Schneider, Annette, Varoquaux, Gaël, Colliot, Olivier, and Maier-Hein, Lena

Subjects

Computer Science - Computer Vision and Pattern Recognition, Computer Science - Artificial Intelligence, Computer Science - Machine Learning

Abstract

Medical imaging is spearheading the AI transformation of healthcare. Performance reporting is key to determine which methods should be translated into clinical practice. Frequently, broad conclusions are simply derived from mean performance values. In this paper, we argue that this common practice is often a misleading simplification as it ignores performance variability. Our contribution is threefold. (1) Analyzing all MICCAI segmentation papers (n = 221) published in 2023, we first observe that more than 50% of papers do not assess performance variability at all. Moreover, only one (0.5%) paper reported confidence intervals (CIs) for model performance. (2) To address the reporting bottleneck, we show that the unreported standard deviation (SD) in segmentation papers can be approximated by a second-order polynomial function of the mean Dice similarity coefficient (DSC). Based on external validation data from 56 previous MICCAI challenges, we demonstrate that this approximation can accurately reconstruct the CI of a method using information provided in publications. (3) Finally, we reconstructed 95% CIs around the mean DSC of MICCAI 2023 segmentation papers. The median CI width was 0.03 which is three times larger than the median performance gap between the first and second ranked method. For more than 60% of papers, the mean performance of the second-ranked method was within the CI of the first-ranked method. We conclude that current publications typically do not provide sufficient evidence to support which models could potentially be translated into clinical practice., Comment: Paper accepted at MICCAI 2024 conference

Published

2024

2. FUTURE-AI: International consensus guideline for trustworthy and deployable artificial intelligence in healthcare

Author

Lekadir, Karim, Feragen, Aasa, Fofanah, Abdul Joseph, Frangi, Alejandro F, Buyx, Alena, Emelie, Anais, Lara, Andrea, Porras, Antonio R, Chan, An-Wen, Navarro, Arcadi, Glocker, Ben, Botwe, Benard O, Khanal, Bishesh, Beger, Brigit, Wu, Carol C, Cintas, Celia, Langlotz, Curtis P, Rueckert, Daniel, Mzurikwao, Deogratias, Fotiadis, Dimitrios I, Zhussupov, Doszhan, Ferrante, Enzo, Meijering, Erik, Weicken, Eva, González, Fabio A, Asselbergs, Folkert W, Prior, Fred, Krestin, Gabriel P, Collins, Gary, Tegenaw, Geletaw S, Kaissis, Georgios, Misuraca, Gianluca, Tsakou, Gianna, Dwivedi, Girish, Kondylakis, Haridimos, Jayakody, Harsha, Woodruf, Henry C, Mayer, Horst Joachim, Aerts, Hugo JWL, Walsh, Ian, Chouvarda, Ioanna, Buvat, Irène, Tributsch, Isabell, Rekik, Islem, Duncan, James, Kalpathy-Cramer, Jayashree, Zahir, Jihad, Park, Jinah, Mongan, John, Gichoya, Judy W, Schnabel, Julia A, Kushibar, Kaisar, Riklund, Katrine, Mori, Kensaku, Marias, Kostas, Amugongo, Lameck M, Fromont, Lauren A, Maier-Hein, Lena, Alberich, Leonor Cerdá, Rittner, Leticia, Phiri, Lighton, Marrakchi-Kacem, Linda, Donoso-Bach, Lluís, Martí-Bonmatí, Luis, Cardoso, M Jorge, Bobowicz, Maciej, Shabani, Mahsa, Tsiknakis, Manolis, Zuluaga, Maria A, Bielikova, Maria, Fritzsche, Marie-Christine, Camacho, Marina, Linguraru, Marius George, Wenzel, Markus, De Bruijne, Marleen, Tolsgaard, Martin G, Ghassemi, Marzyeh, Ashrafuzzaman, Md, Goisauf, Melanie, Yaqub, Mohammad, Abadía, Mónica Cano, Mahmoud, Mukhtar M E, Elattar, Mustafa, Rieke, Nicola, Papanikolaou, Nikolaos, Lazrak, Noussair, Díaz, Oliver, Salvado, Olivier, Pujol, Oriol, Sall, Ousmane, Guevara, Pamela, Gordebeke, Peter, Lambin, Philippe, Brown, Pieta, Abolmaesumi, Purang, Dou, Qi, Lu, Qinghua, Osuala, Richard, Nakasi, Rose, Zhou, S Kevin, Napel, Sandy, Colantonio, Sara, Albarqouni, Shadi, Joshi, Smriti, Carter, Stacy, Klein, Stefan, Petersen, Steffen E, Aussó, Susanna, Awate, Suyash, Raviv, Tammy Riklin, Cook, Tessa, Mutsvangwa, Tinashe E M, Rogers, Wendy A, Niessen, Wiro J, Puig-Bosch, Xènia, Zeng, Yi, Mohammed, Yunusa G, Aquino, Yves Saint James, Salahuddin, Zohaib, and Starmans, Martijn P A

Subjects

Computer Science - Computers and Society, Computer Science - Artificial Intelligence, Computer Science - Computer Vision and Pattern Recognition, Computer Science - Machine Learning, I.2.0, I.4.0, I.5.0

Abstract

Despite major advances in artificial intelligence (AI) for medicine and healthcare, the deployment and adoption of AI technologies remain limited in real-world clinical practice. In recent years, concerns have been raised about the technical, clinical, ethical and legal risks associated with medical AI. To increase real world adoption, it is essential that medical AI tools are trusted and accepted by patients, clinicians, health organisations and authorities. This work describes the FUTURE-AI guideline as the first international consensus framework for guiding the development and deployment of trustworthy AI tools in healthcare. The FUTURE-AI consortium was founded in 2021 and currently comprises 118 inter-disciplinary experts from 51 countries representing all continents, including AI scientists, clinicians, ethicists, and social scientists. Over a two-year period, the consortium defined guiding principles and best practices for trustworthy AI through an iterative process comprising an in-depth literature review, a modified Delphi survey, and online consensus meetings. The FUTURE-AI framework was established based on 6 guiding principles for trustworthy AI in healthcare, i.e. Fairness, Universality, Traceability, Usability, Robustness and Explainability. Through consensus, a set of 28 best practices were defined, addressing technical, clinical, legal and socio-ethical dimensions. The recommendations cover the entire lifecycle of medical AI, from design, development and validation to regulation, deployment, and monitoring. FUTURE-AI is a risk-informed, assumption-free guideline which provides a structured approach for constructing medical AI tools that will be trusted, deployed and adopted in real-world practice. Researchers are encouraged to take the recommendations into account in proof-of-concept stages to facilitate future translation towards clinical practice of medical AI.

Published

2023

3. Understanding metric-related pitfalls in image analysis validation

Author

Reinke, Annika, Tizabi, Minu D., Baumgartner, Michael, Eisenmann, Matthias, Heckmann-Nötzel, Doreen, Kavur, A. Emre, Rädsch, Tim, Sudre, Carole H., Acion, Laura, Antonelli, Michela, Arbel, Tal, Bakas, Spyridon, Benis, Arriel, Blaschko, Matthew, Buettner, Florian, Cardoso, M. Jorge, Cheplygina, Veronika, Chen, Jianxu, Christodoulou, Evangelia, Cimini, Beth A., Collins, Gary S., Farahani, Keyvan, Ferrer, Luciana, Galdran, Adrian, van Ginneken, Bram, Glocker, Ben, Godau, Patrick, Haase, Robert, Hashimoto, Daniel A., Hoffman, Michael M., Huisman, Merel, Isensee, Fabian, Jannin, Pierre, Kahn, Charles E., Kainmueller, Dagmar, Kainz, Bernhard, Karargyris, Alexandros, Karthikesalingam, Alan, Kenngott, Hannes, Kleesiek, Jens, Kofler, Florian, Kooi, Thijs, Kopp-Schneider, Annette, Kozubek, Michal, Kreshuk, Anna, Kurc, Tahsin, Landman, Bennett A., Litjens, Geert, Madani, Amin, Maier-Hein, Klaus, Martel, Anne L., Mattson, Peter, Meijering, Erik, Menze, Bjoern, Moons, Karel G. M., Müller, Henning, Nichyporuk, Brennan, Nickel, Felix, Petersen, Jens, Rafelski, Susanne M., Rajpoot, Nasir, Reyes, Mauricio, Riegler, Michael A., Rieke, Nicola, Saez-Rodriguez, Julio, Sánchez, Clara I., Shetty, Shravya, van Smeden, Maarten, Summers, Ronald M., Taha, Abdel A., Tiulpin, Aleksei, Tsaftaris, Sotirios A., Van Calster, Ben, Varoquaux, Gaël, Wiesenfarth, Manuel, Yaniv, Ziv R., Jäger, Paul F., and Maier-Hein, Lena

Subjects

Computer Science - Computer Vision and Pattern Recognition

Abstract

Validation metrics are key for the reliable tracking of scientific progress and for bridging the current chasm between artificial intelligence (AI) research and its translation into practice. However, increasing evidence shows that particularly in image analysis, metrics are often chosen inadequately in relation to the underlying research problem. This could be attributed to a lack of accessibility of metric-related knowledge: While taking into account the individual strengths, weaknesses, and limitations of validation metrics is a critical prerequisite to making educated choices, the relevant knowledge is currently scattered and poorly accessible to individual researchers. Based on a multi-stage Delphi process conducted by a multidisciplinary expert consortium as well as extensive community feedback, the present work provides the first reliable and comprehensive common point of access to information on pitfalls related to validation metrics in image analysis. Focusing on biomedical image analysis but with the potential of transfer to other fields, the addressed pitfalls generalize across application domains and are categorized according to a newly created, domain-agnostic taxonomy. To facilitate comprehension, illustrations and specific examples accompany each pitfall. As a structured body of information accessible to researchers of all levels of expertise, this work enhances global comprehension of a key topic in image analysis validation., Comment: Shared first authors: Annika Reinke and Minu D. Tizabi; shared senior authors: Lena Maier-Hein and Paul F. J\"ager. Published in Nature Methods. arXiv admin note: text overlap with arXiv:2206.01653

Published

2023

4. NVIDIA FLARE: Federated Learning from Simulation to Real-World

Author

Roth, Holger R., Cheng, Yan, Wen, Yuhong, Yang, Isaac, Xu, Ziyue, Hsieh, Yuan-Ting, Kersten, Kristopher, Harouni, Ahmed, Zhao, Can, Lu, Kevin, Zhang, Zhihong, Li, Wenqi, Myronenko, Andriy, Yang, Dong, Yang, Sean, Rieke, Nicola, Quraini, Abood, Chen, Chester, Xu, Daguang, Ma, Nic, Dogra, Prerna, Flores, Mona, and Feng, Andrew

Subjects

Computer Science - Machine Learning, Computer Science - Artificial Intelligence, Computer Science - Computer Vision and Pattern Recognition, Computer Science - Networking and Internet Architecture, Computer Science - Software Engineering

Abstract

Federated learning (FL) enables building robust and generalizable AI models by leveraging diverse datasets from multiple collaborators without centralizing the data. We created NVIDIA FLARE as an open-source software development kit (SDK) to make it easier for data scientists to use FL in their research and real-world applications. The SDK includes solutions for state-of-the-art FL algorithms and federated machine learning approaches, which facilitate building workflows for distributed learning across enterprises and enable platform developers to create a secure, privacy-preserving offering for multiparty collaboration utilizing homomorphic encryption or differential privacy. The SDK is a lightweight, flexible, and scalable Python package. It allows researchers to apply their data science workflows in any training libraries (PyTorch, TensorFlow, XGBoost, or even NumPy) in real-world FL settings. This paper introduces the key design principles of NVFlare and illustrates some use cases (e.g., COVID analysis) with customizable FL workflows that implement different privacy-preserving algorithms. Code is available at https://github.com/NVIDIA/NVFlare., Comment: Accepted at the International Workshop on Federated Learning, NeurIPS 2022, New Orleans, USA (https://federated-learning.org/fl-neurips-2022); Revised version v2: added Key Components list, system metrics for homomorphic encryption experiment; Extended v3 for journal submission

Published

2022

5. Metrics reloaded: recommendations for image analysis validation

Author

Maier-Hein, Lena, Reinke, Annika, Godau, Patrick, Tizabi, Minu D., Buettner, Florian, Christodoulou, Evangelia, Glocker, Ben, Isensee, Fabian, Kleesiek, Jens, Kozubek, Michal, Reyes, Mauricio, Riegler, Michael A., Wiesenfarth, Manuel, Kavur, A. Emre, Sudre, Carole H., Baumgartner, Michael, Eisenmann, Matthias, Heckmann-Nötzel, Doreen, Rädsch, Tim, Acion, Laura, Antonelli, Michela, Arbel, Tal, Bakas, Spyridon, Benis, Arriel, Blaschko, Matthew B., Cardoso, M. Jorge, Cheplygina, Veronika, Cimini, Beth A., Collins, Gary S., Farahani, Keyvan, Ferrer, Luciana, Galdran, Adrian, van Ginneken, Bram, Haase, Robert, Hashimoto, Daniel A., Hoffman, Michael M., Huisman, Merel, Jannin, Pierre, Kahn, Charles E., Kainmueller, Dagmar, Kainz, Bernhard, Karargyris, Alexandros, Karthikesalingam, Alan, Kofler, Florian, Kopp-Schneider, Annette, Kreshuk, Anna, Kurc, Tahsin, Landman, Bennett A., Litjens, Geert, Madani, Amin, Maier-Hein, Klaus, Martel, Anne L., Mattson, Peter, Meijering, Erik, Menze, Bjoern, Moons, Karel G. M., Müller, Henning, Nichyporuk, Brennan, Nickel, Felix, Petersen, Jens, Rajpoot, Nasir, Rieke, Nicola, Saez-Rodriguez, Julio, Sánchez, Clara I., Shetty, Shravya, van Smeden, Maarten, Summers, Ronald M., Taha, Abdel A., Tiulpin, Aleksei, Tsaftaris, Sotirios A., Van Calster, Ben, Varoquaux, Gaël, and Jäger, Paul F.

Published

2024

6. Understanding metric-related pitfalls in image analysis validation

Author

Reinke, Annika, Tizabi, Minu D., Baumgartner, Michael, Eisenmann, Matthias, Heckmann-Nötzel, Doreen, Kavur, A. Emre, Rädsch, Tim, Sudre, Carole H., Acion, Laura, Antonelli, Michela, Arbel, Tal, Bakas, Spyridon, Benis, Arriel, Buettner, Florian, Cardoso, M. Jorge, Cheplygina, Veronika, Chen, Jianxu, Christodoulou, Evangelia, Cimini, Beth A., Farahani, Keyvan, Ferrer, Luciana, Galdran, Adrian, van Ginneken, Bram, Glocker, Ben, Godau, Patrick, Hashimoto, Daniel A., Hoffman, Michael M., Huisman, Merel, Isensee, Fabian, Jannin, Pierre, Kahn, Charles E., Kainmueller, Dagmar, Kainz, Bernhard, Karargyris, Alexandros, Kleesiek, Jens, Kofler, Florian, Kooi, Thijs, Kopp-Schneider, Annette, Kozubek, Michal, Kreshuk, Anna, Kurc, Tahsin, Landman, Bennett A., Litjens, Geert, Madani, Amin, Maier-Hein, Klaus, Martel, Anne L., Meijering, Erik, Menze, Bjoern, Moons, Karel G. M., Müller, Henning, Nichyporuk, Brennan, Nickel, Felix, Petersen, Jens, Rafelski, Susanne M., Rajpoot, Nasir, Reyes, Mauricio, Riegler, Michael A., Rieke, Nicola, Saez-Rodriguez, Julio, Sánchez, Clara I., Shetty, Shravya, Summers, Ronald M., Taha, Abdel A., Tiulpin, Aleksei, Tsaftaris, Sotirios A., Van Calster, Ben, Varoquaux, Gaël, Yaniv, Ziv R., Jäger, Paul F., and Maier-Hein, Lena

Published

2024

7. Metrics reloaded: Recommendations for image analysis validation

Author

Maier-Hein, Lena, Reinke, Annika, Godau, Patrick, Tizabi, Minu D., Buettner, Florian, Christodoulou, Evangelia, Glocker, Ben, Isensee, Fabian, Kleesiek, Jens, Kozubek, Michal, Reyes, Mauricio, Riegler, Michael A., Wiesenfarth, Manuel, Kavur, A. Emre, Sudre, Carole H., Baumgartner, Michael, Eisenmann, Matthias, Heckmann-Nötzel, Doreen, Rädsch, Tim, Acion, Laura, Antonelli, Michela, Arbel, Tal, Bakas, Spyridon, Benis, Arriel, Blaschko, Matthew, Cardoso, M. Jorge, Cheplygina, Veronika, Cimini, Beth A., Collins, Gary S., Farahani, Keyvan, Ferrer, Luciana, Galdran, Adrian, van Ginneken, Bram, Haase, Robert, Hashimoto, Daniel A., Hoffman, Michael M., Huisman, Merel, Jannin, Pierre, Kahn, Charles E., Kainmueller, Dagmar, Kainz, Bernhard, Karargyris, Alexandros, Karthikesalingam, Alan, Kenngott, Hannes, Kofler, Florian, Kopp-Schneider, Annette, Kreshuk, Anna, Kurc, Tahsin, Landman, Bennett A., Litjens, Geert, Madani, Amin, Maier-Hein, Klaus, Martel, Anne L., Mattson, Peter, Meijering, Erik, Menze, Bjoern, Moons, Karel G. M., Müller, Henning, Nichyporuk, Brennan, Nickel, Felix, Petersen, Jens, Rajpoot, Nasir, Rieke, Nicola, Saez-Rodriguez, Julio, Sánchez, Clara I., Shetty, Shravya, van Smeden, Maarten, Summers, Ronald M., Taha, Abdel A., Tiulpin, Aleksei, Tsaftaris, Sotirios A., Van Calster, Ben, Varoquaux, Gaël, and Jäger, Paul F.

Subjects

Computer Science - Computer Vision and Pattern Recognition

Abstract

Increasing evidence shows that flaws in machine learning (ML) algorithm validation are an underestimated global problem. Particularly in automatic biomedical image analysis, chosen performance metrics often do not reflect the domain interest, thus failing to adequately measure scientific progress and hindering translation of ML techniques into practice. To overcome this, our large international expert consortium created Metrics Reloaded, a comprehensive framework guiding researchers in the problem-aware selection of metrics. Following the convergence of ML methodology across application domains, Metrics Reloaded fosters the convergence of validation methodology. The framework was developed in a multi-stage Delphi process and is based on the novel concept of a problem fingerprint - a structured representation of the given problem that captures all aspects that are relevant for metric selection, from the domain interest to the properties of the target structure(s), data set and algorithm output. Based on the problem fingerprint, users are guided through the process of choosing and applying appropriate validation metrics while being made aware of potential pitfalls. Metrics Reloaded targets image analysis problems that can be interpreted as a classification task at image, object or pixel level, namely image-level classification, object detection, semantic segmentation, and instance segmentation tasks. To improve the user experience, we implemented the framework in the Metrics Reloaded online tool, which also provides a point of access to explore weaknesses, strengths and specific recommendations for the most common validation metrics. The broad applicability of our framework across domains is demonstrated by an instantiation for various biological and medical image analysis use cases., Comment: Shared first authors: Lena Maier-Hein, Annika Reinke. arXiv admin note: substantial text overlap with arXiv:2104.05642 Published in Nature Methods

Published

2022

8. CrossMoDA 2021 challenge: Benchmark of Cross-Modality Domain Adaptation techniques for Vestibular Schwannoma and Cochlea Segmentation

Author

Dorent, Reuben, Kujawa, Aaron, Ivory, Marina, Bakas, Spyridon, Rieke, Nicola, Joutard, Samuel, Glocker, Ben, Cardoso, Jorge, Modat, Marc, Batmanghelich, Kayhan, Belkov, Arseniy, Calisto, Maria Baldeon, Choi, Jae Won, Dawant, Benoit M., Dong, Hexin, Escalera, Sergio, Fan, Yubo, Hansen, Lasse, Heinrich, Mattias P., Joshi, Smriti, Kashtanova, Victoriya, Kim, Hyeon Gyu, Kondo, Satoshi, Kruse, Christian N., Lai-Yuen, Susana K., Li, Hao, Liu, Han, Ly, Buntheng, Oguz, Ipek, Shin, Hyungseob, Shirokikh, Boris, Su, Zixian, Wang, Guotai, Wu, Jianghao, Xu, Yanwu, Yao, Kai, Zhang, Li, Ourselin, Sebastien, Shapey, Jonathan, and Vercauteren, Tom

Subjects

Electrical Engineering and Systems Science - Image and Video Processing, Computer Science - Computer Vision and Pattern Recognition

Abstract

Domain Adaptation (DA) has recently raised strong interests in the medical imaging community. While a large variety of DA techniques has been proposed for image segmentation, most of these techniques have been validated either on private datasets or on small publicly available datasets. Moreover, these datasets mostly addressed single-class problems. To tackle these limitations, the Cross-Modality Domain Adaptation (crossMoDA) challenge was organised in conjunction with the 24th International Conference on Medical Image Computing and Computer Assisted Intervention (MICCAI 2021). CrossMoDA is the first large and multi-class benchmark for unsupervised cross-modality DA. The challenge's goal is to segment two key brain structures involved in the follow-up and treatment planning of vestibular schwannoma (VS): the VS and the cochleas. Currently, the diagnosis and surveillance in patients with VS are performed using contrast-enhanced T1 (ceT1) MRI. However, there is growing interest in using non-contrast sequences such as high-resolution T2 (hrT2) MRI. Therefore, we created an unsupervised cross-modality segmentation benchmark. The training set provides annotated ceT1 (N=105) and unpaired non-annotated hrT2 (N=105). The aim was to automatically perform unilateral VS and bilateral cochlea segmentation on hrT2 as provided in the testing set (N=137). A total of 16 teams submitted their algorithm for the evaluation phase. The level of performance reached by the top-performing teams is strikingly high (best median Dice - VS:88.4%; Cochleas:85.7%) and close to full supervision (median Dice - VS:92.5%; Cochleas:87.7%). All top-performing methods made use of an image-to-image translation approach to transform the source-domain images into pseudo-target-domain images. A segmentation network was then trained using these generated images and the manual annotations provided for the source image., Comment: In Medical Image Analysis

Published

2022

9. Common Limitations of Image Processing Metrics: A Picture Story

Author

Reinke, Annika, Tizabi, Minu D., Sudre, Carole H., Eisenmann, Matthias, Rädsch, Tim, Baumgartner, Michael, Acion, Laura, Antonelli, Michela, Arbel, Tal, Bakas, Spyridon, Bankhead, Peter, Benis, Arriel, Blaschko, Matthew, Buettner, Florian, Cardoso, M. Jorge, Chen, Jianxu, Cheplygina, Veronika, Christodoulou, Evangelia, Cimini, Beth, Collins, Gary S., Engelhardt, Sandy, Farahani, Keyvan, Ferrer, Luciana, Galdran, Adrian, van Ginneken, Bram, Glocker, Ben, Godau, Patrick, Haase, Robert, Hamprecht, Fred, Hashimoto, Daniel A., Heckmann-Nötzel, Doreen, Hirsch, Peter, Hoffman, Michael M., Huisman, Merel, Isensee, Fabian, Jannin, Pierre, Kahn, Charles E., Kainmueller, Dagmar, Kainz, Bernhard, Karargyris, Alexandros, Karthikesalingam, Alan, Kavur, A. Emre, Kenngott, Hannes, Kleesiek, Jens, Kleppe, Andreas, Kohler, Sven, Kofler, Florian, Kopp-Schneider, Annette, Kooi, Thijs, Kozubek, Michal, Kreshuk, Anna, Kurc, Tahsin, Landman, Bennett A., Litjens, Geert, Madani, Amin, Maier-Hein, Klaus, Martel, Anne L., Mattson, Peter, Meijering, Erik, Menze, Bjoern, Moher, David, Moons, Karel G. M., Müller, Henning, Nichyporuk, Brennan, Nickel, Felix, Noyan, M. Alican, Petersen, Jens, Polat, Gorkem, Rafelski, Susanne M., Rajpoot, Nasir, Reyes, Mauricio, Rieke, Nicola, Riegler, Michael, Rivaz, Hassan, Saez-Rodriguez, Julio, Sánchez, Clara I., Schroeter, Julien, Saha, Anindo, Selver, M. Alper, Sharan, Lalith, Shetty, Shravya, van Smeden, Maarten, Stieltjes, Bram, Summers, Ronald M., Taha, Abdel A., Tiulpin, Aleksei, Tsaftaris, Sotirios A., Van Calster, Ben, Varoquaux, Gaël, Wiesenfarth, Manuel, Yaniv, Ziv R., Jäger, Paul, and Maier-Hein, Lena

Subjects

Electrical Engineering and Systems Science - Image and Video Processing, Computer Science - Computer Vision and Pattern Recognition

Abstract

While the importance of automatic image analysis is continuously increasing, recent meta-research revealed major flaws with respect to algorithm validation. Performance metrics are particularly key for meaningful, objective, and transparent performance assessment and validation of the used automatic algorithms, but relatively little attention has been given to the practical pitfalls when using specific metrics for a given image analysis task. These are typically related to (1) the disregard of inherent metric properties, such as the behaviour in the presence of class imbalance or small target structures, (2) the disregard of inherent data set properties, such as the non-independence of the test cases, and (3) the disregard of the actual biomedical domain interest that the metrics should reflect. This living dynamically document has the purpose to illustrate important limitations of performance metrics commonly applied in the field of image analysis. In this context, it focuses on biomedical image analysis problems that can be phrased as image-level classification, semantic segmentation, instance segmentation, or object detection task. The current version is based on a Delphi process on metrics conducted by an international consortium of image analysis experts from more than 60 institutions worldwide., Comment: Shared first authors: Annika Reinke and Minu D. Tizabi. This is a dynamic paper on limitations of commonly used metrics. It discusses metrics for image-level classification, semantic and instance segmentation, and object detection. For missing use cases, comments or questions, please contact a.reinke@dkfz.de. Substantial contributions to this document will be acknowledged with a co-authorship

Published

2021

10. Federated learning for predicting clinical outcomes in patients with COVID-19

Author

Dayan, Ittai, Roth, Holger R, Zhong, Aoxiao, Harouni, Ahmed, Gentili, Amilcare, Abidin, Anas Z, Liu, Andrew, Costa, Anthony Beardsworth, Wood, Bradford J, Tsai, Chien-Sung, Wang, Chih-Hung, Hsu, Chun-Nan, Lee, CK, Ruan, Peiying, Xu, Daguang, Wu, Dufan, Huang, Eddie, Kitamura, Felipe Campos, Lacey, Griffin, de Antônio Corradi, Gustavo César, Nino, Gustavo, Shin, Hao-Hsin, Obinata, Hirofumi, Ren, Hui, Crane, Jason C, Tetreault, Jesse, Guan, Jiahui, Garrett, John W, Kaggie, Joshua D, Park, Jung Gil, Dreyer, Keith, Juluru, Krishna, Kersten, Kristopher, Rockenbach, Marcio Aloisio Bezerra Cavalcanti, Linguraru, Marius George, Haider, Masoom A, AbdelMaseeh, Meena, Rieke, Nicola, Damasceno, Pablo F, e Silva, Pedro Mario Cruz, Wang, Pochuan, Xu, Sheng, Kawano, Shuichi, Sriswasdi, Sira, Park, Soo Young, Grist, Thomas M, Buch, Varun, Jantarabenjakul, Watsamon, Wang, Weichung, Tak, Won Young, Li, Xiang, Lin, Xihong, Kwon, Young Joon, Quraini, Abood, Feng, Andrew, Priest, Andrew N, Turkbey, Baris, Glicksberg, Benjamin, Bizzo, Bernardo, Kim, Byung Seok, Tor-Díez, Carlos, Lee, Chia-Cheng, Hsu, Chia-Jung, Lin, Chin, Lai, Chiu-Ling, Hess, Christopher P, Compas, Colin, Bhatia, Deepeksha, Oermann, Eric K, Leibovitz, Evan, Sasaki, Hisashi, Mori, Hitoshi, Yang, Isaac, Sohn, Jae Ho, Murthy, Krishna Nand Keshava, Fu, Li-Chen, de Mendonça, Matheus Ribeiro Furtado, Fralick, Mike, Kang, Min Kyu, Adil, Mohammad, Gangai, Natalie, Vateekul, Peerapon, Elnajjar, Pierre, Hickman, Sarah, Majumdar, Sharmila, McLeod, Shelley L, Reed, Sheridan, Gräf, Stefan, Harmon, Stephanie, Kodama, Tatsuya, Puthanakit, Thanyawee, Mazzulli, Tony, de Lavor, Vitor Lima, Rakvongthai, Yothin, Lee, Yu Rim, Wen, Yuhong, Gilbert, Fiona J, Flores, Mona G, and Li, Quanzheng

Subjects

Patient Safety, Good Health and Well Being, COVID-19, Electronic Health Records, Humans, Machine Learning, Outcome Assessment, Health Care, Prognosis, SARS-CoV-2, Medical and Health Sciences, Immunology

Abstract

Federated learning (FL) is a method used for training artificial intelligence models with data from multiple sources while maintaining data anonymity, thus removing many barriers to data sharing. Here we used data from 20 institutes across the globe to train a FL model, called EXAM (electronic medical record (EMR) chest X-ray AI model), that predicts the future oxygen requirements of symptomatic patients with COVID-19 using inputs of vital signs, laboratory data and chest X-rays. EXAM achieved an average area under the curve (AUC) >0.92 for predicting outcomes at 24 and 72 h from the time of initial presentation to the emergency room, and it provided 16% improvement in average AUC measured across all participating sites and an average increase in generalizability of 38% when compared with models trained at a single site using that site's data. For prediction of mechanical ventilation treatment or death at 24 h at the largest independent test site, EXAM achieved a sensitivity of 0.950 and specificity of 0.882. In this study, FL facilitated rapid data science collaboration without data exchange and generated a model that generalized across heterogeneous, unharmonized datasets for prediction of clinical outcomes in patients with COVID-19, setting the stage for the broader use of FL in healthcare.

Published

2021

11. The Future of Digital Health with Federated Learning

Author

Rieke, Nicola, Hancox, Jonny, Li, Wenqi, Milletari, Fausto, Roth, Holger, Albarqouni, Shadi, Bakas, Spyridon, Galtier, Mathieu N., Landman, Bennett, Maier-Hein, Klaus, Ourselin, Sebastien, Sheller, Micah, Summers, Ronald M., Trask, Andrew, Xu, Daguang, Baust, Maximilian, and Cardoso, M. Jorge

Subjects

Computer Science - Computers and Society, Computer Science - Machine Learning

Abstract

Data-driven Machine Learning has emerged as a promising approach for building accurate and robust statistical models from medical data, which is collected in huge volumes by modern healthcare systems. Existing medical data is not fully exploited by ML primarily because it sits in data silos and privacy concerns restrict access to this data. However, without access to sufficient data, ML will be prevented from reaching its full potential and, ultimately, from making the transition from research to clinical practice. This paper considers key factors contributing to this issue, explores how Federated Learning (FL) may provide a solution for the future of digital health and highlights the challenges and considerations that need to be addressed., Comment: This is a pre-print version of https://www.nature.com/articles/s41746-020-00323-1

Published

2020

12. Privacy-preserving Federated Brain Tumour Segmentation

Author

Li, Wenqi, Milletarì, Fausto, Xu, Daguang, Rieke, Nicola, Hancox, Jonny, Zhu, Wentao, Baust, Maximilian, Cheng, Yan, Ourselin, Sébastien, Cardoso, M. Jorge, and Feng, Andrew

Subjects

Computer Science - Computer Vision and Pattern Recognition

Abstract

Due to medical data privacy regulations, it is often infeasible to collect and share patient data in a centralised data lake. This poses challenges for training machine learning algorithms, such as deep convolutional networks, which often require large numbers of diverse training examples. Federated learning sidesteps this difficulty by bringing code to the patient data owners and only sharing intermediate model training updates among them. Although a high-accuracy model could be achieved by appropriately aggregating these model updates, the model shared could indirectly leak the local training examples. In this paper, we investigate the feasibility of applying differential-privacy techniques to protect the patient data in a federated learning setup. We implement and evaluate practical federated learning systems for brain tumour segmentation on the BraTS dataset. The experimental results show that there is a trade-off between model performance and privacy protection costs., Comment: MICCAI MLMI 2019

Published

2019

13. 2017 Robotic Instrument Segmentation Challenge

Author

Allan, Max, Shvets, Alex, Kurmann, Thomas, Zhang, Zichen, Duggal, Rahul, Su, Yun-Hsuan, Rieke, Nicola, Laina, Iro, Kalavakonda, Niveditha, Bodenstedt, Sebastian, Herrera, Luis, Li, Wenqi, Iglovikov, Vladimir, Luo, Huoling, Yang, Jian, Stoyanov, Danail, Maier-Hein, Lena, Speidel, Stefanie, and Azizian, Mahdi

Subjects

Computer Science - Computer Vision and Pattern Recognition

Abstract

In mainstream computer vision and machine learning, public datasets such as ImageNet, COCO and KITTI have helped drive enormous improvements by enabling researchers to understand the strengths and limitations of different algorithms via performance comparison. However, this type of approach has had limited translation to problems in robotic assisted surgery as this field has never established the same level of common datasets and benchmarking methods. In 2015 a sub-challenge was introduced at the EndoVis workshop where a set of robotic images were provided with automatically generated annotations from robot forward kinematics. However, there were issues with this dataset due to the limited background variation, lack of complex motion and inaccuracies in the annotation. In this work we present the results of the 2017 challenge on robotic instrument segmentation which involved 10 teams participating in binary, parts and type based segmentation of articulated da Vinci robotic instruments.

Published

2019

14. CrossMoDA 2021 challenge: Benchmark of cross-modality domain adaptation techniques for vestibular schwannoma and cochlea segmentation

Author

Dorent, Reuben, Kujawa, Aaron, Ivory, Marina, Bakas, Spyridon, Rieke, Nicola, Joutard, Samuel, Glocker, Ben, Cardoso, Jorge, Modat, Marc, Batmanghelich, Kayhan, Belkov, Arseniy, Calisto, Maria Baldeon, Choi, Jae Won, Dawant, Benoit M., Dong, Hexin, Escalera, Sergio, Fan, Yubo, Hansen, Lasse, Heinrich, Mattias P., Joshi, Smriti, Kashtanova, Victoriya, Kim, Hyeon Gyu, Kondo, Satoshi, Kruse, Christian N., Lai-Yuen, Susana K., Li, Hao, Liu, Han, Ly, Buntheng, Oguz, Ipek, Shin, Hyungseob, Shirokikh, Boris, Su, Zixian, Wang, Guotai, Wu, Jianghao, Xu, Yanwu, Yao, Kai, Zhang, Li, Ourselin, Sébastien, Shapey, Jonathan, and Vercauteren, Tom

Published

2023

15. CFCM: Segmentation via Coarse to Fine Context Memory

Author

Milletari, Fausto, Rieke, Nicola, Baust, Maximilian, Esposito, Marco, and Navab, Nassir

Subjects

Computer Science - Computer Vision and Pattern Recognition

Abstract

Recent neural-network-based architectures for image segmentation make extensive usage of feature forwarding mechanisms to integrate information from multiple scales. Although yielding good results, even deeper architectures and alternative methods for feature fusion at different resolutions have been scarcely investigated for medical applications. In this work we propose to implement segmentation via an encoder-decoder architecture which differs from any other previously published method since (i) it employs a very deep architecture based on residual learning and (ii) combines features via a convolutional Long Short Term Memory (LSTM), instead of concatenation or summation. The intuition is that the memory mechanism implemented by LSTMs can better integrate features from different scales through a coarse-to-fine strategy; hence the name Coarse-to-Fine Context Memory (CFCM). We demonstrate the remarkable advantages of this approach on two datasets: the Montgomery county lung segmentation dataset, and the EndoVis 2015 challenge dataset for surgical instrument segmentation., Comment: Accepted for presentation at MICCAI 2018

Published

2018

16. Fast 5DOF Needle Tracking in iOCT

Author

Weiss, Jakob, Rieke, Nicola, Nasseri, Mohammad Ali, Maier, Mathias, Eslami, Abouzar, and Navab, Nassir

Subjects

Computer Science - Computer Vision and Pattern Recognition

Abstract

Purpose. Intraoperative Optical Coherence Tomography (iOCT) is an increasingly available imaging technique for ophthalmic microsurgery that provides high-resolution cross-sectional information of the surgical scene. We propose to build on its desirable qualities and present a method for tracking the orientation and location of a surgical needle. Thereby, we enable direct analysis of instrument-tissue interaction directly in OCT space without complex multimodal calibration that would be required with traditional instrument tracking methods. Method. The intersection of the needle with the iOCT scan is detected by a peculiar multi-step ellipse fitting that takes advantage of the directionality of the modality. The geometric modelling allows us to use the ellipse parameters and provide them into a latency aware estimator to infer the 5DOF pose during needle movement. Results. Experiments on phantom data and ex-vivo porcine eyes indicate that the algorithm retains angular precision especially during lateral needle movement and provides a more robust and consistent estimation than baseline methods. Conclusion. Using solely crosssectional iOCT information, we are able to successfully and robustly estimate a 5DOF pose of the instrument in less than 5.5 ms on a CPU.

Published

2018

17. Concurrent Segmentation and Localization for Tracking of Surgical Instruments

Author

Laina, Iro, Rieke, Nicola, Rupprecht, Christian, Vizcaíno, Josué Page, Eslami, Abouzar, Tombari, Federico, and Navab, Nassir

Subjects

Computer Science - Computer Vision and Pattern Recognition

Abstract

Real-time instrument tracking is a crucial requirement for various computer-assisted interventions. In order to overcome problems such as specular reflections and motion blur, we propose a novel method that takes advantage of the interdependency between localization and segmentation of the surgical tool. In particular, we reformulate the 2D instrument pose estimation as heatmap regression and thereby enable a concurrent, robust and near real-time regression of both tasks via deep learning. As demonstrated by our experimental results, this modeling leads to a significantly improved performance than directly regressing the tool position and allows our method to outperform the state of the art on a Retinal Microsurgery benchmark and the MICCAI EndoVis Challenge 2015., Comment: I. Laina and N. Rieke contributed equally to this work. Accepted to MICCAI 2017

Published

2017

18. Automatic Initialization and Failure Detection for Surgical Tool Tracking in Retinal Microsurgery

Author

Vizcaíno, Josué Page, Rieke, Nicola, Tan, David Joseph, Tombari, Federico, Eslami, Abouzar, Navab, Nassir, Maier-Hein, geb. Fritzsche, Klaus Hermann, editor, Deserno, geb. Lehmann, Thomas Martin, editor, Handels, Heinz, editor, and Tolxdorff, Thomas, editor

Published

2017

19. MELLODDY: Cross-pharma Federated Learning at Unprecedented Scale Unlocks Benefits in QSAR without Compromising Proprietary Information

Author

Heyndrickx, Wouter, primary, Mervin, Lewis, additional, Morawietz, Tobias, additional, Sturm, Noé, additional, Friedrich, Lukas, additional, Zalewski, Adam, additional, Pentina, Anastasia, additional, Humbeck, Lina, additional, Oldenhof, Martijn, additional, Niwayama, Ritsuya, additional, Schmidtke, Peter, additional, Fechner, Nikolas, additional, Simm, Jaak, additional, Arany, Adam, additional, Drizard, Nicolas, additional, Jabal, Rama, additional, Afanasyeva, Arina, additional, Loeb, Regis, additional, Verma, Shlok, additional, Harnqvist, Simon, additional, Holmes, Matthew, additional, Pejo, Balazs, additional, Telenczuk, Maria, additional, Holway, Nicholas, additional, Dieckmann, Arne, additional, Rieke, Nicola, additional, Zumsande, Friederike, additional, Clevert, Djork-Arné, additional, Krug, Michael, additional, Luscombe, Christopher, additional, Green, Darren, additional, Ertl, Peter, additional, Antal, Peter, additional, Marcus, David, additional, Do Huu, Nicolas, additional, Fuji, Hideyoshi, additional, Pickett, Stephen, additional, Acs, Gergely, additional, Boniface, Eric, additional, Beck, Bernd, additional, Sun, Yax, additional, Gohier, Arnaud, additional, Rippmann, Friedrich, additional, Engkvist, Ola, additional, Göller, Andreas H., additional, Moreau, Yves, additional, Galtier, Mathieu N., additional, Schuffenhauer, Ansgar, additional, and Ceulemans, Hugo, additional

Published

2023

20. Image Descriptors in Angiography

Author

Hofschen, Katharina, Geissler, Timo, Rieke, Nicola, Berge, Christian Schulte zu, Navab, Nassir, Demirci, Stefanie, Tolxdorff, Thomas, editor, Deserno, Thomas M., editor, Handels, Heinz, editor, and Meinzer, Hans-Peter, editor

Published

2016

21. Real-Time Online Adaption for Robust Instrument Tracking and Pose Estimation

Author

Rieke, Nicola, Tan, David Joseph, Tombari, Federico, Vizcaíno, Josué Page, di San Filippo, Chiara Amat, Eslami, Abouzar, Navab, Nassir, Hutchison, David, Series editor, Kanade, Takeo, Series editor, Kittler, Josef, Series editor, Kleinberg, Jon M., Series editor, Mattern, Friedemann, Series editor, Mitchell, John C., Series editor, Naor, Moni, Series editor, Pandu Rangan, C., Series editor, Steffen, Bernhard, Series editor, Terzopoulos, Demetri, Series editor, Tygar, Doug, Series editor, Weikum, Gerhard, Series editor, Ourselin, Sebastien, editor, Joskowicz, Leo, editor, Sabuncu, Mert R., editor, Unal, Gozde, editor, and Wells, William, editor

Published

2016

22. Privacy-Preserving Federated Brain Tumour Segmentation

Author

Li, Wenqi, primary, Milletarì, Fausto, additional, Xu, Daguang, additional, Rieke, Nicola, additional, Hancox, Jonny, additional, Zhu, Wentao, additional, Baust, Maximilian, additional, Cheng, Yan, additional, Ourselin, Sébastien, additional, Cardoso, M. Jorge, additional, and Feng, Andrew, additional

Published

2019

23. Real-time localization of articulated surgical instruments in retinal microsurgery

Author

Rieke, Nicola, Tan, David Joseph, Amat di San Filippo, Chiara, Tombari, Federico, Alsheakhali, Mohamed, Belagiannis, Vasileios, Eslami, Abouzar, and Navab, Nassir

Published

2016

24. Surgical Tool Tracking and Pose Estimation in Retinal Microsurgery

Author

Rieke, Nicola, Tan, David Joseph, Alsheakhali, Mohamed, Tombari, Federico, di San Filippo, Chiara Amat, Belagiannis, Vasileios, Eslami, Abouzar, Navab, Nassir, Hutchison, David, Series editor, Kanade, Takeo, Series editor, Kittler, Josef, Series editor, Kleinberg, Jon M., Series editor, Mattern, Friedemann, Series editor, Mitchell, John C., Series editor, Naor, Moni, Series editor, Pandu Rangan, C., Series editor, Steffen, Bernhard, Series editor, Terzopoulos, Demetri, Series editor, Tygar, Doug, Series editor, Weikum, Gerhard, Series editor, Navab, Nassir, editor, Hornegger, Joachim, editor, Wells, William M., editor, and Frangi, Alejandro, editor

Published

2015

25. Contributors

Author

An, Senjian, primary, Bennamoun, Mohammed, additional, Bisagno, Niccoló, additional, Boussaid, Farid, additional, Buongiorno, Domenico, additional, Cavallaro, Andrea, additional, Celiktutan, Oya, additional, Chakraborty, Shayok, additional, Chessa, Manuela, additional, Colantonio, Sara, additional, Conci, Nicola, additional, Coppini, Giuseppe, additional, Dimiccoli, Mariella, additional, Florea, Corneliu, additional, Florea, Laura, additional, Frisoli, Antonio, additional, Giorgi, Daniela, additional, Gunes, Hatice, additional, Gurrin, Cathal, additional, Hu, Feng, additional, Ke, Qiuhong, additional, Liu, Jun, additional, Loconsole, Claudio, additional, Marcheschi, Simone, additional, Martini, Chiara, additional, McDaniel, Troy, additional, Moore, Meredith, additional, Morales, Maria-Aurora, additional, Navab, Nassir, additional, Noceti, Nicoletta, additional, Odone, Francesca, additional, Panchanathan, Sethuraman, additional, Pascali, Maria A., additional, Rieke, Nicola, additional, Saraç Stroppa, Mine, additional, Sariyanidi, Evangelos, additional, Smeaton, Alan F., additional, Sohel, Ferdous, additional, Solari, Fabio, additional, Solazzi, Massimiliano, additional, Sotgiu, Edoardo, additional, Stroppa, Fabio, additional, Sun, Lifeng, additional, Tang, Hao, additional, Tombari, Federico, additional, Tsema, Aleksandr, additional, Venkateswara, Hemanth, additional, Vertan, Constantin, additional, Wang, Peng, additional, Yang, Shiqiang, additional, and Zhu, Zhigang, additional

Published

2018

26. Computer Vision and Machine Learning for Surgical Instrument Tracking

Author

Rieke, Nicola, primary, Tombari, Federico, additional, and Navab, Nassir, additional

Published

2018

27. CFCM: Segmentation via Coarse to Fine Context Memory

Author

Milletari, Fausto, primary, Rieke, Nicola, additional, Baust, Maximilian, additional, Esposito, Marco, additional, and Navab, Nassir, additional

Published

2018

28. Abstract: Real-Time Online Adaption for Robust Instrument Tracking and Pose Estimation

Author

Rieke, Nicola, Tan, David Joseph, Tombari, Federico, Vizcaíno, Josué Page, di San Filippo, Chiara Amat, Eslami, Abouzar, Navab, Nassir, Maier-Hein, geb. Fritzsche, Klaus Hermann, editor, Deserno, geb. Lehmann, Thomas Martin, editor, Handels, Heinz, editor, and Tolxdorff, Thomas, editor

Published

2017

29. Rapid artificial intelligence solutions in a pandemic—The COVID-19-20 Lung CT Lesion Segmentation Challenge

Author

Roth, Holger R., primary, Xu, Ziyue, additional, Tor-Díez, Carlos, additional, Sanchez Jacob, Ramon, additional, Zember, Jonathan, additional, Molto, Jose, additional, Li, Wenqi, additional, Xu, Sheng, additional, Turkbey, Baris, additional, Turkbey, Evrim, additional, Yang, Dong, additional, Harouni, Ahmed, additional, Rieke, Nicola, additional, Hu, Shishuai, additional, Isensee, Fabian, additional, Tang, Claire, additional, Yu, Qinji, additional, Sölter, Jan, additional, Zheng, Tong, additional, Liauchuk, Vitali, additional, Zhou, Ziqi, additional, Moltz, Jan Hendrik, additional, Oliveira, Bruno, additional, Xia, Yong, additional, Maier-Hein, Klaus H., additional, Li, Qikai, additional, Husch, Andreas, additional, Zhang, Luyang, additional, Kovalev, Vassili, additional, Kang, Li, additional, Hering, Alessa, additional, Vilaça, João L., additional, Flores, Mona, additional, Xu, Daguang, additional, Wood, Bradford, additional, and Linguraru, Marius George, additional

Published

2022

30. MELLODDY: cross pharma federated learning at unprecedented scale unlocks benefits in QSAR without compromising proprietary information

Author

Heyndrickx, Wouter, primary, Mervin, Lewis, additional, Morawietz, Tobias, additional, Sturm, Noé, additional, Friedrich, Lukas, additional, Zalewski, Adam, additional, Pentina, Anastasia, additional, Humbeck, Lina, additional, Oldenhof, Martijn, additional, Niwayama, Ritsuya, additional, Schmidtke, Peter, additional, Fechner, Nikolas, additional, Simm, Jaak, additional, Arany, Adam, additional, Drizard, Nicolas, additional, Jabal, Rama, additional, Afanasyeva, Arina, additional, Loeb, Regis, additional, Verma, Shlok, additional, Harnqvist, Simon, additional, Holmes, Matthew, additional, Pejo, Balasz, additional, Telenczuk, Maria, additional, Holway, Nicholas, additional, Dieckmann, Arne, additional, Rieke, Nicola, additional, Zumsande, Friederike, additional, Clevert, Djork-Arné, additional, Krug, Michael, additional, Luscombe, Christopher, additional, Green, Darren, additional, Ertl, Peter, additional, Antal, Peter, additional, Marcus, David, additional, Do Huu, Nicolas, additional, Fuji, Hideyoshi, additional, Pickett, Stephen, additional, Acs, Gergely, additional, Boniface, Eric, additional, Beck, Bernd, additional, Sun, Yax, additional, Gohier, Arnaud, additional, Rippmann, Friedrich, additional, Engkvist, Ola, additional, Göller, Andreas H., additional, Moreau, Yves, additional, Galtier, Mathieu N., additional, Schuffenhauer, Ansgar, additional, and Ceulemans, Hugo, additional

Published

2022

31. Concurrent Segmentation and Localization for Tracking of Surgical Instruments

Author

Laina, Iro, primary, Rieke, Nicola, additional, Rupprecht, Christian, additional, Vizcaíno, Josué Page, additional, Eslami, Abouzar, additional, Tombari, Federico, additional, and Navab, Nassir, additional

Published

2017

32. Rapid artificial intelligence solutions in a pandemic—The COVID-19-20 Lung CT Lesion Segmentation Challenge

Author

Roth, Holger R., Xu, Ziyue, Diez, Carlos Tor, Jacob, Ramon Sanchez, Zember, Jonathan, Molto, Jose, Li, Wenqi, Xu, Sheng, Turkbey, Baris, Turkbey, Evrim, Yang, Dong, Harouni, Ahmed, Rieke, Nicola, Hu, Shishuai, Isensee, Fabian, Tang, Claire, Yu, Qinji, Sölter, Jan, Zheng, Tong, Liauchuk, Vitali, Zhou, Ziqi, Moltz, Jan Hendrik, Oliveira, Bruno, Xia, Yong, Maier-Hein, Klaus H., Li, Qikai, Husch, Andreas, Zhang, Luyang, Kovalev, Vassili, Kang, Li, Hering, Alessa, Vilaça, João L., Flores, Mona, Xu, Daguang, Wood, Bradford, Linguraru, Marius George, Roth, Holger R., Xu, Ziyue, Diez, Carlos Tor, Jacob, Ramon Sanchez, Zember, Jonathan, Molto, Jose, Li, Wenqi, Xu, Sheng, Turkbey, Baris, Turkbey, Evrim, Yang, Dong, Harouni, Ahmed, Rieke, Nicola, Hu, Shishuai, Isensee, Fabian, Tang, Claire, Yu, Qinji, Sölter, Jan, Zheng, Tong, Liauchuk, Vitali, Zhou, Ziqi, Moltz, Jan Hendrik, Oliveira, Bruno, Xia, Yong, Maier-Hein, Klaus H., Li, Qikai, Husch, Andreas, Zhang, Luyang, Kovalev, Vassili, Kang, Li, Hering, Alessa, Vilaça, João L., Flores, Mona, Xu, Daguang, Wood, Bradford, and Linguraru, Marius George

Abstract

Artificial intelligence (AI) methods for the automatic detection and quantification of COVID-19 lesions in chest computed tomography (CT) might play an important role in the monitoring and management of the disease. We organized an international challenge and competition for the development and comparison of AI algorithms for this task, which we supported with public data and state-of-the-art benchmark methods. Board Certified Radiologists annotated 295 public images from two sources (A and B) for algorithms training (n=199, source A), validation (n=50, source A) and testing (n=23, source A; n=23, source B). There were 1,096 registered teams of which 225 and 98 completed the validation and testing phases, respectively. The challenge showed that AI models could be rapidly designed by diverse teams with the potential to measure disease or facilitate timely and patient-specific interventions. This paper provides an overview and the major outcomes of the COVID-19 Lung CT Lesion Segmentation Challenge - 2020.

Published

2022

33. Real-Time Online Adaption for Robust Instrument Tracking and Pose Estimation

Author

Rieke, Nicola, primary, Tan, David Joseph, additional, Tombari, Federico, additional, Vizcaíno, Josué Page, additional, di San Filippo, Chiara Amat, additional, Eslami, Abouzar, additional, and Navab, Nassir, additional

Published

2016

34. Rapid Artificial Intelligence Solutions in a Pandemic - The COVID-19-20 Lung CT Lesion Segmentation Challenge

Author

Roth, Holger, primary, Xu, Ziyue, additional, Diez, Carlos Tor, additional, Jacob, Ramon Sanchez, additional, Zember, Jonathan, additional, Molto, Jose, additional, Li, Wenqi, additional, Xu, Sheng, additional, Turkbey, Baris, additional, Turkbey, Evrim, additional, Yang, Dong, additional, Harouni, Ahmed, additional, Rieke, Nicola, additional, Hu, Shishuai, additional, Isensee, Fabian, additional, Tang, Claire, additional, Yu, Qinji, additional, Sölter, Jan, additional, Zheng, Tong, additional, Liauchuk, Vitali, additional, Zhou, Ziqi, additional, Moltz, Jan, additional, Oliveira, Bruno, additional, Xia, Yong, additional, Maier-Hein, Klaus, additional, Li, Qikai, additional, Husch, Andreas, additional, Zhang, Luyang, additional, Kovalev, Vassili, additional, Kang, Li, additional, Hering, Alessa, additional, Vilaça, João, additional, Flores, Mona, additional, Xu, Daguang, additional, Wood, Bradford, additional, and Linguraru, Marius, additional

Published

2021

35. Common Limitations of Image Processing Metrics:A Picture Story

Author

Reinke, Annika, Tizabi, Minu D., Sudre, Carole H., Eisenmann, Matthias, Rädsch, Tim, Baumgartner, Michael, Acion, Laura, Antonelli, Michela, Bakas, Spyridon, Bankhead, Peter, Benis, Arriel, Cardoso, M. Jorge, Cheplygina, Veronika, Christodoulou, Evangelia, Cimini, Beth, Collins, Gary S., Farahani, Keyvan, Ginneken, Bram van, Glocker, Ben, Godau, Patrick, Hamprecht, Fred, Hashimoto, Daniel A., Heckmann-Nötzel, Doreen, Hoffman, Michael M., Huisman, Merel, Isensee, Fabian, Jannin, Pierre, Kahn, Charles E., Karargyris, Alexandros, Karthikesalingam, Alan, Kainz, Bernhard, Kavur, Emre, Kenngott, Hannes, Kleesiek, Jens, Kooi, Thijs, Kozubek, Michal, Kreshuk, Anna, Kurc, Tahsin, Landman, Bennett A., Litjens, Geert, Madani, Amin, Maier-Hein, Klaus, Martel, Anne L., Mattson, Peter, Meijering, Erik, Menze, Bjoern, Moher, David, Moons, Karel G. M., Müller, Henning, Nichyporuk, Brennan, Nickel, Felix, Noyan, M. Alican, Petersen, Jens, Polat, Gorkem, Rajpoot, Nasir, Reyes, Mauricio, Rieke, Nicola, Riegler, Michael, Rivaz, Hassan, Saez-Rodriguez, Julio, Gutierrez, Clarisa Sanchez, Schroeter, Julien, Saha, Anindo, Shetty, Shravya, Smeden, Maarten van, Stieltjes, Bram, Summers, Ronald M., Taha, Abdel A., Tsaftaris, Sotirios A., Calster, Ben Van, Varoquaux, Gaël, Wiesenfarth, Manuel, Yaniv, Ziv R., Kopp-Schneider, Annette, Jäger, Paul, and Maier-Hein, Lena

Abstract

While the importance of automatic image analysis is continuously increasing, recent meta-research revealed major flaws with respect to algorithm validation. Performance metrics are particularly key for meaningful, objective, and transparent performance assessment and validation of the used automatic algorithms, but relatively little attention has been given to the practical pitfalls when using specific metrics for a given image analysis task. These are typically related to (1) the disregard of inherent metric properties, such as the behaviour in the presence of class imbalance or small target structures, (2) the disregard of inherent data set properties, such as the non-independence of the test cases, and (3) the disregard of the actual biomedical domain interest that the metrics should reflect. This living dynamically document has the purpose to illustrate important limitations of performance metrics commonly applied in the field of image analysis. In this context, it focuses on biomedical image analysis problems that can be phrased as image-level classification, semantic segmentation, instance segmentation, or object detection task. The current version is based on a Delphi process on metrics conducted by an international consortium of image analysis experts from more than 60 institutions worldwide.

Published

2021

36. Rapid Artificial Intelligence Solutions in a Pandemic - The COVID-19-20 Lung CT Lesion Segmentation Challenge.

Author

Roth, Holger, Xu, Ziyue, Diez, Carlos Tor, Jacob, Ramon Sanchez, Zember, Jonathan, Molto, Jose, Li, Wenqi, Xu, Sheng, Turkbey, Baris, Turkbey, Evrim, Yang, Dong, Harouni, Ahmed, Rieke, Nicola, Hu, Shishuai, Isensee, Fabian, Tang, Claire, Yu, Qinji, Sölter, Jan, Zheng, Tong, Liauchuk, Vitali, Zhou, Ziqi, Moltz, Jan, Oliveira, Bruno, Xia, Yong, Maier-Hein, Klaus, Li, Qikai, Husch, Andreas, Zhang, Luyang, Kovalev, Vassili, Kang, Li, Hering, Alessa, Vilaça, João, Flores, Mona, Xu, Daguang, Wood, Bradford, Linguraru, Marius, Roth, Holger, Xu, Ziyue, Diez, Carlos Tor, Jacob, Ramon Sanchez, Zember, Jonathan, Molto, Jose, Li, Wenqi, Xu, Sheng, Turkbey, Baris, Turkbey, Evrim, Yang, Dong, Harouni, Ahmed, Rieke, Nicola, Hu, Shishuai, Isensee, Fabian, Tang, Claire, Yu, Qinji, Sölter, Jan, Zheng, Tong, Liauchuk, Vitali, Zhou, Ziqi, Moltz, Jan, Oliveira, Bruno, Xia, Yong, Maier-Hein, Klaus, Li, Qikai, Husch, Andreas, Zhang, Luyang, Kovalev, Vassili, Kang, Li, Hering, Alessa, Vilaça, João, Flores, Mona, Xu, Daguang, Wood, Bradford, and Linguraru, Marius

Abstract

Artificial intelligence (AI) methods for the automatic detection and quantification of COVID-19 lesions in chest computed tomography (CT) might play an important role in the monitoring and management of the disease. We organized an international challenge and competition for the development and comparison of AI algorithms for this task, which we supported with public data and state-of-the-art benchmark methods. Board Certified Radiologists annotated 295 public images from two sources (A and B) for algorithms training (n=199, source A), validation (n=50, source A) and testing (n=23, source A; n=23, source B). There were 1,096 registered teams of which 225 and 98 completed the validation and testing phases, respectively. The challenge showed that AI models could be rapidly designed by diverse teams with the potential to measure disease or facilitate timely and patient-specific interventions. This paper provides an overview and the major outcomes of the COVID-19 Lung CT Lesion Segmentation Challenge - 2020.

Published

2021

37. Sickle Cell Disease Severity Prediction from Percoll Gradient Images Using Graph Convolutional Networks

Author

Albarqouni, Shadi, Cardoso, M. Jorge, Dou, Qi, Kamnitsas, Konstantinos, Khanal, Bishesh, Rekik, Islem, Rieke, Nicola, Sheet, Debdoot, Tsaftaris, Sotirios, Xu, Daguang, Xu, Ziyue, Albarqouni, S ( Shadi ), Cardoso, M J ( M. Jorge ), Dou, Q ( Qi ), Kamnitsas, K ( Konstantinos ), Khanal, B ( Bishesh ), Rekik, I ( Islem ), Rieke, N ( Nicola ), Sheet, D ( Debdoot ), Tsaftaris, S ( Sotirios ), Xu, D ( Daguang ), Xu, Z ( Ziyue ), Sadafi, Ario, Makhro, Asya, Livshits, Leonid, Navab, Nassir, Bogdanova, Anna; https://orcid.org/0000-0003-0502-5381, Marr, Carsten, Albarqouni, Shadi, Cardoso, M. Jorge, Dou, Qi, Kamnitsas, Konstantinos, Khanal, Bishesh, Rekik, Islem, Rieke, Nicola, Sheet, Debdoot, Tsaftaris, Sotirios, Xu, Daguang, Xu, Ziyue, Albarqouni, S ( Shadi ), Cardoso, M J ( M. Jorge ), Dou, Q ( Qi ), Kamnitsas, K ( Konstantinos ), Khanal, B ( Bishesh ), Rekik, I ( Islem ), Rieke, N ( Nicola ), Sheet, D ( Debdoot ), Tsaftaris, S ( Sotirios ), Xu, D ( Daguang ), Xu, Z ( Ziyue ), Sadafi, Ario, Makhro, Asya, Livshits, Leonid, Navab, Nassir, Bogdanova, Anna; https://orcid.org/0000-0003-0502-5381, and Marr, Carsten

Abstract

Sickle cell disease (SCD) is a severe genetic hemoglobin disorder that results in premature destruction of red blood cells. Assessment of the severity of the disease is a challenging task in clinical routine, since the causes of broad variance in SCD manifestation despite the common genetic cause remain unclear. Identification of biomarkers that would predict the severity grade is of importance for prognosis and assessment of responsiveness of patients to therapy. Detection of the changes in red blood cell (RBC) density by means of separation of Percoll density gradients could be such a marker as it allows to resolve intercellular differences and follow the most damaged dense cells prone to destruction and vasoocclusion. Quantification and interpretation of the images obtained from the distribution of RBCs in Percoll gradients is an important prerequisite for establishment of this approach. Here, we propose a novel approach combining a graph convolutional network, a convolutional neural network, fast Fourier transform, and recursive feature elimination to predict the severity of SCD directly from a Percoll image. Two important but expensive laboratory blood test parameters are used for training the graph convolutional network. To make the model independent from such tests during prediction, these two parameters are estimated by a neural network from the Percoll image directly. On a cohort of 216 subjects, we achieve a prediction performance that is only slightly below an approach where the groundtruth laboratory measurements are used. Our proposed method is the first computational approach for the difficult task of SCD severity prediction. The two-step approach relies solely on inexpensive and simple blood analysis tools and can have a significant impact on the patients’ survival in low resource regions where access to medical instruments and doctors is limited.

Published

2021

38. Guest Editorial Special Issue on Federated Learning for Medical Imaging: Enabling Collaborative Development of Robust AI Models

Author

Roth, Holger R., Rieke, Nicola, Albarqouni, Shadi, and Li, Quanzheng

Abstract

Federated Learning (FL) could solve the challenges of training AI models on large datasets for medical imaging due to data privacy and ownership concerns by allowing collaborative training without the need for sharing raw data. This Special Issue on Federated Learning for Medical Imaging features papers covering FL-related topics and discussing their implications for healthcare and medical imaging. The included articles focus on a broad range of federated scenarios and applications, such as semi-supervised and self-supervised learning, histopathology, image reconstruction, graph neural networks, privacy preservation, active learning, data auditing, multi-task learning, personalization, and swarm learning. The importance of training unbiased, privacy-preserving, and generalizable AI models that have the potential to be translated into clinical practice increases the need for collaborative training techniques such as FL. The articles included in this Special Issue have moved the needle markedly forward in this regard.

Published

2023

39. Federated Learning used for predicting outcomes in SARS-COV-2 patients

Author

Flores, Mona, primary, Dayan, Ittai, additional, Roth, Holger, additional, Zhong, Aoxiao, additional, Harouni, Ahmed, additional, Gentili, Amilcare, additional, Abidin, Anas, additional, Liu, Andrew, additional, Costa, Anthony, additional, Wood, Bradford, additional, Tsai, Chien-Sung, additional, Wang, Chih-Hung, additional, Hsu, Chun-Nan, additional, Lee, CK, additional, Ruan, Colleen, additional, Xu, Daguang, additional, Wu, Dufan, additional, Huang, Eddie, additional, Kitamura, Felipe, additional, Lacey, Griffin, additional, Corradi, Gustavo César de Antônio, additional, Shin, Hao-Hsin, additional, Obinata, Hirofumi, additional, Ren, Hui, additional, Crane, Jason, additional, Tetreault, Jesse, additional, Guan, Jiahui, additional, Garrett, John, additional, Park, Jung Gil, additional, Dreyer, Keith, additional, Juluru, Krishna, additional, Kersten, Kristopher, additional, Rockenbach, Marcio Aloisio Bezerra Cavalcanti, additional, Linguraru, Marius, additional, Haider, Masoom, additional, AbdelMaseeh, Meena, additional, Rieke, Nicola, additional, Damasceno, Pablo, additional, Silva, Pedro Mario Cruz e, additional, Wang, Pochuan, additional, Xu, Sheng, additional, Kawano, Shuichi, additional, Sriswa, Sira, additional, Park, Soo Young, additional, Grist, Thomas, additional, Buch, Varun, additional, Jantarabenjakul, Watsamon, additional, Wang, Weichung, additional, Tak, Won Young, additional, Li, Xiang, additional, Lin, Xihong, additional, Kwon, Fred, additional, Gilbert, Fiona, additional, Kaggie, Josh, additional, Li, Quanzheng, additional, Quraini, Abood, additional, Feng, Andrew, additional, Priest, Andrew, additional, Turkbey, Baris, additional, Glicksberg, Benjamin, additional, Bizzo, Bernardo, additional, Kim, Byung Seok, additional, Tor-Diez, Carlos, additional, Lee, Chia-Cheng, additional, Hsu, Chia-Jung, additional, Lin, Chin, additional, Lai, Chiu-Ling, additional, Hess, Christopher, additional, Compas, Colin, additional, Bhatia, Deepi, additional, Oermann, Eric, additional, Leibovitz, Evan, additional, Sasaki, Hisashi, additional, Mori, Hitoshi, additional, Yang, Isaac, additional, Sohn, Jae Ho, additional, Murthy, Krishna Nand Keshava, additional, Fu, Li-Chen, additional, de Mendonça, Matheus Ribeiro Furtado, additional, Fralick, Mike, additional, Kang, Min Kyu, additional, Adil, Mohammad, additional, Gangai, Natalie, additional, Vateekul, Peerapon, additional, Elnajjar, Pierre, additional, Hickman, Sarah, additional, Majumdar, Sharmila, additional, McLeod, Shelley, additional, Reed, Sheridan, additional, Graf, Stefan, additional, Harmon, Stephanie, additional, Kodama, Tatsuya, additional, Puthanakit, Thanyawee, additional, Mazzulli, Tony, additional, Lavor, Vitor de Lima, additional, Rakvongthai, Yothin, additional, Lee, Yu Rim, additional, and Wen, Yuhong, additional

Published

2021

40. The future of digital health with federated learning

Author

Rieke, Nicola, primary, Hancox, Jonny, additional, Li, Wenqi, additional, Milletarì, Fausto, additional, Roth, Holger R., additional, Albarqouni, Shadi, additional, Bakas, Spyridon, additional, Galtier, Mathieu N., additional, Landman, Bennett A., additional, Maier-Hein, Klaus, additional, Ourselin, Sébastien, additional, Sheller, Micah, additional, Summers, Ronald M., additional, Trask, Andrew, additional, Xu, Daguang, additional, Baust, Maximilian, additional, and Cardoso, M. Jorge, additional

Published

2020

41. The future of digital health with federated learning

Author

Rieke, Nicola, Hancox, Jonny, Li, Wenqi, Milletarì, Fausto, Roth, Holger R., Albarqouni, Shadi, Bakas, Spyridon, Galtier, Mathieu N., Landman, Bennett A., Maier-Hein, Klaus, Ourselin, Sébastien, Sheller, Micah, Summers, Ronald M., Trask, Andrew, Xu, Daguang, Baust, Maximilian, and Cardoso, M. Jorge

Subjects

ddc

Published

2019

42. Computer-Vision-gestützte Chirurgie: Tracking von Instrumenten in Echtzeit mit Maschinellen Lernverfahren

Author

Rieke, Nicola Christin, Navab, Nassir (Prof. Dr.), and Sznitman, Raphael (Prof. Dr.)

Subjects

Medizin und Gesundheit, ddc:610

Abstract

Visual tracking of surgical instruments is a key component of various computer-assisted interventions, yet a very challenging problem in the field of Computer Vision. This dissertation presents novel approaches which leverage machine learning techniques for precise real-time tracking and 2D pose estimation of instruments. The achieved results demonstrate that the proposed methods based on Random Forests and Deep Learning provide remarkable advantages with respect to the state of the art in terms of accuracy, robustness and generalization. Das visuelle Tracking von chirurgischen Instrumenten stellt einen Kernbestandteil für eine Vielzahl computergestützter Eingriffe dar – gleichzeitig jedoch auch ein sehr anspruchsvolles Problem der Computer Vision. Diese Dissertation präsentiert neuartige Ansätze, um Techniken des maschinellen Lernens für Echtzeit-Tracking und 2D-Posenbestimmung von Instrumenten einzusetzen. Die erzielten Ergebnisse verdeutlichen, dass die auf Random-Forests oder Deep-Learning basierenden entwickelten Methoden in Bezug auf Präzision, Robustheit und Generalisierung bemerkenswerte Vorteile gegenüber dem bisherigen Stand der Forschung aufweisen.

Published

2019

43. Computer Vision-Assisted Surgery: Real-Time Instrument Tracking with Machine Learning

Author

Sznitman, Raphael (Prof. Dr.), Navab, Nassir (Prof. Dr.), Rieke, Nicola Christin, Sznitman, Raphael (Prof. Dr.), Navab, Nassir (Prof. Dr.), and Rieke, Nicola Christin

Abstract

Visual tracking of surgical instruments is a key component of various computer-assisted interventions, yet a very challenging problem in the field of Computer Vision. This dissertation presents novel approaches which leverage machine learning techniques for precise real-time tracking and 2D pose estimation of instruments. The achieved results demonstrate that the proposed methods based on Random Forests and Deep Learning provide remarkable advantages with respect to the state of the art in terms of accuracy, robustness and generalization., Das visuelle Tracking von chirurgischen Instrumenten stellt einen Kernbestandteil für eine Vielzahl computergestützter Eingriffe dar – gleichzeitig jedoch auch ein sehr anspruchsvolles Problem der Computer Vision. Diese Dissertation präsentiert neuartige Ansätze, um Techniken des maschinellen Lernens für Echtzeit-Tracking und 2D-Posenbestimmung von Instrumenten einzusetzen. Die erzielten Ergebnisse verdeutlichen, dass die auf Random-Forests oder Deep-Learning basierenden entwickelten Methoden in Bezug auf Präzision, Robustheit und Generalisierung bemerkenswerte Vorteile gegenüber dem bisherigen Stand der Forschung aufweisen.

Published

2019

44. Computer Vision-Assisted Surgery: Real-Time Instrument Tracking with Machine Learning

Author

Navab, Nassir (Prof. Dr.), Navab, Nassir (Prof. Dr.);Sznitman, Raphael (Prof. Dr.), Rieke, Nicola Christin, Navab, Nassir (Prof. Dr.), Navab, Nassir (Prof. Dr.);Sznitman, Raphael (Prof. Dr.), and Rieke, Nicola Christin

Abstract

Visual tracking of surgical instruments is a key component of various computer-assisted interventions, yet a very challenging problem in the field of Computer Vision. This dissertation presents novel approaches which leverage machine learning techniques for precise real-time tracking and 2D pose estimation of instruments. The achieved results demonstrate that the proposed methods based on Random Forests and Deep Learning provide remarkable advantages with respect to the state of the art in terms of accuracy, robustness and generalization., Das visuelle Tracking von chirurgischen Instrumenten stellt einen Kernbestandteil für eine Vielzahl computergestützter Eingriffe dar – gleichzeitig jedoch auch ein sehr anspruchsvolles Problem der Computer Vision. Diese Dissertation präsentiert neuartige Ansätze, um Techniken des maschinellen Lernens für Echtzeit-Tracking und 2D-Posenbestimmung von Instrumenten einzusetzen. Die erzielten Ergebnisse verdeutlichen, dass die auf Random-Forests oder Deep-Learning basierenden entwickelten Methoden in Bezug auf Präzision, Robustheit und Generalisierung bemerkenswerte Vorteile gegenüber dem bisherigen Stand der Forschung aufweisen.

Published

2019

45. Multi-domain adaptation in brain MRI through paired consistency and adversarial learning

Author

Wang, Qian, Milletari, Fausto, Rieke, Nicola, Nguyen, Hien V., Roysam, Badri, Albarqouni, Shadi, Cardoso, M. Jorge, Xu, Ziyue, Kamnitsas, Konstantinos, Patel, Vishal, Jiang, Steve, Zhou, Kevin, Luu, Khoa, Le, Ngan, Orbes-Arteaga, Mauricio, Varsavsky, Thomas, Sudre, Carole H., Eaton-Rosen, Zach, Haddow, Lewis J., Sørensen, Lauge, Nielsen, Mads, Pai, Akshay, Ourselin, Sébastien, Modat, Marc, Nachev, Parashkev, Wang, Qian, Milletari, Fausto, Rieke, Nicola, Nguyen, Hien V., Roysam, Badri, Albarqouni, Shadi, Cardoso, M. Jorge, Xu, Ziyue, Kamnitsas, Konstantinos, Patel, Vishal, Jiang, Steve, Zhou, Kevin, Luu, Khoa, Le, Ngan, Orbes-Arteaga, Mauricio, Varsavsky, Thomas, Sudre, Carole H., Eaton-Rosen, Zach, Haddow, Lewis J., Sørensen, Lauge, Nielsen, Mads, Pai, Akshay, Ourselin, Sébastien, Modat, Marc, and Nachev, Parashkev

Abstract

Supervised learning algorithms trained on medical images will often fail to generalize across changes in acquisition parameters. Recent work in domain adaptation addresses this challenge and successfully leverages labeled data in a source domain to perform well on an unlabeled target domain. Inspired by recent work in semi-supervised learning we introduce a novel method to adapt from one source domain to n target domains (as long as there is paired data covering all domains). Our multi-domain adaptation method utilises a consistency loss combined with adversarial learning. We provide results on white matter lesion hyperintensity segmentation from brain MRIs using the MICCAI 2017 challenge data as the source domain and two target domains. The proposed method significantly outperforms other domain adaptation baselines.

Published

2019

46. Chapter 4 - Computer Vision and Machine Learning for Surgical Instrument Tracking: Focus: Random Forest-Based Microsurgical Tool Tracking

Author

Rieke, Nicola, Tombari, Federico, and Navab, Nassir

Published

2018

47. Fast 5DOF needle tracking in iOCT

Author

Weiss, Jakob, primary, Rieke, Nicola, additional, Nasseri, Mohammad Ali, additional, Maier, Mathias, additional, Eslami, Abouzar, additional, and Navab, Nassir, additional

Published

2018

48. Ultrasound interactive segmentation with tensor-graph methods

Author

Rieke, Nicola, primary, Hennersperger, Christoph, additional, Mateus, Diana, additional, and Navab, Nassir, additional

Published

2014

49. Realistic Data Enrichment for Robust Image Segmentation in Histopathology

Author

Cechnicka, Sarah, Ball, James, Reynaud, Hadrien, Arthurs, Callum, Roufosse, Candice, Kainz, Bernhard, Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Koch, Lisa, editor, Cardoso, M. Jorge, editor, Ferrante, Enzo, editor, Kamnitsas, Konstantinos, editor, Islam, Mobarakol, editor, Jiang, Meirui, editor, Rieke, Nicola, editor, Tsaftaris, Sotirios A., editor, and Yang, Dong, editor

Published

2024

50. Domain Adaptation of MRI Scanners as an Alternative to MRI Harmonization

Author

Kushol, Rafsanjany, Frayne, Richard, Graham, Simon J., Wilman, Alan H., Kalra, Sanjay, Yang, Yee-Hong, Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Koch, Lisa, editor, Cardoso, M. Jorge, editor, Ferrante, Enzo, editor, Kamnitsas, Konstantinos, editor, Islam, Mobarakol, editor, Jiang, Meirui, editor, Rieke, Nicola, editor, Tsaftaris, Sotirios A., editor, and Yang, Dong, editor

Published

2024