基于 3T MRI 的 Meynert 基底核深度学习分割。
Deep Learning Segmentation of the Nucleus Basalis of Meynert on 3T MRI.
机构信息
From the Department of Biomedical Engineering (D.J.D., G.W.J., S.N., H.F.J.G., C. Chang., V.L.M., C. Constantinidis, D.J.E.), Vanderbilt University, Nashville, Tennessee
Institute of Imaging Science (D.J.D., G.W.J., S.N., J.S.S., J.W.J., H.F.J.G., C. Chang, V.L.M., B.M.D., D.J.E.), Vanderbilt University, Nashville, Tennessee.
出版信息
AJNR Am J Neuroradiol. 2023 Sep;44(9):1020-1025. doi: 10.3174/ajnr.A7950. Epub 2023 Aug 10.
BACKGROUND AND PURPOSE
The nucleus basalis of Meynert is a key subcortical structure that is important in arousal and cognition and has been explored as a deep brain stimulation target but is difficult to study due to its small size, variability among patients, and lack of contrast on 3T MR imaging. Thus, our goal was to establish and evaluate a deep learning network for automatic, accurate, and patient-specific segmentations with 3T MR imaging.
MATERIALS AND METHODS
Patient-specific segmentations can be produced manually; however, the nucleus basalis of Meynert is difficult to accurately segment on 3T MR imaging, with 7T being preferred. Thus, paired 3T and 7T MR imaging data sets of 21 healthy subjects were obtained. A test data set of 6 subjects was completely withheld. The nucleus was expertly segmented on 7T, providing accurate labels for the paired 3T MR imaging. An external data set of 14 patients with temporal lobe epilepsy was used to test the model on brains with neurologic disorders. A 3D-Unet convolutional neural network was constructed, and a 5-fold cross-validation was performed.
RESULTS
The novel segmentation model demonstrated significantly improved Dice coefficients over the standard probabilistic atlas for both healthy subjects (mean, 0.68 [SD, 0.10] versus 0.45 [SD, 0.11], = .002, test) and patients (0.64 [SD, 0.10] versus 0.37 [SD, 0.22], < .001). Additionally, the model demonstrated significantly decreased centroid distance in patients (1.18 [SD, 0.43] mm, 3.09 [SD, 2.56] mm, = .007).
CONCLUSIONS
We developed the first model, to our knowledge, for automatic and accurate patient-specific segmentation of the nucleus basalis of Meynert. This model may enable further study into the nucleus, impacting new treatments such as deep brain stimulation.
背景与目的
基底核梅内尔特核是一个关键的皮质下结构,在觉醒和认知中很重要,已经被探索作为深部脑刺激的靶点,但由于其体积小、患者间的可变性以及在 3T MR 成像上缺乏对比度,因此很难研究。因此,我们的目标是建立和评估一个深度学习网络,以便在 3T MR 成像上进行自动、准确和患者特异性的分割。
材料与方法
患者特异性分割可以手动生成;然而,基底核梅内尔特核在 3T MR 成像上很难准确分割,而 7T 则更受欢迎。因此,我们获得了 21 名健康受试者的配对 3T 和 7T MR 成像数据集。一个由 6 名受试者组成的测试数据集完全被排除在外。7T 上对核进行了专家分割,为配对的 3T MR 成像提供了准确的标签。一个由 14 名颞叶癫痫患者组成的外部数据集被用于在有神经障碍的大脑上测试模型。构建了一个 3D-Unet 卷积神经网络,并进行了 5 倍交叉验证。
结果
新的分割模型在健康受试者(平均,0.68 [SD,0.10] 与 0.45 [SD,0.11], =.002, 检验)和患者(0.64 [SD,0.10] 与 0.37 [SD,0.22], <.001)中均显著提高了 Dice 系数,优于标准概率图谱。此外,该模型在患者中还显著降低了质心距离(1.18 [SD,0.43] 毫米,3.09 [SD,2.56] 毫米, =.007)。
结论
我们开发了首个模型,据我们所知,用于基底核梅内尔特核的自动和准确的患者特异性分割。该模型可能使对该核的进一步研究成为可能,从而影响深部脑刺激等新的治疗方法。
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