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FreeSurfer 中包含的两种全脑分割方法(ASEG 和 SAMSEG)的可靠性和敏感性。

Reliability and sensitivity of two whole-brain segmentation approaches included in FreeSurfer - ASEG and SAMSEG.

机构信息

Center for Lifespan Changes in Brain and Cognition, University of Oslo, Pb. 1094, Blindern, Oslo 0317, Norway.

Center for Lifespan Changes in Brain and Cognition, University of Oslo, Pb. 1094, Blindern, Oslo 0317, Norway.

出版信息

Neuroimage. 2021 Aug 15;237:118113. doi: 10.1016/j.neuroimage.2021.118113. Epub 2021 May 1.

DOI:10.1016/j.neuroimage.2021.118113
PMID:33940143
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9052126/
Abstract

Accurate and reliable whole-brain segmentation is critical to longitudinal neuroimaging studies. We undertake a comparative analysis of two subcortical segmentation methods, Automatic Segmentation (ASEG) and Sequence Adaptive Multimodal Segmentation (SAMSEG), recently provided in the open-source neuroimaging package FreeSurfer 7.1, with regard to reliability, bias, sensitivity to detect longitudinal change, and diagnostic sensitivity to Alzheimer's disease. First, we assess intra- and inter-scanner reliability for eight bilateral subcortical structures: amygdala, caudate, hippocampus, lateral ventricles, nucleus accumbens, pallidum, putamen and thalamus. For intra-scanner analysis we use a large sample of participants (n = 1629) distributed across the lifespan (age range = 4-93 years) and acquired on a 1.5T Siemens Avanto (n = 774) and a 3T Siemens Skyra (n = 855) scanners. For inter-scanner analysis we use a sample of 24 participants scanned on the day with three models of Siemens scanners: 1.5T Avanto, 3T Skyra and 3T Prisma. Second, we test how each method detects volumetric age change using longitudinal follow up scans (n = 491 for Avanto and n = 245 for Skyra; interscan interval = 1-10 years). Finally, we test sensitivity to clinically relevant change. We compare annual rate of hippocampal atrophy in cognitively normal older adults (n = 20), patients with mild cognitive impairment (n = 20) and Alzheimer's disease (n = 20). We find that both ASEG and SAMSEG are reliable and lead to the detection of within-person longitudinal change, although with notable differences between age-trajectories for most structures, including hippocampus and amygdala. In summary, SAMSEG yields significantly lower differences between repeated measures for intra- and inter-scanner analysis without compromising sensitivity to changes and demonstrating ability to detect clinically relevant longitudinal changes.

摘要

准确可靠的全脑分割对于纵向神经影像学研究至关重要。我们对两种皮质下分割方法(自动分割(ASEG)和序列自适应多模态分割(SAMSEG))进行了比较分析,这两种方法最近在开源神经影像学软件包 FreeSurfer 7.1 中提供,涉及可靠性、偏差、检测纵向变化的敏感性以及阿尔茨海默病的诊断敏感性。首先,我们评估了 8 个双侧皮质下结构的内扫描和跨扫描可靠性:杏仁核、尾状核、海马体、侧脑室、伏隔核、苍白球、壳核和丘脑。对于内扫描分析,我们使用了分布在整个生命周期(年龄范围为 4-93 岁)的大量参与者样本(n=1629),这些样本分别在 1.5T 西门子 Avanto(n=774)和 3T 西门子 Skyra(n=855)扫描仪上采集。对于跨扫描分析,我们使用了 24 名参与者的样本,这些参与者在同一天使用三种西门子扫描仪模型(1.5T Avanto、3T Skyra 和 3T Prisma)进行扫描。其次,我们测试了每种方法如何使用纵向随访扫描检测容积年龄变化(Avanto 有 n=491,Skyra 有 n=245;扫描间隔为 1-10 年)。最后,我们测试了对临床相关变化的敏感性。我们比较了认知正常的老年参与者(n=20)、轻度认知障碍患者(n=20)和阿尔茨海默病患者(n=20)的海马体每年萎缩率。我们发现,ASEG 和 SAMSEG 都是可靠的,并且可以检测到个体内的纵向变化,尽管大多数结构(包括海马体和杏仁核)的年龄轨迹存在明显差异。总之,SAMSEG 在内扫描和跨扫描分析中显著降低了重复测量之间的差异,而不影响对变化的敏感性,并证明了检测临床相关纵向变化的能力。

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本文引用的文献

1
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2
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3
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4
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bioRxiv. 2025 Feb 20:2024.06.03.592804. doi: 10.1101/2024.06.03.592804.
5
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6
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5
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6
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9
Neurodevelopmental origins of lifespan changes in brain and cognition.大脑与认知寿命变化的神经发育起源
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10
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