基于成像物理模型与流形结构的自监督磁共振指纹参数量化方法

doi:10.11938/cjmr20253173

摘要/Abstract

摘要：

磁共振指纹成像是一种高效的多参数定量成像技术，但传统方法依赖信号字典进行参数量化，存在离散化误差大与匹配效率低下等问题．针对现有监督学习方法依赖伪标签、缺乏物理可解释性的局限性，本文提出了一种融合成像物理模型与流形结构建模的自监督磁共振指纹参数量化方法．该方法通过布洛赫方程驱动的自监督物理一致性学习获得可靠的无标签约束，并结合流形结构驱动的知识蒸馏，将长帧的特征迁移至短帧模型，实现物理约束与结构先验的联合优化，从而同时提升无标签条件下的精度与效率．实验验证了本方法在准确性与鲁棒性方面的优势，为实现高效可靠的磁共振指纹参数估计提供了新思路．

关键词: 磁共振指纹成像, 自监督学习, 参数量化, 成像物理模型, 流形结构

Abstract:

Magnetic resonance fingerprint (MRF) is an efficient multi-parameter quantitative imaging technology. However, traditional methods relying on signal dictionaries for parameter quantization are plagued by significant discretization errors and low matching efficiency. To overcome the limitations of existing supervised learning approaches that depend on pseudo-labels and lack physical interpretability, this study proposes a self-supervised parameter quantization method that integrates imaging physical models and manifold structure modeling. This method establishes reliable unlabeled constraints through Bloch equation-driven self-supervised physical consistency learning. By incorporating manifold structure-driven knowledge distillation, it transfers features of long frames to short frame models, realizing joint optimization of physical constraints and structural priors, thereby improving both accuracy and efficiency under unlabeled conditions. Experiments have verified this method’s superior accuracy and robustness, providing a novel approach for efficient and reliable MRF parameter estimation.

Key words: magnetic resonance fingerprint imaging, self-supervised learning, parameter quantization, imaging physical model, manifold structure

中图分类号:

李晓迪, 纪雨萍, 胡悦. 基于成像物理模型与流形结构的自监督磁共振指纹参数量化方法[J]. 波谱学杂志, 2026, 43(1): 46-60.

LI Xiaodi, JI Yuping, HU Yue. Self-supervised Magnetic Resonance Fingerprint Parameter Quantization Method Based on Imaging Physical Model and Manifold Structure[J]. Chinese Journal of Magnetic Resonance, 2026, 43(1): 46-60.

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方法	T₁			T₂
方法	NMSE	SSIM	PSNR	NMSE	SSIM	PSNR
SCQ^[16]	0.0071±0.0006	0.9809±0.0044	30.91±0.7194	0.0264±0.0039	0.9345±0.0168	25.37±0.7681
SPR^[15]	0.0081±0.0007	0.9800±0.0043	30.32±0.4961	0.0181±0.0046	0.9526±0.0147	27.24±1.1641
CONV-ICA^[29]	0.0060±0.0005	0.9842±0.0029	31.63±0.5046	0.0179±0.0025	0.8704±0.0502	27.21±0.3463
EI^[30]	0.0144±0.0058	0.9783±0.0036	28.15±1.7734	0.0385±0.0088	0.9019±0.0168	22.19±2.1771
NLEI^[19]	0.0147±0.0038	0.9755±0.0036	27.87±1.0816	0.0184±0.0016	0.9725±0.0031	27.06±0.4581
Distilled SPQ （本文方法）	0.0099±0.0030	0.9800±0.0030	29.60±1.2653	0.0172±0.0021	0.9003±0.0512	27.54±0.3693

方法	T₁/ms			T₂/ms
方法	白质	灰质	脑脊液	白质	灰质	脑脊液
参考值	794.6±58.6	1346.2±78.5	3357.9±102.3	73.9±5.5	90.4±5.3	820.7±111.3
Distilled SPQ（本文方法）	812.1±55.5	1373.0±87.3	3222.7±174.9	71.6±7.8	84.8±8.9	799.1±157.4
文献[31]	788~898	1286~1393	/	63~80	78~117	/

方法	T₁ NMSE	T₂ NMSE
SPQ-200	0.0227±0.0028	0.0208±0.0026
SPQ-500	0.0092±0.0029	0.0194±0.0023
Distilled SPQ（本文方法）	0.0099±0.0030	0.0172±0.0021

λ	T₁ NMSE	T₂ NMSE
0.01	0.0104±0.0032	0.0185±0.0024
0.1	0.0102±0.0031	0.0180±0.0023
1.0	0.0099±0.0030	0.0172±0.0021
10	0.0109±0.0034	0.0200±0.0025

方法	训练时间	参数量化时间
SCQ^[16]	6.5 h	0.173 s
SPR^[15]	6.2 h	0.172 s
CONV-ICA^[29]	6.0 h	0.170 s
EI^[30]	35.6 h	78.077 s
NLEI^[19]	49.7 h	1.204 s
Distilled SPQ（本文方法）	18.5 h	0.352 s