体外大鼠腰段脊髓运动神经元电紧张性耦合的产后变化研究
Postnatal changes in motoneurone electrotonic coupling studied in the in vitro rat lumbar spinal cord.
作者信息
Walton K D, Navarrete R
机构信息
Department of Physiology and Biophysics, New York University Medical Center, NY 10016.
出版信息
J Physiol. 1991 Feb;433:283-305. doi: 10.1113/jphysiol.1991.sp018426.
Abstract
- Electrotonic coupling between motoneurones innervating ankle flexor and extensor muscles, as well as between unidentified lumbar motoneurones, was studied using intracellular recordings in an in vitro spinal cord-hindlimb preparation isolated from rats between birth (P0) and 13 days (P13). 2. Graded ventral root stimulation could elicit graded, short latency depolarizations (SLD) which preceded, coincided with, or followed the antidromic action potential. These SLDs were identified as electrotonic junctional potentials by their latency, relative insensitivity to changes in membrane potential and their resistance to one or more of the following: (1) high-frequency stimulation, (2) collision with a somatofugal action potential, (3) removal of Ca2+ from the bathing solution. 3. SLDs were studied in 162 neurones and were identified in 77.2% of the cells in preparations from P0 to P3 rats (n = 57), but only in 30.8% at P8 to P13 (n = 39). 4. SLDs were largest in the youngest animals (P0 to P3), decreasing from a mean of 1.31 mV (+/- 0.17, n = 34) to 0.56 mV (+/- 0.10, n = 7) at P8 to P13. The SLDs comprised two to eight (4.3 +/- 0.36) all-or-none components as determined from twenty collision experiments. 5. Electrotonic coupling between motoneurones was specific. SLDs could be elicited in given motoneurones by stimulation of their homonymous but never of their antagonistic muscle nerves. 6. These results indicate that electrotonic coupling between lumbar motoneurones in neonatal animals exhibits a high degree of specificity and that its significance, as judged by the amplitude and frequency of occurrence of SLDs, decreases postnatally at a rate that can be correlated with the functional maturity of the motoneurones and the muscular system.
摘要
- 利用细胞内记录技术,在出生(P0)至13天(P13)的大鼠离体脊髓-后肢标本中,研究了支配踝关节屈肌和伸肌的运动神经元之间以及未明确身份的腰段运动神经元之间的电紧张性耦联。2. 分级的腹根刺激可引发分级的、潜伏期短的去极化(SLD),其先于、与逆向动作电位同时出现或跟随其后。这些SLD根据其潜伏期、对膜电位变化相对不敏感以及对以下一种或多种情况的抵抗性被确定为电紧张性连接电位:(1)高频刺激,(2)与向胞体传导的动作电位碰撞,(3)从浴液中去除Ca2+。3. 在162个神经元中研究了SLD,在P0至P3大鼠的标本中,77.2%的细胞(n = 57)可检测到SLD,但在P8至P13时仅为30.8%(n = 39)。4. SLD在最年幼的动物(P0至P3)中最大,从P8至P13时平均从1.31 mV(±0.17,n = 34)降至0.56 mV(±0.10,n = 7)。根据20次碰撞实验确定,SLD由2至8个(4.3±0.36)全或无成分组成。5. 运动神经元之间的电紧张性耦联具有特异性。通过刺激其同名肌肉神经而非拮抗肌神经,可在特定运动神经元中引发SLD。6. 这些结果表明,新生动物腰段运动神经元之间的电紧张性耦联具有高度特异性,并且从SLD的幅度和出现频率判断,其重要性在出生后以与运动神经元和肌肉系统功能成熟度相关的速率下降。
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