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Due to the susceptibility to external distortions, systematic error in EMT needs to be compensated algorithmically. Compensation algorithms for EMT in guidewire procedures are only practical in an online setting.<\/jats:p>\n<\/jats:sec>\nMethods<\/jats:bold>\n<\/jats:title>\nWe collect positional data and train a symmetric artificial neural network (ANN) architecture for compensating navigation error. The results are evaluated in both online and offline scenarios and are compared to polynomial fits. We assess spatial uncertainty of the compensation proposed by the ANN. Simulations based on real data show how this uncertainty measure can be utilized to improve accuracy and limit radiation exposure in hybrid navigation.<\/jats:p>\n<\/jats:sec>\nResults<\/jats:bold>\n<\/jats:title>\nANNs compensate unseen distortions by more than 70%, outperforming polynomial regression. Working on known distortions, ANNs outperform polynomials as well. We empirically demonstrate a linear relationship between tracking accuracy and model uncertainty. The effectiveness of hybrid tracking is shown in a simulation experiment.<\/jats:p>\n<\/jats:sec>\nConclusion<\/jats:bold>\n<\/jats:title>\nANNs are suitable for EMT error compensation and can generalize across unseen distortions. Model uncertainty needs to be assessed when spatial error compensation algorithms are developed, so that training data collection can be optimized. Finally, we find that error compensation in EMT reduces the need for X-ray images in hybrid navigation.<\/jats:p>\n<\/jats:sec>","DOI":"10.1007\/s11548-020-02189-w","type":"journal-article","created":{"date-parts":[[2020,5,22]],"date-time":"2020-05-22T00:02:36Z","timestamp":1590105756000},"page":"1043-1051","update-policy":"https:\/\/doi.org\/10.1007\/springer_crossmark_policy","source":"Crossref","is-referenced-by-count":6,"title":["Leveraging spatial uncertainty for online error compensation in EMT"],"prefix":"10.1007","volume":"15","author":[{"given":"Henry","family":"Krumb","sequence":"first","affiliation":[]},{"given":"Sofie","family":"Hofmann","sequence":"additional","affiliation":[]},{"given":"David","family":"K\u00fcgler","sequence":"additional","affiliation":[]},{"given":"Ahmed","family":"Ghazy","sequence":"additional","affiliation":[]},{"given":"Bernhard","family":"Dorweiler","sequence":"additional","affiliation":[]},{"given":"Judith","family":"Bredemann","sequence":"additional","affiliation":[]},{"given":"Robert","family":"Schmitt","sequence":"additional","affiliation":[]},{"given":"Georgios","family":"Sakas","sequence":"additional","affiliation":[]},{"given":"Anirban","family":"Mukhopadhyay","sequence":"additional","affiliation":[]}],"member":"297","published-online":{"date-parts":[[2020,5,22]]},"reference":[{"key":"2189_CR1","unstructured":"Abadi M, Agarwal A, Barham P, Brevdo E, Chen Z, Citro C, Corrado GS, Davis A, Dean J, Devin M, Ghemawat S, Goodfellow I, Harp A, Irving G, Isard M, Jia Y, Jozefowicz R, Kaiser L, Kudlur M, Levenberg J, Man\u00e9 D, Monga R, Moore S, Murray D, Olah C, Schuster M, Shlens J, Steiner B, Sutskever I, Talwar K, Tucker P, Vanhoucke V, Vasudevan V, Vi\u00e9gas F, Vinyals O, Warden P, Wattenberg M, Wicke M, Yu Y, Zheng X (2015) TensorFlow: large-scale machine learning on heterogeneous systems. https:\/\/www.tensorflow.org\/. 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