Connectomics in neuroImaging : third International Workshop, CNI 2019, held in conjunction with MICCAI 2019, Shenzhen, China, October 13, 2019, Proceedings. CNI (Workshop) (3rd : 2019 : Shenzhen Shi, China)最新文献

英文中文

Rapid Acceleration of the Permutation Test via Transpositions. 通过换位快速加速置换检验。

Connectomics in neuroImaging : third International Workshop, CNI 2019, held in conjunction with MICCAI 2019, Shenzhen, China, October 13, 2019, Proceedings. CNI (Workshop) (3rd : 2019 : Shenzhen Shi, China)

Pub Date : 2019-10-01 Epub Date: 2019-10-10 DOI: 10.1007/978-3-030-32391-2_5

Moo K Chung, Linhui Xie, Shih-Gu Huang, Yixian Wang, Jingwen Yan, Li Shen

The permutation test is an often used test procedure for determining statistical significance in brain network studies. Unfortunately, generating every possible permutation for large-scale brain imaging datasets such as HCP and ADNI with hundreds of subjects is not practical. Many previous attempts at speeding up the permutation test rely on various approximation strategies such as estimating the tail distribution with known parametric distributions. In this study, we propose the novel transposition test that exploits the underlying algebraic structure of the permutation group. The method is applied to a large number of diffusion tensor images in localizing the regions of the brain network differences.

排列检验是确定脑网络研究中统计显著性的常用检验方法。不幸的是，为大规模脑成像数据集(如HCP和ADNI)生成所有可能的排列是不现实的。许多先前的加速置换检验的尝试依赖于各种近似策略，例如用已知的参数分布估计尾部分布。在这项研究中，我们提出了利用置换群的潜在代数结构的新的置换检验。将该方法应用于大量弥散张量图像中，用于脑网络差异区域的定位。

引用次数: 24

Covariance Shrinkage for Dynamic Functional Connectivity. 动态功能连接的协方差收缩

Pub Date : 2019-10-01 Epub Date: 2019-10-10 DOI: 10.1007/978-3-030-32391-2_4

Nicolas Honnorat, Ehsan Adeli, Qingyu Zhao, Adolf Pfefferbaum, Edith V Sullivan, Kilian Pohl

The tracking of dynamic functional connectivity (dFC) states in resting-state fMRI scans aims to reveal how the brain sequentially processes stimuli and thoughts. Despite the recent advances in statistical methods, estimating the high dimensional dFC states from a small number of available time points remains a challenge. This paper shows that the challenge is reduced by linear covariance shrinkage, a statistical method used for the estimation of large covariance matrices from small number of samples. We present a computationally efficient formulation of our approach that scales dFC analysis up to full resolution resting-state fMRI scans. Experiments on synthetic data demonstrate that our approach produces dFC estimates that are closer to the ground-truth than state-of-the-art estimation approaches. When comparing methods on the rs-fMRI scans of 162 subjects, we found that our approach is better at extracting functional networks and capturing differences in rs-fMRI acquisition and diagnosis.

对静息态 fMRI 扫描中的动态功能连接（dFC）状态进行追踪，旨在揭示大脑如何有序地处理刺激和思维。尽管最近统计方法取得了进步，但从少量可用时间点估算高维 dFC 状态仍然是一项挑战。本文介绍了线性协方差收缩法，这是一种用于从少量样本中估计大协方差矩阵的统计方法。我们提出了一种计算高效的方法，可将 dFC 分析扩展到全分辨率静息态 fMRI 扫描。对合成数据的实验证明，我们的方法产生的 dFC 估计值比最先进的估计方法更接近地面实况。在对 162 名受试者的 rs-fMRI 扫描进行方法比较时，我们发现我们的方法在提取功能网络和捕捉 rs-fMRI 采集与诊断差异方面更胜一筹。

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引用次数: 0

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