Aligning multi-sequence CMR towards fully automated myocardial pathology segmentation
Aligning multi-sequence CMR towards fully automated myocardial pathology segmentation
Myocardial pathology segmentation (MyoPS) is critical for the risk stratification and treatment planning of myocardial infarction (MI). Multi-sequence cardiac magnetic resonance (MS-CMR) images can provide valuable information. For instance, balanced steady-state free precession cine sequences present clear anatomical boundaries, while late gadolinium enhancement and T2-weighted CMR sequences visualize myocardial scar and edema of MI, respectively. Existing methods usually fuse anatomical and pathological information from different CMR sequences for MyoPS, but assume that these images have been spatially aligned. However, MS-CMR images are usually unaligned due to the respiratory motions in clinical practices, which poses additional challenges for MyoPS. This work presents an automatic MyoPS framework for unaligned MS-CMR images. Specifically, we design a combined computing model for simultaneous image registration and information fusion, which aggregates multi-sequence features into a common space to extract anatomical structures (i.e., myocardium). Consequently, we can highlight the informative regions in the common space via the extracted myocardium to improve MyoPS performance, considering the spatial relationship between myocardial pathologies and myocardium. Experiments on a private MS-CMR dataset and a public dataset from the MYOPS2020 challenge show that our framework could achieve promising performance for fully automatic MyoPS.
multi-sequence cardiac magnetic resonance, Myocardial pathology, registration, segmentation
3474-3486
Ding, Wangbin
ce6c8e72-9208-49fc-b79d-780d4293bc15
Li, Lei
2da88502-0bd8-4e6b-8f7d-0c01a48b399e
Qiu, Junyi
ebd2dcf4-1c11-4fe1-b0e3-e31087d3e93a
Wang, Sihan
fd4f700b-a400-40c0-b34a-00d275fdd84d
Huang, Liqin
4565d61e-d3eb-4ffd-97af-731ae41e5335
Chen, Yinyin
b83e0c07-20b8-4531-915e-5ef8d3852460
Yang, Shan
b48b3d3d-b1f7-47ea-9bac-df4aea3a8c63
Zhuang, Xiahai
c58e977b-e70e-4b37-9acd-b7f8070d98a8
1 December 2023
Ding, Wangbin
ce6c8e72-9208-49fc-b79d-780d4293bc15
Li, Lei
2da88502-0bd8-4e6b-8f7d-0c01a48b399e
Qiu, Junyi
ebd2dcf4-1c11-4fe1-b0e3-e31087d3e93a
Wang, Sihan
fd4f700b-a400-40c0-b34a-00d275fdd84d
Huang, Liqin
4565d61e-d3eb-4ffd-97af-731ae41e5335
Chen, Yinyin
b83e0c07-20b8-4531-915e-5ef8d3852460
Yang, Shan
b48b3d3d-b1f7-47ea-9bac-df4aea3a8c63
Zhuang, Xiahai
c58e977b-e70e-4b37-9acd-b7f8070d98a8
Ding, Wangbin, Li, Lei and Qiu, Junyi
,
et al.
(2023)
Aligning multi-sequence CMR towards fully automated myocardial pathology segmentation.
IEEE Transactions on Medical Imaging, 42 (12), .
(doi:10.1109/TMI.2023.3288046).
Abstract
Myocardial pathology segmentation (MyoPS) is critical for the risk stratification and treatment planning of myocardial infarction (MI). Multi-sequence cardiac magnetic resonance (MS-CMR) images can provide valuable information. For instance, balanced steady-state free precession cine sequences present clear anatomical boundaries, while late gadolinium enhancement and T2-weighted CMR sequences visualize myocardial scar and edema of MI, respectively. Existing methods usually fuse anatomical and pathological information from different CMR sequences for MyoPS, but assume that these images have been spatially aligned. However, MS-CMR images are usually unaligned due to the respiratory motions in clinical practices, which poses additional challenges for MyoPS. This work presents an automatic MyoPS framework for unaligned MS-CMR images. Specifically, we design a combined computing model for simultaneous image registration and information fusion, which aggregates multi-sequence features into a common space to extract anatomical structures (i.e., myocardium). Consequently, we can highlight the informative regions in the common space via the extracted myocardium to improve MyoPS performance, considering the spatial relationship between myocardial pathologies and myocardium. Experiments on a private MS-CMR dataset and a public dataset from the MYOPS2020 challenge show that our framework could achieve promising performance for fully automatic MyoPS.
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e-pub ahead of print date: 22 June 2023
Published date: 1 December 2023
Keywords:
multi-sequence cardiac magnetic resonance, Myocardial pathology, registration, segmentation
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Local EPrints ID: 488805
URI: http://eprints.soton.ac.uk/id/eprint/488805
ISSN: 0278-0062
PURE UUID: 576f2b1f-c0e3-4b80-aafc-97d0c52ee9db
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Date deposited: 05 Apr 2024 16:44
Last modified: 10 Apr 2024 02:14
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Contributors
Author:
Wangbin Ding
Author:
Lei Li
Author:
Junyi Qiu
Author:
Sihan Wang
Author:
Liqin Huang
Author:
Yinyin Chen
Author:
Shan Yang
Author:
Xiahai Zhuang
Corporate Author: et al.
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