Neuroscience
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Ketamine is a promising therapeutic for treatment-resistant depression (TRD) but is associated with an array of short-term psychomimetic side-effects. These disparate drug effects may be elicited through the modulation of neural circuit activity. The purpose of this study was to therefore delineate dose- and time-dependent changes in ketamine-induced neural oscillatory patterns in regions of the brain implicated in depression. ⋯ These low dose ketamine-induced oscillatory alterations were accompanied by a reduction in immobility time in the forced swim test. These results show that ketamine induces time-dependent effects on neural oscillations at specific frequencies. These drug-induced changes may differentially contribute to the psychomimetic and therapeutic effects of the drug.
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The transition of neuronal burst firing from the interictal to ictal state contributes to seizure initiation in human temporal lobe epilepsy. The low-Mg2+ model of seizure is characterized by initial spontaneous interictal bursting events, which later developed into ictaform discharges. Both experimental and clinical studies point to a complex link between spreading depolarization (SD) and epileptiform field potentials (EFP), including SD-induced epileptic seizures. ⋯ In addition, SD significantly accelerated the transition from interictal to ictal state compared to the control tissues. Ictal activities after induction of SD exhibited a significantly longer duration. This study revealed that SD accelerates interictal-to-ictal transitions and facilitates development of ictaform discharges, possibly via the enhancement of neural synchronization, and points to the potential role of SD in seizure initiation.
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Sodium tanshinone IIA sulfonate (STS) can protect against brain damage induced by stroke. However, the neural protection mechanism of STS remains unclear. We investigated whether STS performs its protective function by suppressing autophagy and inflammatory activity during brain injury. ⋯ STS treatment reduced neuroinflammation, as assessed by the infiltration of macrophages and neutrophils, corresponding with reduced numbers of macrophages, T cells, and B cells in ischemia/reperfusion (I/R) brains. In addition, STS treatment also attenuated the upregulation of autophagy associated proteins, such as LC3-II, Beclin-1 and Sirt 6, which was induced by MCAO. These results demonstrated that STS can provide remarkable protection against ischemic stroke, possibly via the inhibition of autophagy and inflammatory activity.
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During cerebral ischemia, brain lactate concentration increases, and astrogliosis is triggered. Herein, we investigated lactate's role in astrogliosis and explored the functions of lactate-activated astrocytes in vitro. In rat models of cerebral ischemia, we observed increased glial fibrillary acidic protein (GFAP) expression, reflecting astrogliosis, and increased lactate levels in the ischemic brain region. ⋯ Genes upregulated by lactate treatment included those regulating astrogliosis and axon guidance. Consistently, lactate-treated astrocytes induced neuronal outgrowth upon coculture. Our results suggest that lactate promotes reactive astrogliosis and confers axon guidance potential to astrocytes under OGD.
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Sensory integration (SI) is a cognitive process whereby the brain uses unimodal or multimodal sensory features to create a comprehensive representation of the environment. Integration of sensory input is necessary to achieve a coherent perception of the environment, and to subsequently plan and coordinate action. The neural mechanisms mediating SI are poorly understood; however, recent studies suggest that the regulation of SI involves N-methyl-d-aspartate receptors (NMDARs) in orbitofrontal cortex (OFC). ⋯ In the olfactory tests, systemic treatment with CPP impaired the test requiring SI while sparing olfactory oddity, demonstrating a selective impairment in the olfactory SI. Intra-OFC blockade of NMDARs impaired olfactory SI, without effect on visual SI, demonstrating that intra-OFC NMDARs are essential for olfactory, but not visual SI. The present results are discussed in the context of the function of the OFC and its associated circuitry.