Reliability and similarity of resting state functional connectivity networks imaged using wearable, high-density diffuse optical tomography in the home setting
Reliability and similarity of resting state functional connectivity networks imaged using wearable, high-density diffuse optical tomography in the home setting
Background: When characterizing the brain's resting state functional connectivity (RSFC) networks, demonstrating networks' similarity across sessions and reliability across different scan durations is essential for validating results and possibly minimizing the scanning time needed to obtain stable measures of RSFC. Recent advances in optical functional neuroimaging technologies have resulted in fully wearable devices that may serve as a complimentary tool to functional magnetic resonance imaging (fMRI) and allow for investigations of RSFC networks repeatedly and easily in non-traditional scanning environments. Methods: Resting-state cortical hemodynamic activity was repeatedly measured in a single individual in the home environment during COVID-19 lockdown conditions using the first ever application of a 24-module (72 sources, 96 detectors) wearable high-density diffuse optical tomography (HD-DOT) system. Twelve-minute recordings of resting-state data were acquired over the pre-frontal and occipital regions in fourteen experimental sessions over three weeks. As an initial validation of the data, spatial independent component analysis was used to identify RSFC networks. Reliability and similarity scores were computed using metrics adapted from the fMRI literature. Results: We observed RSFC networks over visual regions (visual peripheral, visual central networks) and higher-order association regions (control, salience and default mode network), consistent with previous fMRI literature. High similarity was observed across testing sessions and across chromophores (oxygenated and deoxygenated haemoglobin, HbO and HbR) for all functional networks, and for each network considered separately. Stable reliability values (described here as a <10% change between time windows) were obtained for HbO and HbR with differences in required scanning time observed on a network-by-network basis. Discussion: Using RSFC data from a highly sampled individual, the present work demonstrates that wearable HD-DOT can be used to obtain RSFC measurements with high similarity across imaging sessions and reliability across recording durations in the home environment. Wearable HD-DOT may serve as a complimentary tool to fMRI for studying RSFC networks outside of the traditional scanning environment and in vulnerable populations for whom fMRI is not feasible.
Functional brain networks, HD-DOT, High-density diffuse optical tomography, Home setting, Reliability, Resting-state functional connectivity, Similarity, Wearable neuroimaging
Uchitel, Julie
cccd2dab-6dfe-427e-8321-52b9027dd5d7
Blanco, Borja
8996dee4-3d49-4388-96d9-0a5b978ca8bd
Vidal-Rosas, Ernesto
1da82633-b581-468e-b41a-117b6893a84d
Collins-Jones, Liam
feb485c6-6722-4b97-8be7-c0b1fdd9cd18
Cooper, Robert J.
e44d8765-b9b9-402c-b6fe-6bc9288051f7
1 November 2022
Uchitel, Julie
cccd2dab-6dfe-427e-8321-52b9027dd5d7
Blanco, Borja
8996dee4-3d49-4388-96d9-0a5b978ca8bd
Vidal-Rosas, Ernesto
1da82633-b581-468e-b41a-117b6893a84d
Collins-Jones, Liam
feb485c6-6722-4b97-8be7-c0b1fdd9cd18
Cooper, Robert J.
e44d8765-b9b9-402c-b6fe-6bc9288051f7
Uchitel, Julie, Blanco, Borja, Vidal-Rosas, Ernesto, Collins-Jones, Liam and Cooper, Robert J.
(2022)
Reliability and similarity of resting state functional connectivity networks imaged using wearable, high-density diffuse optical tomography in the home setting.
NeuroImage, 263, [119663].
(doi:10.1016/j.neuroimage.2022.119663).
Abstract
Background: When characterizing the brain's resting state functional connectivity (RSFC) networks, demonstrating networks' similarity across sessions and reliability across different scan durations is essential for validating results and possibly minimizing the scanning time needed to obtain stable measures of RSFC. Recent advances in optical functional neuroimaging technologies have resulted in fully wearable devices that may serve as a complimentary tool to functional magnetic resonance imaging (fMRI) and allow for investigations of RSFC networks repeatedly and easily in non-traditional scanning environments. Methods: Resting-state cortical hemodynamic activity was repeatedly measured in a single individual in the home environment during COVID-19 lockdown conditions using the first ever application of a 24-module (72 sources, 96 detectors) wearable high-density diffuse optical tomography (HD-DOT) system. Twelve-minute recordings of resting-state data were acquired over the pre-frontal and occipital regions in fourteen experimental sessions over three weeks. As an initial validation of the data, spatial independent component analysis was used to identify RSFC networks. Reliability and similarity scores were computed using metrics adapted from the fMRI literature. Results: We observed RSFC networks over visual regions (visual peripheral, visual central networks) and higher-order association regions (control, salience and default mode network), consistent with previous fMRI literature. High similarity was observed across testing sessions and across chromophores (oxygenated and deoxygenated haemoglobin, HbO and HbR) for all functional networks, and for each network considered separately. Stable reliability values (described here as a <10% change between time windows) were obtained for HbO and HbR with differences in required scanning time observed on a network-by-network basis. Discussion: Using RSFC data from a highly sampled individual, the present work demonstrates that wearable HD-DOT can be used to obtain RSFC measurements with high similarity across imaging sessions and reliability across recording durations in the home environment. Wearable HD-DOT may serve as a complimentary tool to fMRI for studying RSFC networks outside of the traditional scanning environment and in vulnerable populations for whom fMRI is not feasible.
Text
1-s2.0-S1053811922007844-main
- Version of Record
More information
Accepted/In Press date: 2 October 2022
e-pub ahead of print date: 4 October 2022
Published date: 1 November 2022
Additional Information:
Publisher Copyright:
© 2022
Keywords:
Functional brain networks, HD-DOT, High-density diffuse optical tomography, Home setting, Reliability, Resting-state functional connectivity, Similarity, Wearable neuroimaging
Identifiers
Local EPrints ID: 488986
URI: http://eprints.soton.ac.uk/id/eprint/488986
ISSN: 1053-8119
PURE UUID: fc00e125-fd1e-446a-8383-9ee538ecc5e6
Catalogue record
Date deposited: 10 Apr 2024 16:40
Last modified: 11 Apr 2024 02:06
Export record
Altmetrics
Contributors
Author:
Julie Uchitel
Author:
Borja Blanco
Author:
Ernesto Vidal-Rosas
Author:
Liam Collins-Jones
Author:
Robert J. Cooper
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics