Activity‐induced tissue oxygenation changes in rat cerebellar cortex: interplay of postsynaptic activation and blood flow

Abstract

Functional neuroimaging relies on the robust coupling between neuronal activity, metabolism and cerebral blood flow (CBF), but the physiological basis of the neuroimaging signals is still poorly understood. We examined the mechanisms of activity‐dependent changes in tissue oxygenation in relation to variations in CBF responses and postsynaptic activity in rat cerebellar cortex. To increase synaptic activity we stimulated the monosynaptic, glutamatergic climbing fibres that excite Purkinje cells via AMPA receptors. We used local field potentials to indicate synaptic activity, and recorded tissue oxygen partial pressure (P_tiss,O2) by polarographic microelectrodes, and CBF using laser‐Doppler flowmetry. The disappearance rate of oxygen in the tissue increased linearly with synaptic activity. This indicated that, without a threshold, oxygen consumption increased as a linear function of synaptic activity. The reduction in P_tiss,O2 preceded the rise in CBF. The time integral (area) of the negative P_tiss,O2 response increased non‐linearly showing saturation at high levels of synaptic activity, concomitant with a steep rise in CBF. This was accompanied by a positive change in P_tiss,O2. Neuronal nitric oxide synthase inhibition enhanced the initial negative P_tiss,O2 response (‘dip’), while attenuating the evoked CBF increase and positive P_tiss,O2 response equally. This indicates that increases in CBF counteract activity‐induced reductions in P_tiss,O2, and suggests the presence of a tissue oxygen reserve. The changes in P_tiss,O2 and CBF were strongly attenuated by AMPA receptor blockade. Our findings suggest an inverse relationship between negative P_tiss,O2 and CBF responses, and provide direct in vivo evidence for a tight coupling between activity in postsynaptic AMPA receptors and cerebellar oxygen consumption.