用于多模态功能近红外光谱和脑电图的共定位光电极设计

Co-localized optode-electrode design for multimodal functional near infrared spectroscopy and electroencephalography.

作者信息

Rogers De'Ja, O'Brien Walker Joseph, Gao Yuanyuan, Zimmermann Bernhard, Grover Shrey, Zhang Yiwen, Gaona Anna Kawai, Duwadi Sudan, Anderson Jessica E, Carlton Laura, Rahimi Parisa, Farzam Parya Y, von Lühmann Alexander, Reinhart Robert M G, Boas David A, Yücel Meryem A

机构信息

Boston University, Neurophotonics Center, Department of Biomedical Engineering, Boston, Massachusetts, United States.

Boston University, Department of Electrical and Computer Engineering, Boston, Massachusetts, Unites States.

出版信息

Neurophotonics. 2025 Apr;12(2):025006. doi: 10.1117/1.NPh.12.2.025006. Epub 2025 Apr 8.

DOI:10.1117/1.NPh.12.2.025006

PMID:40201225

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11978466/

Abstract

SIGNIFICANCE

Neuroscience of the everyday world requires continuous mobile brain imaging in real time and in ecologically valid environments, which aids in directly translating research for human benefit. Combined functional near-infrared spectroscopy (fNIRS) and electroencephalography (EEG) studies have increased in demand, as the combined systems can provide great insights into cortical hemodynamics, neuronal activity, and neurovascular coupling. However, fNIRS-EEG studies remain limited in modularity and portability due to restrictions in combined cap designs, especially for high-density (HD) fNIRS measurements.

AIM

We have built and tested custom fNIRS sources that attach to electrodes without decreasing the overall modularity and portability of the probe.

APPROACH

To demonstrate the design's utility, we screened for any potential interference and performed a HD-fNIRS-EEG measurement with co-located opto-electrode positions during a modified Stroop task.

RESULTS

No observable interference was present from the fNIRS source optodes in the EEG spectral analysis. The performance, fNIRS, and EEG results of the Stroop task supported the trends from previous research. We observed increased activation with both fNIRS and EEG within the regions of interest.

CONCLUSION

Overall, these results suggest that the co-localization method is a promising approach to multimodal imaging.

摘要

意义

日常世界的神经科学需要在真实且符合生态效度的环境中进行连续实时的移动脑成像，这有助于将研究直接转化为对人类有益的成果。功能近红外光谱（fNIRS）与脑电图（EEG）相结合的研究需求不断增加，因为这种组合系统能够深入洞察皮层血流动力学、神经元活动以及神经血管耦合。然而，由于组合帽设计的限制，尤其是对于高密度（HD）fNIRS测量而言，fNIRS - EEG研究在模块化和便携性方面仍然受限。

目的

我们构建并测试了可连接到电极上的定制fNIRS光源，且不降低探头的整体模块化和便携性。

方法

为了证明该设计的实用性，我们筛查了任何潜在干扰，并在改良的斯特鲁普任务期间，在光电极位置共定位的情况下进行了HD - fNIRS - EEG测量。

结果

在脑电图频谱分析中，未观察到来自fNIRS光源光极的明显干扰。斯特鲁普任务的表现、fNIRS和脑电图结果支持了先前研究的趋势。我们观察到在感兴趣区域内，fNIRS和脑电图均出现激活增加。

结论

总体而言，这些结果表明共定位方法是一种有前景的多模态成像方法。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/5e85/11978466/6ebca3d000fe/NPh-012-025006-g001.jpg

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用于多模态功能近红外光谱和脑电图的共定位光电极设计

Co-localized optode-electrode design for multimodal functional near infrared spectroscopy and electroencephalography.

作者信息

机构信息

出版信息

SIGNIFICANCE

AIM

APPROACH

RESULTS

CONCLUSION

意义

目的

方法

结果

结论

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