Peaglet: A user-friendly probabilistic Kernel density estimation of intracranial cortical and subcortical stimulation sites

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS

ACS Applied Bio Materials Pub Date : 2024-05-23 DOI:10.1016/j.jneumeth.2024.110177

Andrea Bellacicca , Marco Rossi , Luca Viganò , Luciano Simone , Henrietta Howells , Matteo Gambaretti , Alberto Gallotti , Antonella Leonetti , Guglielmo Puglisi , Francesca Talami , Lorenzo Bello , Cerri Gabriella , Luca Fornia

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引用次数: 0

Abstract

Background

Data on human brain function obtained with direct electrical stimulation (DES) in neurosurgical patients have been recently integrated and combined with modern neuroimaging techniques, allowing a connectome-based approach fed by intraoperative DES data. Within this framework is crucial to develop reliable methods for spatial localization of DES-derived information to be integrated within the neuroimaging workflow.

New method

To this aim, we applied the Kernel Density Estimation for modelling the distribution of DES sites from different patients into the MNI space. The algorithm has been embedded in a MATLAB-based User Interface, Peaglet. It allows an accurate probabilistic weighted and unweighted estimation of DES sites location both at cortical level, by using shortest path calculation along the brain 3D geometric topology, and subcortical level, by using a volume-based approach.

Results

We applied Peaglet to investigate spatial estimation of cortical and subcortical stimulation sites provided by recent brain tumour studies. The resulting NIfTI maps have been anatomically investigated with neuroimaging open-source tools.

Comparison with existing methods

Peaglet processes differently cortical and subcortical data following their distinguishing geometrical features, increasing anatomical specificity of DES-related results and their reliability within neuroimaging environments.

Conclusions

Peaglet provides a robust probabilistic estimation of the cortical and subcortical distribution of DES sites going beyond a region of interest approach, respecting cortical and subcortical intrinsic geometrical features. Results can be easily integrated within the neuroimaging workflow to drive connectomic analysis.

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peaglet：对颅内皮层和皮层下刺激点进行概率核密度估计的用户友好型工具

背景通过对神经外科患者进行直接电刺激（DES）获得的人脑功能数据最近已与现代神经影像学技术相结合，实现了以术中 DES 数据为基础的连通组方法。为此，我们应用核密度估计法（Kernel Density Estimation）将不同患者的 DES 位置分布建模到 MNI 空间。该算法已嵌入基于 MATLAB 的用户界面 Peaglet。通过沿大脑三维几何拓扑的最短路径计算，该算法可在皮层水平和皮层下水平准确估算出DES刺激点位置的加权和非加权概率。与现有方法的比较Peaglet根据皮层和皮层下的不同几何特征，对皮层和皮层下数据进行了不同的处理，提高了DES相关结果的解剖特异性和在神经成像环境中的可靠性。结果可轻松集成到神经成像工作流程中，以推动连接组学分析。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

ACS Applied Bio Materials Chemistry-Chemistry (all)

CiteScore

9.40

自引率

2.10%

发文量

464