Analysis of oxygen metabolism implies a neural origin for the negative BOLD
response in human visual cortex.
Citation Info
BN Pasley, BA Inglis, RD Freeman
Analysis of oxygen metabolism implies a neural origin for the negative BOLD
response in human visual cortex.
NeuroImage. 36:269-276
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Abstract
The sustained negative blood oxygenation level-dependent (BOLD) response in
functional MRI is observed universally, but its interpretation is
controversial. The origin of the negative response is of fundamental
importance because it could provide a measurement of neural deactivation.
However, a substantial component of the negative response may be due to a
non-neural hemodynamic artifact. To distinguish these possibilities, we
have measured evoked BOLD, cerebral blood flow (CBF), and oxygen metabolism
responses to a fixed visual stimulus from two different baseline conditions.
One is a normal resting baseline and the other is a lower baseline induced
by a sustained negative response. For both baseline conditions, CBF and
oxygen metabolism responses reach the same peak amplitude. Consequently,
evoked responses from the negative baseline are larger than those from the
resting baseline. The larger metabolic response from negative baseline
presumably reflects a greater neural response that is required to reach the
same peak amplitude as that from resting baseline. Furthermore, the ratio
of CBF to oxygen metabolism remains approximately the same from both
baseline states (~2:1). This tight coupling between hemodynamic and
metabolic components implies that the magnitude of any hemodynamic artifact
is inconsequential. We conclude that the negative response is a
functionally significant index of neural deactivation in early visual
cortex.