Activity-induced changes in cerebellar blood flow

M. Lauritzen; K. Caesar

doi:10.1016/S0531-5131(02)00197-8

Activity-induced changes in cerebellar blood flow

M. Lauritzen^*, K. Caesar

^*Corresponding author af dette arbejde

Neuronal Signalling

Abstract

Changes in brain cellular activity are accompanied almost invariably by changes in the local cerebral blood flow (CBF). In most functional imaging studies, the increase in local blood flow is assumed to correlate with an increase in the net spike activity of the neurons in the activated region. The question raised in this work is whether the increase in perfusion correlates to spike activity or synaptic transmission, or both. By utilizing measurements of neuronal activity, i.e., single-cell spike activity and synaptic activity of ensembles of neurons (i.e., field potentials), we were able to show that activity-dependent increases in CBF are independent of spiking activity; however, it can be explained by active and passive pre- and postsynaptic mechanisms distinct from spiking. Our work has primarily been focused on the cerebellar cortex where CBF was monitored by laser-Doppler flowmetry and neuronal activity was measured using a glass electrode positioned close to the Purkinje cell.

Originalsprog	Engelsk
Tidsskrift	International Congress Series
Vol/bind	1235
Udgave nummer	C
Sider (fra-til)	251-257
Antal sider	7
ISSN	0531-5131
DOI	https://doi.org/10.1016/S0531-5131(02)00197-8
Status	Udgivet - 1 jul. 2002

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10.1016/S0531-5131(02)00197-8

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title = "Activity-induced changes in cerebellar blood flow",

abstract = "Changes in brain cellular activity are accompanied almost invariably by changes in the local cerebral blood flow (CBF). In most functional imaging studies, the increase in local blood flow is assumed to correlate with an increase in the net spike activity of the neurons in the activated region. The question raised in this work is whether the increase in perfusion correlates to spike activity or synaptic transmission, or both. By utilizing measurements of neuronal activity, i.e., single-cell spike activity and synaptic activity of ensembles of neurons (i.e., field potentials), we were able to show that activity-dependent increases in CBF are independent of spiking activity; however, it can be explained by active and passive pre- and postsynaptic mechanisms distinct from spiking. Our work has primarily been focused on the cerebellar cortex where CBF was monitored by laser-Doppler flowmetry and neuronal activity was measured using a glass electrode positioned close to the Purkinje cell.",

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T1 - Activity-induced changes in cerebellar blood flow

AU - Lauritzen, M.

AU - Caesar, K.

PY - 2002/7/1

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N2 - Changes in brain cellular activity are accompanied almost invariably by changes in the local cerebral blood flow (CBF). In most functional imaging studies, the increase in local blood flow is assumed to correlate with an increase in the net spike activity of the neurons in the activated region. The question raised in this work is whether the increase in perfusion correlates to spike activity or synaptic transmission, or both. By utilizing measurements of neuronal activity, i.e., single-cell spike activity and synaptic activity of ensembles of neurons (i.e., field potentials), we were able to show that activity-dependent increases in CBF are independent of spiking activity; however, it can be explained by active and passive pre- and postsynaptic mechanisms distinct from spiking. Our work has primarily been focused on the cerebellar cortex where CBF was monitored by laser-Doppler flowmetry and neuronal activity was measured using a glass electrode positioned close to the Purkinje cell.

AB - Changes in brain cellular activity are accompanied almost invariably by changes in the local cerebral blood flow (CBF). In most functional imaging studies, the increase in local blood flow is assumed to correlate with an increase in the net spike activity of the neurons in the activated region. The question raised in this work is whether the increase in perfusion correlates to spike activity or synaptic transmission, or both. By utilizing measurements of neuronal activity, i.e., single-cell spike activity and synaptic activity of ensembles of neurons (i.e., field potentials), we were able to show that activity-dependent increases in CBF are independent of spiking activity; however, it can be explained by active and passive pre- and postsynaptic mechanisms distinct from spiking. Our work has primarily been focused on the cerebellar cortex where CBF was monitored by laser-Doppler flowmetry and neuronal activity was measured using a glass electrode positioned close to the Purkinje cell.

KW - Cerebellum

KW - Cerebral blood flow

KW - Electrophysiology

KW - GABA

KW - Glutamate

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DO - 10.1016/S0531-5131(02)00197-8

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SN - 0531-5131

VL - 1235

SP - 251

EP - 257

JO - International Congress Series

JF - International Congress Series

IS - C

ER -

Activity-induced changes in cerebellar blood flow

Abstract

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