结果:NOS阳性触液神经元主要见于中脑水管和第三脑室(3V)。
Results:The NOS positive CSF contacting neurons were mainly at the cerebral aqueduct and the third ventricle(3V).
目的观察大鼠第三脑室、中脑水管及中缝背核内多巴胺能触液神经元的分布情况。
Objective To observe the distribution of dopaminergic cerebrospinal fluid-contacting neurons (CSF-CNs) in the third ventricle and the mesencephalic aqueduct of rat.
本文以刀解及HE染色光镜观察,研究家兔中脑水管形态及其室管膜细胞构筑学。
Gross anatomy of the mesencephalic aqueduct and its ependymal cytoarchitecture were investigated with dissection and light microscopy after he staining in the rabbit.
以扫描与透射电镜观察家兔中脑水管室管膜上皮,主要有纤毛、微绒毛、花球状和泡球状结构,以及三种室管膜上细胞。
The dominant structures of ependyma of cerebral aqueduct in the rabbit are the cilia, microvilli, spherical structures and three types of the supraependymal cells that were observed with SEM and TEM.
结论大鼠第三脑室、中脑水管及中缝背核内存在多巴胺能触液神经元,其在脑-脑脊液之间的信息传递中有着重要的作用。
Conclusion the dopaminergic CSF-CNs located in the third ventricle and mesencephalic aqueduct might play an important role in transmitting information between brain and cerebrospinal fluid of the rat.
本研究应用HRP逆行追踪法研究了大白鼠中脑水管周围灰质(PAG)向小脑皮层的投射。 结果表明:小脑皮层的所有注射区域均接受PAG的投射。
A cerebellar afferent connection from the periaqueductal grey (PAG) has been demonstrated in the rat by means of retrograde transport of horseradish peroxidase (HRP) in the present study.
在其他一些情形中,人们也许不能有效控制他们的中脑导水管周围灰质和其他的中脑部区域。
In other cases, people may not be able to keep their periaqueductal gray and other midbrain regions under control.
当研究人员在中脑导水管周围灰质内植入电极并且进行刺激时,这些小东西立刻开始奔逃并且不受控制地跳动。
When neuroscientists put electrodes into the periaqueductal gray region of rat brains and stimulated the neurons there, the creatures immediately started to run and jump uncontrollably.
不过,小脑扁桃体和中脑导水管周围灰质是大脑的两个古老原始的区域,可以追溯到亿万年前。
But the amygdala and the periaqueductal gray are ancient parts of the brain, dating back hundreds of millions of years.
目的:分析K物质在大鼠中脑导水管周围灰质中参与痛觉调制的作用,揭示内源性镇痛系统的神经递质机制。
AIM: To analyze the effect of substance K on pain modulation in the periaqueductal gray (PAG) of rats and indicate the neurotransmitter mechanism in endogenous analgesia system.
结论对于因导水管狭窄、后颅窝和中脑占位引起的梗阻性脑积水患者ETV有很好的效果。
Conclusion ETV is an effective method treating obstructive hydrocephalus caused by aqueduct stenosis and occupying lesions in posterior cranial fossa and midbrain.
应用神经束路追踪技术对大鼠孤束核(NTS)和最后区(AP)向中脑导水管周围灰质(PAG)的直接投射进行了观察。
The direct projections from the nucleus tractus solitarius (NTS) and area postrema (AP) to the periaqueductal gray (PAG) were investigated in the rat by using tract-tracing techniques.
脑积水的原因很多,除了脑脊液产生过多,也由吸收障碍或中脑导水管堵塞等引起。
Hydrocephalus, except for many reasons, also produce overmuch cerebrospinal fluid by absorption obstacles or midbrain aqueduct jams caused.
目的:探讨大鼠中脑导水管周围灰质(PAG)内NO在应激性高血压(SIH)发病中的作用。
Aim: To study the role of NO in the midbrain periaqueductal gray (PAG) in the development of stress induced hypertension (SIH).
目的:探讨大鼠中脑导水管周围灰质(PAG)内NO在应激性高血压(SIH)发病中的作用。
Aim: To study the role of NO in the midbrain periaqueductal gray (PAG) in the development of stress induced hypertension (SIH).
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