Kanno Shigenori, Liu Junyan, Kawamura Ai, Ota Shoko, Kawakami Nobuko, Iseki Chifumi, Kakinuma Kazuo, Matsubara Shiho, Katsuse Kazuto, Sato Kazushi, Takeuchi Takashi, Tanaka Yoshitaka, Kodama Hiroyasu, Nagasaka Tatsuo, Sai Masahiro, Odagiri Hayato, Saito Mioko, Takanami Kentaro, Mugikura Shunji, Suzuki Kyoko
Department of Behavioural Neurology and Cognitive Neuroscience, Tohoku University Graduate School of Medicine, 2-1, Seiryo-machi, Aoba-ku, Sendai, 980-8575, Miyagi, Japan.
Department of Neurology, The University of Tokyo, Tokyo, Japan.
Fluids Barriers CNS. 2024 Dec 30;21(1):108. doi: 10.1186/s12987-024-00611-y.
Disproportionately enlarged subarachnoid space hydrocephalus (DESH) is one of the neuroradiological characteristics of idiopathic normal pressure hydrocephalus (iNPH), which makes statistical analyses of brain images difficult. This study aimed to develop and validate methods of accurate brain segmentation and spatial normalisation in patients with DESH by using the Computational Anatomy Toolbox (CAT12).
Two hundred ninety-eight iNPH patients with DESH and 25 healthy controls (HCs) who underwent cranial MRI were enrolled in this study. We selected the structural images of 169 patients to create customised tissue probability maps and diffeomorphic anatomical registration through exponentiated Lie algebra (DARTEL) templates for patients with DESH (DESH-TPM and DESH-Template). The structural images of 38 other patients were used to evaluate the validity of the DESH-TPM and DESH-Template. DESH-TPM and DESH-Template were created using the 114 well-segmented images after the segmentation processing of CAT12. In the validation study, we compared the accuracy of brain segmentation and spatial normalisation among three conditions: customised condition, applying DESH-TPM and DESH-Template to CAT12 and patient images; standard condition, applying the default setting of CAT12 to patient images; and reference condition, applying the default setting of CAT12 to HC images.
In the validation study, we identified three error types during segmentation. (1) The proportions of misidentifying the dura and/or extradural structures as brain structures in the customised, standard, and reference conditions were 10.5%, 44.7%, and 13.6%, respectively; (2) the failure rates of white matter hypointensity (WMH) cancellation in the customised, standard, and reference conditions were 18.4%, 44.7%, and 0%, respectively; and (3) the proportions of cerebrospinal fluid (CSF)-image deficits in the customised, standard, and reference conditions were 97.4%, 84.2%, and 28%, respectively. The spatial normalisation accuracy of grey and white matter images in the customised condition was the highest among the three conditions, especially in terms of superior convexity.
Applying the combination of the DESH-TPM and DESH-Template to CAT12 could improve the accuracy of grey and white matter segmentation and spatial normalisation in patients with DESH. However, this combination could not improve the CSF segmentation accuracy. Another approach is needed to overcome this challenge.
蛛网膜下腔不成比例扩大性脑积水(DESH)是特发性正常压力脑积水(iNPH)的神经放射学特征之一,这使得脑图像的统计分析变得困难。本研究旨在通过使用计算解剖学工具箱(CAT12)开发并验证DESH患者准确的脑分割和空间归一化方法。
本研究纳入了298例患有DESH的iNPH患者和25名健康对照(HC),他们均接受了头颅MRI检查。我们选择了169例患者的结构图像来创建定制的组织概率图,并通过指数李代数(DARTEL)模板对DESH患者进行微分同胚解剖配准(DESH-TPM和DESH-模板)。另外38例患者的结构图像用于评估DESH-TPM和DESH-模板的有效性。DESH-TPM和DESH-模板是在CAT12分割处理后使用114幅分割良好的图像创建的。在验证研究中,我们比较了三种情况下脑分割和空间归一化的准确性:定制情况,将DESH-TPM和DESH-模板应用于CAT12和患者图像;标准情况,将CAT12的默认设置应用于患者图像;参考情况,将CAT12的默认设置应用于HC图像。
在验证研究中,我们在分割过程中识别出三种错误类型。(1)在定制、标准和参考情况下,将硬脑膜和/或硬膜外结构误识别为脑结构的比例分别为10.5%、44.7%和13.6%;(2)在定制、标准和参考情况下,白质低信号(WMH)消除失败率分别为18.4%、44.7%和0%;(3)在定制、标准和参考情况下,脑脊液(CSF)图像缺损的比例分别为97.4%、84.2%和28%。定制情况下灰质和白质图像的空间归一化准确性在三种情况中最高,尤其是在额上凸方面。
将DESH-TPM和DESH-模板结合应用于CAT12可以提高DESH患者灰质和白质分割以及空间归一化的准确性。然而,这种结合不能提高CSF分割的准确性。需要另一种方法来克服这一挑战。
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