体外研究大鼠丘脑网状核神经元的内在特性。
Intrinsic properties of nucleus reticularis thalami neurones of the rat studied in vitro.
作者信息
Avanzini G, de Curtis M, Panzica F, Spreafico R
机构信息
Dipartimento di Neurofisiologia, Istituto Neurologico, Besta, Milan, Italy.
出版信息
J Physiol. 1989 Sep;416:111-22. doi: 10.1113/jphysiol.1989.sp017752.
Abstract
- Neurones of the nucleus reticularis thalami of the rat were studied by intracellular recordings from in vitro slices. The resting membrane potential was -56.28 +/- 5.86 mV (mean value +/- S.D.); input resistance was 43.09 +/- 9.74 M omega; the time constant tau was 16.51 +/- 3.99 ms. At the resting membrane potential tonic firing is present, while at membrane potentials more negative than -60 mV a burst firing mode gradually prevails. 2. Prolonged depolarizing current pulses superimposed on a steady hyperpolarization consistently activated sequences of burst-after-hyperpolarization complexes. The all-or-none burst response consisted of Na+-mediated, TTX-sensitive fast action potentials superimposed on a low threshold spike (LTS). The burst was followed by a stereotyped after-hyperpolarization lasting 100-120 ms (BAHP), with a maxima -85 mV. The BAHP was blocked by Cd2+ and apamine but not by 8-Br cyclic AMP. The early component of BAHP was significantly attenuated by TEA. The oscillatory rhythmic discharges were abolished by agents which blocked the BAHP. 3. The presence of strong after-hyperpolarizing potentials (SAHP and BAHP) in RTN neurones plays a significant role in determining two different functional states, defined as tonic and oscillatory burst firing modes, respectively.
摘要
- 采用体外脑片细胞内记录法对大鼠丘脑网状核神经元进行了研究。静息膜电位为-56.28±5.86 mV(平均值±标准差);输入电阻为43.09±9.74 MΩ;时间常数τ为16.51±3.99 ms。在静息膜电位时存在紧张性放电,而当膜电位比-60 mV更负时,爆发性放电模式逐渐占主导。2. 叠加在稳定超极化上的长时间去极化电流脉冲持续激活爆发后超极化复合体序列。全或无爆发反应由叠加在低阈值尖峰(LTS)上的Na⁺介导、对河豚毒素敏感的快速动作电位组成。爆发后紧接着是持续100 - 120 ms的定型后超极化(BAHP),最大值为-85 mV。BAHP可被Cd²⁺和蜂毒明肽阻断,但不能被8 - 溴环磷酸腺苷阻断。BAHP的早期成分被TEA显著减弱。阻断BAHP的药物可消除振荡性节律性放电。3. RTN神经元中强后超极化电位(SAHP和BAHP)的存在分别在决定两种不同功能状态(分别定义为紧张性和振荡性爆发放电模式)中起重要作用。
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