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Lateralization of cortical activity, networks, and hemodynamic lag after stroke: A resting‐state <scp>fNIRS</scp> study

Gongcheng Xu, Tiandi Chen, Jiahui Yin, Guangjian Shao, Yubo Fan, Zengyong Li

2024Journal of Biophotonics10 citationsDOI

Abstract

Focal damage due to stroke causes widespread abnormal changes in brain function and hemispheric asymmetry. In this study, functional near-infrared spectroscopy (fNIRS) was used to collect resting-state hemoglobin data from 85 patients with subacute stroke and 26 healthy controls, to comparatively analyze the characteristics of lateralization after stroke in terms of cortical activity, functional networks, and hemodynamic lags. Higher intensity of motor cortical activity, lower hemispheric autonomy, and more abnormal hemodynamic leads or lags were found in the affected hemisphere. Lateralization metrics of the three aspects were all associated with the Fugl-Meyer score. The results of this study prove that three lateralization metrics may provide clinical reference for stroke rehabilitation. Meanwhile, the present study piloted the use of resting-state fNIRS for analyzing hemodynamic lag, demonstrating the potential of fNIRS to assess hemodynamic abnormalities in addition to the study of cortical neurological function after stroke.

Topics & Concepts

Lateralization of brain functionStroke (engine)HemodynamicsResting state fMRIHaemodynamic responsePsychologyCardiologyNeuroscienceFunctional near-infrared spectroscopyPhysical medicine and rehabilitationMedicineInternal medicineCognitionBlood pressureEngineeringMechanical engineeringHeart ratePrefrontal cortexOptical Imaging and Spectroscopy TechniquesFunctional Brain Connectivity StudiesHeart Rate Variability and Autonomic Control