Abstract
While functional imaging is widely used in studies of the brain, how well the hemodynamic signal represents the underlying neural activity is still unclear. And there is a debate on whether hemodynamic signal is more tightly related to synaptic activity or action potentials. This study intends to address these questions by examining neurovascular coupling driven by pyramidal cells in the motor cortex of rats. Pyramidal cells in the motor cortex of rats were selectively transduced with the light sensitive cation channel channelrhodopsin-2 (ChR2). Electrophysiological recordings and optical intrinsic signal imaging were performed simultaneously and synchronously to capture the neural activity and hemodynamics induced by optical stimulation of ChR2-expressing pyramidal cells. Our results indicate that both synaptic activity (local field potential, LFP) and action potentials (multi-unit activity, MUA) are tightly related to hemodynamic signals. While LFPs in γ band are better in predicting hemodynamic signals elicited by short stimuli, MUA has better predictions to hemodynamic signals elicited by long stimuli. Our results also indicate that strong nonlinearity exists in neurovascular coupling.
Highlights
Studies of neurovascular coupling explore the link between neural activity and hemodynamics [1,2]
A linear neurovascular coupling system conceivably allows for the extraction of information about neural activity from hemodynamics since neural activity can be deconvolved from hemodynamics with a hemodynamic response function (HRF), previous fMRI and optical studies provide mixed conclusions on the linearity of neurovascular coupling
This study investigates the neurovascular coupling system driven by cortical pyramidal neurons in the M1 area of adult rats
Summary
Studies of neurovascular coupling explore the link between neural activity and hemodynamics [1,2]. Through certain signaling pathways, which are not fully understood [4,5], the diameter of local arterioles expand and local blood supply will increase to meet the oxygen and glucose metabolic demands of increased neuronal activity. Functional imaging methods, such as fMRI [6,7] and optical imaging [8,9], identify such changes in blood supply (hemodynamics) to local brain regions in addition to the increased firing rate of neurons. Whereas some claim a linear relationship [2,10,11,12,13], others identify nonlinearity in neurovascular coupling [14,15,16,17]
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