Investigating the challenges and generalizability of deep learning brain conductivity mapping

Publication date

2020-07-07

Authors

Hampe, Nils
Katscher, Ulrich
van den Berg, CATORCID 0000-0002-5565-6889
Tha, Khin Khin
Mandija, StefanoORCID 0000-0002-4612-5509

Editors

Advisors

Supervisors

Document Type

Article

Collections

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License

taverne

Abstract

To investigate deep learning electrical properties tomography (EPT) for application on different simulated and in-vivo datasets, including pathologies for brain conductivity reconstructions, 3D patch-based convolutional neural networks were trained to predict conductivity maps from B 1 transceive phase data. To compare the performance of DL-EPT networks on different datasets, three datasets were used throughout this work, one from simulations and two from in-vivo measurements from healthy volunteers and patients with brain lesions, respectively. At first, networks trained on simulations were tested on all datasets with different levels of homogeneous Gaussian noise introduced in training and testing. Secondly, to investigate potential robustness towards systematical differences between simulated and measured phase maps, in-vivo data with conductivity labels from conventional EPT were used for training. High quality conductivity reconstructions from networks trained on simulations with and without noise confirm the potential of deep learning for EPT. However, when this network is used for in-vivo reconstructions, measurement related artifacts affect the quality of conductivity maps. Training DL-EPT networks using conductivity labels from conventional EPT improves the quality of the results. Networks trained on realistic simulations yield reconstruction artifacts when applied to in-vivo data. Training with realistic phase data and conductivity labels from conventional EPT allows for reducing these artifacts.

Keywords

EPT, MRI, brain tissue conductivity, deep learning, electrical properties tomography, electromagnetic field simulations, Taverne, Radiological and Ultrasound Technology, Radiology Nuclear Medicine and imaging, Journal Article

Citation

Hampe, N, Katscher, U, van den Berg, C A T, Tha, K K & Mandija, S 2020, 'Investigating the challenges and generalizability of deep learning brain conductivity mapping', Physics in medicine and biology, vol. 65, no. 13, 135001. https://doi.org/10.1088/1361-6560/ab9356