Neuroscience
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To elucidate whether interleukin-18 (IL-18) or interferon-γ (IFN-γ) participates in neurodegeneartion, we investigated the changes in IL-18 and IFN-γ systems within the rat hippocampus following status epilepticus (SE). In non-SE induced animals, IL-18, IL-18 receptor α (IL-18Rα), IFN-γ and IFN-γ receptor α (IFN-γRα) immunoreactivity was not detected in the hippocampus. Following SE, IL-18 immunoreactivity was increased in CA1-3 pyramidal cells as well as dentate granule cells. ⋯ IFN-γRα immunoreactivity was increased in neurons as well as astrocytes. Intracerebroventricular infusions of recombinant rat IL-18 or IFN-γ alleviated SE-induced neuronal damages, while neutralization of IL-18, IFN-γ or their receptors aggravated them, as compared to saline-infused animals. These findings suggest that astroglial-mediated IFN-γ pathway in response to IL-18 induction may play an important role in alleviation of SE-induced neuronal damages.
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Low current cortex stimulation produces a sparse and distributed set of activated cells often with distances of several hundred micrometers between cell bodies and the microelectrode. A modeling study based on recently measured densities of high threshold sodium channels Nav1.2 in dendrites and soma and low threshold sodium channels Nav1.6 in the axon shall identify spike initiation sites including a discussion on dendritic spikes. Varying excitability along the neural axis has been observed while studying different electrode positions and configurations. ⋯ Therefore thin dendrites can profit from the stronger electrical field close to the electrode but low current stimulation cannot activate large diameter dendrites, contrary to the inverse recruitment order known from peripheral nerve stimulation. When local depolarization fails to generate a dendritic spike, stimulation is possible via intracellular current flow that initiates an action potential, for example 200 mum distant in the low threshold AIS or in certain cases at the distal dendrite ending. Beside these exceptions, spike initiation site for cathodic low current stimulation appears rather close to the electrode.
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Noxious stimuli activate a complex cerebral network. During central sensitization to pain, activity in most of these areas is changed. One of these areas is the posterior parietal cortex (PPC). ⋯ Compared to sham stimulation, no significant effect of rTMS was observed on pain stimulus intensity and the area of allodynia. However, a reduction of the hyperalgesic area was observed for rTMS of the left PPC (P<0.05). We discuss the role of the PPC in central sensitization to pain, in spatial discrimination of pain stimuli and in spatial-attention to pain stimuli.
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Though acupuncture has long been used to treat various kinds of pain, its mechanisms remain partly understood. Our recent study has shown that it may inhibit cyclooxygenase-2 (COX-2) in the spinal dorsal horn where COX-2 is upregulated after the development of neuropathic pain following spinal nerve ligation (SNL). The current study directly compared the effect of acupuncture with COX-2 inhibitor celecoxib in the spinal cord after SNL in rats. ⋯ Paw-withdrawal-threshold to mechanical stimulation and paw-withdrawal-latency to thermal test were tested for neuropathic pain at four intervals following the treatments in comparison with the pre-treatment and non-treatment controls. The results demonstrate that electroacupuncture (EA) had a long lasting and better analgesic effect than celecoxib in reducing neuropathic hypersensitivity. Though COX-2 expression in the spinal L4-L6 dorsal horn by immunostaining was significantly reduced by acupuncture just as well as by celecoxib, the superior analgesic mechanism of acupuncture appears well beyond COX-2 inhibition alone.
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It is generally assumed that long lasting synaptic potentiation (long-term potentiation, LTP) and depression (long-term depression, LTD) result from distinct patterns of afferent activity, with high and low frequency activity favouring LTP and LTD, respectively. However, a novel form of N-methyl-d-aspartate (NMDA) receptor-dependent synaptic potentiation in the hippocampal CA1 area in vivo induced by low frequency afferent stimulation has recently been demonstrated. Here, we further characterize the mechanisms mediating this low frequency stimulation (LFS)-induced LTP in area CA1 of intact, urethane-anesthetized preparations. ⋯ Conversely, initial induction of LFS-LTP reduced the amount of subsequent HFS-LTP. Together, these experiments reveal a surprising similarity in the molecular mechanisms (dependence on NMDA receptors, protein kinase A, protein synthesis) mediating LTP induced by highly distinct (1 vs. 100 Hz) induction protocols. Importantly, these findings further challenge the "high-frequency-LTP, low-frequency LTD" dogma by demonstrating that this dichotomy does not account for all types of plasticity phenomena at central synapses.