Construction of a New Length Feature for Evaluating the Morphological Changes of BrainWhite Matter Fibers
Dong Weihong1, Qin Jiaolong2*, Ni Huangjing3,4,5, Luo Dandan2, Wu Ye2, Yao Zhijian6, Lu Qing1#*
1(School of Biological Sciences & Medical Engineering, Southeast University, Nanjing 210096, China) 2(School of Computer Science & Engineering, Nanjing University of Science and Technology, Nanjing 210094, China) 3(School of Computer Scienc, Nanjing University of Posts and Telecommunications, Nanjing 210023, China) 4(School of Software Science, Nanjing University of Posts and Telecommunications, Nanjing 210023, China) 5(School of Cyberspace Security, Nanjing University of Posts and Telecommunications, Nanjing 210023, China) 6(Department of Psychiatry, the Affiliated Brain Hospital of Nanjing Medical University, Nanjing 210029, China)
Abstract:Based on diffusion tensor imaging (DTI) data, whole brain white matter fibers can be presented in three dimensions. At present, morphological analysis of brain white matter fibers has been used to study the changes of fiber morphology in the development process or pathological conditions. In this study, we proposed a new feature to characterize the length of brain white matter fibers by calculating the euclidean space distance accumulated by points along the fiber, and further explored the stability of the feature from two aspects using 50 samples from the human connectome project (HCP) dataset. First, the influence of white matter fibers reconstructed by different fiber tracking algorithms on the feature. Second, under the same fiber tracking algorithm, the influence of different fiber numbers on the feature. Finally, 254 subjects from the HCP dataset were included, and we used the feature to preliminarily explore the influence of gender on the morphology of brain white matter fibers by voxel-based analysis (VBA). Through the calculation of intra-class correlation coefficients (ICC) model, it was found that when the overall lengths of white matter fibers reconstructed by the two fiber tracking algorithms were relatively close, the ICCs of the corresponding feature values in most intracranial voxels were above 0.4. In addition, under the same fiber tracking algorithm, different numbers of white matter fibers had little influence on the feature, and the ICCs corresponding to the feature values of intracranial voxels were concentrated above 0.8. The analysis of the influence of gender on the morphology of white matter fibers in the brain showed that compared with males, the length feature values of brain white matter fibers in females were significantly higher in the thalamus, fornix, middle cerebellar peduncle and pallidum. Males had significantly higher feature values in the right rectus and the right pallidum than females. The length feature of brain white matter fibers proposed in this paper is expected to enrich analysis methods of brain white matter fiber morphology for uses in the studies of brain development and brain related diseases.
董卫红, 秦姣龙, 倪黄晶, 罗丹丹, 吴烨, 姚志剑, 卢青. 一种新的评估脑白质纤维形态变化的长度特征构建[J]. 中国生物医学工程学报, 2024, 43(2): 173-182.
Dong Weihong, Qin Jiaolong, Ni Huangjing, Luo Dandan, Wu Ye, Yao Zhijian, Lu Qing. Construction of a New Length Feature for Evaluating the Morphological Changes of BrainWhite Matter Fibers. Chinese Journal of Biomedical Engineering, 2024, 43(2): 173-182.
[1] Basser PJ, Pajevic S, Pierpaoli C, et al. In vivo fiber tractography using DT-MRI data [J]. Magnetic Resonance in Medicine, 2000, 44(4): 625-632. [2] Jeurissen B, Descoteaux M, Mori S, et al. Diffusion MRI fiber tractography of the brain [J]. Nmr in Biomedicine, 2019, 32(4): e3785. [3] Zhang Fan, Daducci A, He Yong, et al. Quantitative mapping of the brain′s structural connectivity using diffusion MRI tractography: A review [J]. Neuroimage, 2022, 249: 118870. [4] Basser PJ, Pierpaoli C. Microstructural and physiological features of tissues elucidated by quantitative-diffusion-tensor MRI [J]. Journal of Magnetic Resonance Series B, 1996, 111(3): 209-219. [5] Jensen JH, Helpern JA. MRI quantification of non-Gaussian water diffusion by kurtosis analysis [J]. NMR in Biomedicine, 2010, 23(7): 698-710. [6] Zhang Hui, Schneider T, Wheeler-Kingshott CA, et al. NODDI: practical in vivo neurite orientation dispersion and density imaging of the human brain [J]. Neuroimage, 2012, 61(4): 1000-1016. [7] Hagmann P, Cammoun L, Gigandet X, et al. Mapping the structural core of human cerebral cortex [J]. PLoS Biology, 2008, 6(7): 1479-1493. [8] Ingalhalikar M, Smith A, Parker D, et al. Sex differences in the structural connectome of the human brain [J]. Proceedings of the National Academy of Sciences of the United States of America, 2014, 111(2): 823-828. [9] Roberts JA, Perry A, Lord AR, et al. The contribution of geometry to the human connectome [J]. Neuroimage, 2016, 124: 379-393. [10] Sporns O, Tononi G, Kotter R. The human connectome: A structural description of the human brain [J]. PLoS Computational Biology, 2005, 1(4): 245-251. [11] Van Dellen E, Sommer IE, Bohlken MM, et al. Minimum spanning tree analysis of the human connectome [J]. Human Brain Mapping, 2018, 39(6): 2455-2471. [12] Bajada CJ, Schreiber J, Caspers S. Fiber length profiling: a novel approach to structural brain organization [J]. Neuroimage, 2019, 186: 164-173. [13] Behrman-Lay AM, Usher C, Conturo TE, et al. Fiber bundle length and cognition: a length-based tractography MRI study [J]. Brain Imaging and Behavior, 2015, 9(4): 765-775. [14] Catani M, Allin MPG, Husain M, et al. Symmetries in human brain language pathways correlate with verbal recall [J]. Proceedings of the National Academy of Sciences of the United States of America, 2007, 104(43): 17163-17168. [15] Chandio BQ, Risacher SL, Pestilli F, et al. Bundle analytics, a computational framework for investigating the shapes and profiles of brain pathways across populations [J]. Scientific Reports, 2020, 10(1): 17149. [16] Colby JB, Soderberg L, Lebel C, et al. Along-tract statistics allow for enhanced tractography analysis [J]. Neuroimage, 2012, 59(4): 3227-3242. [17] Grinberg F, Maximov II, Farrher E, et al. Microstructure-informed slow diffusion tractography in humans enhances visualisation of fibre pathways [J]. Magnetic Resonance Imaging, 2018, 45: 7-17. [18] Rheault F, De Benedictis A, Daducci A, et al. Tractostorm: the what, why, and how of tractography dissection reproducibility [J]. Human Brain Mapping, 2020, 41(7): 1859-1874. [19] Song JW, Mitchell PD, Kolasinski J, et al. Asymmetry of white matter pathways in developing human brains [J]. Cerebal Cortex, 2015, 25(9): 2883-2893. [20] Yeatman JD, Dougherty RF, Myall NJ, et al. Tract profiles of white matter properties: automating fiber-tract quantification [J]. PLoS ONE, 2012, 7(11): e49790. [21] Raffelt DA, Smith RE, Ridgway GR, et al. Connectivity-based fixel enhancement: whole-brain statistical analysis of diffusion MRI measures in the presence of crossing fibres [J]. Neuroimage, 2015, 117: 40-55. [22] Raffelt DA, Tournier J, Smith RE, et al. Investigating white matter fibre density and morphology using fixel-based analysis [J]. Neuroimage, 2017, 144: 58-73. [23] Lewis JD, Theilmann RJ, Fonov V, et al. Callosal fiber length and interhemispheric connectivity in adults with autism: Brain overgrowth and underconnectivity [J]. Human Brain Mapping, 2013, 34(7): 1685-1695. [24] Gan Jun, Zhong M, Fan Jie, et al. Abnormal white matter structural connectivity in adults with obsessive-compulsive disorder [J]. Translational Psychiatry, 2017, 7(3): e1062. [25] Denier N, Walther S, Schneider C, et al. Reduced tract length of the medial forebrain bundle and the anterior thalamic radiation in bipolar disorder with melancholic depression [J]. Journal of Affective Disorders, 2020, 274: 8-14. [26] Kemp HI, Petropoulos IN, Rice ASC, et al. Use of corneal confocal microscopy to evaluate small nerve fibers in patients with human immunodeficiency virus [J]. Jama Ophthalmology, 2017, 135(7): 795-799. [27] Bracht T, Soravia L, Moggi F, et al. The role of the orbitofrontal cortex and the nucleus accumbens for craving in alcohol use disorder [J]. Translational Psychiatry, 2021, 11(1): 267. [28] Correia S, Lee SY, Voorn T, et al. Quantitative tractography metrics of white matter integrity in diffusion-tensor MRI [J]. Neuroimage, 2008, 42(2): 568-581. [29] Pannek K, Mathias JL, Bigler ED, et al. The average pathlength map: a diffusion MRI tractography-derived index for studying brain pathology [J]. Neuroimage, 2011, 55(1): 133-141. [30] Mori S, Crain BJ, Chacko VP, et al. Three-dimensional tracking of axonal projections in the brain by magnetic resonance imaging [J]. Annals of Neurology, 1999, 45(2): 265-269. [31] Tournier J, Calamante F, Connelly A. MRtrix: diffusion tractography in crossing fiber regions [J]. International Journal of Imaging Systems and Technology, 2012, 22(1): 53-66. [32] Wu Ye, Hong Y, Ahmad S, et al. Active cortex tractography [C] // Medical Image Computing and Computer Assisted Intervention. Cham: Springer, 2021: 467-476. [33] Smith RE, Tournier J-D, Calamante F, et al. SIFT: Spherical-deconvolution informed filtering of tractograms [J]. Neuroimage, 2013, 67: 298-312. [34] Zuo Xinian, Xing Xiuxia. Effects of non-local diffusion on structural mri preprocessing and default network mapping: statistical comparisons with isotropic/anisotropic diffusion [J]. PLoS ONE, 2011, 6(10): e26703. [35] Landis JR, Koch GG. Measurement of observer agreement for categorical data [J]. Biometrics, 1977, 33(1): 159-174. [36] Mori S, Oishi K, Jiang Hangyi, et al. Stereotaxic white matter atlas based on diffusion tensor imaging in an ICBM template [J]. Neuroimage, 2008, 40(2): 570-582. [37] Rolls ET, Huang CC, Lin CP, et al. Automated anatomical labelling atlas 3 [J]. Neuroimage, 2020, 206: 116189. [38] Schüz A, Braitenberg V. The human cortical white matter: quantitative aspects of cortico-cortical long-range connectivity [M] // Cortical Areas. Boca Raton: CRC Press, 2002: 389-398. [39] Van Eijk L, Hansell NK, Strike LT, et al. Region-specific sex differences in the hippocampus [J]. Neuroimage, 2020, 215: 116781. [40] Dhamala E, Jamison KW, Sabuncu MR, et al. Sex classification using long-range temporal dependence of resting-state functional MRI time series [J]. Human Brain Mapping, 2020, 41(13): 3567-3579. [41] Sacher J, Neumann J, Okon-Singer H, et al. Sexual dimorphism in the human brain: evidence from neuroimaging [J]. Magnetic Resonance Imaging, 2013, 31(3): 366-375. [42] Ozer MA, Kayalioglu G, Erturk M. Topographic anatomy of the fornix as a guide for the transcallosal-interforniceal approach with a special emphasis on sex differences [J]. Neurologia Medico-Chirurgica, 2005, 45(12): 607-612. [43] Cahn AJ, Little G, Beaulieu C, et al. Diffusion properties of the fornix assessed by deterministic tractography shows age, sex, volume, cognitive, hemispheric, and twin relationships in young adults from the Human Connectome Project [J]. Brain Structure & Function, 2021, 226(2): 381-395. [44] Xin Jiang, Zhang Yaoxue, Tang Yan, et al. Brain differences between men and women: evidence from deep learning [J]. Frontiers in Neuroscience, 2019, 13: 185. [45] Ruigrok ANV, Salimi-Khorshidi G, Lai MC, et al. A meta-analysis of sex differences in human brain structure [J]. Neuroscience and Biobehavioral Reviews, 2014, 39: 34-50.
