一种种子点聚类与方向修正的纤维追踪算法

doi:10.11938/cjmr20243095

摘要/Abstract

摘要：

纤维追踪算法能通过纤维方向分布函数对脑部纤维进行追踪．考虑到水分子间的弥散作用是相互的，通过扫描数据重建的纤维方向分布函数可能存在误差，本文在传统流线型追踪算法的基础上，结合最大余弦相似度，提出了一种方向修正优化的纤维追踪算法．同时，考虑到人脑内存在各向异性弥散和各向同性弥散的水分子，且后者占比较大，使用最大期望算法对具有相同性质的种子点进行聚类，减少各向同性弥散体素点的追踪．最后分别使用模拟数据和真实数据进行实验，结果表明，本文提出算法追踪所需时间更少，相较于传统流线型纤维追踪算法纤维平均长度更长，错误追踪纤维簇数量显著少于传统纤维追踪算法，正确追踪纤维束比率显著高于传统纤维追踪算法，在大部分特定纤维束的追踪上也有着更高的重叠率与更低的过度估计率，更能体现实际情况下纤维的结构分布．

关键词: 纤维追踪, 最大期望聚类, 移动最小二乘法, 流线型纤维追踪算法

Abstract:

The fiber tracking algorithm can track the brain fibers through the fiber orientation distribution function. Considering that the dispersion of water molecules is mutual and the fiber orientation distribution function reconstructed from scanned data may have errors, this paper proposes a fiber tracking algorithm optimized by direction correction based on the traditional streamline tracking algorithm combined with the maximum cosine similarity. Meanwhile, considering the existence of anisotropically dispersed and isotropically dispersed water molecules in the human brain, and that the latter accounts for a larger proportion, the maximum expectation algorithm is used to cluster the seed points with the same properties to reduce the tracking of isotropically dispersed voxel points. Finally, the experiments were conducted using simulated and real data respectively, and the results show that the proposed algorithm takes less time for tracking, the average fiber length is longer compared to the traditional streamline tracking streamline tracking (STT) algorithm, the number of incorrectly tracked clusters is significantly less and the ratio of correctly tracked bundles significantly higher than that of the traditional fiber tracking algorithm. Additionally, it demonstrates a higher overlap rate and a lower overestimation rate in the tracking of most specific fiber bundles, better reflecting the structural distribution of fibers in practical scenarios.

Key words: fiber tracking, maximum expectation clustering, moving least squares, streamline tracking algorithm

中图分类号:

TP391.41

李浩东, 王远军. 一种种子点聚类与方向修正的纤维追踪算法[J]. 波谱学杂志, 2024, 41(4): 430-442.

LI Haodong, WANG Yuanjun. A Fiber Tracking Algorithm with Seed Point Clustering and Orientation Correction[J]. Chinese Journal of Magnetic Resonance, 2024, 41(4): 430-442.

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参考文献 27

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评估参数	参数定义
IB	至少有一条追踪纤维束的错误纤维簇数量
VB	至少有一条追踪纤维束的正确纤维簇数量
IC	IB中的流线数量与追踪到的总的流线数量的比值
VC	VB中的流线数量与追踪到的总的流线数量的比值
OL	VB中的流线在真实纤维束中的体素数量与真实纤维束内体素总数的比值
OR	VB中的流线在真实纤维束之外的体素数量与真实纤维束内体素总数的比值

算法（均以CSA为重建模型）	IB/簇	VB/簇	IC/%	VC/%	OL/%	OR/%
传统STT算法	92	22	25.45	22.94	55.08	15.68
EuDX算法	181	22	40.01	29.83	45.20	46.46
MSTT算法	73	22	34.75	30.45	57.11	10.70
EM-STT算法	64	22	38.14	43.95	61.97	6.11
EM-MSTT算法	50	22	40.00	45.39	60.57	4.62

纤维簇	OL_EM-MSTT/%	OL_EuDX/%	OL_STT/%
CA	0	0	0
CC	73.839	48.743	66.066
Cingulum_left	68.209	64.403	65.309
Cingulum_right	68.915	54.019	60.711
CP	0	0	0
CST_left	55.384	15.192	86.885
CST_right	93.041	23.954	93.159
Fornix	58.672	60.891	55.098
FPT_left	79.141	40.277	70.873
FPT_right	78.657	69.175	63.173
ICP_left	61.53	87.299	51.831
ICP_right	69.382	85.118	59.593
ILF_left	70.873	92.549	64.728
ILF_right	72.071	43.874	65.118
MCP	64.808	46.177	56.735
OR_left	66.196	49.246	62.255
OR_right	69.757	45.066	64.938
POPT_left	75.582	51.243	67.654
POPT_right	84.312	68.454	81.571
SCP_left	44.862	37.176	43.26
SCP_right	59.348	45.813	57.184
SLF_left	55.613	37.52	50.871
SLF_right	72.212	43.055	64.282
UF_left	73.601	44.564	65.289
UF_right	74.841	46.213	68.793

纤维簇	OR_EM-MSTT/%	OR_EuDX/%	OR_STT/%
CA	0	0	0
CC	16.26	91.455	33.531
Cingulum_left	13.853	68.95	24.478
Cingulum_right	10.428	59.699	26.387
CP	0	0	0
CST_left	0.597	6.057	0.329
CST_right	0.467	7.065	0.53
Fornix	17.991	91.711	29.334
FPT_left	3.45	32.986	6.945
FPT_right	9.876	56.532	16.741
ICP_left	29.943	140.771	60.037
ICP_right	20.682	129.07	44.528
ILF_left	24.861	110.708	39.684
ILF_right	17.411	98.978	33.422
MCP	13.203	78.426	26.03
OR_left	14.995	64.918	23.818
OR_right	13.014	79.618	24.491
POPT_left	10.306	54.182	18.969
POPT_right	2.481	14.867	3.065
SCP_left	49.547	122.086	63.624
SCP_right	25.669	78.782	37.109
SLF_left	37.496	139.848	57.985
SLF_right	14.786	109.349	32.889
UF_left	18.773	113.686	37.099
UF_right	18.524	98.526	30.538

算法	平均纤维长度/mm	耗时/s
EM-MSTT	74.29	46.4
EuDX	75.96	78.66
STT	45.14	3446.65