在体大鼠海马CA1区侧枝/联合纤维通路和TA通路的不同EPSP空间整合特性

在麻醉Wistar大鼠上,结合脑室给药,应用双电极刺激技术刺激海马独立的两条侧枝／联合纤维通路、TA通路,并在CA1区放射层记录兴奋性突触后电位（EPSP）,对海马CA1区锥体细胞近、远端树突EPSP的空间整合进行了初步探讨。结果表明,海马CA1区锥体细胞近、远端树突的空间整合都是亚线性的;近端树突的空间整合不受期望值大小的影响,但远端树突的空间整合随期望值增加而减小（更趋于亚线性）。此外,荷包牡丹碱没有影响EPSP的空间整合;但瞬时A型钾通道（IAK^＋）的拮抗剂氨基吡啶-4却使得近端树突的空间整合趋于线性发展。本研究表明,海马CA1锥体细胞近、远端树突不同的被动、主动特征使它们具有了不同的空间整合特性。由于近端树突接受海马内部侧枝／联合纤维投射的信息,远端树突通过TA通路接受内嗅皮层投射的信息,由此提示,CA1区锥体细胞对来自海马内部和直接来自皮层的信息输入采用了不同的整合方式。     

胚胎海马修复成年大鼠隔核-齿回-海马本体的神经元连接

本文利用脑内移植技术,研究胚胎海马修复成年大鼠隔核—齿回—海马本体的神经元连接用5μg秋水仙碱(colchicine)以局部注射的方式,选择性地损毁大鼠海马齿回的颗粒细胞。注射后1.5月,在损毁区未见颗粒细胞和苔状纤维残留;在齿回分子层,乙酰胆碱酯酶染色所显示的精细分层消失。取20天胚胎的海马并移植到宿主的损毁区,在30—40天实验期内,移植物在宿主脑内生长良好。脑切片经Timm染色,可以观察到当移植物齿回颗粒细胞靠近宿主CA 3区锥体细胞、两者之间又无胶质细胞疤痕阻挡时,移植物的苔状纤维沿宿主CA 3区透明层生长并接近CA 1区,基本上恢复了宿主原来的支配模式。在移植物的齿回颗粒细胞区,乙酰胆碱酯酶(AChE)的反应要比移植物的锥体细胞区更为显著。上述结果表明神经移植物能修复被损毁的隔核-齿回-海马本体的神经元连接。     

刺激鲫鱼小脑腹外侧区诱发的Mauthner细胞兴奋性突触后电位

实验采用微电极胞内记录技术探查鲫鱼Mauthner细胞(M-细胞)对小脑刺激的电反应特征。电刺激鲫鱼小脑腹外侧部,可在双侧M-细胞胞体、腹侧树突和外侧树突近端记录到一种复合性兴奋性突触后电位(小脑诱发性EPSP)。小脑诱发性EPSP潜伏期较短(0.63±0.09 ms),持续时间较长(5.49±1.13 ms),幅度分级和刺激频率依从等特征。以较高强度刺激小脑常引起M-细胞顺向激活。多点胞内连续穿刺实验显示小脑诱发性EPSP起源于腹侧树突远端。实验结果提示,小脑-M-细胞通路可能包含一组长短不等的神经元链,它们根据链的短或长,由近及远依次投射在腹侧树突远端。     

血小板激活因子对大鼠海马脑片CA1区LTP的作用

目的:为了探讨血小板激活因子(platelet-activating factor,PAF)对大鼠海马脑片CA1区的长时程增强效应(long-term potentiation,LTP)的影响.方法:应用离体脑片电生理记录技术,记录大鼠海马CA1区的兴奋性突触后电位EPSP,研究了PAF对大鼠海马脑片CA1区的突触传递和可塑性的影响.结果:小剂量(1μmol/L)PAF可诱发大鼠海马CA1区LTP的产生;大剂量(10～50μmol/L)PAF不能诱发大鼠海马CA1区LTP的产生,且不能阻止高频电刺激(HFS,100 Hz,1 000 ms×2,每隔20 s给予)Schffer侧支引起的大鼠海马脑片CA1区LTP的形成和维持.大剂量PAF对海马CA1区基础EPSP没有影响.PAF受体拮抗剂银杏苦内酯(ginkgolide B,GB)可拮抗小剂量PAF诱发大鼠海马CA1区LTP的产生.结论:大剂量PAF具有神经毒性,可能是通过抑制海马CA1区的LTP的形成而参与艾滋病痴呆(HIV-1 associated dementia,HAD)的形成机制.     

HIV-1 gp120对鼠海马长时程增强效应的影响

为了探讨人类免疫缺陷病毒Ⅰ型(HIV-1)的包膜糖蛋白gp120对鼠海马脑片CA1区的突触传递及可塑性的影响,应用离体脑片记录技术,记录大鼠海马CA1区的兴奋性突触后电位(excitatory postsynaptic potential,EPSP),研究了gp120对高频电刺激Schaffer侧支引起的鼠长时程增强效应(long-term potentiation,LTP)的影响.结果发现:gp120对大鼠海马CA1区LTP产生抑制作用,对其基础EPSP没有影响,而且这种抑制效应随着gp120浓度增大而增强,即具有剂量依赖性.PKA/PKC蛋白激酶抑制剂H7可以反转这种抑制效应.提示:gp120可能是通过抑制海马CA1区的LTP而参与艾滋病相关性痴呆(HIV-1 associated dementia,HAD)的形成.     

电针和吗啡对伤害性刺激猫内脏大神经引起的海马诱发电位的影响

在氯醛糖麻醉并箭毒化的50只猫中,观察了强电流刺激内脏大神经时的背侧海马诱发电位(Hippocampal evoked potential,HEP)以及电针和吗啡对其影响。结果显示,用20V电压刺激内脏大神经可以兴奋包括 Aδ和 C 纤维在内的几乎全部纤维,并且可以在海马内记录到波形稳定的 HEP。以负波为主的 HEP 在海马锥体细胞层附近以及下脚复合体的表浅层记录到,以正波为主的 HEP 在海马锥体细胞顶树突的中下部记录明显。只有刺激强度达到兴奋内脏大神经的 Aδ纤维时才可记录出 HEP。吗啡对 HEP 有显著的抑制作用。电针也可以明显抑制 HEP 的振幅,并有后作用。上述结果提示,内脏大神经中的感觉纤维,包括痛纤维的冲动可以传至海马。     

慢性应激对大鼠海马锥体细胞形态结构的效应

为研究慢性应激相关精神障碍的发病机制,采用尼氏（Nissl）染色法、高尔基（Golgi）镀染法和透射电镜技术,探讨慢性应激对大鼠海马CA1、CA3区锥体细胞形态结构的效应.结果显示应激组大鼠海马CA1区锥体细胞形态结构较对照组无明显变化.应激组海马CA3区锥体细胞数（35.14±3.85）较对照组(38.74±3.54)显著减少（P＜0.05）;顶树突的总长度（155.67 μm±33.32 μm）较对照组（195.63 μm±34.61 μm）显著缩短（P＜0.05）;应激组大鼠海马CA3区锥体细胞出现超微结构的改变,包括细胞固缩、体积缩小、核膜皱缩、线粒体变性和粗面内质网模糊不清.这提示海马CA3区锥体细胞形态结构的改变,可能是慢性应激相关精神障碍的病理生理基础.     

牦牛海马的形态特征及成体神经发生的初探

采用传统H.E 染色和Golgi-Cox 染色方法观察成年牦牛海马结构的形态和细胞构筑,并通过DCX - DAB免疫组化染色和DCX/ NeuN、GFAP / NeuN 双重免疫荧光标记等技术观察齿状回颗粒下层中的新生神经元和放射状胶质细胞。结果表明,牦牛海马结构主要包括齿状回和海马本部,二者分层清晰。海马的主要细胞为颗粒细胞、苔藓细胞和锥体细胞。CA3 区的锥体细胞胞体较CA1 区的大,但其顶树突的平均长度较短。CA1 区的锥体细胞明显分为两层,而CA3 区的则为一层。DCX 阳性细胞的胞体主要集中在齿状回颗粒下层靠近门区处,沿颗粒层内侧单个或少数聚集分布。沿齿状回颗粒下层分布着一层GFAP 阳性的放射状胶质细胞样细胞,其胞质和单极性的细长突起均呈GFAP 阳性,而胞核为阴性。在整个海马结构中均有大量星形GFAP 阳性细胞散在分布,特别是海马分子层和门区内靠近颗粒层部分的密度较其它部位大。牦牛海马的形态结构与绵羊的相似,而与大鼠、小鼠、家猫、兔子等小型哺乳动物有一定差别。两种DCX 免疫组化实验结果表明在牦牛海马中存在着新生神经元。GFAP 免疫荧光标记表明,牦牛海马结构中分布有星形胶质细胞;特别是放射状胶质细胞。     

应激诱发的海马神经元突触增强参与大鼠的新环境学习

本文旨在研究应激对海马新环境空间学习记忆的损伤作用机制.在大鼠海马CA1区埋植电极,刺激schaffer侧枝记录CA1区树突层的兴奋性突触后场电位(field excitatory postsynaptic potential,fEPSP),探索应激对火鼠新环境空间学习的突触可塑性的影响.同时研究了再次新环境空间学习时...     

电刺激右后背海马诱导双侧前背海马网络癫痫

目的 :急性强直电刺激右侧后背HPC诱导双侧HPC癫痫电网络形成的细胞机制。方法 :强直电刺激 (6 0Hz,2s,0 .4～ 0 .6mA)大鼠右后背HPCCA1基树突区 ,每隔 10min刺激一次 ,施加 10个刺激串。结果 :①分别抑制双侧CA1神经元单位放电频率 ,对侧的抑制效应更明显 (对侧 :6 2 .94 %± 3.6 8% ;同侧 :36 .6 1%± 3.14 % ,P <0 .0 1) ,出现抑制后爆发式放电。随着刺激串数的增加 ,抑制作用逐渐减弱。②同步原发性网络和单位后放电 ,以同侧CA1多见 (P<0 .0 1)。③ 90Hz或 12 0Hz原发性或继发性网络后放电仅仅累及同侧CA1。④对侧CA3基树突区网络与下托神经元单位放电出现同步继发性后放电 ,反复发作 ,持续约数小时。结论 :电刺激诱导的对侧HPC抑制后爆发式放电和长时程、反复发作的网络与单个神经元同步继发性后放电可能是跨半球癫痫网络形成的重要表现形式。     

Pyramidal cell-to-inhibitory cell spike transduction explicable by active dendritic conductances in inhibitory cell

In the guinea-pig hippocampal CA3 region, the synaptic connection from pyramidal neurons tostratum pyramidale inhibitory neurons is remarkable. Anatomically, the connection usually consists of a single release site on an interneuronal dendrite, sometimes 200 m or more from the soma. Nevertheless, the connection is physiologically powerful, in that a single presynaptic action potential can evoke, with probability 0.1 to 0.6, a postsynaptic action potential with latency 2 to 6 ms. We construct a model interneuron and show that the anatomical and physiological observations can be reconciled if the interneuron dendrites are electrically excitable. Excitable dendrites could also account for depolarization-induced amplification of the pyramidal cell-interneuron EPSP in the voltage range subthreshold for spike generation.     

Postnatal neuronal plasticity of the pyramidal cells of CA1 area of the hippocampus as a reaction to neurotoxic damage.

Kainic acid (KA) was injected into both lateral ventricles of the brain of adult laboratory rats with the aim of verifying whether damage to afferent fibres in the hippocampal CA1 area would also be reflected in changes in the dendritic arborization of the neurones after maturation of these structures was completed. A significant proportion of the afferent fibres ending in area CA1 comes from CA3-4. The neurodegenerative effect of KA on the neurones in CA3-4 thus leads to marked reconstruction of the dendritic network of the pyramidal cells in the CA1 area. In the CA1 area of the experimental animals, there are fewer segments in the proximal part of the basal dendrites and in the lateral branches of the apical dendrites. The total number of segments in the apical dendrites is smaller and the higher order segments are likewise reduced. In the experimental group, the segments of both the basal and the apical dendrites are shorter. In the experimental animals, dendritic spine density in the lateral preterminal branches, the distal part of the apical shaft, the terminal segments of the lateral branches and the apical preterminal branches are smaller than in the controls, whereas in the segments proximal to the soma of the pyramidal cells it is greater. It can be seen from the results that area CA1 of the hippocampus is endowed, even in adulthood, not only with high functional plasticity, but also with surprisingly high morphological plasticity.     

Phosphorylation of CRMP2 is involved in proper bifurcation of the apical dendrite of hippocampal CA1 pyramidal neurons

The neural circuit in the hippocampus is important for higher brain functions. Dendrites of CA1 pyramidal neurons mainly receive input from the axons of CA3 pyramidal neurons in this neural circuit. A CA1 pyramidal neuron has a single apical dendrite and multiple basal dendrites. In wild‐type mice, most of CA1 pyramidal neurons extend a single trunk, or alternatively, the apical dendrite bifurcates into two daughter trunks at the stratum radiatum layer. We previously reported the proximal bifurcation phenotype in Sema3A?/?, p35?/?, and CRMP4?/? mice. Cdk5/p35 phosphorylates CRMP2 at Ser522, and inhibition of this phosphorylation suppressed Sema3A‐induced growth cone collapse. In this study, we analyzed the bifurcation points of the apical dendrites of hippocampal CA1 pyramidal neurons in CRMP2KI/KI mice in which the Cdk5/p35‐phosphorylation site Ser522 was mutated into an Ala residue. The proximal bifurcation phenotype was not observed in CRMP2KI/KI mice; however, severe proximal bifurcation of apical dendrites was found in CRMP2KI/KI;CRMP4?/? mice. Cultured hippocampal neurons from CRMP2KI/KI and CRMP2KI/KI;CRMP4?/? embryos showed an increased number of dendritic branching points compared to those from wild‐type embryos. Sema3A increased the number of branching points and the total length of dendrites in wild‐type hippocampal neurons, but these effects of Sema3A for dendrites were notobserved in CRMP2KI/KI and CRMP2KI/KI;CRMP4?/?hippocampal neurons. Binding of CRMP2 to tubulin increased in both CRMP2KI/KI and CRMP2KI/KI:CRMP4?/? brain lysates. These results suggest that CRMP2 and CRMP4 synergistically regulate dendritic development, and CRMP2 phosphorylation is critical for proper bifurcation of apical dendrite of CA1 pyramidal neurons. © 2012 Wiley Periodicals, Inc. Develop Neurobiol, 2013     

SP-SR interneurones: a novel class of neurones of the CA2 region of the hippocampus

The CA2 region of the hippocampus has distinctive properties and inputs and may be linked with the pathology of specific psychiatric and neurological disorders. It is, therefore, important to understand CA2 circuitry and its involvement in the circuitry of the hippocampus. Properties of CA2 basket cells have been reported. However, other classes of CA2 interneurones with cell bodies located in stratum pyramidale remained to be described. In this study, the unusual axonal arbors of a novel subclass of dendrite-preferring CA2 interneurones whose somata are located in the pyramidal cell layer was revealed following intracellular recordings and biocytin labeling. One to four apical dendrites emerged from the soma, branched in stratum radiatum (SR) forming a tuft, but rarely penetrated stratum lacunosum-moleculare (SLM). One or two basal dendrites branched close to the soma, the branches extended through stratum oriens (SO) and often reached the alveus. Unlike CA2 bistratified cells, the axons of these cells arborized almost exclusively in SR with few, if any, branches extending to stratum pyramidale (SP), SO, or SLM. These interneurones again, unlike bistratified cells, were immunonegative for parvalbumin and cholecystokinin. Electrophysiologically, they were similar to some CA2 basket and bistratified cells in that they presented a "sag" in response to hyperpolarizing current injections and displayed spike frequency adaptation. They targeted the apical dendrites of neighboring CA2 pyramidal cells and received inputs from them.     

Computational simulation of the input-output relationship in hippocampal pyramidal cells

The precise mapping of how complex patterns of synaptic inputs are integrated into specific patterns of spiking output is an essential step in the characterization of the cellular basis of network dynamics and function. Relative to other principal neurons of the hippocampus, the electrophysiology of CA1 pyramidal cells has been extensively investigated. Yet, the precise input-output relationship is to date unknown even for this neuronal class. CA1 pyramidal neurons receive laminated excitatory inputs from three distinct pathways: recurrent CA1 collaterals on basal dendrites, CA3 Schaffer collaterals, mostly on oblique and proximal apical dendrites, and entorhinal perforant pathway on distal apical dendrites. We implemented detailed computer simulations of pyramidal cell electrophysiology based on three-dimensional anatomical reconstructions and compartmental models of available biophysical properties from the experimental literature. To investigate the effect of synaptic input on axosomatic firing, we stochastically distributed a realistic number of excitatory synapses in each of the three dendritic layers. We then recorded the spiking response to different stimulation patterns. For all dendritic layers, synchronous stimuli resulted in trains of spiking output and a linear relationship between input and output firing frequencies. In contrast, asynchronous stimuli evoked non-bursting spike patterns and the corresponding firing frequency input-output function was logarithmic. The regular/irregular nature of the input synaptic intervals was only reflected in the regularity of output inter-burst intervals in response to synchronous stimulation, and never affected firing frequency. Synaptic stimulations in the basal and proximal apical trees across individual neuronal morphologies yielded remarkably similar input-output relationships. Results were also robust with respect to the detailed distributions of dendritic and synaptic conductances within a plausible range constrained by experimental evidence. In contrast, the input-output relationship in response to distal apical stimuli showed dramatic differences from the other dendritic locations as well as among neurons, and was more sensible to the exact channel densities. Action Editor: Alain Destexhe     

Laminar analysis of hippocampal potentials evoked by peripheral stimulation

From areas SA₁ and SA₂ of the dorsal hippocampus of unanesthetized rabbits immobilized with d-tubocurarine a laminar analysis was made of evoked potentials (EP) in response to stimulation of the sciatic nerves. Inversion of the initial surface-positive phase of the EP was observed at the level of the pyramidal layer. The subsequent surface-negative phase reached a maximum value in the layer of basal dendrites of the pyramidal cells. The initial portion was inverted somewhat above the pyramidal layer and reached its maximum value approximately at the boundary of the pyramidal and radial layers. The change in sign of the remaining portion of this component occurred 0.3–0.4 mm deeper than the pyramidal layer. It is suggested that both components of the EP picked up from the hippocampal surface are due to an excitatory postsynaptic potential (EPSP) at the apical (positive phase), and basal (negative phase) dendrites. The positivity in the region of the pyramidal somata appears to be an extracellular reflection of a composite postsynaptic potential (IPSP) generated in this region.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 2, No. 4. pp. 434–438, July–August, 1970.     

Comparative mapping of opioid receptors and enkephalin immunoreactive nerve terminals in the rat hippocampus. A radiohistochemical and immunocytochemical study

Opioid receptors can be localized to the hippocampal formation of the rat by autoradiography. The binding of 3H-enkephalinamide to fixed and mounted tissue sections has all the characteristics associated with binding to opioid receptors. It is saturable, of high affinity and displays stereospecificity. The opioid receptor distribution shows striking regional variation throughout the hippocampal formation. Areas with high density include the pyramidal cell layer of both regio superior (CA1) and regio inferior (CA3), stratum moleculare of the hippocampus, the cell layer of subiculum, the superficial part of presubiculum and the deep layer (VI) of the medial and lateral entorhinal cortices. Areas with low to medium densities include regions corresponding to the dendritic field of the pyramidal cells (str. oriens, str. radiatum and the mossy fiber zone), the dentate granule cell layer and the molecular layer of the dentate area. Enkephalin-like immunoreactivity is detected in both intrinsic neuronal systems: 1) the mossy fibers which terminate on the proximal part of the CA3 pyramidal cell dendrites and on CA4 pyramidal cells, 2) cell bodies with multiple short processes, probably interneurons, dispersed throughout the hilus of the dentate area, the pyramidal cell layer of hippocampus, the str. radiatum, and occasionally in the str. moleculare and in the str. oriens, and extrinsic neuronal systems: 1) the lateral perforant path and 2) the lateral temporo-ammonic tract. Thus, the hippocampus contains intrinsic systems of enkephalin-like immunoreactive nerve terminals which may exert their effect on the opioid receptors with a localization corresponding to the pyramidal cells and their apical dendrites. Extrinsic enkephalinergic systems corresponding to the terminal fields of the lateral perforant path and the temporoammonic tract, both of entorhinal origin, may influence the opioid receptors located in the molecular layer of the dentate area, and in the molecular layer of the hippocampus and the subiculum. Thus, the enkephalin-like immunoreactive nerve terminals are all located in areas which contain opioid binding sites. This suggests that the "opioid peptide-opioid receptor" systems may regulate hippocampal neuronal activity via neurotransmission or neuromodulation. However, a high or medium number of opioid binding sites occur over the pyramidal cell bodies and the dentate granule cell bodies, and these opioid binding sites are not in close contact with the major enkephalinergic systems.(ABSTRACT TRUNCATED AT 400 WORDS)     

The features of the hippocampal structure as a neuroanatomical basis for differences in behavior

Neuromorphological and behavioural studies have been made on several strains of mice (C57B1, DBA/2, SEC) and on the spiny mouse Acomys cahirinus. It was shown that animals with different genotypes differ by the size of fascia dentata and by the extension of the pyramidal layer in CA3 field of the hippocamp. Animals with a higher learning capacity exhibited smaller layer of granular cells in the fascia dentata, which may be due to a lower density of neurones in this region. Terminals of the mossy fibers--the axons of granular cells--were found mainly on the apical dendrites of the pyramidal cells in CA3 field. On the contrary, in animals with lower capacities to learning, mossy fiber terminals were observed mainly on the basal dendrites of the pyramidal cells, the extent of the granular layer in these animals being significantly larger.     

Comparative mapping of opioid receptors and enkephalin immunoreactive nerve terminals in the rat hippocampus

Summary Opioid receptors can be localized to the hippocampal formation of the rat by autoradiography. The binding of ³H-enkephalinamide to fixed and mounted tissue sections has all the characteristics associated with binding to opioid receptors. It is saturable, of high affinity and displays stereospecificity. The opioid receptor distribution shows striking regional variation throughout the hippocampal formation. Areas with high density include the pyramidal cell layer of both regio superior (CA1) and regio inferior (CA3), stratum moleculare of the hippocampus, the cell layer of subiculum, the superficial part of presubiculum and the deep layer (VI) of the medial and lateral entorhinal cortices. Areas with low to medium densities include regions corresponding to the dendritic field of the pyramidal cells (str. oriens, str. radiatum and the mossy fiber zone), the dentate granule cell layer and the molecular layer of the dentate area. Enkephalin-like immunoreactivity is detected in both intrinsic neuronal systems: 1) the mossy fibers which terminate on the proximal part of the CA3 pyramidal cell dendrites and on CA4 pyramidal cells, 2) cell bodies with multiple short processes, probably interneurons, dispersed throughout the hilus of the dentate area, the pyramidal cell layer of hippocampus, the str. radiatum, and occasionally in the str. moleculare and in the str. oriens, and extrinsic neuronal systems: 1) the lateral perforant path and 2) the lateral temporo-ammonic tract. Thus, the hippocampus contains intrinsic systems of enkephalin-like immunoreactive nerve terminals which may exert their effect on the opioid receptors with a localization corresponding to the pyramidal cells and their apical dendrites. Extrinsic enkephalinergic systems corresponding to the terminal fields of the lateral perforant path and the temporoammonic tract, both of entorhinal origin, may influence the opioid receptors located in the molecular layer of the dentate area, and in the molecular layer of the hippocampus and the subiculum. Thus, the enkephalinlike immunoreactive nerve terminals are all located in areas which contain opioid binding sites. This suggests that the opioid peptide-opioid receptor systems may regulate hippocampal neuronal activity via neurotransmission or neuromodulation. However, a high or medium number of opioid binding sites occur over the pyramidal cell bodies and the dentate granule cell bodies, and these opioid binding sites are not in close contact with the major enkephalinergic systems. Such binding sites could represent newly synthesized opioid receptors ready for the enkephalinergic synapses of the cells and/or internalization of opioid receptors after stimulation at the synapses. Another possibility is the existence of cytoplasmic opioid binding sites (possibly t-RNA synthetase) with specific intracellular functions.     

Function of synapses in the CA1 region of the hippocampus: their contribution to the generation or control of epileptiform activity

1. In the kainic acid lesioned hippocampus there is a loss of functional inhibition that is associated with reduction of the IPSPs recorded intracellularly from the surviving CA1 pyramidal cells. The possible pre- or postsynaptic origin of this change has been investigated. 2. Iontophoretic application of GABA to the soma and dendrites of CA1 pyramidal cells indicated that there had been no change in the efficacy of the postsynaptic GABA receptors on these cells. 3. Although a pre-synaptic mechanism is implicated, at one week post lesion we were unable to find any difference in the Ca+ dependent K+ evoked release of endogenous GABA. However, at survival times greater than 1 week immunohistological studies showed a decrease in the number of somatostatin positive non-pyramidal cells in the stratum oriens of the CA1 area. 4. In addition to the reduction of functional inhibition, changes in excitatory neurotransmitter mechanisms were also found to contribute to the epileptiform burst discharge. A slow component of the epileptiform EPSP recorded from CA1 pyramidal cells has been recorded and was found to be antagonized by the NMDA-receptor antagonist D-APV. 5. Methods of controlling epileptiform activity in the kainic acid lesioned hippocampus have been tested. Stimulation of the substantia nigra and ventral tegmental areas produced profound inhibition of pyramidal cell activity in control hippocampi; however, they, were found to be ineffective in controlling the epileptiform burst. 6. A second method involved the use of hippocampal suspension grafts. Whilst this approach has yielded some encouraging data, further studies are necessary before the mechanism of the improvement in inhibitory synaptic function can be explained.