Vascular Response to Spreading Depolarization Predicts Stroke Outcome

Background: Cortical spreading depolarization (CSD) is a massive neuro-glial depolarization wave, which propagates across the cerebral cortex. In stroke, CSD is a necessary and ubiquitous mechanism for the development of neuronal lesions that initiates in the ischemic core and propagates through the penumbra extending the tissue injury. Although CSD propagation induces dramatic changes in cerebral blood flow, the vascular responses in different ischemic regions and their consequences on reperfusion and recovery remain to be defined. Methods: Ischemia was performed using the thrombin model of stroke and reperfusion was induced by r-tPA (recombinant tissue-type plasminogen activator) administration in mice. We used in vivo electrophysiology and laser speckle contrast imaging simultaneously to assess both electrophysiological and hemodynamic characteristics of CSD after ischemia onset. Neurological deficits were assessed on day 1, 3, and 7. Furthermore, infarct sizes were quantified using 2,3,5-triphenyltetrazolium chloride on day 7. Results: After ischemia, CSDs were evidenced by the characteristic propagating DC shift extending far beyond the ischemic area. On the vascular level, we observed 2 types of responses: some mice showed spreading hyperemia confined to the penumbra area (penumbral spreading hyperemia) while other showed spreading hyperemia propagating in the full hemisphere (full hemisphere spreading hyperemia). Penumbral spreading hyperemia was associated with severe stroke-induced damage, while full hemisphere spreading hyperemia indicated beneficial infarct outcome and potential viability of the infarct core. In all animals, thrombolysis with r-tPA modified the shape of the vascular response to CSD and reduced lesion volume. Conclusions: Our results show that different types of spreading hyperemia occur spontaneously after the onset of ischemia. Depending on their shape and distribution, they predict severity of injury and outcome. Furthermore, our data show that modulating the hemodynamic response to CSD may be a promising therapeutic strategy to attenuate stroke outcome

Etude de l'implication de l'endothéline et de l'urotensine-II dans la circulation cérébrale et l'ischémie cérébrale focale chez le rat

CAEN-BU Sciences et STAPS (141182103) / SudocSudocFranceF

Predominant Enhancement of Glucose Uptake in Astrocytes versus Neurons during Activation of the Somatosensory Cortex

International audienceGlucose is the primary energetic substrate of the brain, and measurements of its metabolism are the basis of major functional cerebral imaging methods. Contrary to the general view that neurons are fueled solely by glucose in proportion to their energetic needs, recent in vitro and ex vivo analyses suggest that glucose preferentially feeds astrocytes. However, the cellular fate of glucose in the intact brain has not yet been directly observed. We have used a real-time method for measuring glucose uptake in astrocytes and neurons in vivo in male rats by imaging the trafficking of the nonmetabolizable glucose analog 6-deoxy-N-(7-nitrobenz-2-oxa-1,3-diazol-4-yl)-aminoglucose (6-NBDG) using two-photon microscopy. During resting conditions we found that astrocytes and neurons both take up 6-NBDG at the same rate in the barrel cortex of the rat. However, during intense neuronal activity triggered by whisker stimulation, astrocytes rapidly accelerated their uptake, whereas neuronal uptake remained almost unchanged. After the stimulation period, astrocytes returned to their preactivation rates of uptake paralleling the neuronal rate of uptake. These observations suggest that glucose is taken up primarily by astrocytes, supporting the view that functional imaging experiments based on glucose analogs extraction may predominantly reflect the metabolic activity of the astrocytic network

Investigations of octylglyceryl dextran- graft -poly(lactic acid) nanoparticles for peptide delivery to the brain

International audienceDevelop modified dextran nanoparticles showing potential to assist with drug permeation across the blood-brain barrier for the delivery of neuropeptides

Prolonged deficit of gamma oscillations in the peri-infarct cortex of mice after stroke

International audienceDays and weeks after an ischemic stroke, the peri-infarct area adjacent to the necrotic tissue exhibits very intense synaptic reorganization aimed at regaining lost functions. In order to enhance functional recovery, it is important to understand the mechanisms supporting neural repair and neuroplasticity in the cortex surrounding the lesion. Brain oscillations of the local field potential (LFP) are rhythmic fluctuations of neuronal excitability that synchronize neuronal activity to organize information processing and plasticity. Although the oscillatory activity of the brain has been probed after stroke in both animals and humans using electroencephalography (EEG), the latter is ineffective to precisely map the oscillatory changes in the peri-infarct zone where synaptic plasticity potential is high. Here, we worked on the hypothesis that the brain oscillatory system is altered in the surviving peri-infarct cortex, which may slow down the functional repair and reduce the recovery. In order to document the relevance of this hypothesis, oscillatory power was measured at various distances from the necrotic core at 7 and 21 days after a permanent cortical ischemia induced in mice. Delta and theta oscillations remained at a normal power in the peri-infarct cortex, in contrast to low gamma oscillations that displayed a gradual decrease, when approaching the border of the lesion. A broadband increase of power was also observed in the homotopic contralateral sites. Thus, the proximal peri-infarct cortex could become a target of therapeutic interventions applied to correct the oscillatory regimen in order to boost post-stroke functional recovery

Effects of urotensin-II on cerebral blood flow and ischemia in anesthetized rats

International audienceUrotensin-II (U-II) is a cyclic peptide identified recently in many mammalian species including man. U-II and its receptor are expressed in the central nervous system, in the cardiovascular system and in other peripheral tissues. Although this peptide has been reported initially to be a potent vasoconstrictor, increasing evidence shows that its vascular actions strongly depend on species and vascular beds. Here we analyzed the effects of U-II administration on cerebral blood flow (CBF) under physiological conditions and following cerebral ischemia in rats. Although intravenous injection of U-II had minimal effects on CBF as measured by the technique of laser Doppler flowmetry, its administration (10 nmol) into the lateral cerebral ventricle induced gradual and long lasting increase in CBF (+61% at 1 h post-injection, p<0.05). These U-II-mediated CBF increases were not related to the transient systemic pressor actions of the peptide and were reduced by nitric oxide synthase inhibition (61 vs 17%, p<0.05). Intracerebroventricular administration of U-II following the induction of cerebral ischemia, failed to alter residual CBF in the affected cerebral hemisphere. Nonetheless, following reperfusion (90 min after ischemia), U-II-treated animals displayed a remarkable hyperperfusion compared to vehicle-treated rats (+168%, p<0.05). The volume of infarction was significantly increased in U-II-treated rats (+40%, p<0.05). These results provide the first evidence that U-II increases cerebral blood flow when administered into the cerebral ventricle and exacerbates brain damage following an ischemic insult

Effect of human QRFPR ligands in the insulin tolerance test in mice.

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