Dini Leandro I, Vedolin Leonardo M, Bertholdo Debora, Grando Rafael D, Mazzola Alessandro, Dini Simone A, Isolan Gustavo R, da Costa Jaderson C, Campero Alvaro
Neurosurgery, Grupo Hospitalar Conceição (GHC), Porto Alegre, RS, Brazil ; Neurosurgery, Grupo Hospitalar Conceição (GHC), Porto Alegre, RS, Brazil.
Surg Neurol Int. 2013 Apr 12;4:51. doi: 10.4103/2152-7806.110508. Print 2013.
Diffusion tensor imaging (DTI)-based tractography is a noninvasive in vivo method for tracing white matter bundles. This raises possibilities for qualitative and quantitative assessment of the structural organization of tracts. Nevertheless, questions remain about neuroanatomical accuracy, reproducibility for clinical purposes, and accessibility of the best method for broader application. The aim of this study was to combine the fiber dissection technique and tractography to provide more pertinent insight into brain anatomy and, as a result, to test a protocol for reconstruction of six major frontal lobe tracts.
A combination of fiber dissection of formalin-fixed brain tissue after freezing (Klingler's technique) and virtual dissection (tractography) was used to develop a protocol to reconstruct major frontal tracts. Apparent diffusion coefficient (ADC), fractional anisotropy (FA), number of voxels (NVO), volume (VOL), number (NTR), and length (LEN) of tracts were evaluated to assess intra- and interobserver reproducibility. Statistical reliability was evaluated using intraclass correlation coefficients (ICCs) and the Pearson association coefficient (r).
The virtual dissection obtained by tractography seemed to reproduce the anatomic knowledge of the white matter tracts obtained through the classic method. In reliability study, most ICC and r values corresponded at least to large correlation. The magnitude of correlation was very high (ICC 0.7-0.9) or almost perfect (ICC 0.9-1.0) for the FA and ADC measures of every tract studied.
The DTI protocol proposed herein provided a reliable method for analysis of reconstructed frontal lobe tracts, especially for the FA and ADC variables.
基于扩散张量成像(DTI)的纤维束成像技术是一种用于追踪白质束的无创活体方法。这为白质束结构组织的定性和定量评估提供了可能。然而,关于神经解剖学准确性、临床应用的可重复性以及更广泛应用的最佳方法的可及性等问题仍然存在。本研究的目的是将纤维解剖技术与纤维束成像相结合,以更深入地了解脑解剖结构,并因此测试一种重建六条主要额叶束的方案。
采用冷冻后福尔马林固定脑组织的纤维解剖(克林格勒技术)与虚拟解剖(纤维束成像)相结合的方法,制定一种重建主要额叶束的方案。评估表观扩散系数(ADC)、各向异性分数(FA)、体素数量(NVO)、体积(VOL)、束的数量(NTR)和长度(LEN),以评估观察者内和观察者间的可重复性。使用组内相关系数(ICC)和皮尔逊相关系数(r)评估统计可靠性。
纤维束成像获得的虚拟解剖似乎再现了通过经典方法获得的白质束的解剖学知识。在可靠性研究中,大多数ICC和r值至少对应高度相关。对于所研究的每条束的FA和ADC测量,相关程度非常高(ICC 0.7 - 0.9)或几乎完美(ICC 0.9 - 1.0)。
本文提出的DTI方案为分析重建的额叶束提供了一种可靠的方法,特别是对于FA和ADC变量。
