磁共振神经节造影术测量背根神经节容积。
Dorsal Root Ganglion Volumetry by MR Gangliography.
机构信息
From the Department of Neuroradiology (S.W., M.S., J.H., F.H., C.N.-K., T.K., G.A.H., M.P., M.S.).
Neurology (N.U., C.S.), University Hospital Würzburg, Würzburg, Germany.
出版信息
AJNR Am J Neuroradiol. 2022 May;43(5):769-775. doi: 10.3174/ajnr.A7487. Epub 2022 Apr 21.
BACKGROUND AND PURPOSE
Dorsal root ganglion MR imaging (MR gangliography) is increasingly gaining clinical-scientific relevance. However, dorsal root ganglion morphometry by MR imaging is typically performed under the assumption of ellipsoid geometry, which remains to be validated.
MATERIALS AND METHODS
Sixty-four healthy volunteers (37 [57.8%] men; mean age, 31.5 [SD, 8.3] years) underwent MR gangliography of the bilateral L4-S2 levels (3D-T2WI TSE spectral attenuated inversion recovery-sampling perfection with application-optimized contrasts by using different flip angle evolution, isotropic voxels = 1.1 mm³, TE = 301 ms). Ground truth dorsal root ganglion volumes were bilaterally determined for 96 dorsal root ganglia (derivation cohort) by expert manual 3D segmentation by 3 independent raters. These ground truth dorsal root ganglion volumes were then compared with geometric ellipsoid dorsal root ganglion approximations as commonly practiced for dorsal root ganglion morphometry. On the basis of the deviations from ellipsoid geometry, improved volume estimation could be derived and was finally applied to a large human validation cohort (510 dorsal root ganglia).
RESULTS
Commonly used equations of ellipsoid geometry underestimate true dorsal root ganglion volume by large degrees (factor = 0.42-0.63). Ground truth segmentation enabled substantially optimizing dorsal root ganglion geometric approximation using its principal axes lengths by deriving the dorsal root ganglion volume term of [Formula: see text]. Using this optimization, the mean volumes of 510 lumbosacral healthy dorsal root ganglia were as follows: L4: 211.3 (SD, 52.5) mm³, L5: 290.7 (SD, 90.9) mm³, S1: 384.2 (SD, 145.0) mm³, and S2: 192.4 (SD, 52.6) mm³. Dorsal root ganglion volume increased from L4 to S1 and decreased from S1 to S2 (< .001). Dorsal root ganglion volume correlated with subject height ( = . 22, < .001) and was higher in men (< .001).
CONCLUSIONS
Dorsal root ganglion volumetry by measuring its principal geometric axes on MR gangliography can be substantially optimized. By means of this optimization, dorsal root ganglion volume distribution was estimated in a large healthy cohort for the clinically most relevant lumbosacral levels, L4-S2.
背景与目的
背根神经节磁共振成像(MR 神经造影)在临床科学领域的相关性日益增强。然而,MR 成像下的背根神经节形态测量通常假设为椭球体几何形状,这仍有待验证。
材料与方法
64 名健康志愿者(37 名男性,占 57.8%;平均年龄 31.5 [标准差 8.3] 岁)接受双侧 L4-S2 水平的 MR 神经造影(3D-T2WI TSE 谱衰减反转恢复-采样完美应用对比度,采用不同的翻转角演化,各向同性体素=1.1 mm³,TE=301 ms)。通过 3 位独立的评估者进行专家手动 3D 分割,双侧确定了 96 个背根神经节的真实背根神经节体积(推导队列)。然后,将这些真实的背根神经节体积与通常用于背根神经节形态测量的椭球背根神经节近似值进行比较。基于与椭球几何形状的偏差,可以推导出改进的体积估计值,并最终应用于大型人体验证队列(510 个背根神经节)。
结果
通常使用的椭球几何方程会大大低估真实背根神经节的体积(因子=0.42-0.63)。通过使用其主轴长度对背根神经节进行几何近似的精确分割,实现了对背根神经节的优化。通过这种优化,510 个腰骶部健康背根神经节的平均体积如下:L4:211.3(标准差,52.5)mm³;L5:290.7(标准差,90.9)mm³;S1:384.2(标准差,145.0)mm³;S2:192.4(标准差,52.6)mm³。从 L4 到 S1,背根神经节体积增加,从 S1 到 S2 减少(<0.001)。背根神经节体积与受试者身高相关(r=0.22,<0.001),男性较高(<0.001)。
结论
通过在 MR 神经造影中测量其主要几何轴,可以对背根神经节体积进行实质性优化。通过这种优化,我们对临床上最相关的腰骶水平(L4-S2)的大型健康队列进行了背根神经节体积分布的估计。
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