Deep learning-based reconstruction of in vivo pelvis conductivity with a 3D patch-based convolutional neural network trained on simulated MR data

Soraya Gavazzi; Cornelis A.T. van den Berg; Mark H.F. Savenije; H. Petra Kok; Peter de Boer; Lukas J.A. Stalpers; Jan J.W. Lagendijk; Hans Crezee; Astrid L.H.M.W. van Lier

doi:10.1002/mrm.28285

Deep learning-based reconstruction of in vivo pelvis conductivity with a 3D patch-based convolutional neural network trained on simulated MR data

Soraya Gavazzi^*, Cornelis A.T. van den Berg, Mark H.F. Savenije, H. Petra Kok, Peter de Boer, Lukas J.A. Stalpers, Jan J.W. Lagendijk, Hans Crezee, Astrid L.H.M.W. van Lier

^*Corresponding author for this work

Research output: Contribution to journal › Article › Academic › peer-review

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Abstract

PURPOSE: To demonstrate that mapping pelvis conductivity at 3T with deep learning (DL) is feasible.

METHODS: 210 dielectric pelvic models were generated based on CT scans of 42 cervical cancer patients. For all dielectric models, electromagnetic and MR simulations with realistic accuracy and precision were performed to obtain B 1 + and transceive phase (ϕ ± ). Simulated B 1 + and ϕ ± served as input to a 3D patch-based convolutional neural network, which was trained in a supervised fashion to retrieve the conductivity. The same network architecture was retrained using only ϕ ± in input. Both network configurations were tested on simulated MR data and their conductivity reconstruction accuracy and precision were assessed. Furthermore, both network configurations were used to reconstruct conductivity maps from a healthy volunteer and two cervical cancer patients. DL-based conductivity was compared in vivo and in silico to Helmholtz-based (H-EPT) conductivity.

RESULTS: Conductivity maps obtained from both network configurations were comparable. Accuracy was assessed by mean error (ME) with respect to ground truth conductivity. On average, ME < 0.1 Sm -1 for all tissues. Maximum MEs were 0.2 Sm -1 for muscle and tumour, and 0.4 Sm -1 for bladder. Precision was indicated with the difference between 90 th and 10 th conductivity percentiles, and was below 0.1 Sm -1 for fat, bone and muscle, 0.2 Sm -1 for tumour and 0.3 Sm -1 for bladder. In vivo, DL-based conductivity had median values in agreement with H-EPT values, but a higher precision.

CONCLUSION: Anatomically detailed, noise-robust 3D conductivity maps with good sensitivity to tissue conductivity variations were reconstructed in the pelvis with DL.

Original language	English
Pages (from-to)	2772-2787
Number of pages	16
Journal	Magnetic Resonance in Medicine
Volume	84
Issue number	5
DOIs	https://doi.org/10.1002/mrm.28285
Publication status	Published - 1 Nov 2020

Keywords

conductivity mapping
deep learning EPT
MR simulations
pelvis MRI

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Gavazzi, S., van den Berg, C. A. T., Savenije, M. H. F., Kok, H. P., de Boer, P., Stalpers, L. J. A., Lagendijk, J. J. W., Crezee, H., & van Lier, A. L. H. M. W. (2020). Deep learning-based reconstruction of in vivo pelvis conductivity with a 3D patch-based convolutional neural network trained on simulated MR data. Magnetic Resonance in Medicine, 84(5), 2772-2787. https://doi.org/10.1002/mrm.28285

@article{d7c9e5dd6689427f8d92a57750decb0e,

title = "Deep learning-based reconstruction of in vivo pelvis conductivity with a 3D patch-based convolutional neural network trained on simulated MR data",

abstract = "PURPOSE: To demonstrate that mapping pelvis conductivity at 3T with deep learning (DL) is feasible.METHODS: 210 dielectric pelvic models were generated based on CT scans of 42 cervical cancer patients. For all dielectric models, electromagnetic and MR simulations with realistic accuracy and precision were performed to obtain B 1 + and transceive phase (ϕ ± ). Simulated B 1 + and ϕ ± served as input to a 3D patch-based convolutional neural network, which was trained in a supervised fashion to retrieve the conductivity. The same network architecture was retrained using only ϕ ± in input. Both network configurations were tested on simulated MR data and their conductivity reconstruction accuracy and precision were assessed. Furthermore, both network configurations were used to reconstruct conductivity maps from a healthy volunteer and two cervical cancer patients. DL-based conductivity was compared in vivo and in silico to Helmholtz-based (H-EPT) conductivity. RESULTS: Conductivity maps obtained from both network configurations were comparable. Accuracy was assessed by mean error (ME) with respect to ground truth conductivity. On average, ME < 0.1 Sm -1 for all tissues. Maximum MEs were 0.2 Sm -1 for muscle and tumour, and 0.4 Sm -1 for bladder. Precision was indicated with the difference between 90 th and 10 th conductivity percentiles, and was below 0.1 Sm -1 for fat, bone and muscle, 0.2 Sm -1 for tumour and 0.3 Sm -1 for bladder. In vivo, DL-based conductivity had median values in agreement with H-EPT values, but a higher precision. CONCLUSION: Anatomically detailed, noise-robust 3D conductivity maps with good sensitivity to tissue conductivity variations were reconstructed in the pelvis with DL.",

keywords = "conductivity mapping, deep learning EPT, MR simulations, pelvis MRI",

author = "Soraya Gavazzi and {van den Berg}, {Cornelis A.T.} and Savenije, {Mark H.F.} and Kok, {H. Petra} and {de Boer}, Peter and Stalpers, {Lukas J.A.} and Lagendijk, {Jan J.W.} and Hans Crezee and {van Lier}, {Astrid L.H.M.W.}",

note = "{\textcopyright} 2020 The Authors. Magnetic Resonance in Medicine published by Wiley Periodicals LLC on behalf of International Society for Magnetic Resonance in Medicine.",

year = "2020",

month = nov,

day = "1",

doi = "10.1002/mrm.28285",

language = "English",

volume = "84",

pages = "2772--2787",

journal = "Magnetic Resonance in Medicine",

issn = "0740-3194",

publisher = "John Wiley & Sons Inc.",

number = "5",

}

Gavazzi, S, van den Berg, CAT, Savenije, MHF, Kok, HP, de Boer, P, Stalpers, LJA, Lagendijk, JJW, Crezee, H & van Lier, ALHMW 2020, 'Deep learning-based reconstruction of in vivo pelvis conductivity with a 3D patch-based convolutional neural network trained on simulated MR data', Magnetic Resonance in Medicine, vol. 84, no. 5, pp. 2772-2787. https://doi.org/10.1002/mrm.28285

Deep learning-based reconstruction of in vivo pelvis conductivity with a 3D patch-based convolutional neural network trained on simulated MR data. / Gavazzi, Soraya; van den Berg, Cornelis A.T.; Savenije, Mark H.F. et al.
In: Magnetic Resonance in Medicine, Vol. 84, No. 5, 01.11.2020, p. 2772-2787.

Research output: Contribution to journal › Article › Academic › peer-review

TY - JOUR

T1 - Deep learning-based reconstruction of in vivo pelvis conductivity with a 3D patch-based convolutional neural network trained on simulated MR data

AU - Gavazzi, Soraya

AU - van den Berg, Cornelis A.T.

AU - Savenije, Mark H.F.

AU - Kok, H. Petra

AU - de Boer, Peter

AU - Stalpers, Lukas J.A.

AU - Lagendijk, Jan J.W.

AU - Crezee, Hans

AU - van Lier, Astrid L.H.M.W.

PY - 2020/11/1

Y1 - 2020/11/1

N2 - PURPOSE: To demonstrate that mapping pelvis conductivity at 3T with deep learning (DL) is feasible.METHODS: 210 dielectric pelvic models were generated based on CT scans of 42 cervical cancer patients. For all dielectric models, electromagnetic and MR simulations with realistic accuracy and precision were performed to obtain B 1 + and transceive phase (ϕ ± ). Simulated B 1 + and ϕ ± served as input to a 3D patch-based convolutional neural network, which was trained in a supervised fashion to retrieve the conductivity. The same network architecture was retrained using only ϕ ± in input. Both network configurations were tested on simulated MR data and their conductivity reconstruction accuracy and precision were assessed. Furthermore, both network configurations were used to reconstruct conductivity maps from a healthy volunteer and two cervical cancer patients. DL-based conductivity was compared in vivo and in silico to Helmholtz-based (H-EPT) conductivity. RESULTS: Conductivity maps obtained from both network configurations were comparable. Accuracy was assessed by mean error (ME) with respect to ground truth conductivity. On average, ME < 0.1 Sm -1 for all tissues. Maximum MEs were 0.2 Sm -1 for muscle and tumour, and 0.4 Sm -1 for bladder. Precision was indicated with the difference between 90 th and 10 th conductivity percentiles, and was below 0.1 Sm -1 for fat, bone and muscle, 0.2 Sm -1 for tumour and 0.3 Sm -1 for bladder. In vivo, DL-based conductivity had median values in agreement with H-EPT values, but a higher precision. CONCLUSION: Anatomically detailed, noise-robust 3D conductivity maps with good sensitivity to tissue conductivity variations were reconstructed in the pelvis with DL.

AB - PURPOSE: To demonstrate that mapping pelvis conductivity at 3T with deep learning (DL) is feasible.METHODS: 210 dielectric pelvic models were generated based on CT scans of 42 cervical cancer patients. For all dielectric models, electromagnetic and MR simulations with realistic accuracy and precision were performed to obtain B 1 + and transceive phase (ϕ ± ). Simulated B 1 + and ϕ ± served as input to a 3D patch-based convolutional neural network, which was trained in a supervised fashion to retrieve the conductivity. The same network architecture was retrained using only ϕ ± in input. Both network configurations were tested on simulated MR data and their conductivity reconstruction accuracy and precision were assessed. Furthermore, both network configurations were used to reconstruct conductivity maps from a healthy volunteer and two cervical cancer patients. DL-based conductivity was compared in vivo and in silico to Helmholtz-based (H-EPT) conductivity. RESULTS: Conductivity maps obtained from both network configurations were comparable. Accuracy was assessed by mean error (ME) with respect to ground truth conductivity. On average, ME < 0.1 Sm -1 for all tissues. Maximum MEs were 0.2 Sm -1 for muscle and tumour, and 0.4 Sm -1 for bladder. Precision was indicated with the difference between 90 th and 10 th conductivity percentiles, and was below 0.1 Sm -1 for fat, bone and muscle, 0.2 Sm -1 for tumour and 0.3 Sm -1 for bladder. In vivo, DL-based conductivity had median values in agreement with H-EPT values, but a higher precision. CONCLUSION: Anatomically detailed, noise-robust 3D conductivity maps with good sensitivity to tissue conductivity variations were reconstructed in the pelvis with DL.

KW - conductivity mapping

KW - deep learning EPT

KW - MR simulations

KW - pelvis MRI

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U2 - 10.1002/mrm.28285

DO - 10.1002/mrm.28285

M3 - Article

C2 - 32314825

AN - SCOPUS:85083641075

SN - 0740-3194

VL - 84

SP - 2772

EP - 2787

JO - Magnetic Resonance in Medicine

JF - Magnetic Resonance in Medicine

IS - 5

ER -

Deep learning-based reconstruction of in vivo pelvis conductivity with a 3D patch-based convolutional neural network trained on simulated MR data

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