电刺激蝙蝠小脑对中脑上丘神经元听反应的影响

实验在２３只成年中华鼠耳蝠（Ｍｙｏｌｉｓｃｈｉｎｅｎｓｉｓ）上进行。使用常规电生理学方法,观察了电刺激小脑对上丘神经元听反应的影响。在所观察的１７１个上丘神经元中,有１１６个（占６７．８４％）神经元听反应受到影响,其中７２个（占４２．１１％）表现为抑制效应,４４个（占２５．７３％）为易化效应。刺激小脑对上丘神经听反应的影响是双侧的。抑制或易化程度与电刺激强度、声刺激强度以及声、电刺激间隔有关。结果提示,小脑可以对上丘神经元听反应进行调制,这种调制作用可能是小脑调控回声定位过程中听觉－运动的中枢机制之一。     

电刺激蝙蝠中脑上丘对下丘听神经元电活动的影响

实验在24只鲁氏菊头蝠(Rhinolophus rouxi)上进行.使用玻璃微电极在中脑下丘中央核记录听神经元电反应.刺激点位于上丘核.共观察了294个对超声刺激产生反应的下丘听单位.当电刺激上丘时,有122个听单位的反应受到影响,占所观察总数的41.5%.其中96个单位表现为抑制性影响(占32.65%),26个单位表现为易代性效应(占8.84%).其余172个单位不受上丘刺激的影响(58.50%).实验中发现,上述抑制潜伏期一般在5毫秒以上,抑制时程较长.抑制程度与上丘刺激电流强度呈相关关系(r=0.99).实验中还发现,刺激上丘同样可抑制部分下丘神经元的自发放电活动,其抑制后效应相当长,有的可达120毫秒以上.     

GABA介导杏仁外侧核对皮层A Ⅰ区神经元声反应的抑制:在体微电泳研究

在SD大鼠上应用多顺利完成微电极方法,观察微电泳CABA及其受体的拮抗剂或激动剂对杏仁外侧核（LA）抑制皮层AⅠ神经元声反应效应的影响。结果显示,电泳GABA能抑制皮层AⅠ区神经元的电活动,电泳GABAA受体拮抗剂bicuculline（BIC）则能易化其反应;电刺激LA能抑制皮层AⅠ区听神经元声反应,电泳GABA产生类拟于刺激LA的抑制效应;LA对皮层AⅠ区神经的抑制效应能被BIC所翻转,而不能被什氨酸受体拮抗剂strychnine所翻转,电泳GABAB型受体例激动剂baclofen对神经元声反应无影响。上术结果表明,GABA可能是介民LA抑制皮层AⅠ区神经元声反应的最终递质,并且是通过GABAA受体作用的。     

γ-氨基丁酸能抑制对大棕蝠听皮层神经元声反应特性的影响

为了探讨γ－氨基丁酸（γ-aminobutyric acid,GABA)能抑制对大棕蝠(Eptesicus fuscus)听皮层(auditory cortex,AC)神经元声反应特性的影响,采用多管微电极电泳方法,观察了8只大棕蝠AC神经元去ABA能抑制前后声刺激诱发的反应。结果显示,微电泳GABAa受体拮抗剂荷包牡丹碱(bicuculline,Bic)去ABA能抑制可改变声刺激诱发的反应模式;极大地增加神经元冲动发放率,缩短反应的潜伏期和降低反应的最小阈值;不同程度地改变强度－发放率和强度－潜伏期函数。结果提示：1、GABA能抑制对AC神经元声信号处理起重要作用;2、GABA能抑制可改变AC神经元兴奋性支配或输入的效应,并因此定型AC神经元的声反应性质,即发放模式、阈值、强度－发放率和强度－潜伏期函数;3、GABA能抑制为AC神经元的声诱发活动提供一种调制性抑制。     

后掩蔽效应对大棕蝠下丘神经元声反应的影响

以回声定位蝙蝠为模式动物,采用在体动物细胞外单位记录法,研究了后掩蔽效应对下丘神经元声反应的影响。结果显示,部分神经元(38％,12／31)对测试声刺激的反应明显受到掩蔽声的抑制,其后掩蔽效应强弱与掩蔽声和测试声的相对强度差(inter-stimulus level difference,SLD),以及测试声与掩蔽声之间的间隔时间(inter-stimulus onset asynchrony,SOA)有关：当掩蔽声强度升高或测试声强度降低时,后掩蔽效应增强;而SOA的缩短,亦可见后掩蔽效应增强。另外,相当数量的神经元(52%,16／31)对测试声刺激的反应并不受掩蔽声的影响,其中有的神经元只有在特定SLD和SOA时,才表现出后掩蔽效应。而少数下丘神经元(10％,3／31)在特定SLD和SOA时,掩蔽声对测试声反应有易化作用。上述结果表明,部分下丘神经元参与了声认知活动中的后掩蔽形成过程,推测下丘神经元在定型声反应特性中,对掩蔽声诱导的兴奋前抑制性输入与测试声诱导的兴奋性输入之间的时相性动态整合起关键作用。     

抑制性频谱整合对大棕蝠下丘神经元声强敏感性的影响

自由声场条件下 ,采用特定双声刺激方法研究了不同频率通道之间的非线性整合对下丘神经元声强敏感性的调制作用。实验在 1 2只麻醉与镇定的大棕蝠 (Eptesicusfuscus)上进行 ,双电极同步记录 2个配对神经元的声反应动作电位。主要结果如下 :1 )所获 1 1 0个 (5 5对 )配对神经元中 ,85 5 %表现为抑制性频谱整合作用 ,其余 1 4 5 %为易化性频谱整合 ;2 )阈上 1 0dB (SPL)放电率抑制百分比与神经元最佳频率 (BF)及记录深度呈负相关 ;3)抑制效率随声刺激强度升高而逐步下降 ;4 )当掩蔽声分别位于神经元兴奋性频率调谐曲线(FTC)内 (MSin) /外 (MSout)时 ,其抑制效率存在差异。前者的放电率抑制百分比及声反应动力学范围(DR)下降百分比均显著高于后者 ;5 )抑制性频谱整合导致 3类DR改变 :6 1 6 %为下降、 1 0 9%增加、另有2 7 5 %变化小于 1 0 %。本结果进一步支持如下设想 :下丘不同频率通道之间的抑制性频谱整合参与了对强度编码的主动神经调制活动     

普氏蹄蝠下丘CF-CF联合敏感神经元的声反应

为了研究普氏蹄蝠(Hipposideros pratti)下丘(IC)中恒频-恒频(CF-CF)联合敏感神经元声反应特性,以及易化型和抑制型CF-CF联合敏感神经元在IC高频表征区神经元中所占的比例,实验记录了普氏蹄蝠IC神经元在不同频率和声强下的单声反应以及在不同延迟下的双声反应。本实验采用在体细胞内电生理技术从7只听力正常的蝙蝠上共获得77个IC声敏感神经元。所获得的数据经过处理并应用Sigma Plot 10.0软件作图。研究结果显示,77个神经元中37(48.1%)个为CF-CF联合敏感神经元,且多数为抑制型(24/37),少数为(13/37)易化型。实验结果说明普氏蹄蝠IC中既存在易化型也存在抑制型CF-CF联合敏感神经元,其中抑制型CF-CF联合敏感神经元比易化型所占比例更高。这些CF-CF联合敏感神经元有助于蝙蝠在巡航过程中处理回声信息时进行频谱和时相的整合。     

大鼠初级听皮层神经元对声音空间信息的编码

尽管大脑听皮层神经元对声音空间信息的编码已有不少的研究报道,但其编码机制并不十分清楚,相关研究在大鼠的初级听皮层也未见详细的研究报道．用神经电生理学方法在大鼠初级听皮层考察了151个听神经元的听空间反应域,分析了神经元对来自不同空间方位声刺激反应的放电数和平均首次发放潜伏期的关系．结果表明,多数(52.32%)神经元对来自对侧听空间的声刺激反应较强,表现为对侧偏好型特征,其他神经元分别归类为同侧偏好型(18.54%)、中间偏好型(18.54%)、全向型(3.31%)和复杂型(7.28%)．多数神经元偏好的听空间区域的几何中心位于记录部位对侧听空间的中部和上部．绝大多数初级听皮层神经元对来自偏好听空间的声刺激反应的放电数较多、反应潜伏期较短,对来自非偏好听空间的声刺激反应的放电数较少、反应潜伏期较长,放电数与平均首次发放潜伏期呈显著负相关．在对声音空间信息的编码中,大脑初级听皮层可能综合放电数和潜伏期的信息以实现对声源方位的编码．     

刺激家兔杏仁基底核对外膝体“ON”神经元感受野反应特性的影响

利用细胞外记录,在乌拉坦麻醉和三碘委按酚麻痹的３７只新西兰兔上,考察刺激杏仁基底核对外膝体神经元感受野反应特性的影响。实验观察到,在１１７个具有“ＯＮ”反应外膝体神经元中,４７个单位在电刺激杏仁基底核时不同程度地受到抑制或易化性影响,即细胞反应强度和／或感受野范围均有改变。产生这些影响的潜伏期为７－４１ｍｓ,最大时程约２８ｍｓ。撤除电刺激３ｍｉｎ后,感受野反应特性即告恢复。单独刺激杏仁核不能引起外     

去甲肾上腺素对大鼠丘脑束旁核痛反应神经元电活动的影响

本文观察了41只大鼠脑室注射去甲肾上腺素(NE)后对两侧束旁核痛反应神经元同时由活动的影响。结果表明:1.两个痛兴奋神经元(PEN)的电活动同时受至抑制,表现为诱发放电数目减少,潜伏期延长。2.两个痛抑制神经元(PIN)的抑制效应同时被解除,即诱发放电数目增加,抑制时程箱短。3.一个PEN的电活动受到抑制的同时,另一个PIN的电活动加强。上述结果证明NE能够同时影响丘脑束旁核PEN和PIN的电活动。     

Bilateral collicular interaction: modulation of auditory signal processing in amplitude domain

In the ascending auditory pathway, the inferior colliculus (IC) receives and integrates excitatory and inhibitory inputs from many lower auditory nuclei, intrinsic projections within the IC, contralateral IC through the commissure of the IC and from the auditory cortex. All these connections make the IC a major center for subcortical temporal and spectral integration of auditory information. In this study, we examine bilateral collicular interaction in modulating amplitude-domain signal processing using electrophysiological recording, acoustic and focal electrical stimulation. Focal electrical stimulation of one (ipsilateral) IC produces widespread inhibition (61.6%) and focused facilitation (9.1%) of responses of neurons in the other (contralateral) IC, while 29.3% of the neurons were not affected. Bilateral collicular interaction produces a decrease in the response magnitude and an increase in the response latency of inhibited IC neurons but produces opposite effects on the response of facilitated IC neurons. These two groups of neurons are not separately located and are tonotopically organized within the IC. The modulation effect is most effective at low sound level and is dependent upon the interval between the acoustic and electric stimuli. The focal electrical stimulation of the ipsilateral IC compresses or expands the rate-level functions of contralateral IC neurons. The focal electrical stimulation also produces a shift in the minimum threshold and dynamic range of contralateral IC neurons for as long as 150 minutes. The degree of bilateral collicular interaction is dependent upon the difference in the best frequency between the electrically stimulated IC neurons and modulated IC neurons. These data suggest that bilateral collicular interaction mainly changes the ratio between excitation and inhibition during signal processing so as to sharpen the amplitude sensitivity of IC neurons. Bilateral interaction may be also involved in acoustic-experience-dependent plasticity in the IC. Three possible neural pathways underlying the bilateral collicular interaction are discussed.     

Hypothalamic influences on unit activity in the cat sensomotor cortex

Experiments on unanesthetized, immobilized cats showed different effects of individual hypothalamic nuclei on spontaneous unit activity in the sensomotor cortex. Compared with the posterior hypothalamic nucleus (PHN) and its anteromedial region (AMH), in response to stimulation of the lateral hypothalamic nucleus (LHN) changes in spontaneous activity were more frequently found. The ratio between activation and inhibitory responses was 36 and 36% for AMH, 51 and 30% for LHN, and 47 and 28% for PHN. An approximately equal number of sensomotor neurons (27–34%) gave tonic responses. Phasic changes in spontaneous activity were observed more often in response to stimulation of LHN, less frequently to stimulation of AMH and PHN. Responses of "nonpyramidal" neurons to stimulation of AMH and LHN were identical. "Pyramidal" units were more sensitive to LHN stimulation. Variations in hypothalamic effects depending on the type of response of sensomotor neurons to sensory stimuli were detected. Cells with tonic responses were more susceptible to influences of LHN and AMH than cells which responded by phasic changes in spontaneous activity to sensory stimuli. Fewer still positive responses were recorded in areactive neurons.Medical Institute, Chita. Translated from Neirofiziologiya, Vol. 4, No. 2, pp. 115–122, March–April, 1972.     

Responses of caudate neurons to various visual stimuli in alert cats

Responses of caudate neurons to two kinds of visual stimuli, namely diffuse light and a more local stimulus (a slit of light), oriented in different directions on a screen, were studied in alert cats during natural fixation of the gaze. The number of neurons which responded to local stimulation was several times greater than the number responding to diffuse light. Besides on-responses to local stimulation, a more distinct phase of inhibition of activity during presentation of the stimulus and off-responses also appeared. The latent periods of responses to both kinds of stimulation were commensurate at 40–90 msec for most neurons. Differences in neuronal responses also were found on a change in orientation of the slit. The results are discussed from the standpoint of participation of the caudate nucleus in visual information analysis.     

Responses of neurons in the rat nucleus submedius to noxious and innocuous mechanical cutaneous stimulation

Extracellular recordings were used to characterize responses to cutaneous mechanical stimulation of 78 neurons in the rat nucleus submedius (SM). Thirty-nine of these units were activated by some type of cutaneous mechanical stimulation. Eighteen cells were activated exclusively by noxious stimuli. In 13 of these cells, responses were of swift onset and relatively rapid termination following stimulus application. In contrast, in three neurons responses were delayed both in onset and termination, and in two the response was immediate, but the markedly increased evoked activity outlasted stimulus application by 13 min. Receptive fields (RFs) of these nociceptive neurons were generally large, although none were bilateral. Four SM neurons were activated by innocuous stimuli, but their maximal response was obtained only after noxious stimulation. Responses of all of these neurons were of immediate onset and recovery, and their RFs were large (two were bilateral). Twelve SM neurons were activated maximally by innocuous stimuli. Responses of seven of these cells were immediate in onset and termination, while that of three were delayed in both onset and termination. Two of the 12 innocuous-only neurons quickly became unresponsive to repeated stimulus applications, and could be reactivated only after a rest period during which no stimuli were applied. RFs of these units were also generally large, and in three cases were bilateral. Five SM neurons responded by decreasing, or completely ceasing, their firing subsequent to noxious-only (n = 2), or innocuous-only (n = 3) stimulation. Four of these units had large RFs (two were bilateral). The remaining 39 SM neurons could not be activated by any type of mechanical cutaneous stimulation we tried. Electrical stimulation of the ventrolateral orbital cortex (VLO) was employed to examine frontal cortical projections of 21 SM neurons. Ten of these units were activated, although all of them synaptically rather than antidromically, and two were inhibited. There was no clear-cut relationship between neuronal location, physiological type, RF site, or VLO stimulation effects among the 39 SM neurons. These results provide further support for the involvement of SM neurons in nociceptive information signaling, and suggest additionally that the role of the nucleus is not limited to nociception but encompasses a wider range of cutaneous sensations.     

Responses of Neurons in the Rat Nucleus Submedius to Noxious and Innocuous Mechanical Cutaneous Stimulation

Extracellular recordings were used to characterize responses to cutaneous mechanical stimulation of 78 neurons in the rat nucleus submedius (SM). Thirty-nine of these units were activated by some type of cutaneous mechanical stimulation. Eighteen cells were activated exclusively by noxious stimuli. In 13 of these cells, responses were of swift onset and relatively rapid termination following stimulus application. In contrast, in three neurons responses were delayed both in onset and termination, and in two the response was immediate, but the markedly increased evoked activity outlasted stimulus application by 13 min. Receptive fields (RFs) of these nociceptive neurons were generally large, although none were bilateral. Four SM neurons were activated by innocuous stimuli, but their maximal response was obtained only after noxious stimulation. Responses of all of these neurons were of immediate onset and recovery, and their RFs were large (two were bilateral). Twelve SM neurons were activated maximally by innocuous stimuli. Responses of seven of these cells were immediate in onset and termination, while that of three were delayed in both onset and termination. Two of the 12 innocuous-only neurons quickly became unresponsive to repeated stimulus applications, and could be reactivated only after a rest period during which no stimuli were applied. RFs of these units were also generally large, and in three cases were bilateral. Five SM neurons responded by decreasing, or completely ceasing, their firing subsequent to noxious-only (n = 2), or innocuous-only (n = 3) stimulation. Four of these units had large RFs (two were bilateral). The remaining 39 SM neurons could not be activated by any type of mechanical cutaneous stimulation we tried.

Electrical stimulation of the ventrolateral orbital cortex (VLO) was employed to examine frontal cortical projections of 21 SM neurons. Ten of these units were activated, although all of them synaptically rather than antidromically, and two were inhibited. There was no clear-cut relationship between neuronal location, physiological type, RF site, or VLO stimulation effects among the 39 SM neurons.

These results provide further support for the involvement of SM neurons in nociceptive information signaling, and suggest additionally that the role of the nucleus is not limited to nociception but encompasses a wider range of cutaneous sensations.     

Conditions of appearance of off responses of sensomotor cortical neurons to photic stimulation in cats

In acute experiments on cats under chloralose anesthesia (70 mg/kg) unit activity was recorded extra- and intracellularly in the sensomotor cortex (areas 4 and 6) during prolonged (up to 1000 msec) photic stimulation. Responses of on-off type were generated by 100% of neurons tested to photic stimuli whose duration corresponded to the recovery cycle of functional changes after a single flash, determined by the paired stimulation method. Cutaneous stimulation affected the appearance of the photic off response if it led to a spike discharge of the neuron before the off response. It is suggested that IPSPs of cortical neurons largely determine both the duration of the cycle of functional recovery after a single flash and also differences in the pattern of generation of the off response and its interaction with responses to cutaneous stimulation.A. A. Zhdanov Leningrad State University. Translated from Neirofiziologiya, Vol. 9, No. 4, pp. 355–360, July–August, 1977.     

Multimodal interneurons in the cricket brain: properties of identified extrinsic mushroom body cells

Summary 322 neurons were recorded intracellularly within the central part of the insect brain and 150 of them were stained with Lucifer Yellow or cobaltous sulphide. Responses to mechanical, olfactory, visual and acoustical stimulation were determined and compared between morphologically different cell types in different regions of the central brain. Almost all neurons responded to multimodal stimulation and showed complex responses. It was not possible to divide the cells into different groups using physiological criteria alone.Extrinsic neurons with projections to the calyces connect the mushroom bodies with the deutocerebrum and also with parts of the diffuse protocerebrum. These cells probably give input to the mushroom body system. The majority are multimodal and they often show olfactory responses. Among those cells that extend from the antennal neuropil are neurons that respond to non-antennal stimulation (Figs. 1, 2).Extrinsic neurons with projections in the lobes of the mushroom bodies often project to the lateral protocerebrum. Anatomical and physiological evidence suggest that they form an output system of the mushroom bodies. They are also multimodal and often exhibit long lasting after discharges and changes in sensitivity and activity level, which can be related to specific stimuli or stimulus combinations (Figs. 3, 4).Extrinsic neurons, especially those projecting to the region where both lobes bifurcate, exhibit stronger responses to multimodal stimuli than other local brain neurons. Intensity coding for antennal stimulation is not different from other areas of the central protocerebrum, but the signal-tonoise ratio is increased (Fig. 5).Abbreviation AGT antenno-glomerular tract     

大鼠下丘神经元对重复刺激适应性的时频表征

自由声场下,通过给大鼠不同刺激呈现率（presentation rate,PR）的重复声刺激,用钨丝单电极记录神经元的放电信号,系统分析了下丘神经元对重复刺激的表征特性。作为发放率表征的刺激后脉冲发放数（spike count,SC）随着刺激重复不断减少,作为时间表征的首次发放潜伏期（first spike latency,FSL）逐渐延长,时间过程均呈指数形式变化。起始型神经元FSL 的时间常数大于SC,在FSL上呈现慢适应;持续性神经元FSL 的时间常数小于SC,在SC 上呈现慢适应。随着刺激呈现率PR 的增加,过渡过程的时间常数缩短,稳态SC减少,
稳态FSL延长。稳态SC 和FSL与PR呈对数线性关系,SC 的线性度更高。下丘神经元的适应性能够提高对新奇刺激的响应能力,为皮层下检测异常信息提供了可能。