TY - GEN
T1 - BiMSRec
T2 - 28th International Conference on Medical Image Computing and Computer Assisted Intervention, MICCAI 2025
AU - Long, Nuoer
AU - Yang, Kaiwen
AU - Xie, Xinyu
AU - Yu, Zitong
AU - Tan, Tao
AU - Sun, Yue
N1 - Publisher Copyright:
© The Author(s), under exclusive license to Springer Nature Switzerland AG 2026.
PY - 2026
Y1 - 2026
N2 - Traditional multi-modal medical image fusion methods typically employ a hierarchical feature fusion strategy. However, due to inconsistencies among features at different scales, these approaches often introduce unanticipated deformations during the fusion process. Such deformations accumulate through successive registration steps and ultimately result in oscillatory distortions at the fine-detail level. To address this challenge, we propose a progressive image reconstruction framework that is guided by multi-scale deformation fields. Specifically, the input images are first mapped into feature spaces at multiple scales and a deformation field prediction strategy is employed to generate multiple deformation fields that capture both local and global transformation trends simultaneously. Notably, the deformation fields generated across all scales possess the intrinsic capability to directly perform image registration. This capability eliminates the need for sequential propagation of registration outcomes and effectively mitigates cumulative deformation issues. In the image reconstruction phase, we adopt a progressive coarse-to-fine strategy, leveraging multi-scale deformation fields to achieve accurate structure restoration and fusion. Extensive experimental results demonstrate that the proposed method significantly enhances image alignment accuracy and fusion quality across multiple datasets, offering an efficient and robust solution for multi-modal medical image processing.
AB - Traditional multi-modal medical image fusion methods typically employ a hierarchical feature fusion strategy. However, due to inconsistencies among features at different scales, these approaches often introduce unanticipated deformations during the fusion process. Such deformations accumulate through successive registration steps and ultimately result in oscillatory distortions at the fine-detail level. To address this challenge, we propose a progressive image reconstruction framework that is guided by multi-scale deformation fields. Specifically, the input images are first mapped into feature spaces at multiple scales and a deformation field prediction strategy is employed to generate multiple deformation fields that capture both local and global transformation trends simultaneously. Notably, the deformation fields generated across all scales possess the intrinsic capability to directly perform image registration. This capability eliminates the need for sequential propagation of registration outcomes and effectively mitigates cumulative deformation issues. In the image reconstruction phase, we adopt a progressive coarse-to-fine strategy, leveraging multi-scale deformation fields to achieve accurate structure restoration and fusion. Extensive experimental results demonstrate that the proposed method significantly enhances image alignment accuracy and fusion quality across multiple datasets, offering an efficient and robust solution for multi-modal medical image processing.
KW - Deformation Field
KW - Medical Image Fusion
KW - Multi-modal
UR - https://www.scopus.com/pages/publications/105017848687
U2 - 10.1007/978-3-032-04937-7_5
DO - 10.1007/978-3-032-04937-7_5
M3 - Conference contribution
AN - SCOPUS:105017848687
SN - 9783032049360
T3 - Lecture Notes in Computer Science
SP - 46
EP - 55
BT - Medical Image Computing and Computer Assisted Intervention, MICCAI 2025 - 28th International Conference, 2025, Proceedings
A2 - Gee, James C.
A2 - Hong, Jaesung
A2 - Sudre, Carole H.
A2 - Golland, Polina
A2 - Alexander, Daniel C.
A2 - Iglesias, Juan Eugenio
A2 - Venkataraman, Archana
A2 - Kim, Jong Hyo
PB - Springer Science and Business Media Deutschland GmbH
Y2 - 23 September 2025 through 27 September 2025
ER -