Acquiring and predicting multidimensional diﬀusion (MUDI) data: an open challenge

Marco Pizzolato; Marco  Palombo; Elisenda  Bonet-Carne; Chantal M.W.  Tax; Francesco  Grussu; Andrada  Ianus; Fabian Bogusz; Tomasz Pieciak; Lipeng Ning; Hugo Larochelle; Maxime  Descoteaux; Maxime  Chamberland; Stefano B.  Blumberg; Thomy  Mertzanidou; Daniel C.  Alexander; Maryam  Afzali; Santiago  Aja-Fernández; Derek K.  Jones; Carl-Fredrik  Westin; Yogesh  Rathi; Steven H.  Baete; Lucilio  Cordero-Grande; Thilo  Ladner; Paddy J.  Slator; Joseph V. Hajnal; Jean-Philippe  Thiran; Anthony N.  Price; Farshid  Sepehrband; Fan Zhang; Jana  Hutter

doi:10.1007/978-3-030-52893-5_17

Acquiring and predicting multidimensional diﬀusion (MUDI) data: an open challenge

Marco Pizzolato
, Marco Palombo
, Elisenda Bonet-Carne
, Chantal M.W. Tax
, Francesco Grussu
, Andrada Ianus
, Fabian Bogusz
, Tomasz Pieciak
, Lipeng Ning
, Hugo Larochelle
, Maxime Descoteaux
, Maxime Chamberland
, Stefano B. Blumberg
, Thomy Mertzanidou
, Daniel C. Alexander
, Maryam Afzali
, Santiago Aja-Fernández
, Derek K. Jones
, Carl-Fredrik Westin
, Yogesh Rathi

Steven H. Baete, Lucilio Cordero-Grande, Thilo Ladner, Paddy J. Slator, Joseph V. Hajnal, Jean-Philippe Thiran, Anthony N. Price, Farshid Sepehrband, Fan Zhang, Jana Hutter

University College London
Cardiff University
Champalimaud Centre for the Unknown
AGH University of Krakow
Massachusetts General Hospital/Harvard Medical School
Google Brain
Université de Sherbrooke
Imperial College London
University of Valladolid
New York University School of Medicine
King's College London
Swiss Federal Institute of Technology Zurich
University of Southern California at Los Angeles

Research output: Chapter in Book/Report/Conference proceeding › Book chapter › Research › peer-review

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Abstract

In magnetic resonance imaging (MRI), the image contrast is the result of the subtle interaction between the physicochemical properties of the imaged living tissue and the parameters used for image acquisition. By varying parameters such as the echo time (TE) and the inversion time (TI), it is possible to collect images that capture diﬀerent expressions of this sophisticated interaction. Sensitization to diﬀusion summarized by the b-value - constitutes yet another explorable “dimension” to modify the image contrast which reﬂects the degree of dispersion of water in various directions within the tissue microstructure. The full exploration of this multidimensional acquisition parameter space oﬀers the promise of a more comprehensive description of the living tissue but at the expense of lengthy MRI acquisitions, often unfeasible in clinical practice. The harnessing of multidimensional information passes through the use of intelligent sampling strategies for reducing the amount of images to acquire, and the design of methods for exploiting the redundancy in such information. This chapter reports the results of the MUDI challenge, comparing diﬀerent strategies for predicting the acquired densely sampled multidimensional data from sub-sampled versions of it.

Original language	English
Title of host publication	Computational Diffusion MRI
Editors	‪Elisenda Bonet-Carne
Publisher	Springer
Publication date	2020
Pages	195-208
ISBN (Print)	978-3-030-52892-8
DOIs	https://doi.org/10.1007/978-3-030-52893-5_17
Publication status	Published - 2020
Event	22nd International Conference on Medical Image Computing and Computer-Assisted Intervention - Shenzhen, China Duration: 13 Oct 2019 → 17 Oct 2019 Conference number: 22

Conference

Conference	22nd International Conference on Medical Image Computing and Computer-Assisted Intervention
Number	22
Country/Territory	China
City	Shenzhen
Period	13/10/2019 → 17/10/2019

Series	Mathematics and Visualization
ISSN	1612-3786

Keywords

MUDI
Diﬀusion
Relaxation
Quantitative Imaging

Access to Document

10.1007/978-3-030-52893-5_17

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Pizzolato, M., Palombo, M., Bonet-Carne, E., Tax, C. M. W., Grussu, F., Ianus, A., Bogusz, F., Pieciak, T., Ning, L., Larochelle, H., Descoteaux, M., Chamberland, M., Blumberg, S. B., Mertzanidou, T., Alexander, D. C., Afzali, M., Aja-Fernández, S., Jones, D. K., Westin, C.-F., ... Hutter, J. (2020). Acquiring and predicting multidimensional diﬀusion (MUDI) data: an open challenge. In E. Bonet-Carne (Ed.), Computational Diffusion MRI (pp. 195-208). Springer. https://doi.org/10.1007/978-3-030-52893-5_17

@inbook{de992f0d9f8b47c3b61d4dbb518a8405,

title = "Acquiring and predicting multidimensional diﬀusion (MUDI) data: an open challenge",

abstract = "In magnetic resonance imaging (MRI), the image contrast is the result of the subtle interaction between the physicochemical properties of the imaged living tissue and the parameters used for image acquisition. By varying parameters such as the echo time (TE) and the inversion time (TI), it is possible to collect images that capture diﬀerent expressions of this sophisticated interaction. Sensitization to diﬀusion summarized by the b-value - constitutes yet another explorable “dimension” to modify the image contrast which reﬂects the degree of dispersion of water in various directions within the tissue microstructure. The full exploration of this multidimensional acquisition parameter space oﬀers the promise of a more comprehensive description of the living tissue but at the expense of lengthy MRI acquisitions, often unfeasible in clinical practice. The harnessing of multidimensional information passes through the use of intelligent sampling strategies for reducing the amount of images to acquire, and the design of methods for exploiting the redundancy in such information. This chapter reports the results of the MUDI challenge, comparing diﬀerent strategies for predicting the acquired densely sampled multidimensional data from sub-sampled versions of it. ",

keywords = "MUDI, Diﬀusion, Relaxation, Quantitative Imaging",

author = "Marco Pizzolato and Marco Palombo and Elisenda Bonet-Carne and Tax, \{Chantal M.W.\} and Francesco Grussu and Andrada Ianus and Fabian Bogusz and Tomasz Pieciak and Lipeng Ning and Hugo Larochelle and Maxime Descoteaux and Maxime Chamberland and Blumberg, \{Stefano B.\} and Thomy Mertzanidou and Alexander, \{Daniel C.\} and Maryam Afzali and Santiago Aja-Fern{\'a}ndez and Jones, \{Derek K.\} and Carl-Fredrik Westin and Yogesh Rathi and Baete, \{Steven H.\} and Lucilio Cordero-Grande and Thilo Ladner and Slator, \{Paddy J.\} and Hajnal, \{Joseph V.\} and Jean-Philippe Thiran and Price, \{Anthony N.\} and Farshid Sepehrband and Fan Zhang and Jana Hutter",

year = "2020",

doi = "10.1007/978-3-030-52893-5\_17",

language = "English",

isbn = "978-3-030-52892-8",

series = "Mathematics and Visualization",

publisher = "Springer",

pages = "195--208",

editor = "‪Elisenda Bonet-Carne",

booktitle = "Computational Diffusion MRI",

note = "22nd International Conference on Medical Image Computing and Computer-Assisted Intervention, MICCAI 2019 ; Conference date: 13-10-2019 Through 17-10-2019",

}

Pizzolato, M, Palombo, M, Bonet-Carne, E, Tax, CMW, Grussu, F, Ianus, A, Bogusz, F, Pieciak, T, Ning, L, Larochelle, H, Descoteaux, M, Chamberland, M, Blumberg, SB, Mertzanidou, T, Alexander, DC, Afzali, M, Aja-Fernández, S, Jones, DK, Westin, C-F, Rathi, Y, Baete, SH, Cordero-Grande, L, Ladner, T, Slator, PJ, Hajnal, JV, Thiran, J-P, Price, AN, Sepehrband, F, Zhang, F & Hutter, J 2020, Acquiring and predicting multidimensional diﬀusion (MUDI) data: an open challenge. in E Bonet-Carne (ed.), Computational Diffusion MRI. Springer, Mathematics and Visualization, pp. 195-208, 22nd International Conference on Medical Image Computing and Computer-Assisted Intervention, Shenzhen, China, 13/10/2019. https://doi.org/10.1007/978-3-030-52893-5_17

Acquiring and predicting multidimensional diﬀusion (MUDI) data: an open challenge. / Pizzolato, Marco; Palombo, Marco ; Bonet-Carne, Elisenda et al.
Computational Diffusion MRI. ed. / ‪Elisenda Bonet-Carne. Springer, 2020. p. 195-208 (Mathematics and Visualization).

Research output: Chapter in Book/Report/Conference proceeding › Book chapter › Research › peer-review

TY - CHAP

T1 - Acquiring and predicting multidimensional diﬀusion (MUDI) data: an open challenge

AU - Pizzolato, Marco

AU - Palombo, Marco

AU - Bonet-Carne, Elisenda

AU - Tax, Chantal M.W.

AU - Grussu, Francesco

AU - Ianus, Andrada

AU - Bogusz, Fabian

AU - Pieciak, Tomasz

AU - Ning, Lipeng

AU - Larochelle, Hugo

AU - Descoteaux, Maxime

AU - Chamberland, Maxime

AU - Blumberg, Stefano B.

AU - Mertzanidou, Thomy

AU - Alexander, Daniel C.

AU - Afzali, Maryam

AU - Aja-Fernández, Santiago

AU - Jones, Derek K.

AU - Westin, Carl-Fredrik

AU - Rathi, Yogesh

AU - Baete, Steven H.

AU - Cordero-Grande, Lucilio

AU - Ladner, Thilo

AU - Slator, Paddy J.

AU - Hajnal, Joseph V.

AU - Thiran, Jean-Philippe

AU - Price, Anthony N.

AU - Sepehrband, Farshid

AU - Zhang, Fan

AU - Hutter, Jana

N1 - Conference code: 22

PY - 2020

Y1 - 2020

N2 - In magnetic resonance imaging (MRI), the image contrast is the result of the subtle interaction between the physicochemical properties of the imaged living tissue and the parameters used for image acquisition. By varying parameters such as the echo time (TE) and the inversion time (TI), it is possible to collect images that capture diﬀerent expressions of this sophisticated interaction. Sensitization to diﬀusion summarized by the b-value - constitutes yet another explorable “dimension” to modify the image contrast which reﬂects the degree of dispersion of water in various directions within the tissue microstructure. The full exploration of this multidimensional acquisition parameter space oﬀers the promise of a more comprehensive description of the living tissue but at the expense of lengthy MRI acquisitions, often unfeasible in clinical practice. The harnessing of multidimensional information passes through the use of intelligent sampling strategies for reducing the amount of images to acquire, and the design of methods for exploiting the redundancy in such information. This chapter reports the results of the MUDI challenge, comparing diﬀerent strategies for predicting the acquired densely sampled multidimensional data from sub-sampled versions of it.

AB - In magnetic resonance imaging (MRI), the image contrast is the result of the subtle interaction between the physicochemical properties of the imaged living tissue and the parameters used for image acquisition. By varying parameters such as the echo time (TE) and the inversion time (TI), it is possible to collect images that capture diﬀerent expressions of this sophisticated interaction. Sensitization to diﬀusion summarized by the b-value - constitutes yet another explorable “dimension” to modify the image contrast which reﬂects the degree of dispersion of water in various directions within the tissue microstructure. The full exploration of this multidimensional acquisition parameter space oﬀers the promise of a more comprehensive description of the living tissue but at the expense of lengthy MRI acquisitions, often unfeasible in clinical practice. The harnessing of multidimensional information passes through the use of intelligent sampling strategies for reducing the amount of images to acquire, and the design of methods for exploiting the redundancy in such information. This chapter reports the results of the MUDI challenge, comparing diﬀerent strategies for predicting the acquired densely sampled multidimensional data from sub-sampled versions of it.

KW - MUDI

KW - Diﬀusion

KW - Relaxation

KW - Quantitative Imaging

U2 - 10.1007/978-3-030-52893-5_17

DO - 10.1007/978-3-030-52893-5_17

M3 - Book chapter

SN - 978-3-030-52892-8

T3 - Mathematics and Visualization

SP - 195

EP - 208

BT - Computational Diffusion MRI

A2 - Bonet-Carne, ‪Elisenda

PB - Springer

T2 - 22nd International Conference on Medical Image Computing and Computer-Assisted Intervention

Y2 - 13 October 2019 through 17 October 2019

ER -

Acquiring and predicting multidimensional diﬀusion (MUDI) data: an open challenge

Abstract

Conference

Keywords

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