L-NNA对猫眼球运动神经元突触后诱发电位的影响

本研究探讨内源性一氧化氮(NO)对猫中脑·间脑结合部Forel′sfieldH(FFH)区神经元与下斜肌(inferioroblique,IO)眼球运动神经元(oculomotoneurons,OMNs)之间兴奋性突触传递的影响。首先电刺激FFH内侧区,在IOOMNs池内诱发兴奋性单突触电场电位,然后观察颈动脉注入NO合酶抑制剂N硝基L精氨酸(LNNA)后这一电位的变化。结果表明,应用LNNA后2～3min,这一突触后电位的振幅开始逐渐减小,6～10min时减小至最低水平,而后缓慢恢复。预先给予NO前体L精氨酸(LArg)可抵消LNNA的上述效应,但LArg本身并不引起这一电位出现变化。这些结果提示:生理情况下,动眼神经核内存在着NO的基础释放,NO对FFH神经元与OMNs之间的突触传递过程具有促进作用     

液压打击损伤后海马CA1区神经元兴奋性变化的研究

为考察脑损伤对海马CA1区锥体神经元电活动的影响并研究大黄素对神经元的超兴奋性和突触传递的作用,应用液压打击大鼠脑损伤模型和细胞外记录方法提取诱发的海马CA1区场兴奋性突触后电位(fPSP)和群峰电位(PS),进行相关的数据处理和分析。发现损伤侧比非损伤侧的fPSP斜率明显升高,PS波峰个教显著增加,而PS潜伏期明显减小;在灌流液中施加大黄素,CA1区诱发场电位明显减弱。研究结果表明：颅脑损伤可造成海马CA1区锥体神经元的迟发性过度兴奋;大黄素对神经元的兴奋性有抑制作用,可能对颅脑损伤后的中枢神经系统具有保护功能。     

海马锥体神经元树突中电压依赖性钾通道研究进展

海马锥体神经元树突上分布着多种电压依赖性钾离子通道,但这些通道在胞体和树突不同部位的分布密度以及在突触电活动中的功能意义各不相同。倒传递动作电位（b-AP）和兴奋性突触后电位（EPSP）是树突中常见的功能电信号。本文简要介绍了近年来海马锥体神经元树突上这些钾离子通道及其电活动的生理和病理学研究成果。     

海马CA1区ripple节律相关高频放电中间神经元

通过在清醒小（Mus musculus）大脑同步记录海马区单神经元放电和场电位,发现在海马CAl区存在两类-9慢波睡眠时海马特征场电位“ripple”高频振荡（100-250Hz）相关的高频放电中间神经元．这两类神经元在慢波睡眠时的放电与ripple在时间上有高度同步性,对应每个ripple振荡波,它们都有一串高频放电．其中一类中间神经元（类型Ⅰ）在一个ripple振荡波的每个子振荡周期基本有1个放电,而另一类中间神经元（类型Ⅱ）则有1-2个放电．在ripple振荡波时段,这两类中间神经元的峰值放电频率分别高达310±33．17Hz（类型Ⅰ）和410±47．61Hz（类型Ⅱ）．动物清醒活动时,这两类中间神经元的放电与海马场电位的theta节律有锁相关系,它们的最大放电概率在theta节律的波谷段．给予动物摇晃刺激时,这两类中间神经元的放电频率均会短促增加．这些研究结果显示,海马CAl区的这种高频放电中间神经元参与调节海马神经元网络的整体活动状态．     

兴奋性和抑制性活动平衡神经网络中的混沌现象

兴奋性和抑制性活动平衡神经网络中的混沌现象动物皮层脑片受到恒定电流刺激时,神经元放电较为规则,而行为动物大脑神经元呈现不规则的放电模式,这是否意味着完整大脑神经元的不规则放电是由其突触输入存在着强烈的时间波动所致？但对于单个皮层神经元而言,即使单个突...     

骨髓间充质干细胞向神经细胞分化的研究

无论是在体外实验、还是在体内实验,MSCs都可以向中枢神经系统(CNS)神经细胞分化,但争议颇多。因为功能性神经元不仅要具有典型神经元的形态、特异性标记,还要求具有可兴奋性、能和其他神经元形成突触联系、产生突触电位等,所以对于骨髓间充质干细胞是否能诱导出真正具有功能的神经元存在很大分歧。在此对MSCs向神经细胞诱导分化研究的现况、存在的问题及发展前景给以综述。     

突触前α7烟碱受体对海马神经元兴奋性突触传递的调控

采用盲法膜片钳技术观察突触前烟碱受体(nicotinic acetylcholinel receptors,nAChRs)对海马脑片CAl区锥体神经元兴奋性突触传递的调控作用。结果显示,nAChRs激动剂碘化二甲基苯基哌嗪(dimethylphenyl—piperazinium iodide,DMPP)不能在CAl区锥体神经元上诱发出烟碱电流。DMPP对CAl区锥体神经元自发兴奋性突触后电流(spontaneous excitatory postsynaptic current,sEPSC)具有明显的增频和增幅作用,并呈现明显的浓度依赖关系。DMPP对微小兴奋性突触后电流(miniature excitatory postsynaptic current,mEPSC)具有增频作用,但不具有增幅作用。上述DMPP增强突触传递的作用不能被nAChRs拮抗剂美加明、六烃季铵和双氢-β-刺桐丁所阻断,但可被α-银环蛇毒素阻断。上述结果提示,海马脑片CAl区锥体神经元兴奋性突触前nAChRs含有对α-银环蛇毒素敏感的胡亚单位,其激活可增强海马CAl区锥体神经元突触前递质谷氨酸的释放,从而对兴奋性突触传递发挥调控作用。     

非鸣禽脑中雌激素受体的免疫组织化学定位

应用免疫组织化学方法对非鸣禽环命脑中雌激素受体（ＥＲ）的分面进行了定位研究。结果发现：（１）ＥＲ在间脑的视前区、旁嗅叶、下丘脑腹内侧、腹外侧区及中脑丘间核（ＩＣｏ）水平有广泛分布;（２）大量脑啡肽（ｍｅｔ－ＥＮＫ）和ＥＲ双标神经元集中分 中脑丘间核的背内侧亚核（ＤＭ）中。结果提示：在鸟类可能存在一条联系发声、听觉和内分泌系统的神经网络。     

吗啡对大鼠海马神经元突触传递的作用及机制探讨

目的 :从离子通道角度研究吗啡对中枢神经系统兴奋性及抑制性突触传递的作用并探讨其机制。方法 :　原代培养新生Wistar大鼠的海马神经元。采用膜片钳技术研究吗啡对其兴奋性及抑制性突触后电流及谷氨酸诱发电流的影响。结果 :①吗啡可明显增强海马神经元兴奋性突触传递 ,加吗啡后自发兴奋性突触后电流 (sEPSC)的发放频率增加了 ( 2 0 7.8± 2 0 .9) %。此作用可被阿片受体阻断剂纳洛酮阻断 (P <0 .0 1) ;②吗啡对微小兴奋性突触后电流 (mEPSC)的发放频率及谷氨酸诱发电流的幅度没有明显影响 (P >0 .0 5 ) ;③吗啡可明显抑制神经元自发抑制性突触后电流 (sIPSC) ,纳洛酮可拮抗吗啡作用 (n =13 ,P <0 .0 1)。结论 :实验结果提示吗啡对海马神经元的兴奋作用不是由于吗啡直接作用于兴奋性氨基酸—谷氨酸突触传递过程 ,而是可能由于抑制了抑制性中间神经元 ,间接产生的兴奋作用。     

慢性神经痛对抑郁状态以及中枢多巴胺神经元电生理的影响

目的：探讨大鼠慢性神经痛导致抑郁症状发生后,中脑腹侧被盖区多巴胺能神经元自发放电活动的改变情况。方法：24只健康成年大鼠进行随机分组（n=12）：假手术组（Sham）大鼠仅进行坐骨神经分支暴露,坐骨神经损伤组（SNI）进行坐骨神经分支选择性损伤。在神经损伤后的第3、7、14、28、42、56天进行机械刺激计算缩足反射阈值,并进行糖水偏好、强迫游泳、旷场实验等行为学实验来评价大鼠是否发生抑郁症状;利用在体多通道电生理技术,对SNI组大鼠和假手术组大鼠中脑腹侧被盖区神经元分别进行记录分析。结果：与假手术组比较,SNI组大鼠的机械痛阈值明显降低（P<0.01）;在旷场实验、糖水偏好、强迫游泳较对照组出现显著性差异（P<0.01）;大鼠中脑腹侧被盖区多巴胺能神经元自发放电频率、簇状放电活动中动作电位的数量明显增加（P<0.01）。结论：慢性疼痛可以导致大鼠抑郁相关症状的发生,中脑腹侧被盖区多巴胺能神经元自发放电频率增加与疼痛后抑郁发生相关。     

Neural mechanism generating firing patterns in jaw motoneurons during the food-induced response in Aplysia kurodai

1. In each right and left buccal ganglia of Aplysia kurodai, we identified 4 premotor neurons impinging on the ipsilateral jaw-closing and -opening motoneurons. Three of them (MA1 neurons) had features of multifunctional neurons. Current-induced spikes in the MA1 neurons produced excitatory junction potentials (EJPs) in the buccal muscle fibers. In addition, tactile stimulation of the buccal muscle surface produced a train of spikes in the MA1 neurons without synaptic input. The other neuron (MA2) had only a premotor function. 2. The MA1 and MA2 neurons had similar synaptic effects on the jaw-closing and -opening motoneurons. Current-induced spikes in the premotor neurons gave rise to monosynaptic inhibitory postsynaptic potentials (IPSPs) in the ipsilateral jaw-closing motoneurons. Simultaneously, spikes in one of the MA1 neurons and the MA2 also gave rise to monosynaptic excitatory postsynaptic potentials (EPSPs) in the ipsilateral jaw-opening motoneuron. 3. The IPSPs and the EPSPs induced by spikes in the premotor neurons were reversibly blocked by d-tubocurarine and hexamethonium, respectively, suggesting that the MA1 and MA2 neurons are cholinergic. 4. When depolarizing and hyperpolarizing current pulses were passed into one premotor neuron, attenuated but similar potential changes were produced in another randomly selected premotor neuron in the same ganglion, suggesting that they are electronically coupled.     

Ultrastructural study of the cat hypertrophic inferior olive following anterograde tracing, immunocytochemistry, and intracellular labeling

Contralateral cerebellectomy can induce hypertrophy of olivary neurons in cat. In the present study we examined the ultrastructure of the cat hypertrophic inferior olive following GABA-, dopamine- and serotonin-immunocytochemistry, anterograde tracing from the mesodiencephalic junction, and intracellular labeling with HRP. Compared to normal olivary neurons the hypertrophic cells showed larger cell bodies, more and longer somatic spines which were linked by gap junctions, and longer distal dendrites with relatively few spines. The hypertrophic olivary neurons received less GABAergic boutons on their dendrites but an equal percentage was apposed to their somata as compared to normal cells. Relatively many mesodiencephalic terminals, a similar serotoninergic, and a slightly increased dopaminergic input were found. The axon of one intracellularly labeled hypertrophic cell gave off recurrent collaterals bearing varicosities filled with vesicles. These results indicated that 1) hypertrophic olivary cells are affected by trophic factors not only at the cell body but also at the level of the somatic spines, dendrites, and axon, 2) the ratio of excitatory to inhibitory terminals is increased in the hypertrophic neuropil, whereas the monoaminergic input remains stationary, and 3) the electronic coupling between hypertrophic olivary neurons has shifted from a dendritic to a more somatic location due to a relatively high number of gap junctions between the somatic spines.     

Principle of neuronal organization of defensive reflexes in mollusks

Spontaneous and evoked synaptic activity of command neurons for the defensive response of spiracle closing were studied by simultaneous intracellular recording of activity of several identified CNS neurons in snails. Comparison of monosynaptic EPSPs in command neurons evoked by discharges of presynaptic neurons with spontaneous synaptic potentials indicated that the central organization of the defensive reflex is in the form of a two-layered neuron net in which each neuron of the afferent layer possesses a local receptive field, but which overlaps with other afferent neurons. Each neuron of the afferent layer is connected with each neuron of the efferent layer by monosynaptic excitatory connections that differ in efficiency (maximal only with one neuron of the efferent layer). Both receptive fields of neurons of the afferent layer and "fields of efficiency of synaptic connections" are distributed according to the normal law. As a result of this organization the neuron net acquires a new quality: The action of different stimuli leads to the appearance of differently located "spatial excitation profiles" of efferent layer neurons even when this action of the stimulus occurs not at the center of the receptive field.Institute of Higher Nervous Activity and Neurophysiology, Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 16, No. 1, pp. 26–34, January-February, 1984.     

Corticofugal postsynaptic influences on red nucleus neurons

The responses of red nucleus neurons to stimulation of the sensorimotor cortex was studied on nembutal-anesthetized cats. Most of the rubrospinal neurons were identified according to their antidromic activation. Stimulation of the sensorimotor cortex was shown to evoke in the red nucleus neurons monosynaptic excitatory potentials with a latency of 1.85 msec, polysynaptic excitatory potentials (EPSP), and inhibitory postsynaptic potentials (IPSP) with a latency of 9–24 msec. The EPSP often produced spikes. The probability of generation of spreading excitation is greater with motor cortex stimulation. The monosynaptic EPSP are assumed to arise under the influence of the impulses arriving over the corticorubral neurons as a result of excitation of axodendritic synapses. The radial type of branching of red nucleus neurons facilitates the transition from electrotonically spreading local depolarization to an action potential triggered by the initial axonal segment. Polysynaptic EPSP and IPSP seem to be a result of activation of fast pyramidal neurons whose axon collaterals are connected via interneurons with the soma of the red nucleus neurons.L. A. Orbeli Institute of Physiology of the Academy of Sciences of the Armenian SSR, Erevan. Translated from Neirofiziologiya, Vol. 3, No. 1, pp. 43–51, January–February, 1971.     

Postural interneurons in the abdominal nervous system of lobster

The nature of the synaptic relationship between 7 identified postural interneurons and 5 pairs of superficial motoneurons was examined by obtaining dual intracellular recordings from interneuron-motoneuron pairs in the lobster 2nd abdominal ganglion. For six different interneuron-motoneuron pairs EPSPs recorded from motoneurons occurred with a short (1 to 3 ms) fixed latency following each presynaptic spike recorded from the interneuron. This suggests that there is a monosynaptic relationship between these interneurons and motoneurons. Monosynaptic pathways accounted for 27% of all excitatory connections. Preliminary evidence indicates that the monosynaptic potentials are mediated by an excitatory chemical synapse since: all IPSPs occurred with latencies greater than 5 ms, there was no evidence for electrical coupling, and one of the interneurons produced facilitating PSPs. A majority of all monosynaptic connections were made by two of the flexion producing interneurons (FPIs), 201 and 301. The synaptic outputs of these FPIs were similar in that both made monosynaptic connections with a different bilaterally homologous pair of motoneurons. Both also produced larger EPSPs and more vigorous spiking in contralateral members of the bilateral motoneuron pairs. A previous study demonstrated that interneurons 201 and 301 are the only postural interneurons yet identified that express motor programs indistinguishable from command neurons. Taken together, these results suggest that certain intersegmental interneurons share properties with command neurons and driver neurons, and that there may not be a sharp morphological or functional distinction between these two cell types.     

Subthreshold aortic nerve inputs to neurons in nucleus of the solitary tract

Subthreshold aortic nerve (AN) inputs to neurons receiving a monosynaptic AN-evoked input (MSNs: respond to each of two AN stimuli separated by 5 ms) and neurons receiving a polysynaptic AN input (PSNs) in the nucleus of the solitary tract (NTS) were identified in anesthetized rats. In extracellular recordings from 24 MSNs and 49 PSNs, 12% of MSNs and 29% of PSNs only responded to AN stimulation during the application of excitatory amino acids. In intracellular recordings from 24 MSNs and 22 PSNs, 12% of MSNs and 14% of PSNs responded to AN stimulation with excitatory postsynaptic potentials that did not evoke action potential discharge. Reductions in arterial pressure produced minimal changes in the spontaneous discharge of suprathreshold AN-evoked neurons, suggesting that these neurons receive excitatory inputs from nonbaroreceptor sources. The results suggest that some baroreflex-related NTS neurons exist in a "reserve state and can be changed to an active state or vice versa. This will change the number of neurons involved in baroreflex circuits and provides a novel mechanism for regulating baroreflex function independently of alterations in peripheral afferent input.     

Regular pulse train transformation by the monosynaptic connection-neurophysiological data and their treating with simple stochastic neuron model

Firing pattern of neuronal activity evoked by regular stimulation of monosynaptic inputs to the neurons is described with simple stochastic neuron model. The model gives definite possibilities for an indirect evaluation of transformation in the real neurons which have to fit the following demands: 1) background activity was absent; 2) evoked activity was stationary within the wide range of stimulation frequencies; 3) spike occurrence times were within narrow limits in relation to the nearest stimuli. Experimental data obtained on three types of monosynaptic connections with different intensity of excitatory postsynaptic effects are compared with the model.     

Synaptic organization of supraspinal control over propriospinal ventral horn interneurons in cat and monkey spinal cord

Synaptic responses evoked in propriospinal neurons of the upper lumbar segments (L₃–L₄) by reticulo-, vestibulo-, and corticospinal impulses were studied in experiments on cats and monkeys. Propriospinal cells, identified by antidromic stimulation, were stained with Procion red, so that they could be localized in the different zones of the ventral horn. Monosynaptic reticular and vestibular excitatory influences were discovered in cats; convergence of these influences on the same neurons was demonstrated. In monkeys bulbospinal monosynaptic effects were supplemented by monosynaptic influences arriving from the motor cortex; convergence of monosynaptic excitatory influences from all supraspinal sources studied was found on some propriospinal neurons. The propriospinal neurons studied also had synaptic inputs from primary afferents.I. M. Sechenov Institute of Evolutionary Physiology and Biochemistry, Academy of Sciences of the USSR, Leningrad. Translated from Neirofiziologiya, Vol. 9, No. 2, pp. 177–184, March–April, 1977.     

Neural mechanisms generating the leech swimming rhythm: Swim-initiator neurons excite the network of swim oscillator neurons

Summary This paper describes newly identified excitatory connections linking the segmentally iterated swim-initiator interneurons with the network of oscillator neurons that generates the leech swimming rhythm. Apparently monosynaptic excitatory chemical connections are made from one class of swim-initiator neurons (cells 204/205) to several members of the swim oscillator network, including cells 28, 115 and, as described by Weeks (1982c), cell 208. A second class of swim-initiator neurons, cells 21 and 61, also excites this subset of the oscillator neurons.The unpaired swim oscillator neuron, cell 208, also chemically excites cells 28 and 115, apparently directly. Thus, in addition to its role as a member of the swim oscillator, the excitatory output from cell 208 to the swim oscillator adds to that provided by the swim-initiator neurons.The results of this paper enlarge the subset of identified swim oscillator neurons synaptically excited by the swim-initiator neurons. These newly described targets of the swim-initiators strengthen the hypotheses that: 1) the swim-initiator neurons supply much of the tonic excitatory drive responsible for activation and maintenance of the swim central motor program, and 2) the two classes of swim-initiators, cells 204/205 and cells 21/61, act synergistically to initiate and maintain swimming.Abbreviations EPSP excitatory postsynaptic potential - IPSP inhibitory postsynaptic potential - CNS central nervous system