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基于多分辨率图的局部解剖特征的体积皮质基函数。

Multi-Resolution Graph Based Volumetric Cortical Basis Functions From Local Anatomic Features.

出版信息

IEEE Trans Biomed Eng. 2019 Dec;66(12):3381-3392. doi: 10.1109/TBME.2019.2904473. Epub 2019 Mar 13.

DOI:10.1109/TBME.2019.2904473
PMID:30872218
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6995658/
Abstract

OBJECTIVE

Modern clinical MRI collects millimeter scale anatomic information, but scalp electroencephalography source localization is ill posed, and cannot resolve individual sources at that resolution. Dimensionality reduction in the space of cortical sources is needed to improve computational and storage complexity, yet volumetric methods still employ simplistic grid coarsening that eliminates fine scale anatomic structure. We present an approach to extend near-arbitrary spatial scaling to volumetric localization.

METHODS

Starting from a voxelwise brain parcellation, sub-parcels are identified from local cortical connectivity with an iterated graph cut approach. Spatial basis functions in each parcel are constructed using either a decomposition of the local leadfield matrix or spectral basis functions of local cortical connectivity graphs.

RESULTS

We present quantitative evaluation with extensive simulations and use multiple sets of real data to highlight how parameter changes impact computed reconstructions. Our results show that volumetric basis functions can improve accuracy by as much as 30%, while reducing computational complexity by over two orders of magnitude. In real data from epilepsy surgical candidates, accurate localization of seizure onset regions is demonstrated.

CONCLUSION

Spatial dimensionality reduction with volumetric basis functions improves reconstruction accuracy while reducing computational complexity.

SIGNIFICANCE

Near-arbitrary spatial dimensionality reduction will enable volumetric reconstruction with modern computationally intensive algorithms and anatomically driven multi-resolution methods.

摘要

目的

现代临床 MRI 可采集毫米级解剖学信息,但头皮脑电图源定位存在不适定性问题,无法在该分辨率下解析单个源。需要降低皮质源空间的维数以降低计算和存储复杂度,但体积方法仍然采用简单的网格细化,消除了精细的解剖结构。我们提出了一种将近乎任意空间比例扩展到体积定位的方法。

方法

从体素脑分割开始,使用迭代图割方法从局部皮质连接中识别出次体素。在每个体素中使用局部引导场矩阵的分解或局部皮质连接图的谱基函数构建空间基函数。

结果

我们通过广泛的模拟进行了定量评估,并使用多组真实数据突出了参数变化如何影响计算重建。我们的结果表明,体积基函数可以将准确性提高多达 30%,同时将计算复杂度降低两个数量级以上。在癫痫手术候选者的真实数据中,演示了发作起始区域的准确定位。

结论

使用体积基函数进行空间维数降低可提高重建准确性,同时降低计算复杂度。

意义

近乎任意的空间维数降低将使具有现代计算密集型算法和解剖驱动的多分辨率方法的体积重建成为可能。

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