Human Brain Mapping based on COLD Signal Hemodynamic Response and Electrical Neuroimaging

TL;DR

This paper discusses a non-invasive, multimodal approach combining COLD signal hemodynamic response and electrical neuroimaging to map brain activity, leveraging the strengths of EEG and NIRS for detailed spatio-temporal neural analysis.

Contribution

It introduces an integrated method using EEG and NIRS to improve brain mapping by overcoming individual modality limitations and enhancing understanding of neural functions.

Findings

EEG and NIRS integration provides high temporal and spatial resolution.

Combined modality offers more comprehensive brain activity insights.

Method enhances detection of neural dynamics during complex tasks.

Abstract

To understand Working of Human Brain measurements related to the brain function are required. These measurements should be possibly non-invasive. Brain should be disturbed as less as possible during the measurement. Integration of various modalities plays a vital role in understanding the cognitive and the behavioral changes in the human brain. It is an important source of converging evidence about specific aspects of neural functions and dysfunctions under certain pathological conditions. Focal changes in cortical blood flow are tightly coupled with the changes in neuronal activity. This constitutes the option to map the hemodynamic response and infer principles of the cortical processing, even of complex tasks. The very high temporal resolution of EEG and good spatial resolution by NIRS make this concurrent measurement unique to study the spatio-temporal dynamics of large scale neuronal networks in the human brain. Such integration of two techniques will help to overcome the limitations of a specific method. Such as insensitivity of electroencephalogram (EEG) to unsynchronized neural events or lack of near infrared spectroscopy (NIRS) to low metabolic demand. A combination of EEG and NIRS will be more informative than the two separate analyses in both modalities.