Image-Derived Phenotype Extraction for Genetic Discovery via Unsupervised Deep Learning in CMR Images
Image-Derived Phenotype Extraction for Genetic Discovery via Unsupervised Deep Learning in CMR Images
Prospective studies with linked image and genetic data, such as the UK Biobank (UKB), provide an unprecedented opportunity to extract knowledge on the genetic basis of image-derived phenotypes. However, the extent of phenotypes tested within so-called genome-wide association studies (GWAS) is usually limited to handcrafted features, where the main limitation to proceed otherwise is the high dimensionality of both the imaging and genetic data. Here, we propose an approach where the phenotyping is performed in an unsupervised manner, via autoencoders that operate on image-derived 3D meshes. Therefore, the latent variables produced by the encoder condense the information related to the geometry of the biologic structure of interest. The network’s training proceeds in two steps: the first is genotype-agnostic and the second enforces an association with a set of genetic markers selected via GWAS on the intermediate latent representation. This genotype-dependent optimisation procedure allows the refinement of the phenotypes produced by the autoencoder to better understand the effect of the genetic markers encountered. We tested and validated our proposed method on left-ventricular meshes derived from cardiovascular magnetic resonance images from the UKB, leading to the discovery of novel genetic associations that, to the best of our knowledge, had not been yet reported in the literature on cardiac phenotypes.
699-708
Bonazzola, Rodrigo
d53c0c7e-b98b-44df-9ce0-63a7f86d4bc0
Ravikumar, Nishant
e31cd3f7-b112-4078-b5fc-0cfc005a061a
Attar, Rahman
f5efd538-042a-4647-9d46-1370d3049b72
Ferrante, Enzo
a35d4d1c-84bc-4a8e-83d0-4f0f110d6925
Syeda-Mahmood, Tanveer
78e13c20-63a3-4037-b401-98936f5dc277
Frangi, Alejandro F.
35127be7-3586-4fff-a4a2-bb79cc228141
21 September 2021
Bonazzola, Rodrigo
d53c0c7e-b98b-44df-9ce0-63a7f86d4bc0
Ravikumar, Nishant
e31cd3f7-b112-4078-b5fc-0cfc005a061a
Attar, Rahman
f5efd538-042a-4647-9d46-1370d3049b72
Ferrante, Enzo
a35d4d1c-84bc-4a8e-83d0-4f0f110d6925
Syeda-Mahmood, Tanveer
78e13c20-63a3-4037-b401-98936f5dc277
Frangi, Alejandro F.
35127be7-3586-4fff-a4a2-bb79cc228141
Bonazzola, Rodrigo, Ravikumar, Nishant, Attar, Rahman, Ferrante, Enzo, Syeda-Mahmood, Tanveer and Frangi, Alejandro F.
(2021)
Image-Derived Phenotype Extraction for Genetic Discovery via Unsupervised Deep Learning in CMR Images.
de Bruijne, Marleen, Cattin, Philippe C., Cotin, Stéphane, Padoy, Nicolas, Speidel, Stefanie, Zheng, Yefeng and Essert, Caroline
(eds.)
In Medical Image Computing and Computer Assisted Intervention – MICCAI 2021 - 24th International Conference, Proceedings.
vol. 12905 LNCS,
Springer Cham.
.
(doi:10.1007/978-3-030-87240-3_67).
Record type:
Conference or Workshop Item
(Paper)
Abstract
Prospective studies with linked image and genetic data, such as the UK Biobank (UKB), provide an unprecedented opportunity to extract knowledge on the genetic basis of image-derived phenotypes. However, the extent of phenotypes tested within so-called genome-wide association studies (GWAS) is usually limited to handcrafted features, where the main limitation to proceed otherwise is the high dimensionality of both the imaging and genetic data. Here, we propose an approach where the phenotyping is performed in an unsupervised manner, via autoencoders that operate on image-derived 3D meshes. Therefore, the latent variables produced by the encoder condense the information related to the geometry of the biologic structure of interest. The network’s training proceeds in two steps: the first is genotype-agnostic and the second enforces an association with a set of genetic markers selected via GWAS on the intermediate latent representation. This genotype-dependent optimisation procedure allows the refinement of the phenotypes produced by the autoencoder to better understand the effect of the genetic markers encountered. We tested and validated our proposed method on left-ventricular meshes derived from cardiovascular magnetic resonance images from the UKB, leading to the discovery of novel genetic associations that, to the best of our knowledge, had not been yet reported in the literature on cardiac phenotypes.
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Published date: 21 September 2021
Additional Information:
Funding Information:
Acknowledgments. This work was funded by the following institutions: The Royal Academy of Engineering [grant number CiET1819\19] and EPSRC [TUSCA EP/V04799X/1] (R.B., N.R. and A.F.F.), The Royal Society through the International Exchanges 2020 Round 2 scheme [grant number IES\R2\202165] (R.B., E.F. and A.F.F). E.F. was also funded by ANPCyT [grant number PICT2018-3907] and UNL [grant numbers CAI+D 50220140100-084LI, 50620190100-145LI].
Publisher Copyright:
© 2021, Springer Nature Switzerland AG.
Venue - Dates:
24th International Conference on Medical Image Computing and Computer Assisted Intervention, MICCAI 2021, , Virtual, Online, 2021-09-27 - 2021-10-01
Identifiers
Local EPrints ID: 477448
URI: http://eprints.soton.ac.uk/id/eprint/477448
ISSN: 0302-9743
PURE UUID: d8427467-c74e-42f4-b32c-43d8f069a5d6
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Date deposited: 06 Jun 2023 17:06
Last modified: 17 Mar 2024 13:18
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Contributors
Author:
Rodrigo Bonazzola
Author:
Nishant Ravikumar
Author:
Rahman Attar
Author:
Enzo Ferrante
Author:
Tanveer Syeda-Mahmood
Author:
Alejandro F. Frangi
Editor:
Marleen de Bruijne
Editor:
Philippe C. Cattin
Editor:
Stéphane Cotin
Editor:
Nicolas Padoy
Editor:
Stefanie Speidel
Editor:
Yefeng Zheng
Editor:
Caroline Essert
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