Foehring R C, Sypert G W, Munson J B
J Neurophysiol. 1987 Apr;57(4):1227-45. doi: 10.1152/jn.1987.57.4.1227.
We tested whether the muscle innervated may influence the expression of motoneuron electrical properties. Properties of individual motor units were examined following cross-reinnervation (X-reinnervation) of cat lateral gastrocnemius (LG) and soleus muscles by the medial gastrocnemius (MG) nerve. We examined animals at two postoperative times: 9-10 wk (medX) and 9-11 mo (longX). For comparison, normal LG and soleus motoneuron properties were also studied. Motor units were classified on the basis of their contractile responses as fast contracting fatigable, fast intermediate fast contracting fatigue resistant, and slow types FF, FI, FR, or S, respectively) (9, 21). Motoneuron electrical properties (rheobase, input resistance, axonal conduction velocity, afterhyperpolarization) were measured. After 9-11 mo, MG motoneurons that innervated LG muscle showed recovery of electrical properties similar to self-regenerated MG motoneurons. The relationships between motoneuron electrical properties were largely similar to self-regenerated MG. For MG motoneurons that innervated LG, motoneuron type (65) predicted motor-unit type in 74% of cases. LongX-soleus motoneurons differed from longX-LG motoneurons or self-regenerated MG motoneurons in mean values for motoneuron electrical properties. The differences in overall means reflected the predominance of type S motor units. The relationships between motoneuron electrical properties were also different than in self-regenerated MG motoneurons. In all cases, the alterations were in the direction of properties of type S units, and the relationship between normal soleus motoneurons and their muscle units. Within motor-unit types, the mean values were typical for that type in self-regenerated MG. Motoneuron type (65) was a fairly strong predictor of motor-unit type in longX soleus. MG motoneurons that innervated soleus displayed altered values for axonal conduction velocity, rheobase, and input resistance, which could indicate incomplete recovery from the axotomized state. However, although mean afterhyperpolarization (AHP) half-decay time was unaltered by axotomy (25), this parameter was significantly lengthened in MG motoneurons that innervated soleus muscle. There were, however, individual motoneuron-muscle-unit mismatches, which suggested that longer mean AHP half-decay time may also be due to incomplete recovery of a subpopulation of motoneurons. Those MG motoneurons able to specify soleus muscle-fiber type exhibited motoneuron electrical properties typical of that same motoneuron type in self-regenerated MG.(ABSTRACT TRUNCATED AT 400 WORDS)
我们测试了所支配的肌肉是否会影响运动神经元电特性的表达。通过内侧腓肠肌(MG)神经对猫的外侧腓肠肌(LG)和比目鱼肌进行交叉神经支配(X-神经支配)后,检查了各个运动单位的特性。我们在术后两个时间点检查动物:9 - 10周(medX)和9 - 11个月(longX)。为了进行比较,还研究了正常LG和比目鱼肌运动神经元的特性。运动单位根据其收缩反应分别分类为快速收缩易疲劳型、快速中间型、快速收缩抗疲劳型和慢速型(分别为FF、FI、FR或S)(9, 21)。测量了运动神经元的电特性(基强度、输入电阻、轴突传导速度、超极化后电位)。9 - 11个月后,支配LG肌肉的MG运动神经元显示出电特性的恢复,类似于自我再生的MG运动神经元。运动神经元电特性之间的关系在很大程度上与自我再生的MG相似。对于支配LG的MG运动神经元,在74%的情况下,运动神经元类型(65)可预测运动单位类型。longX - 比目鱼肌运动神经元在运动神经元电特性的平均值方面与longX - LG运动神经元或自我再生的MG运动神经元不同。总体平均值的差异反映了S型运动单位的优势。运动神经元电特性之间的关系也与自我再生的MG运动神经元不同。在所有情况下,变化都朝着S型单位的特性方向发展,以及正常比目鱼肌运动神经元与其肌肉单位之间的关系。在运动单位类型内,自我再生的MG中该类型的平均值是典型的。在longX比目鱼肌中,运动神经元类型(65)是运动单位类型的一个相当强的预测指标。支配比目鱼肌的MG运动神经元在轴突传导速度、基强度和输入电阻方面显示出改变的值,这可能表明从轴突切断状态的恢复不完全。然而,尽管轴突切断未改变超极化后电位(AHP)的平均半衰期(25),但在支配比目鱼肌的MG运动神经元中,该参数显著延长。然而,存在个别运动神经元 - 肌肉单位不匹配的情况,这表明AHP平均半衰期延长也可能是由于一部分运动神经元恢复不完全所致。那些能够确定比目鱼肌纤维类型的MG运动神经元表现出自我再生的MG中相同运动神经元类型典型的运动神经元电特性。(摘要截断于400字)
