61 resultados para Hippocampal Slices
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Long-term potentiation (LTP) and long-term depression (LTD) of the excitatory synaptic inputs plasticity in the hippocampus is believed to underlie certain types of learning and memory. Especially, stressful experiences, well known to produce long-lasting strong memories of the event themselves, enable LTD by low frequency stimulation (LFS, 3 Hz) but block LTP induction by high frequency stimulation (HFS, 200 Hz). However, it is unknown whether stress-affected synaptic plasticity has an impact on the output plasticity. Thus, we have simultaneously studied the effects of stress on synaptic plasticity and neuronal output in the hippocampal CA1 region of anesthetized Wistar rats. Our results revealed that stress increased basal power spectrum of the evoked synchronized-spikes and enabled LTD induction by LFS. The induction of stress-facilitated LTD but not LFS induced persistent decreases of the power spectrum of the synchronized-spikes and the frequency of the spontaneous unitary discharges; However, HFS induced UP in non-stressed animals and increased the power spectrum of the synchronized-spikes, without affecting the frequency of the spontaneous unitary discharges, but HFS failed to induce UP in stressed animals without affecting the power spectrum of the synchronized-spikes and the frequency of the spontaneous unitary discharges. These observations that stress-facilitated LTD induces the output plasticity through the synchronized-spikes and spontaneous unitary discharges suggest that these types of stress-related plasticity may play significant roles in distribution, amplification and integration of encoded information to other brain structures under stressful conditions. (C) 2004 Elsevier Ireland Ltd and The Japan Neuroscience Society. All rights reserved.
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在戊巴比妥钠麻醉的Sprague-Dawley大鼠上,运用海马Schaffer-CA1双通路条件化作用(低频配对,600对脉冲,5Hz,配对刺激相应的兴奋性突触后电位峰值时间间隔为10ms)在两条Schaffer-CA1条件化通路上同时诱导出突触可塑性,呈现出海马组合突触可塑性.结果显示:不管海马Schaffer-CA1双通路独立与否,双通路条件化作用均可以同时诱导出长时程增强(long-term potentiation,LTP)和长时程抑制(long-term depression,LTD),呈现出LTP/LTD组合突触可塑性.结果表明:海马Schaffer-CA1双通路技术,可实现海马突触可塑性的双向诱导,可塑性的方向取决于突触的自身状态.由此提示,与传统的高频诱导LTP低频诱导LTD相比,在海马Schaffer-CA1双通路条件化作用诱导出的组合突触可塑性可以吏好地编码海马相关的学习记忆,体现了海马突触可塑性的灵活性与稳定性.
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下载PDF阅读器目的 研究三七总皂苷(Panax notoginseng saponins,PNS)对大鼠海马脑片CA1区锥体神经元兴奋性和抑制性突触传递的作用.方法 断头法分离3~4周雄性Wistar大鼠海马半脑,用切片机切出400μm厚度的海马脑片,对CA1区锥体细胞采用"盲法"全细胞膜片钳技术记录,分别检测和分析PNS(0.05~0.4 g/L)对刺激CA1传人纤维引出的兴奋性突触后电流(EPSCs)和抑制性突触后电流(IPSCs)的影响,继而以脉冲间隔为50 ms的配对刺激代替单刺激,通过EPSC2/EPSC1(P2/P1)值的变化观察PNS对双脉冲易化(paired-pulse facilitation,PPF)的影响.结果 0.1~0.4 g/L PNS显著抑制EPSCs(P<0.05),且PNS在抑制P1、P2的同时明显升高P2/P1值(P<0.05),加强了双脉冲易化,但PNS对IPSCs无显著影响(P>0.05).结论 PNS 显著减小大鼠海马CA1区锥体神经元的EPSCs而不影响IPSCs,说明PNS不是通过强化抑制性中间神经元的功能间接地抑制兴奋性神经元,而是对兴奋性突触传递直接产生抑制;PNS明显升高P2/p1值,说明 PNS是通过突触前机制抑制CA1区兴奋性突触传递.
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目的研究异丙酚对大鼠海马CA1区神经元兴奋性突触后电流(EPSC)和自发性兴奋性突触后电流(sEPSC)的影响。方法 Wistar大鼠断头后分离海马脑组织,制成400μm厚度的海马脑片,脑片随机分为5组(n=10)。脂肪乳剂Ⅰ组、异丙酚Ⅰ组、SR95531+异丙酚组:记录EPSC 10 min (基础值)后分别加入10%脂肪乳剂90μl、1%异丙酚90μl(相当于100μmol/L)、10μmol/L SR95531+100 μmol/L异丙酚,继续记录EPSC 40 min,分析EPSC幅值的变化。脂肪乳剂Ⅱ组、异丙酚Ⅱ组:细胞破膜后稳定10-15 min,分别加入10%脂肪乳剂90μl和1%异丙酚90μl,记录sEPSC 40 min,分析sEPSC频率、幅值和半衰期的变化。膜钳制电压均为-70 mV。结果与基础值比较,给药后脂肪乳剂Ⅰ组和 SR95531+异丙酚组EPSC幅值差异无统计学意义,异丙酚Ⅰ组EPSC幅值降低;给药后异丙酚Ⅰ组 EPSC幅值比脂肪乳剂Ⅰ组降低(P<0.05)。与脂肪乳剂Ⅱ组比较,异丙酚Ⅱ组sEPSC的频率、幅值降低、半衰期缩短(P<0.05)。结论异丙酚主要通过增强大鼠海马CA...
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目的:研究异丙酚对大鼠海马CA1区自发性兴奋性突触后电流(sEPSC)的影响。方法:断头法分离Wistar大鼠(13~19 d)海马半脑,用切片机切出400μm厚度的海马脑片,全细胞膜片钳记录CA1区锥体神经元sEPSC。20张脑片分为两组:脂肪乳剂组(n=10)和异丙酚组(n=10)。两组细胞稳定10~15 min后,加入90μl脂肪乳剂或异丙酚(相当于100μmol/L),记录40 min sEPSC。膜钳制电压为-70 mV。结果:100μmol/L异丙酚降低sEPSC的频率达68.1%,降低sEPSC的幅值达29.1%,缩短sEPSC的半衰期达49.3%;另外,异丙酚缩短sEPSC的上升时间达29.1%,减少曲线下面积达74.7%。结论:异丙酚通过影响突触前膜递质释放和突触后膜受体功能两个因素抑制兴奋性突触活动
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目的 观察500μmol/ L 丙泊酚对大鼠海马CA1 区电刺激诱发的兴奋性突触后电流 ( EPSC) 的影响,分析丙泊酚的可能作用机制。方法 断头法分离Wistar 大鼠(13~19 d) 海马半脑, 用切片机切出400μm 厚度的海马脑片,全细胞膜片钳技术记录CA1 区锥体神经元EPSC。实验分 两组:脂肪乳剂组( n = 6) 和丙泊酚组( n = 10) 。先以50μmol/ L 印防己毒素预孵脑片30 min 后,记录 基础EPSC 10 min ,然后加入450μl 脂肪乳剂或丙泊酚(相当于500 μmol/ L ) , 继续记录EPSC 40 min ;继而以配对刺激代替单刺激,观察EPSC2/ EPSC1 比率的变化;改变膜钳制电压( - 80~ + 60 mV) ,观察电流2电压( I2V) 曲线的变化。结果 脂肪乳剂对EPSC 无影响,500μmol/ L 丙泊酚降低 大鼠海马CA1 区EPSC 值,25~30 min 左右达最大抑制效果,EPSC 幅值下降至基础值的6715 % ,明 显低于脂肪乳剂组( P < 0105) ;而且500μmol/ L 丙泊酚明显降低EPSC2/ EPSC1 比率,也使I2V 曲线 左移,降低反转电位至- 35 mV 左右。结论 500μmol/ L 丙泊酚对大鼠海马CA1 区兴奋性突触传 递产生抑制作用,这可能与其增强突触前膜、突触后膜GABAA 受体活性有关。
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目的: 观察咪唑安定或丙泊酚复合戊四氮对突触传递的影响。方法: 分离大鼠海马半脑, 切出400 Lm 厚度的海马脑片, 全细胞膜片钳记录戊四氮+ 咪唑安定组, 戊四氮+ 脂肪乳剂组, 戊四氮+ 丙泊酚组海马CA 1 区神经元兴奋性突触后电流(EP2 SC) 变化。结果: 各组加入10 mmolöL 戊四氮均使EPSC 降至基线值的3510% 左右; 10 LmolöL 咪唑安定使EPSC 幅值上升至 基线值的8612% , 脂肪乳剂不改变EPSC, 100 LmolöL 丙泊酚使EPSC 值上升至基线值的7117%。结论: 戊四氮对正常突触传 递具有抑制作用, 咪唑安定或丙泊酚拮抗戊四氮抑制突触传递的作用, 使已减小的EPSC 有所升高。
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在麻醉Wistar大鼠上,结合脑室给药,应用双电极刺激技术刺激海马独立的两条侧枝/联合纤维通 路、TA通路,并在CAl区放射层记录兴奋性突触后电位(EPSP),对海马CAl区锥体细胞近、远端树突EPSP 的空间整合进行了初步探讨。结果表明,海马CAl区锥体细胞近、远端树突的空间整合都是亚线性的;近端树 突的空间整合不受期望值大小的影响,但远端树突的空间整合随期望值增加而减小(更趋于亚线性)。此外, 荷包牡丹碱没有影响EPSP的空间整合;但瞬时A型钾通道(IAK+)的拮抗剂氨基吡啶-4却使得近端树突的 空间整合趋于线性发展。本研究表明,海马CAl锥体细胞近、远端树突不同的被动、主动特征使它们具有了不 同的空间整合特性。由于近端树突接受海马内部侧枝/联合纤维投射的信息,远端树突通过TA通路接受内嗅皮 层投射的信息,由此提示,CAl区锥体细胞对来自海马内部和直接来自皮层的信息输入采用了不同的整合方 式。
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目的研究异丙酚对海马区突触传递和可塑性的影响。方法断头分离大 鼠海马半脑, 制备加阿厚度海马脑片。张脑片分为六组。脂肪乳剂组和异丙酚组的脑片以印防 己毒素预孵而, 然后加人川脂肪乳剂或异丙酚相当于拌, 观察对兴奋性突触后电流 的影响。月旨肪乳剂长时程增强】」下组、脂肪乳剂长时程抑制组、异丙酚功下组、异丙酚 组的脑片以川脂肪乳剂或异丙酚相当于脚预孵而, 给予高频刺激或低频 刺激, 记录或的发生情况。结果脂肪乳剂对无影响脚异 丙酚使细胞下降至基础值的尸, 使细胞玲上升至基础值的 。脂肪乳剂组给予邓后玲值为基础值的, 脂肪乳剂汀〕组给 予⋯乃后值为基础值的异丙酚组给予后, 可以产生但不能维 持, 后值为基础值的, 异丙酚几组给予后值为基础值的 , 明显低于脂肪乳剂组尸。结论异丙酚对大鼠海马区突触传递 具有双重影响, 出现抑制和兴奋两种效果异丙酚损害大鼠海马区锥体神经元的维持而易 化。 【关键
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目的 观察丙泊酚对大鼠海马CA1 区锥体神经元产生的长时程抑制(L TD) 的影响,并 分析其可能机制。方法 断头法分离wistar 大鼠(13~19 d) 海马半脑,用切片机切出400μm 厚度的 海马脑片。实验分三组:脂肪乳剂组( I 组) ,丙泊酚组(P 组) ,SR95531 + 丙泊酚组( GP 组) 。I 组和P 组以90μL 脂肪乳剂或丙泊酚(相当于100μmol/ L) 预孵脑片60 min ,然后给予低频刺激(L FS) ,记录 L TD 的表达情况; GP 组先在循环液中加入10μmol/ L SR95531 预孵脑片30 min ,再加入100μmol/ L 丙泊酚继续孵育60 min ,继而给予L FS ,记录L TD 的表达情况。结果 I 组给予L FS 后,产生L TD , L FS 后10~40 min 的兴奋性突触后电流( EPSC) 值为基础值的57185 %;P 组给予L FS 后10~40 min 的EPSC 值为基础值的40182 % ,明显低于I 组( P < 0105) ; GP 组给予L FS 后10~40 min 的EPSC 值为基础值的56151 % ,与I 组比较差异无显著意义( P > 0105) ,与P 组比较差异有显著意义( P < 0105) 。结论 100μmol/ L 丙泊酚使大鼠海马CA1 区锥体神经元L TD 表达增强,这种作用与其增强 GABAA 受体功能有关;当阻断GABAA 受体后,这种易化作用消失。
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Experience-dependent long-lasting increases in excitatory synaptic transmission in the hippocampus are believed to underlie certain types of memory(1-3). Whereas stimulation of hippocampal pathways in freely moving rats can readily elicit a long-term potentiation (LTP) of transmission that may last for weeks, previous studies have failed to detect persistent increases in synaptic efficacy after hippocampus-mediated learning(4-6). As changes in synaptic efficacy are contingent on the history of plasticity at the synapses(7), we have examined the effect of experience-dependent hippocampal activation on transmission after the induction of LTP, We show that exploration of a new, non-stressful environment rapidly induces a complete and persistent reversal of the expression of high-frequency stimulation-induced early-phase LTP in the CA1 area of the hippocampus, without affecting baseline transmission in a control pathway. LTP expression is not affected by exploration of familiar environments. We found that spatial exploration affected LTP within a defined time window because neither the induction of LTP nor the maintenance of long-established LTP was blocked. The discovery of a novelty-induced reversal of LTP expression provides strong evidence that extensive long-lasting decreases in synaptic efficacy may act in tandem with enhancements at selected synapses to allow the detection and storage of new information by the hippocampus.
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The characterization of acid-sensing ion channel (ASIC)-like currents has been reported in hippocampal neurons in primary culture. However, it is suggested that the profile of expression of ASICs changes in culture. In this study, we investigated the properties of proton-activated current and its modulation by extracellular Ca2+ and Zn2+ in neurons acutely dissociated from the rat hippocampal CA1 using conventional whole-cell patch-clamp recording. A rapidly decaying inward current and membrane depolarization was induced by exogenous application of acidic solution. The current was sensitive to the extracellular proton with a response threshold of pH 7.0-6.8 and the pH(50) Of 6.1, the reversal potential close to the Na+ equilibrium potential. It had a characteristic of acid-sensing ion channels (ASICs) as demonstrated by its sensitivity to amiloride (IC50 = 19.6 +/- 2.1 muM). Either low [Ca2+](0) or high [Zn2+](0) increased the amplitude of the current. All these characteristics are consistent with a current mediated through a mixture of homomeric ASIC1a and heteromeric ASIC1a + 2a channels and closely replicate many of the characteristics that have been previously reported for hippocampal neurons cultured for a week or more, indicating that culture artifacts do not necessarily flaw the properties of ASICs. Interestingly, we found that high [Zn2+] (>10(-4) M) slowed the decay time constant of the ASIC-like current significantly in both acutely dissociated and cultured hippocampal neurons. In addition, the facilitating effects of low [Ca2+](0) and high [Zn2+](0) on the ASIC-like current were not additive. Since tissue acidosis, extracellular Zn elevation and/or Ca2+ reduction occur concurrently under some physiological and/or pathological conditions, the present observations suggest that hippocampal ASICs may offer a novel pharmacological target for therapeutic invention. (C) 2004 Elsevier B.V. All rights reserved.
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The hippocampus, being sensitive to stress and glucocorticoids, plays significant roles in certain types of learning and memory. Therefore, the hippocampus is probably involved in the increasing drug use, drug seeking, and relapse caused by stress. We have studied the effect of stress with morphine on synaptic plasticity in the CA1 region of the hippocampus in vivo and on a delayed-escape paradigm of the Morris water maze. Our results reveal that acute stress enables long-term depression (LTD) induction by low-frequency stimulation (LFS) but acute morphine causes synaptic potentiation. Remarkably, exposure to an acute stressor reverses the effect of morphine from synaptic potentiation ( similar to 20%) to synaptic depression ( similar to 40%), precluding further LTD induction by LFS. The synaptic depression caused by stress with morphine is blocked either by the glucocorticoid receptor antagonist RU38486 or by the NMDA-receptor antagonist D-APV. Chronic morphine attenuates the ability of acute morphine to cause synaptic potentiation, and stress to enable LTD induction, but not the ability of stress in tandem with morphine to cause synaptic depression. Furthermore, corticosterone with morphine during the initial phase of drug use promotes later delayed-escape behavior, as indicated by the morphine-reinforced longer latencies to escape, leading to persistent morphine-seeking after withdrawal. These results suggest that hippocampal synaptic plasticity may play a significant role in the effects of stress or glucocorticoids on opiate addiction.
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Acid-sensing ion channels (ASICs) composed of ASIC1a subunit exhibit a high Ca2+ permeability and play important roles in synaptic plasticity and acid-induced cell death. Here, we show that ischemia enhances ASIC currents through the phosphorylation at Ser478 and Ser479 of ASIC1a, leading to exacerbated ischemic cell death. The phosphorylation is catalyzed by Ca2+/calmodulin-dependent protein kinase II (CaMKII) activity, as a result of activation of NR2B-containing N-methyl-D-aspartate subtype of glutamate receptors (NMDARs) during ischemia. Furthermore, NR2B-specific antagonist, CaMKII inhibitor, or overexpression of mutated form of ASIC1a with Ser478 or Ser479 replaced by alanine (ASICla-S478A, ASIC1a-S479A) in cultured hippocampal neurons prevented ischemia-induced enhancement of ASIC currents, cytoplasmic Ca2+ elevation, as well as neuronal death. Thus, NMDAR-CaMKII cascade is functionally coupled to ASICs and contributes to acidotoxicity during ischemia. Specific blockade of NMDAR/CaMKII-ASIC coupling may reduce neuronal death after ischemia and other pathological conditions involving excessive glutamate release and acidosis.
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Stress in early life is believed to cause cognitive and affective disorders, and to disrupt hippocampal synaptic plasticity in adolescence into adult, but it is unclear whether exposure to enriched environment (EE) can overcome these effects. Here, we rep
