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通过对特定神经元的选择性失活确定的龙虾口胃神经节模式生成的潜在机制。I. 幽门系统。

Mechanisms underlying pattern generation in lobster stomatogastric ganglion as determined by selective inactivation of identified neurons. I. Pyloric system.

作者信息

Selverston A I, Miller J P

出版信息

J Neurophysiol. 1980 Dec;44(6):1102-21. doi: 10.1152/jn.1980.44.6.1102.

DOI:10.1152/jn.1980.44.6.1102
PMID:6256508
Abstract
  1. Four factors contribute to pattern generation in the pyloric network of the lobster stomatogastric ganglion. These are: a) endogenously oscillating neurons; b) synaptic network properties; c) nonlinear cellular properties, including the generation of plateau potentials; and d) excitatory input from the commissural ganglia. The roles and relative importance of these factors were investigated with a new technique for inactivating single specific identified neurons. 2. In stomatogastric ganglia in which the excitatory input is left intact, a) pattern generation continues when any cell or pair of cells other than the endogenous bursters are inactivated, b) pattern generation also continues when the endogenous bursters are inactivated, c) pattern generation ceases when the endogenous bursters plus one other particular cell are inactivated. This cell, although not an endogenous burster, displays a strong tendency to generate plateau potentials. 3. In stomatogastric ganglia that have been isolated from excitatory input, a) pattern generation continues when any cell or pair of cells other than the endogenous bursters are inactivated, b) pattern generation ceases when the endogenous bursters are inactivated. 4. Some of the inputs to the stomatogastric ganglion normally fire in bursts. However, their potentiation and acceleration of the output pattern are also produced by tonic stimulation of the nerve. The effect of one of those inputs is mimicked by bath application of dopamine to the stomatogastric ganglion. 5. The roles and importance of the three most important factors were qualitatively summarized in a chart specifying the activity of the network as a function of its intactness.
摘要
  1. 有四个因素促成龙虾口胃神经节幽门网络中的模式生成。这些因素是:a) 内源性振荡神经元;b) 突触网络特性;c) 非线性细胞特性,包括平台电位的产生;d) 来自联合神经节的兴奋性输入。利用一种使单个特定识别神经元失活的新技术,对这些因素的作用和相对重要性进行了研究。2. 在兴奋性输入保持完整的口胃神经节中,a) 当除内源性爆发神经元之外的任何单个细胞或细胞对失活时,模式生成仍会继续;b) 当内源性爆发神经元失活时,模式生成也会继续;c) 当内源性爆发神经元加上另一个特定细胞失活时,模式生成停止。这个细胞虽然不是内源性爆发神经元,但表现出强烈的产生平台电位的倾向。3. 在已与兴奋性输入隔离的口胃神经节中,a) 当除内源性爆发神经元之外的任何单个细胞或细胞对失活时,模式生成仍会继续;b) 当内源性爆发神经元失活时,模式生成停止。4. 口胃神经节的一些输入通常会阵发性放电。然而,它们对输出模式的增强和加速也可由对神经的强直刺激产生。其中一种输入的作用可通过向口胃神经节浴加多巴胺来模拟。5. 这三个最重要因素的作用和重要性在一个图表中进行了定性总结,该图表将网络的活动指定为其完整性的函数。

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Mechanisms underlying pattern generation in lobster stomatogastric ganglion as determined by selective inactivation of identified neurons. I. Pyloric system.通过对特定神经元的选择性失活确定的龙虾口胃神经节模式生成的潜在机制。I. 幽门系统。
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