电刺激大鼠尾壳核诱导丘脑外侧背核神经元出现与海马电图变化相关的特征性放电脉冲间隔

本文旨在探讨电刺激右侧尾壳核（caudate putamen nucleus,CPu）对双侧丘脑外侧背核（1aterodorsal thalamic nucleus,LD）单个神经元放电和海马（hippocampus,HPC）电图瞬时时间编码形式的调制性影响。用21只雄性Sprague-Dawley大鼠（150-250g）,重复急性强直电刺激（60Hz,2S,0．4-0．6mA）右侧尾壳核（acute tanizafion of the right caudate putamen nucleus,ATRC）诱发大鼠癫痫模型,4通道同步记录双侧LD神经元单位放电和双侧HPC深部电图。结果如下：重复施加ATRC可以诱导大鼠出现（1）双侧LD-HPC癫痫电网络间的功能性环状联系。起始点为对侧LD神经元原发性单位后放电,随后出现同侧LD神经元原发性单位后放电,然后呈现同侧HPC电图原发性后放电,最终引起对侧HPC电图脱同步化效应;（2）双侧LD神经元放电脉冲间隔（interspike intervals,ISIs）散点分布形式与刺激前呈现镜像对称特征。对侧LD神经元原发性后放电的ISI点分布基于底层而且持续时间较长,具有更加明显的突触可塑性特征;（3）随着ATRC串次的增加,对侧LD神经元原发性单位后放电间的爆发式放电时程逐渐延长,可以募集增强海弓电图同步化电活动;显现对侧LD神经元单个放电脉冲与HPC电图γ电振荡（20-25Hz）间的锁相（phase-lock）和锁时（time-lock）关系。结果提示：ATRC可以募集形成具有联系的双侧LD神经元放电和HPC电图特征性的神经信息编码形式,以对侧更加明显。这些跨越大脑半球、涉及多结构的功能性神经信息网络的建立很可能是癫痫发生、发展和扩布的重要信息编码机制。     

大鼠尾壳核-海马癫痫电网络的神经信息编码特征

目的：观察强直电刺激大鼠右侧尾壳核（CPu）时,CPu-海马（HPC）网络癫痫的神经信息编码特征。方法：雄性SD大鼠59只。急性或慢性强直电刺激CPu（acute tetanization of the right CPu or chronic tetanization of the right CPu,ATRC or CTRC）（60Hz．0．4～0．6mA,2s）诱导大鼠癫痫模型。结果：①ATRC可以诱导双侧HPC神经元出现非对称性癫痫相关性单位电活动．增加对侧HPC单位放电时间间隔（Interspike interval,ISI）点分布的分岔角度。②CTRC可以诱导双侧CPu网络出现尖波样连续发放,同侧振荡样网络发作具有明显的相位移动特征;频率变化顺序为70Hz、110Hz、35Hz以及30Hz．与时间呈显著的负相关;振荡波波峰间隔（Interpeak interval,IPI）和波峰振幅逐渐增大,与时间呈显著正相关。③CTRC后加ATRC可以分别诱导双侧CPu网络出现原发性后放电。结论：激活CPu可以跨大脑半球重建双侧CPu—HPC癫痫电网络．其神经信息编码特征可能成为癫痫发生的神经信息学基础。     

大鼠海马癫痫电网络重建中爆发式放电神经元的活动

本文探讨双侧海马(hippoeampus,HPC)神经网络中爆发式放电神经元(bursting-firing neurons,BFN)的活动规律及其与海马癫痫网络重建的关系。实验用雄性SD大鼠140只(150-250 g),急性强直电刺激(60 Hz,2 s,0.4-0.6 mA)右后背HPC CAl区(acute tetanization of the posterior dorsal hippocampus,ATPDH),同步记录同侧或对侧前背HPC单位放电和深部电图;强直电刺激右前背HPC(acute tetanization of the anterior dorsal hippocampus,AT-ADH),同步记录双侧前背HPC单位放电。实验共记录了13.8％(19/138)双侧前背HPC的BFN,其中13个为刺激诱发性BFN,6个为自发性BFN。强直电刺激引起的诱发反应包括:(1)ATPDH明显调制同侧前背HPC的BFN,产生规则的节律性爆发式放电,刺激后串内动作电位间期(bursting interspike interval,BISI)减小(P<0.001);(2)AT-PDH引起对侧前背HPC的BFN出现抑制后轻度调制效应,刺激后动作电位间期(interspike interval,ISI)增大(P<0.001);(3)ATADH后易化对侧前背HPC的自发性BFN节律,增加ISI(P<0.001)和IBI(P=0.01);(4)ATPDH诱导双侧前背HPC的BFN产生规则的节律性爆发式放电,伴有同步或非同步性网络癫痫的形成。上述实验结果提示,ATPDH沿同侧HPC长轴,跨大脑半球诱发前背HPC单个BFN的形成,其节律性爆     

电刺激诱导大鼠海马癫痫电网络神经信息分析

探讨电刺激致海马(hippocampus,HPC)癫痫网络的神经信息特征和M型胆碱能受体阻断剂东莨菪碱(scopolamine)对该信息特征的调制作用。实验用雄性SD大鼠45只,体重150￣250g。急性强直电(60Hz,2s,0.4￣0.6mA)刺激右侧后背HPC(acutetetanizationoftherightposteriordorsalhippocampus,ATPDH),双电极同步记录同侧HPC网络和单个神经元电活动。分析癫痫发作样高频电振荡(ripple)功率谱(powerspec-trum)、尖波连续发放峰间间隔(interpeakinterval,IPI)和单位时间内平均频率(Hz),并同步分析单个神经元放电脉冲间隔(interspikeinterval,ISI)的变化特征。发现:(1)ATPDH诱导的HPC癫痫放电模式主要包括rip-ple和具有稳定频率特征的尖波样连续发放;(2)东莨菪碱(i.p.)可以提前ripple第1组分最大功率(μV2)与单个神经元原发性单位后放电最大ISI出现的时间,对最大ISI的作用更明显;(3)东莨菪碱可以部分再现重复施加ATPDH诱导出现巨大尖波连续发放IPI和神经元放电ISI平行发展特征。结果提示:M胆碱能受体阻断剂东莨菪碱可以同时调制HPC癫痫网络成员电场和细胞的瞬时编码信息;而成员电场ripple功率谱/连续尖波IPI和神经元放电ISI点分布的对比研究,可以用于分析癫痫网络瞬时编码信息和药物生物学效应。     

电刺激大鼠右后背海马诱导前背海马神经网络癫痫样电活动

本文旨在探讨单侧海马(hippocampus,HPC)内神经网络与HPC癫痫发生的关系及其细胞机制。实验在45只SSprague-Dawley大鼠上完成。急性强直电刺激大鼠右侧后背HPC CAl基树突区(acute tetanizatio of the posterior dorsal hippocampus,ATPDH;60Hz,2s,0.4-0.6mA)诱发HPC癫痫模型,同步记录同侧前背HPC CAl顶树突区单位放电和基树突区深部电图。结果,ATPDH可以沿长铀向前1．8mm处对前背MIC神经网络产生下述效应：(1)同步或非同步原发性单位与深部电图后放电,在同步性后放电锁时(time-lock)关系明显。非同步性后放电的深部电图癫痫样电活动具有宽频带特征(5-90Hz);(2)原发性单位后放-后抑制效应可以引发低频原发性电图后放电,长时程爆发式单位放电可以诱发高频原发性电图后放电;(3)短束原发性电图后放电也可以诱发原发性单位后放电;(4)原发性电图后放电和神经元单位放电的抑制效应具有明显可塑性特征。以上结果提示,重复施加ATPDH可以引起前背HPC癫痫相关性病理生理性神经网络的重建;而单个神经元与神经网络的异常电活动之间具有明显的互动作用和突触传递可塑性特征;沿HPC长铀内在抑制性通路的过度活动也可以诱发电图癫痫样电活动,导致HPC网络癫痫的发生。     

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。     

强直电刺激右背海马诱发双侧海马神经元癫痫相关性单位放电特征

目的：探讨双侧海马细胞癫痫相关性单位放电特征。方法：双玻璃微电极同步记录大鼠44对双侧海马神经元单位放电,每隔5-10min重复强直电刺激右背海马（0.6-0.4mA60Hz2s)一次,共施加10-12个刺激串。结果：强直电刺激可以诱发双侧海马神经元单位放电的原发性和继发性后放,呈现明显的双侧非对称性和动态发展特征,甚至出现双侧交互性改变,与人类颞叶癫痫的病理生理特征相吻合;进行性发展、跨大脑半球扩布和动态变化,强直电刺激对海马细胞单位自发放电具有易化或抑制、调制或解调作用,并取决于这些细胞的基础单位放电,东莨菪碱可以调电刺激引起的海马细胞爆发式单位放电成为紧张性放电,诱导强直电刺激后单位放电频率的抑制效应。结论：强直电刺激右背海马后,双侧海马细胞特征性癫痫相关性单位电活动很可能是颞叶癫痫跨半球脑损伤的病理生理学机制之一。     

癫痫电网络重建过程中的海马-体循环动脉血压调节网络

目的:观察右侧海马(HPC)微量注射印防己毒素(PTX)诱导HPC癫痫电网络重建过程中HPG体循环动脉血压调节网络的形成.方法:将PTX(7.2μg)微量注射到大鼠右侧HPC诱发HPC癫痫,四通道同步记录左侧深部电图、单个HPC细胞外单位放电、左侧股动脉血压和标准Ⅱ导联心电图.结果:将PTX微量注射到右侧HPC后可以引起以下效应:①对侧HPC神经元长时程爆发式单位放电与单位后放电,并具有相似的脉冲间隔(interspike intervals,ISI)点分布;②延迟对侧HPC神经元爆发式单位放电与相对应的股动脉血压下降发生的时间关系;③出现复合式的对侧HPC神经元爆发式单位放电或单位后放电和股动脉血压下降耦合;④具有相似点分布特征的对侧HPC网络波峰间隔(interpeak intervals,IPI)和单个神经元ISI共同参与了HPC-体循环动脉血压调节网络的构成.结论:将PTX微量注射到右侧HPC可以在诱导对侧HPC癫痫网络形成的同时通过特征性的瞬时编码形式调制HPC-体循环动脉血压调节网络的功能活动.     

大鼠离体脑片癫痫放电特征及EC—海马环路的作用

目的和方法：采用４００～５００μｍ大鼠水平脑切片强直电刺激海马Ｓｃｈａｅｆｅｒ侧枝（６０Ｈｚ、２ｓ）全细胞、细胞外同步记录ＣＡ１神经元胞体电活动和相应树突区场电位,探讨其在癫痫发生中的作用。结果：①５３片脑片上记录到细胞内、外同步发生的原发性后放,持续２０ｓ以上,放电形式和持续时间常在第６个刺激串后趋于稳定。ＣＡ１神经元的原发性后放常跟在强直电刺激引起的阵发性去极化或超极化偏移之后（ＰＤＳ、ＰＨＳ）。它可以从紧张性放电向爆发性放电转化,振幅逐渐递增并与细胞外癫痫样放电同步,产生癫痫放电极性偏移;②其中８／４０脑片细胞外可记录到继发性后放之后出现的自发性发作样癫痫放电,长达数分钟,与全细胞记录的ＥＰＳＰ同步。切断ＥＣ与海马之间的联系可以易化海马癫痫电活动（３／５）。结论：ＥＣ输入到海马的神经通路可能在封闭的ＥＣ海马环路中起着重要的门控作用     

刺激大鼠右侧胼胝体激活对侧尾壳核-海马癫痫相关性神经网络

目的：探讨慢性激活右侧胼胝体(corpus callosum,CC)重建对侧尾壳核(caudate-putamen,CPu)-海马(hippocam-pus,HPC)癫痫网络的跨半球机制。方法：SD大鼠50只。慢性强直电刺激(60Hz,0．4～0．6mA,2s)右侧CC(chronic tetanization of the rignt CC,CTRCC),一天一次,8d后再次施加强直电刺激,同步记录左侧CPu(LCPu)和左侧HPC(LHPC)电图。结果：CTRCC①引起LCPu和LHPC出现深部电波的交互性抑制现象,LCPu电图出现持续尖波发放时交互抑制现象消失。②诱发LCPu和LHPC电图出现癫痫点燃现象。③未引起大鼠LCPu和LH-PC电图点燃时,急性强直电刺激可诱发LCPu出现高幅失律,压抑LHPC具有频率特征的尖波连续发放。④联合运用慢性和急性强直电刺激可诱导LCPu或LHPC电图出现原发性后放。结论：慢性激活ROC可促进对侧CPu-HPC癫痫网络的重建。形成新的癫痫病灶。     

Optogenetically Induced Seizure and the Longitudinal Hippocampal Network Dynamics

Epileptic seizure is a paroxysmal and self-limited phenomenon characterized by abnormal hypersynchrony of a large population of neurons. However, our current understanding of seizure dynamics is still limited. Here we propose a novel in vivo model of seizure-like afterdischarges using optogenetics, and report on investigation of directional network dynamics during seizure along the septo-temporal (ST) axis of hippocampus. Repetitive pulse photostimulation was applied to the rodent hippocampus, in which channelrhodopsin-2 (ChR2) was expressed, under simultaneous recording of local field potentials (LFPs). Seizure-like afterdischarges were successfully induced after the stimulation in both W-TChR2V4 transgenic (ChR2V-TG) rats and in wild type rats transfected with adeno-associated virus (AAV) vectors carrying ChR2. Pulse frequency at 10 and 20 Hz, and a 0.05 duty ratio were optimal for afterdischarge induction. Immunohistochemical c-Fos staining after a single induced afterdischarge confirmed neuronal activation of the entire hippocampus. LFPs were recorded during seizure-like afterdischarges with a multi-contact array electrode inserted along the ST axis of hippocampus. Granger causality analysis of the LFPs showed a bidirectional but asymmetric increase in signal flow along the ST direction. State space presentation of the causality and coherence revealed three discrete states of the seizure-like afterdischarge phenomenon: 1) resting state; 2) afterdischarge initiation with moderate coherence and dominant septal-to-temporal causality; and 3) afterdischarge termination with increased coherence and dominant temporal-to-septal causality. A novel in vivo model of seizure-like afterdischarge was developed using optogenetics, which was advantageous in its reproducibility and artifact-free electrophysiological observations. Our results provide additional evidence for the potential role of hippocampal septo-temporal interactions in seizure dynamics in vivo. Bidirectional networks work hierarchically along the ST hippocampus in the genesis and termination of epileptic seizures.     

Septal deafferentation produces continuous rhythmic slow activity (theta) in the rat hippocampus

Hippocampal EEG was recorded in behaving rats in which the brain stem afferents to the septal region were previously damaged. In these animals rhythmic slow activity (RSA or theta) was continuously present, including drinking and immobility. The average frequency of RSA, however, was significantly higher during running (8-9 Hz) than during drinking or awake motionless state (6-8 Hz). In normal rats irregular sharp waves, rather than RSA were present during drinking and immobility. The results suggest that brain stem afferents are necessary to suppress the rhythmic firing of septal "pacemaker" cells.     

The control of seizure-like activity in the rat hippocampal slice

The sudden and transient hypersynchrony of neuronal firing that characterizes epileptic seizures can be considered as the transitory stabilization of metastable states present within the dynamical repertoire of a neuronal network. Using an in vitro model of recurrent spontaneous seizures in the rat horizontal hippocampal slice preparation, we present an approach to characterize the dynamics of the transition to seizure, and to use this information to control the activity and avoid the occurrence of seizure-like events. The transition from the interictal activity (between seizures) to the seizure-like event is aborted by brief (20-50 s) low-frequency (0.5 Hz) periodic forcing perturbations, applied via an extracellular stimulating electrode to the mossy fibers, the axons of the dentate neurons that synapse onto the CA3 pyramidal cells. This perturbation results in the stabilization of an interictal-like low-frequency firing pattern in the hippocampal slice. The results derived from this work shed light on the dynamics of the transition to seizure and will further the development of algorithms that can be used in automated devices to stop seizure occurrence.     

Increased regularity of activity of cortical neurons in learning due to disinhibitory effect of reinforcement

This paper reviews the author's studies on neurophysiologic mechanisms of conditioned reflex learning. Electroencephalograms, evoked potentials, activity of neocortical and hippocampal neurons and the rabbits' behavior in the course of elaboration of defensive and inhibitory conditioned reflexes to light flashes have been recorded. Electric shock (ECS) applied to the paw served as reinforcement. The study demonstrated three types of reinforcement effect on the activity of cortical neurons: activating, disinhibitory, and inhibitory. EEG activation due to reinforcement is accompanied by a change in phasic cortical neuronal activity from chaotic or irregular, typical of rest or inhibition, to regular tonic discharges (in neocortex and hippocampus) and group discharges in the stress rhythm, 5-7 Hz in the hippocampus. Following a number of conditioning trials, the effect of reinforcement is simulated by the effect of a conditioned stimulus. With EEG activation and increased regularity in impulses, facilitation of motor reactions is observed.     

Picosecond Pulse Electrical Field Suppressing Spike Firing in Hippocampal CA1 in Rat In Vivo

Picosecond pulse electrical fields (psPEFs), due to their high temporal-resolution accuracy and localization, were viewed as a potential targeted and noninvasive method for neuromodulation. However, few studies have reported psPEFs regulating neuronal activity in vivo. In this paper, a preliminary study on psPEFs regulating action potentials in hippocampus CA1 of rats in vivo was carried out. By analyzing the neuronal spike firing rate in hippocampus CA1 pre- and post-psPEF stimulation, effects of frequency, duration, and dosimetry of psPEFs were studied. The psPEF used in this study had a pulse width of 500 ps and a field strength of 1 kV/mm, established by 1 kV picosecond voltage pulses. Results showed that the psPEF suppressed spike firing in hippocampal CA1 neurons. The suppression effect was found to be significant except for 10 s, 10 Hz. For short-duration stimulation (10 s), the inhibition rate of spike firing increased with frequency. At longer stimulation durations (1 and 2 min), the inhibition rate increased and decreased alternately as the frequency increased. Despite this, the inhibition rate at high frequencies (5 and 10 kHz) was significantly larger than that at 10 and 100 Hz. A cumulative effect of psPEF on spike firing inhibition was found at low frequencies (10 and 100 Hz), which was saturated when frequency reached 500 Hz or higher. This paper conducts a study on psPEF regulating spike firing in hippocampal CA1 in vivo for the first time and guides subsequent study on psPEF achieving noninvasive neuromodulation. © 2020 Bioelectromagnetics Society     

体感皮层神经元放电间隔的概率密度函数与分布参数

本文建立了估计ISI概率密度函数的标准化ISI直方图和分布参数拟合方法,对34例猫体感皮层神经元自发和诱发放电活动进行了统计分析.