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<figure class='table'><table class='ck-table-resized' style='border-collapse:collapse;font-family:Calibri;font-size:11pt;table-layout:fixed;' cellspacing='0' cellpadding='0' dir='ltr' border='1' data-sheets-root='1' data-sheets-baot='1'><colgroup><col style='width:25%;' width='246'><col style='width:25%;' width='218'><col style='width:25%;' width='235'><col style='width:25%;' width='354'></colgroup><tbody><tr style='height:20px;'><td style='color:#1a202c;overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>NIRS measurement system with probe sets and probe holder grids</td><td style='color:#1a202c;overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>Hitachi Medical Corporation, Tokyo, Japan</td><td style='color:#1a202c;overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>ETG-4000 Optical Topography System&#160;</td><td style='color:#1a202c;overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>The current study protocol requires an optional second adult probe set for 52 channels of measurement in total as well as two 3x5 probe holder grids.&#160;</td></tr><tr style='height:20px;'><td style='color:#1a202c;overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>raw EEG caps</td><td style='color:#1a202c;overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>EASYCAP GmbH, Herrsching, Germany</td><td style='color:#1a202c;overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>C-SCMS-56; C-SCMS-58</td><td style='color:#1a202c;overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>Caps must be provided with holes for NIRS probes by the experimenter. Choose cap size the same size or slightly larger than participant's head circumference.</td></tr><tr style='height:20px;'><td style='color:#1a202c;overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>Technical computing software</td><td style='color:#1a202c;overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>The MathWorks, Inc., Natick, MA</td><td style='color:#1a202c;overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>MATLAB R2014a (or later versions)</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>Serves as base for Psychophysics Toolbox extensions (stimulus presentation), SPM for fNIRS toolbox&#160; (fNIRS data analysis), and ASToolbox (WTC computation).</td></tr></tbody></table></figure>

functional near-infrared spectroscopy for recording brain activity during social interactions

Source:&#160;<a style='text-decoration:none;' href='https://dx.doi.org/10.3791/58807'><span style='-webkit-text-decoration-skip:none;font-family:Arial,sans-serif;font-size:12pt;font-style:normal;font-variant:normal;font-weight:400;text-decoration-skip-ink:none;vertical-align:baseline;white-space:pre-wrap;'>Reindl, V.,&#160;et al<span style='-webkit-text-decoration-skip:none;font-family:Arial,sans-serif;font-size:12pt;font-style:normal;font-variant:normal;font-weight:400;text-decoration-skip-ink:none;vertical-align:baseline;white-space:pre-wrap;'>. Conducting Hyperscanning Experiments with Functional Near-Infrared Spectroscopy. J. Vis. Exp. (2019)</a> &#160;This video demonstrates the use of functional near-infrared spectroscopy (fNIRS) to measure brain activity during social interactions. Participants engage in a coordinated task that increases activity in the prefrontal cortex, a region critical for social behavior, while the system detects changes in light absorption due to blood oxygenation. By analyzing the synchrony of brain activity between participants, the study assesses neural dynamics underlying social interaction.

Functional Near-Infrared Spectroscopy for Recording Brain Activity During Social Interactions

Source:&#160;Reindl, V.,&#160;et al. Conducting Hyperscanning Experiments with Functional Near-Infrared Spectroscopy. J. Vis. Exp. (2019)&#160;This video ...

Begin with a parent-child dyad fitted with probe grids of a functional near-infrared spectroscopy, or fNIRS, system and positioned in front of a shared display.Emitter probes in the grid emit near-infrared light, which penetrates brain tissue.As a baseline, when no stimulus is present, the blood in the cerebral vessels maintains normal metabolic oxygen levels.Record the baseline activity by measuring the reflected light detected by the detector probes.Introduce a visual stimulus that requires the participants to respond by pressing buttons in either cooperation or competition, resulting in increased activity in the prefrontal cortex, a brain region crucial for social interaction.Increased neuronal activity elevates the metabolic oxygen demand, triggering the flow of oxygenated blood carrying oxyhemoglobin.A change in light absorption by the increased oxyhemoglobin reflects the increased activity.Analyze the co-occurrence of increased activity between the participants during the task to assess brain-to-brain synchrony.

functional-near-infrared-spectroscopy-for-recording-brain-activity

Universidad Científica del Sur

Research

JoVE Encyclopedia of Experiments

Neuroscience

Neuroimaging

Structural & Functional Brain Imaging

19 Views. Source: Reindl, V., et al. Conducting Hyperscanning Experiments with Functional Near-Infrared Spectroscopy. J. Vis. Exp. (2019)  This video demonstrates the use of functional near-infrared spectroscopy (fNIRS) to measure brain activity during social interactions. Participants engage in a coordinated task that increases activity in the prefrontal cortex, a region critical for social behavior, while the system detects changes in light absorption due to blood oxygenation. By analyzin...

Video: Functional Near-Infrared Spectroscopy for Recording Brain Activity During Social Interactions - Concept

O-cresol Concentration Online Measurement Based On Near Infrared Spectroscopy Via Partial Least Square Regression

Unlike macroscopic process variables, near-infrared spectroscopy provides process information at the molecular level and can significantly improve the prediction of the components in industrial processes. The ability to record spectra for solid and liquid samples without any pretreatment is advantageous and the method is widely used. However, the disadvantages of analyzing high-dimensional near-infrared spectral data include information redundancy and multicollinearity of the spectral data. Thus, we propose to use partial least squares regression method, which has traditionally been used to reduce the data dimensionality and eliminate the collinearity between the original features. We implement the method for predicting the o-cresol concentration during the production of polyphenylene ether. The proposed approach offers the following advantages over component regression prediction methods: 1) partial least squares regression solves the multicollinearity problem of the independent variables and effectively avoids overfitting, which occurs in a regression analysis due to the high correlation between the independent variables; 2) the use of the near-infrared spectra results in high accuracy because it is a non-destructive and non-polluting method to obtain information at microscopic and molecular scales.

The protocol describes a method of predicting o-cresol concentration during the production of polyphenylene ether using near-infrared spectroscopy and partial least squares regression. To describe the process more clearly and completely, an example of predicting the o-cresol concentration during the production of polyphenylene is used to clarify the steps.

Unlike macroscopic process variables, near-infrared spectroscopy provides process information at the molecular level and can significantly improve the ...

JoVE Journal

Engineering

Qualitative and Comparative Cortical Activity Data Analyses from a Functional Near-Infrared Spectroscopy Experiment Applying Block Design

Neuroimaging studies play a pivotal role in the evaluation of pre- vs. post-interventional neurological conditions such as in rehabilitation and surgical treatment. Among the many neuroimaging technologies used to measure brain activity, functional near-infrared spectroscopy (fNIRS) enables the evaluation of dynamic cortical activities by measuring the local hemoglobin levels similar to functional magnetic resonance imaging (fMRI). Also, due to lesser physical restriction in fNIRS, multiple variants of sensorimotor tasks can be evaluated. Many laboratories have developed several methods for fNIRS data analysis; however, despite the fact that the general principles are the same, there is no universally standardized method. Here, we present the qualitative and comparative analytic methods of data obtained from a multi-channel fNIRS experiment using a block design. For qualitative analysis, we used a software for NIRS as a mass-univariate approach based on the generalized linear model. The NIRS-SPM analysis shows qualitative results for each session by visualizing the activated area during the task. In addition, the non-invasive three-dimensional digitizer can be used to estimate the fNIRS channel locations relative to the brain. To corroborate the NIRS-SPM findings, the amplitude of the changes in hemoglobin levels induced by the sensorimotor task can be statistically analyzed by comparing the data obtained from two different sessions (before and after intervention) of the same study subject using a multi-channel hierarchical mixed model. Our methods can be used to measure the pre- vs. post-intervention analysis in a variety of neurological disorders such as movement disorders, cerebrovascular diseases, and neuropsychiatric disorders.

We describe the analysis of continuous-wave functional near-infrared spectroscopy experiment using a block design with a sensorimotor task. To increase the reliability of the data analysis, we used the qualitative general linear model-based statistical parametric mapping and the comparative hierarchical mixed models for multi-channels.

Neuroimaging studies play a pivotal role in the evaluation of pre- vs. post-interventional neurological conditions such as in rehabilitation and surgical ...

Group Synchronization During Collaborative Drawing Using Functional Near-Infrared Spectroscopy

Functional near-infrared spectroscopy (fNIRS) is a noninvasive method particularly suitable for measuring cerebral cortex activation in multiple subjects, which is relevant for studying group interpersonal interactions in ecological settings. Although many fNIRS systems technically offer the possibility to monitor more than two individuals simultaneously, establishing easy-to-implement setup procedures and reliable paradigms to track hemodynamic and behavioral responses in group interaction is still required. The present protocol combines fNIRS and video-based observation to measure interpersonal synchronization in quartets during a cooperative task.This protocol provides practical recommendations for data acquisition and paradigm design, as well as guiding principles for an illustrative data analysis example. The procedure is designed to assess differences in brain and behavior interpersonal responses between social and non-social conditions inspired by a well-known ice-breaker activity, the Collaborative Face Drawing Task. The described procedures can guide future studies to adapt group naturalistic social interaction activities to the fNIRS environment.

The present protocol combines functional near-infrared spectroscopy (fNIRS) and video-based observationto measure interpersonal synchronization in quartets during a collaborative drawing task.

Functional near-infrared spectroscopy (fNIRS) is a noninvasive method particularly suitable for measuring cerebral cortex activation in multiple subjects, ...

Functional Near-Infrared Spectroscopy for Recording Brain Activity During Social Interactions

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Functional Near-Infrared Spectroscopy for Recording Brain Activity During Social Interactions

O-cresol Concentration Online Measurement Based On Near Infrared Spectroscopy Via Partial Least Square Regression

Qualitative and Comparative Cortical Activity Data Analyses from a Functional Near-Infrared Spectroscopy Experiment Applying Block Design

Group Synchronization During Collaborative Drawing Using Functional Near-Infrared Spectroscopy