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AtrialJSQnet: a new framework for joint segmentation and quantification of left atrium and scars incorporating spatial and shape information

AtrialJSQnet: a new framework for joint segmentation and quantification of left atrium and scars incorporating spatial and shape information
AtrialJSQnet: a new framework for joint segmentation and quantification of left atrium and scars incorporating spatial and shape information

Left atrial (LA) and atrial scar segmentation from late gadolinium enhanced magnetic resonance imaging (LGE MRI) is an important task in clinical practice. The automatic segmentation is however still challenging due to the poor image quality, the various LA shapes, the thin wall, and the surrounding enhanced regions. Previous methods normally solved the two tasks independently and ignored the intrinsic spatial relationship between LA and scars. In this work, we develop a new framework, namely AtrialJSQnet, where LA segmentation, scar projection onto the LA surface, and scar quantification are performed simultaneously in an end-to-end style. We propose a mechanism of shape attention (SA) via an implicit surface projection to utilize the inherent correlation between LA cavity and scars. In specific, the SA scheme is embedded into a multi-task architecture to perform joint LA segmentation and scar quantification. Besides, a spatial encoding (SE) loss is introduced to incorporate continuous spatial information of the target in order to reduce noisy patches in the predicted segmentation. We evaluated the proposed framework on 60 post-ablation LGE MRIs from the MICCAI2018 Atrial Segmentation Challenge. Moreover, we explored the domain generalization ability of the proposed AtrialJSQnet on 40 pre-ablation LGE MRIs from this challenge and 30 post-ablation multi-center LGE MRIs from another challenge (ISBI2012 Left Atrium Fibrosis and Scar Segmentation Challenge). Extensive experiments on public datasets demonstrated the effect of the proposed AtrialJSQnet, which achieved competitive performance over the state-of-the-art. The relatedness between LA segmentation and scar quantification was explicitly explored and has shown significant performance improvements for both tasks. The code has been released via https://zmiclab.github.io/projects.html.

Atrial segmentation, Scar quantification, Shape attention, Spatial encoding
1361-8415
Li, Lei
2da88502-0bd8-4e6b-8f7d-0c01a48b399e
Zimmer, Veronika A.
6191ba19-27ee-40f8-8d4a-bc80beca661e
Schnabel, Julia A.
da581009-2173-416f-8d41-2b513288ee00
Zhuang, Xiahai
c58e977b-e70e-4b37-9acd-b7f8070d98a8
Li, Lei
2da88502-0bd8-4e6b-8f7d-0c01a48b399e
Zimmer, Veronika A.
6191ba19-27ee-40f8-8d4a-bc80beca661e
Schnabel, Julia A.
da581009-2173-416f-8d41-2b513288ee00
Zhuang, Xiahai
c58e977b-e70e-4b37-9acd-b7f8070d98a8

Li, Lei, Zimmer, Veronika A., Schnabel, Julia A. and Zhuang, Xiahai (2021) AtrialJSQnet: a new framework for joint segmentation and quantification of left atrium and scars incorporating spatial and shape information. Medical Image Analysis, 76, [102303]. (doi:10.1016/j.media.2021.102303).

Record type: Article

Abstract

Left atrial (LA) and atrial scar segmentation from late gadolinium enhanced magnetic resonance imaging (LGE MRI) is an important task in clinical practice. The automatic segmentation is however still challenging due to the poor image quality, the various LA shapes, the thin wall, and the surrounding enhanced regions. Previous methods normally solved the two tasks independently and ignored the intrinsic spatial relationship between LA and scars. In this work, we develop a new framework, namely AtrialJSQnet, where LA segmentation, scar projection onto the LA surface, and scar quantification are performed simultaneously in an end-to-end style. We propose a mechanism of shape attention (SA) via an implicit surface projection to utilize the inherent correlation between LA cavity and scars. In specific, the SA scheme is embedded into a multi-task architecture to perform joint LA segmentation and scar quantification. Besides, a spatial encoding (SE) loss is introduced to incorporate continuous spatial information of the target in order to reduce noisy patches in the predicted segmentation. We evaluated the proposed framework on 60 post-ablation LGE MRIs from the MICCAI2018 Atrial Segmentation Challenge. Moreover, we explored the domain generalization ability of the proposed AtrialJSQnet on 40 pre-ablation LGE MRIs from this challenge and 30 post-ablation multi-center LGE MRIs from another challenge (ISBI2012 Left Atrium Fibrosis and Scar Segmentation Challenge). Extensive experiments on public datasets demonstrated the effect of the proposed AtrialJSQnet, which achieved competitive performance over the state-of-the-art. The relatedness between LA segmentation and scar quantification was explicitly explored and has shown significant performance improvements for both tasks. The code has been released via https://zmiclab.github.io/projects.html.

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More information

Accepted/In Press date: 8 November 2021
e-pub ahead of print date: 16 November 2021
Published date: 5 December 2021
Keywords: Atrial segmentation, Scar quantification, Shape attention, Spatial encoding

Identifiers

Local EPrints ID: 488813
URI: http://eprints.soton.ac.uk/id/eprint/488813
ISSN: 1361-8415
PURE UUID: 7a111340-86bc-4231-95cd-ea24c11931ca
ORCID for Lei Li: ORCID iD orcid.org/0000-0003-1281-6472

Catalogue record

Date deposited: 05 Apr 2024 16:45
Last modified: 10 Apr 2024 02:14

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Contributors

Author: Lei Li ORCID iD
Author: Veronika A. Zimmer
Author: Julia A. Schnabel
Author: Xiahai Zhuang

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