Neuroscience
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Depression is among the most debilitating diseases worldwide. Long-term exposure to stressors plays a major role in development of human depression. Chronic mild stress (CMS) seems to be a valid animal model for depression. ⋯ The results also suggest a possible role of edema or inflammation concerning the brain morphology in CMS rats. The overall finding using DTI suggests there might be a major role of loss of myelin sheath, which leads to disrupted connectivity between the limbic area and the prefrontal cortex during the onset of depression. Our findings indicate that interpretation of these indices may provide crucial information about the type and severity of mood disorders.
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Repetitive transcranial magnetic stimulation (rTMS) is a non-invasive neurostimulation technique for the treatment of various neurological and psychiatric disorders. To investigate the working mechanism of this treatment approach, we designed a small-animal coil for dedicated use in rats and we combined this neurostimulation method with small-animal positron emission tomography (microPET or μPET) to quantify regional 2-deoxy-2-((18)F)fluoro-d-glucose ([(18)F]-FDG) uptake in the rat brain, elicited by a low- (1 Hz) and a high- (50 Hz) frequency paradigm. Rats (n=6) were injected with 1 mCi of [(18)F]-FDG 10 min after the start of 30 min of stimulation (1 Hz, 50 Hz or sham), followed by a 20-min μPET image acquisition. ⋯ The effect on [(18)F]-FDG metabolism was 2.9 ± 0.8% at 1 Hz and 2.5 ± 0.8% at 50 Hz for the dentate gyrus clusters and 3.3 ± 0.5% for the additional cluster in the entorhinal cortex at 50 Hz. The maximal (4.19 vs. 2.58) and averaged (2.87 vs. 2.21) T-values are higher for 50 Hz versus 1 Hz. This experimental study demonstrates the feasibility to combine μPET imaging in rats stimulated with rTMS using a custom-made small-animal magnetic stimulation setup to quantify changes in the cerebral [(18)F]-FDG uptake as a measure for neuronal activity.
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In the present study, we addressed the question of whether the up-regulation of laminin expression represents the astroglio-vascular responses to status epilepticus (SE) in the rat brain to better understand the role of vasogenic edema in epileptogenic insult. In the hippocampus, vasogenic edema was observed in the hippocampus 12h after SE when astroglial degeneration was undetected. Vasogenic edema in the hippocampus was more severe in the CA1 region where astroglial loss was absent than in the dentate gyrus showing astroglial degeneration. ⋯ Four weeks after SE, laminin expression was reduced in vessels showing strong SMI-71 expression within vasogenic edema lesion. Inhibition of SE-induced vasogenic edema formation by BQ788 effectively prevented laminin over-expression. Therefore, our findings indicate that laminin over-expression may be one of consequences from vasogenic edema rather than astroglial loss, and that laminin over-expression may promote migration of astrocytes to damaged or newly generated vessels to repair brain-blood barrier (BBB) disruption accompanied by the reconstruction of endothelial barrier.
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This study aims to develop a transient ischemic attack (TIA) model in conscious animals and uses this model to investigate the effect of TIA on subsequent permanent ischemia. TIA was induced by injecting designed temperature-sensitive melted solid lipid microparticles with a melting point around body temperature into male Wistar rats via arterial cannulation. Neurologic deficit was monitored immediately after the injection without anesthesia. ⋯ The <24-h group had less severe neurologic deficits and smaller infarct volumes than that of 24-48-h and control (without prior lipid microparticle treatment) rats. Taken together, we successfully develop a TIA animal model which allows us to monitor the neurologic deficit in real-time. By adopting this model, we validate that TIA (<24h) preconditioning protects the brain from subsequent permanent ischemic stroke.
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The heterozygous reeler mouse (HRM), haploinsufficient for reelin, shares several neurochemical and behavioral similarities with patients suffering from schizophrenia. It has been shown that defective reelin signaling influences the mesolimbic dopaminergic pathways in a specific manner. However, there is only little information about the impact of reelin haploinsufficiency on the monoaminergic innervation of different brain areas, known to be involved in the pathophysiology of schizophrenia. ⋯ Overall, no genotype differences were found in the 5-HT-IR fiber densities. In conclusion, these results support the view that reelin haploinsufficiency differentially influences the catecholaminergic (esp. dopaminergic) systems in brain areas associated with schizophrenia. The reelin haploinsufficient mouse may provide a useful model for studying the role of reelin in hippocampal dysfunction and its effect on the dopaminergic system as related to schizophrenia.