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Abstract
BackgroundSpreading depolarizations that occur in patients with malignant stroke, subarachnoid/intracranial hemorrhage, and traumatic brain injury are known to facilitate neuronal damage in metabolically compromised brain tissue. The dramatic failure of brain ion homeostasis caused by propagating spreading depolarizations results in neuronal and astroglial swelling. In essence, swelling is the initial response and a sign of the acute neuronal injury that follows if energy deprivation is maintained. Choosing spreading depolarizations as a target for therapeutic intervention, we have used human brain slices and in vivo real-time two-photon laser scanning microscopy in the mouse neocortex to study potentially useful therapeutics against spreading depolarization-induced injury.Methodology/Principal FindingsWe have shown that anoxic or terminal depolarization, a spreading depolarization wave ignited in the ischemic core where neurons cannot repolarize, can be evoked in human slices from pediatric brains during simulated ischemia induced by oxygen/glucose deprivation or by exposure to ouabain. Changes in light transmittance (LT) tracked terminal depolarization in time and space. Though spreading depolarizations are notoriously difficult to block, terminal depolarization onset was delayed by dibucaine, a local amide anesthetic and sodium channel blocker. Remarkably, the occurrence of ouabain-induced terminal depolarization was delayed at a concentration of 1 µM that preserves synaptic function. Moreover, in vivo two-photon imaging in the penumbra revealed that, though spreading depolarizations did still occur, spreading depolarization-induced dendritic injury was inhibited by dibucaine administered intravenously at 2.5 mg/kg in a mouse stroke model.Conclusions/SignificanceDibucaine mitigated the effects of spreading depolarization at a concentration that could be well-tolerated therapeutically. Hence, dibucaine is a promising candidate to protect the brain from ischemic injury with an approach that does not rely on the complete abolishment of spreading depolarizations.
Highlights
Within minutes of focal stroke onset, a spreading depolarization originates from an area of severely decreased blood flow known as the ischemic core [1,2,3,4]
We used light transmittance (LT) imaging to confirm that dibucaine diminishes the impact of terminal depolarization on live human neocortical slices prepared from pediatric brain tissue mostly resected for the treatment of intractable epilepsy as well as for neoplasm removal
By imaging changes in LT we verified that terminal depolarization can be evoked in human slices exposed to OGD (Fig. 1A) or 100 mM ouabain (Fig. 2A, top row)
Summary
Within minutes of focal stroke onset, a spreading depolarization originates from an area of severely decreased blood flow known as the ischemic core [1,2,3,4]. We supplemented human slice experiments with a sophisticated in vivo approach using real-time 2-photon laser scanning microscopy (2PLSM) to show that spontaneous spreading depolarization-elicited dendritic damage is greatly reduced following photothrombosis-induced focal ischemia in dibucainetreated mice. This success of dibucaine in reducing the negative effects of spreading depolarization makes it a strong candidate for further investigation to prevent spreading depolarization-induced neuronal damage in the acutely injured brain. Choosing spreading depolarizations as a target for therapeutic intervention, we have used human brain slices and in vivo real-time two-photon laser scanning microscopy in the mouse neocortex to study potentially useful therapeutics against spreading depolarization-induced injury
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