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本文引用的文献

1
Accommodation in motoneurones of the rat and the cat.大鼠和猫运动神经元中的适应性。
J Physiol. 1961 Apr;156(1):75-92. doi: 10.1113/jphysiol.1961.sp006659.
2
Branching dendritic trees and motoneuron membrane resistivity.分支树突状结构与运动神经元膜电阻
Exp Neurol. 1959 Nov;1:491-527. doi: 10.1016/0014-4886(59)90046-9.
3
QUANTITATIVE ASPECTS OF REPETITIVE FIRING OF MAMMALIAN MOTONEURONES, CAUSED BY INJECTED CURRENTS.注入电流引起的哺乳动物运动神经元重复放电的定量研究
J Physiol. 1963 Oct;168(4):911-31. doi: 10.1113/jphysiol.1963.sp007230.
4
DELAYED DEPOLARIZATION AND THE REPETITIVE RESPONSE TO INTRACELLULAR STIMULATION OF MAMMALIAN MOTONEURONES.哺乳动物运动神经元的延迟去极化及对细胞内刺激的重复反应
J Physiol. 1963 Oct;168(4):890-910. doi: 10.1113/jphysiol.1963.sp007229.
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The recording of potentials from motoneurones with an intracellular electrode.用细胞内电极记录运动神经元的电位。
J Physiol. 1952 Aug;117(4):431-60. doi: 10.1113/jphysiol.1952.sp004759.
6
Passive electrical constants in three classes of hippocampal neurons.三类海马神经元的被动电学常数
J Neurophysiol. 1981 Oct;46(4):812-27. doi: 10.1152/jn.1981.46.4.812.
7
A HRP study of the relation between cell size and motor unit type in cat ankle extensor motoneurons.一项关于猫踝关节伸肌运动神经元细胞大小与运动单位类型之间关系的辣根过氧化物酶研究。
J Comp Neurol. 1982 Jul 20;209(1):17-28. doi: 10.1002/cne.902090103.
8
Repetitive firing in trigeminal mesencephalic tract neurons and trigeminal motoneurons.
J Neurophysiol. 1982 Jan;47(1):23-30. doi: 10.1152/jn.1982.47.1.23.
9
The dynamic response of cat alpha-motoneurones investigated by intracellular injection of sinusoidal currents.通过细胞内注入正弦电流研究猫α运动神经元的动态反应。
Exp Brain Res. 1984;54(2):275-82. doi: 10.1007/BF00236227.
10
Relations among passive electrical properties of lumbar alpha-motoneurones of the cat.猫腰段α运动神经元被动电特性之间的关系。
J Physiol. 1984 Nov;356:401-31. doi: 10.1113/jphysiol.1984.sp015473.

大鼠下颌提肌运动神经元的膜特性与放电特性

The membrane properties and firing characteristics of rat jaw-elevator motoneurones.

作者信息

Moore J, Appenteng K

机构信息

Department of Physiology, University of Leeds.

出版信息

J Physiol. 1990 Apr;423:137-53. doi: 10.1113/jphysiol.1990.sp018015.

DOI:10.1113/jphysiol.1990.sp018015
PMID:2388148
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1189750/
Abstract
  1. We have determined the membrane and firing properties of fifty-six jaw-elevator motoneurones in rats that were anaesthetized with pentobarbitone, paralysed and artificially ventilated. 2. Forty-two neurones were identified as masseter motoneurones and fourteen as masseter synergist motoneurones. The membrane potentials for the sample ranged from -60 to -86 (mean = -68; S.D. = 7.3; n = 56), and spike amplitudes from 50 to 95 mV. The duration of the after-hyperpolarization following antidromic spikes in masseter motoneurones ranged from 15 to 50 ms (mean = 30; S.D. = 12.8) and their amplitudes from 1.0 to 4.5 mV (mean = 2.7; S.D. = 2.2; n = 42). 3. The mean input resistance for the total sample was 2.3 M omega (S.D. = 0.9; n = 56), membrane time constant 3.9 ms (S.D. = 0.9; n = 48) and rheobase 4.2 nA (S.D. = 2.6; n = 56). The distribution of these parameters was independent of membrane potential. We found no significant interrelationships between the membrane properties and one interpretation of this is that our sample may be drawn from a homogenous population of motoneurones. We also suggest that elevator motoneurones may have a lower Rm (specific membrane resistivity) value than cat hindlimb motoneurones because they have a similar range of input resistance values but only half the total surface area. 4. Forty-six out of forty-nine neurones fired repetitively to a depolarizing current pulse at a mean threshold of 1.6 x rheobase. Current-frequency plots were constructed for thirteen neurones and all but one showed a primary and secondary range in the firing of the first interspike interval. The mean slope in the primary range was 31 impulses s-1 nA-1 and 77 impulses s-1 nA-1 for the secondary range. The mean minimal firing frequency for steady firing was 26 impulses s-1 and, in response to an increase of stimulation, the rate increased monotonically with a slope of 11 impulses s-1 nA-1. 5. The dynamic sensitivity of twelve neurones was assessed from their response to ramp waveforms of current of constant amplitude but varying frequencies (0.2-2 Hz). Firing initially increased along a steep slope up to a frequency of between 40 and 60 impulses s-1 and then increased along a much shallower slope. Both the threshold for eliciting firing and the firing at the transition point of the two slopes remained constant with changes in ramp frequency.(ABSTRACT TRUNCATED AT 400 WORDS)
摘要
  1. 我们测定了56只经戊巴比妥麻醉、麻痹并进行人工通气的大鼠下颌升肌运动神经元的膜特性和放电特性。2. 42个神经元被鉴定为咬肌运动神经元,14个为咬肌协同肌运动神经元。样本的膜电位范围为-60至-86(平均值=-68;标准差=7.3;n=56),动作电位幅度为50至95mV。咬肌运动神经元逆向动作电位后的超极化持续时间为15至50ms(平均值=30;标准差=12.8),其幅度为1.0至4.5mV(平均值=2.7;标准差=2.2;n=42)。3. 整个样本的平均输入电阻为2.3MΩ(标准差=0.9;n=56),膜时间常数为3.9ms(标准差=0.9;n=48),基强度为4.2nA(标准差=2.6;n=56)。这些参数的分布与膜电位无关。我们发现膜特性之间没有显著的相互关系,对此的一种解释是我们的样本可能取自运动神经元的同质群体。我们还认为,升肌运动神经元的比膜电阻(Rm)值可能低于猫后肢运动神经元,因为它们的输入电阻值范围相似,但总表面积只有猫后肢运动神经元的一半。4. 49个神经元中有46个对去极化电流脉冲以平均阈值1.6倍基强度重复放电。为13个神经元构建了电流-频率图,除一个外,所有图在第一次峰间间隔放电中均显示出初级和次级范围。初级范围的平均斜率为31次冲动·秒⁻¹·nA⁻¹,次级范围为77次冲动·秒⁻¹·nA⁻¹。稳定放电的平均最小放电频率为26次冲动·秒⁻¹,响应刺激增加,放电率以11次冲动·秒⁻¹·nA⁻¹的斜率单调增加。5. 根据12个神经元对恒定幅度但频率变化(0.2 - 2Hz)的电流斜坡波形的反应评估其动态敏感性。放电最初沿陡峭斜率增加至40至60次冲动·秒⁻¹之间的频率,然后沿更平缓的斜率增加。引发放电的阈值和两个斜率转换点处的放电频率均随斜坡频率变化而保持恒定。(摘要截断于400字)