猫背角脊髓小脑束神经元的形态和投射
The morphology and projections of dorsal horn spinocerebellar tract neurones in the cat.
作者信息
Edgley S A, Gallimore C M
机构信息
Department of Physiology, University of Göteborg, Sweden.
出版信息
J Physiol. 1988 Mar;397:99-111. doi: 10.1113/jphysiol.1988.sp016990.
Abstract
- The morphology of dorsal horn neurones located in the mid-lumbar segments of the spinal cord and which have an axonal projection to the cerebellum has been investigated. The neurones were identified by antidromic activation from the cerebellum and by their characteristic input from group II afferents as described in the preceding paper (Edgley & Jankowska, 1988). 2. The cell bodies of the neurones were distributed across the width of the spinal cord in laminae IV and V, but particularly at the border between these laminae. Most were in the caudal half of the fourth lumbar segment (L4), caudal to Clarke's column. However, neurones of this type were encountered as far caudal as the middle of the fifth lumbar segment (L5) and as far rostral as the middle of the third lumbar segment (L3). 3. The morphology of the neurones was investigated following intracellular staining with horseradish peroxidase (HRP). Fourteen well-filled cells were recovered. They had large somata and extensive dendritic arborizations within the dorsal horn which could extend more than 2 mm rostro-caudally. The most dense arborization was in laminae III and IV, just dorsal to the cell bodies. 4. The axons of all fourteen cells could be followed well into the white matter. All of them passed into the dorsal part of the ipsilateral lateral funiculus where they ascended. All followed a similar indirect course through the grey matter. Despite careful inspection, initial axon collaterals were never found. 5. All of the neurones were antidromically activated by low-intensity electrical stimulation of the dorsolateral part of the ipsilateral lateral funiculus in the thoracic region and from the cerebellum. The conduction velocities of the axons ranged from 62 to 112 m s-1 (mean 84.2 (S.D. +/- 10.1) m s-1). 6. The axonal terminations of some neurones were investigated by mapping the most effective locations for antidromic activation from the cerebellar cortex. Most neurones were activated with lowest stimulus intensities from the rostral part of the anterior lobe. A second effective area was found in the posterior lobe, deep to the paramedian lobule. The majority of neurones were activated from both locations, suggesting that their axons branched to terminate in both areas. 7. On the basis of their projection and termination, it is proposed that the axons of these dorsal horn spinocerebellar tract neurones contribute to the dorsal spinocerebellar tract (DSCT).
摘要
- 对位于脊髓腰段中部且轴突投射至小脑的背角神经元的形态进行了研究。如前文所述(埃奇利和扬科夫斯卡,1988年),这些神经元通过小脑的逆向激活以及它们从Ⅱ类传入纤维接收的特征性输入来识别。2. 这些神经元的胞体分布在脊髓灰质板层Ⅳ和Ⅴ的宽度范围内,但特别集中在这两层之间的边界处。大多数位于第四腰段(L4)的后半部,在克拉克柱的尾侧。然而,这种类型的神经元在尾侧最远见于第五腰段(L5)中部,在头侧最远见于第三腰段(L3)中部。3. 用辣根过氧化物酶(HRP)进行细胞内染色后研究了这些神经元的形态。回收了14个填充良好 的细胞。它们具有大的胞体,在背角内有广泛的树突分支,在头尾方向上可延伸超过2毫米。最密集的分支位于板层Ⅲ和Ⅳ,恰在胞体背侧。4. 所有14个细胞的轴突都能很好地追踪到白质中。它们都进入同侧外侧索的背侧部分并在其中上行。所有轴突都沿着相似的间接路径穿过灰质。尽管仔细检查,从未发现初始轴突侧支。5. 所有这些神经元都能通过对胸段同侧外侧索背外侧部分以及小脑进行低强度电刺激而被逆向激活。轴突的传导速度范围为62至112米/秒(平均84.2(标准差±10.1)米/秒)。6. 通过绘制小脑皮质逆向激活的最有效位置来研究一些神经元的轴突终末。大多数神经元在前叶头侧部分用最低刺激强度即可被激活。在后叶,正中旁小叶深部发现了第二个有效区域。大多数神经元从这两个位置都能被激活,这表明它们的轴突分支并在这两个区域终末。7. 根据它们的投射和终末情况,有人提出这些背角脊髓小脑束神经元的轴突对背侧脊髓小脑束(DSCT)有贡献。
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