电磁脑成像分布式源的鲁棒经验贝叶斯重构

IF 8.9 1区医学 Q1 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS

IEEE Transactions on Medical Imaging Pub Date : 2020-03-01 Epub Date: 2019-07-31 DOI:10.1109/TMI.2019.2932290

Chang Cai, Mithun Diwakar, Dan Chen, Kensuke Sekihara, Srikantan S Nagarajan

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引用次数: 0

摘要

电磁脑成像是从磁场和电势的非侵入性记录中重建大脑活动。在这种成像模式中，一个持久的挑战是估计来源的数量、位置和时间进程，特别是对于具有复杂空间范围的分布式脑来源的重建。在这里，我们介绍了一种新的鲁棒经验贝叶斯算法，该算法利用两个关键思想：核平滑和超参数平铺，能够更好地重建分布式脑源活动。由于所提出的算法建立在稀疏源重建算法Champagne的许多性能特征的基础上，因此我们将该算法称为平滑香槟算法。Smooth Champagne对高水平的噪音、干扰和高度相关的脑源活动的影响很强。仿真表明，与基准算法相比，Smooth Champagne在准确确定分布式源活动的空间范围方面表现出色。Smooth Champagne还可以准确地重建真实的脑磁图和脑电图数据。

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Robust Empirical Bayesian Reconstruction of Distributed Sources for Electromagnetic Brain Imaging.

Electromagnetic brain imaging is the reconstruction of brain activity from non-invasive recordings of the magnetic fields and electric potentials. An enduring challenge in this imaging modality is estimating the number, location, and time course of sources, especially for the reconstruction of distributed brain sources with complex spatial extent. Here, we introduce a novel robust empirical Bayesian algorithm that enables better reconstruction of distributed brain source activity with two key ideas: kernel smoothing and hyperparameter tiling. Since the proposed algorithm builds upon many of the performance features of the sparse source reconstruction algorithm - Champagne and we refer to this algorithm as Smooth Champagne. Smooth Champagne is robust to the effects of high levels of noise, interference, and highly correlated brain source activity. Simulations demonstrate excellent performance of Smooth Champagne when compared to benchmark algorithms in accurately determining the spatial extent of distributed source activity. Smooth Champagne also accurately reconstructs real MEG and EEG data.

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来源期刊

IEEE Transactions on Medical Imaging 医学-成像科学与照相技术

CiteScore

21.80

自引率

5.70%

发文量

637

审稿时长

5.6 months

期刊介绍： The IEEE Transactions on Medical Imaging (T-MI) is a journal that welcomes the submission of manuscripts focusing on various aspects of medical imaging. The journal encourages the exploration of body structure, morphology, and function through different imaging techniques, including ultrasound, X-rays, magnetic resonance, radionuclides, microwaves, and optical methods. It also promotes contributions related to cell and molecular imaging, as well as all forms of microscopy. T-MI publishes original research papers that cover a wide range of topics, including but not limited to novel acquisition techniques, medical image processing and analysis, visualization and performance, pattern recognition, machine learning, and other related methods. The journal particularly encourages highly technical studies that offer new perspectives. By emphasizing the unification of medicine, biology, and imaging, T-MI seeks to bridge the gap between instrumentation, hardware, software, mathematics, physics, biology, and medicine by introducing new analysis methods. While the journal welcomes strong application papers that describe novel methods, it directs papers that focus solely on important applications using medically adopted or well-established methods without significant innovation in methodology to other journals. T-MI is indexed in Pubmed® and Medline®, which are products of the United States National Library of Medicine.