多通道神经元锋电位检测和分类的新方法

大脑神经元胞外单细胞动作电位(即锋电位)的检测和分类是提取神经元脉冲序列、研究神经系统信息处理机制的关键．为了提高锋电位的检出率和分类的正确性,设计了一种处理多通道锋电位记录信号的算法,用于分析微电极阵列记录的大鼠海马神经元锋电位信号,电极阵列上的测量点排列紧密,4个通道可以同时记录到来自相同神经元的信号．该算法首先利用一种多通道阈值检测法检出四通道记录信号中的锋电位,然后利用一种基于复合锋电位的主成分特征参数分类法将锋电位分类．仿真数据和实验记录信号的检验结果表明：与相应的单通道算法相比,该算法的锋电位检出率和分类的正确性显著提高,并且可以增加单次实验测得的神经元数目．因此,该算法为实现神经元锋电位的自动检测提供了一种简单有效的新 方法．     

高频电刺激改变神经元锋电位的波形

为了正确检测和研究高频电刺激(high frequencystimulation,HFS)期间神经元的动作电位发放活动,进而深入揭示深部脑刺激治疗神经系统疾病的机制,本课题研究HFS期间锋电位波形的变化.在麻醉大鼠海马CA1区的输入神经通路Schaffer侧支上,施加1~2 min时长的100或者200 Hz顺向高频刺激(orthodromic-HFS,O-HFS),利用微电极阵列采集刺激下游神经元的多通道锋电位信号,并获得由O-HFS经过单突触传导激活的中间神经元的单元锋电位波形及其特征参数.结果表明,O-HFS使得锋电位的幅值明显减小而半高宽明显增加,以基线记录为基准计算百分比值,O-HFS期间锋电位的降支幅值和升支幅值分别可减小20%和40%左右,半高宽则增加10%以上.并且,在大量神经元同时产生动作电位期间,或者在比200 Hz具有更大兴奋作用的100 Hz刺激期间,锋电位波形的改变更多,幅值的减小可达50%,宽度的增加可达20%.可以推测,高频电刺激对于神经元的兴奋作用可能升高细胞膜电位,从而改变细胞膜离子通道的活动特性,导致动作电位波形的改变.这些结果支持深部脑刺激具有兴奋性调节作用的假说,对于正确分析高频电刺激期间神经元锋电位活动具有指导意义,也为进一步研究深部脑刺激(DBS)治疗脑神经系统疾病的机制提供了重要线索.     

笼养大猩猩行为研究中瞬时扫描最适取样时间间隔的确定

2009年9～12月以4只大猩猩(Gorilla gorilla)为研究对象,应用瞬时扫描取样法观察记录其活动行为,建立不同取样间隔与数据准确性和数据独立性的线性回归方程,计算变量系数和常数项的95%置信区间,进而确定瞬时扫描法的最适取样间隔。研究结果表明,大猩猩活动主要集中于上午10:00～11:00时和下午14:00～15:00时(χ2=19.110,df=4,P=0.001),不同大猩猩个体间活动行为存在显著差异(Kruskal Wallis Test,χ2=11.229,df=3,P=0.011)。随着取样间隔的增大,间隔取样与连续取样数据的相关系数呈下降趋势,满足数据准确性需求的最适取样间隔为3～13 min,随取样间隔的增大,数据独立可能性逐渐升高,其中满足数据独立性需求的最适取样间隔为2～8 min。综合考虑以上两种因素,确定针对大猩猩活动行为的瞬时扫描取样的最适间隔为3～8 min。     

基因转录爆发的信号转导机制

随着单分子检测技术水平的提高,学术界发现了与传统认知大相径庭的转录现象——转录爆发。基因转录不是连续平稳且波动较小的过程,而是表现出发生时间极不规律、信使RNA产量波动极大的特征。转录爆发本质上是编码和传递调控信号的方式。本文综述了转录爆发现象、转录爆发的两态模型、转录爆发信号转导机制以及其重要的生物学意义。最后,指出了该领域亟待解决的问题。     

变间隔的脉冲改变高频刺激对于脑神经元的作用

通常采用恒定电脉冲间隔的高频刺激(high-frequency stimulation,HFS),进行深部脑刺激治疗帕金森氏症等运动障碍疾病.为了开发适用于不同脑疾病治疗的新刺激模式,近年来脉冲间隔(inter-pulse-interval,IPI)变化的变频刺激模式受到关注.已有研究表明,即使具有相同的平均电脉冲频率,变频刺激与恒频刺激的治疗效果也不同.我们推测,变频刺激的短小IPI变化就足以改变HFS对于神经元的作用.为了验证此推测,本文在大鼠海马CA1区锥体神经元的输入轴突纤维上交替施加恒频刺激(100或133 Hz,即IPI=10 ms或7.5 ms)和随机变频刺激(100～200 Hz,即IPI=5～10 ms,平均频率为133 Hz),记录并分析刺激下游神经元群体的诱发电位,用于定量评价神经元对于恒频和变频刺激的响应.实验结果表明,持续的恒频刺激使得神经元的响应从最初的同步发放形成的群峰电位(population spike,PS)转变为非同步的动作电位发放(即单元锋电位).但是,当刺激切换为变频模式时,却又可以诱发神经元群体同步产生动作电位,重新形成PS波.并且,变频刺激诱发的PS幅值和神经元发放的同步程度可达基线的单脉冲刺激诱发波的水平.但是,PS的发生率只有脉冲刺激频率的7%左右,表明在持续的变频刺激时,多个脉冲累积的作用才能诱发这种同步的神经元发放.而且PS的出现与前导IPI的长度之间存在一定关系.神经元的轴突和突触等结构对于高频刺激的非线性响应可能是变频刺激诱发同步活动的原因.这些结果表明,变频刺激序列中短小的间隔变化可以产生与恒定间隔不同的调控作用.本文的结果对于揭示脑刺激的作用机制,促进新型刺激模式的开发及其在不同类型脑疾病治疗中的应用具有重要意义.     

川楝素对斜纹夜蛾幼虫取食行为的影响

斜纹夜蛾5龄幼虫的取食活动是非连续进行的。在每两次取食活动之间存在一个取食间间隔．在每次取食活动期间,也存在一非常短暂的取食内间隔。经川楝素处理后的斜纹夜蛾5龄幼虫．其21小时内发生的取食活动和取食间间隔的次数减少．平均每次取食活动和取食间间隔持续的时间延长;可是在每次取食活动中,用于取食的时间明显减少。这是因为．取食内间隔的次数增加了．取食内间隔的时间也延长了。所有上述指标,处理虫与对照之间均存在着显著或极显著的差异。     

用于蛋白质结构预测的一种改进模拟退火算法的研究

将一种模拟退火算法的改进方法——作用遗传交叉算子的并行模拟退火算法PSA／GC,用于蛋白质结构预测的能量最小化问题,通过对三个蛋白质的实际测试,证实了PSA／GC比SA和PSA具有更强的寻优能力,能得到能量值更低的构象。通过对PSA／GC的交叉间隔和交叉手法进行了探讨,得到了有益的结论。     

电刺激大鼠巨细胞网状核对小脑浦肯野细胞自发和诱发电活动的影响

本研究在麻醉并制动的大鼠上观察了电刺激巨细胞网状核(Gi)对小脑浦肯野细胞(PC)自发及诱发简单锋电位的影响。结果如下:(1)刺激Gi可使PC的简单锋电位出现潜伏期小于20ms的抑制性或兴奋性反应,并以抑制性反应为主。抑制性反应持续40-100ms,而兴奋性反应的时程可达200ms以上;(2)注射5-HT_2型受体阻断剂methysergide可以减弱或阻断电刺激Gi对PC自发简单锋电位的抑制作用;(3)条件性Gi刺激可以显著压抑或加强由刺激对侧大脑皮层感觉运动区引起的PC诱发简单锋电位反应。以上结果说明:在大鼠存在Gi-小脑通路,这一通路中的部分纤维是5-HT能的。Gi-小脑纤维可能通过突触和/或非经典突触的化学传递方式对PC的电活动产生某种调制性的影响。推测Gi-小脑传入纤维投射可能在某些小脑功能活动,如肌紧张及姿势的调节等方面发挥重要作用。     

人工模拟降水格局变化对醉马草种子萌发和幼苗生长的影响

降水格局的变化会影响到植物种子萌发出苗过程及幼苗的更新。本研究以呈扩张趋势的草原毒害草醉马草(Achnatherum inebrians)种子为材料,利用环境控制培养箱进行降水量(W-60%,W-30%,W,W+30%,W+60%)和降水间隔(T5,T10)的双因素控制实验,探讨醉马草种子萌发和幼苗生长对降水格局变化的响应规律,以期为探索醉马草的发生规律及预测其潜在分布范围提供科学依据。结果表明:(1)在相同降水间隔条件下,醉马草的出苗速度和出苗率随着总降水量的增加而提高;延长降水间隔促进W和W+30%条件下醉马草出苗,加快出苗进程。(2)无论降水间隔是否变化,总降水量增加60%(W+60%)使出苗势和出苗指数显著提高(P<0.05);在W和W+30%条件下,延长降水间隔使出苗率、出苗势和出苗指数显著提高(P<0.05)。(3)无论降水间隔是否变化,总降水量减少30%(W-30%)显著抑制幼根和幼苗的生长,总降水量增加60%(W+60%)显著促进幼苗的生长(P<0.05);但总降水量增加30%(W+30%)和60%(W+60%)均显著降低根苗比(P<0.05)。降水量增加或减少不同程度地影响醉马草的出苗和生长,但在一定降水范围内,延长降水间隔则促进醉马草的出苗和幼苗生长。     

新疆南部戊肝疫区间隔20年后局部再爆发的调查

为了探讨戊肝流行20年后再爆发的特点,对2001年喀什地区莎车县某乡戊型肝炎的流行和临床特点进行了调查,并对病后半年的部分病例用ELISA方法检测戊肝抗体水平。结果发生在1981～1983年大流行时散发病的疫区,间隔20年后再次局部爆发戊肝,乡总患病率0．64％(167／25979),分布在相邻六个自然村,每村平均患病人数为28人。饮用水为手压井(地下水),全年以8～12月为一高峰,均为维族农民,男98人,女69人,最大年龄54岁,最小年龄12岁,中位年龄28．9岁。临床表现符合急性黄疸型肝炎,病情轻,无重症和死亡病例。抽查病例中病后半年抗-HEVIgG阳性率68％,IgM阳性率16％,双阳性12％。首发病例传染源尚不清楚,可排除水源和食物污染,流行和临床特征符合戊肝,应探讨HEV的变异和人群抗体及保护力的持续时间。     

Nonlinear Relationships in the Patterns of Neuronal Spiking in Cortical Neurons

The pattern of neuronal spiking of cortical neurons was investigated in an awake nonimmobilized rabbit. Thecharacteristics of the interspike intervals (total numberof intervals, mean interval, mean-square deviation) and of the burst (group) activity (burst number, mean spikefrequency in a burst, mean spike number for a burst, meanburst duration) were considered. Nonlinear relationshipbetween the values of mean interspike intervals and thenumber of spike bursts was found. A number of functionswere applied to describe the observed phenomena. On thebasis of regression analysis two populations of corticalneurons with distinct neuronal spiking patterns wereidentified. Bursts occur at a higher rate in one populationthan the other, although both populations exhibit burstsand are otherwise indistinguishable.     

The origin of spontaneous synchronized burst in cultured neuronal networks based on multi-electrode arrays

Many neural networks in mammalian central nervous system (CNS) fire single spike and complex spike burst. In fact, the conditions for triggering burst are not well understood. In the paper multi-electrode arrays (MEA) are used to record the spontaneous electrophysiological activities of cultured rat hippocampal neuronal network for a long time. After about 3 weeks culture, a transition from single spike to burst is observed in several networks. All of these spikes fire quickly before burst begins. The firing rate during the burst is lower than that just before the burst, but differences of inter-spike intervals (ISIs) between two firing patterns are not clear. Moreover, the electrical activities on neighboring electrodes show strong synchrony during the burst activities. In a word, the generation of the burst requires that network should have a sufficient level of excitation as well as a balance of synaptic inhibition.     

大鼠初级传入纤维与脊髓背角神经元间的动作电序列的突触传递

外周感觉神经元通过动作电位序列对信号进行编码,这些动作电位序列经过突触传递最终到达脑部。但是各种脉冲序列如何通过神经元之间的化学突触进行传递依然是一个悬而未决的问题。研究了初级传入A6纤维与背角神经元之间各种动作电位序列的突触传递过程。用于刺激的规则,周期、随机脉冲序列由短簇脉冲或单个脉冲构成。定义“事件”(event)为峰峰问期(intefspike interval)小于或等于规定阈值的最长动作电位串,然后从脉冲序列中提取事件间间期(interevent interval,IEI)。用时间,IEI图与回归映射的方法分析IEI序列,结果表明在突触后输出脉冲序列中可以检测到突触前脉冲序列的主要时间结构特征,特别是在短簇脉冲作为刺激单位时。通过计算输入与输出脉冲序列的互信息,发现短簇脉冲可以更可靠地跨突触传递由输入序列携带的神经信息。这些结果表明外周输入脉冲序列的主要时间结构特征可以跨突触传递,在突触传递神经信息的过程中短簇脉冲更为有效。这一研究在从突触传递角度探索神经信息编码方面迈出了一步。     

Pattern and correlation of fast and slow spontaneous unit activity in the visual cortex

Spontaneous unit activity in the visual cortex and its changes during stimulation by continuous light or flashes were investigated in waking rabbits. The study of distributions of adjacent intervals showed that the neurons differ in the ratio of burst (fast, with intervals of up to 15–40 msec) and nonburst (slow) activity and in the character of changes from one type of activity to the other. Of the total number of spikes 63% were outside bursts; the ratio of their number to the number of spikes within bursts consisting of two or of three or more spikes was 27:3:1. The relative stability of the burst structure of spontaneous activity and the limited number of spikes in them (on average 2.4) were demonstrated. Bursts of three or more spikes (mean 3.6) were irregular, and in 79% of them a longer interval (18.6±2.4 msec) was observed before the shortest interval (7.9±0.9 msec). Bursts of spikes of most neurons during photic stimulation contain more spikes with shorter intervals; they also began more frequently with the shortest interval, possibly signifying an increase in the steepness and amplitude of the EPSPs lying at their basis. However, in 20% of neurons spontaneous bursts included more spikes and with shorter intervals than bursts evoked by flash stimulation.Research Institute of Psychiatry, Ministry of Health of the RSFSR, Moscow. Translated from Neirofiziologiya, Vol. 11, No. 4, pp. 311–320, July–August, 1979.     

Measurement of electrical activity of long-term mammalian neuronal networks on semiconductor neurosensor chips and comparison with conventional microelectrode arrays

Based on complementary metal-oxide semiconductor (CMOS) technology a neurosensor chip with passive palladium electrodes was developed. The CMOS technology allows a high reproducibility of the sensors as well as miniaturization and the on-chip integration of electronics. Networks of primary neurones were taken from murine foetal spinal cord (day 14) and frontal cortex (day 15) tissues and cultured on the silicon surface in a chamber volume of 200 microl with 7 mm diameter. Measurements were performed between days 15 and 59 in vitro. Signals were recorded from both types of cultures. To test the capability of the system to detect pharmacologically induced activity changes two established neuromodulators were applied. The GABA(A)-receptor blocker bicuculline was applied to both tissue cultures, the glycine-receptor blocker strychnine to spinal cord cultures. Four network frequency parameters were analysed: spike rate (SR), burst rate (BR), frequency in bursts (FiB) and peak frequency in bursts (PFiB). Significant changes of spike rate and burst rate were measured with spinal cord cultures after bicuculline application. Significant changes of frequency in bursts and peak frequency in bursts were observed with frontal cortex cultures after bicuculline application. Significant changes of spike rate and frequency in bursts were recorded with spinal cord cultures after strychnine application. These results were compared with results achieved in the same laboratory by using glass-microelectrode arrays (MEAs). This comparison showed for spinal cord similar native spike and burst rate, but higher mean frequency and peak frequency in bursts, whereas frontal cortex activity had higher spike and burst rate and peak frequency in bursts. Application of bicuculline or strychnine to spinal cord networks showed stronger effects on MEAs, whereas with frontal cortex networks the modulation of activity was similar after application of bicuculline.     

Selectivity of stimulus induced responses in cultured hippocampal networks on microelectrode arrays

Sensory information can be encoded using the average firing rate and spike occurrence times in neuronal network responses to external stimuli. Decoding or retrieving stimulus characteristics from the response pattern generally implies that the corresponding neural network has a selective response to various input signals. The role of various spiking activity characteristics (e.g., spike rate and precise spike timing) for basic information processing was widely investigated on the level of neural populations but gave inconsistent evidence for particular mechanisms. Multisite electrophysiology of cultured neural networks grown on microelectrode arrays is a recently developed tool and currently an active research area. In this study, we analyzed the stimulus responses represented by network-wide bursts evoked from various spatial locations (electrodes). We found that the response characteristics, such as the burst initiation time and the spike rate, can be used to retrieve information about the stimulus location. The best selectivity in the response spiking pattern could be found for a small subpopulation of neurones (electrodes) at relatively short post-stimulus intervals. Such intervals were unique for each culture due to the non-uniform organization of the functional connectivity in the network during spontaneous development.     

Multi-scale detection of rate changes in spike trains with weak dependencies

The statistical analysis of neuronal spike trains by models of point processes often relies on the assumption of constant process parameters. However, it is a well-known problem that the parameters of empirical spike trains can be highly variable, such as for example the firing rate. In order to test the null hypothesis of a constant rate and to estimate the change points, a Multiple Filter Test (MFT) and a corresponding algorithm (MFA) have been proposed that can be applied under the assumption of independent inter spike intervals (ISIs). As empirical spike trains often show weak dependencies in the correlation structure of ISIs, we extend the MFT here to point processes associated with short range dependencies. By specifically estimating serial dependencies in the test statistic, we show that the new MFT can be applied to a variety of empirical firing patterns, including positive and negative serial correlations as well as tonic and bursty firing. The new MFT is applied to a data set of empirical spike trains with serial correlations, and simulations show improved performance against methods that assume independence. In case of positive correlations, our new MFT is necessary to reduce the number of false positives, which can be highly enhanced when falsely assuming independence. For the frequent case of negative correlations, the new MFT shows an improved detection probability of change points and thus, also a higher potential of signal extraction from noisy spike trains.     

Proctolin potentiates synaptic transmission in the central nervous system of an insect

1. Bursts of spike activity in the ventral nerve cord of the cockroach were elicited by mechanically stimulating the cercal organs. 2. In the presence of micromolar proctolin, the peak frequency and the duration of a burst were slowly but significantly increased. 3. In contrast, carbachol produced an immediate enhancement of spontaneous activity, but a potentiation of bursts was not seen. 4. It is proposed that proctolin functions as a neuromodulator in the terminal abdominal ganglion of the cockroach.     

State-Dependent Effects of Na Channel Noise on Neuronal Burst Generation

We explore the effects of stochastic sodium (Na) channel activation on the variability and dynamics of spiking and bursting in a model neuron. The complete model segregates Hodgin-Huxley-type currents into two compartments, and undergoes applied current-dependent bifurcations between regimes of periodic bursting, chaotic bursting, and tonic spiking. Noise is added to simulate variable, finite sizes of the population of Na channels in the fast spiking compartment.During tonic firing, Na channel noise causes variability in interspike intervals (ISIs). The variance, as well as the sensitivity to noise, depend on the model's biophysical complexity. They are smallest in an isolated spiking compartment; increase significantly upon coupling to a passive compartment; and increase again when the second compartment also includes slow-acting currents. In this full model, sufficient noise can convert tonic firing into bursting.During bursting, the actions of Na channel noise are state-dependent. The higher the noise level, the greater the jitter in spike timing within bursts. The noise makes the burst durations of periodic regimes variable, while decreasing burst length duration and variance in a chaotic regime. Na channel noise blurs the sharp transitions of spike time and burst length seen at the bifurcations of the noise-free model. Close to such a bifurcation, the burst behaviors of previously periodic and chaotic regimes become essentially indistinguishable.We discuss biophysical mechanisms, dynamical interpretations and physiological implications. We suggest that noise associated with finite populations of Na channels could evoke very different effects on the intrinsic variability of spiking and bursting discharges, depending on a biological neuron's complexity and applied current-dependent state. We find that simulated channel noise in the model neuron qualitatively replicates the observed variability in burst length and interburst interval in an isolated biological bursting neuron.     

How does morphine work on colonic motility? An electromyographic study in the human left and sigmoid colon

The effect of morphine on colonic motility was investigated by recording the colonic myoelectric spiking activity by means of a 50 cm long silastic tube equipped with 4 bipolar AgAgCl ring electrodes fixed at 10 cm intervals that was introduced into the left colon in 8 healthy subjects by flexible sigmoidoscopy. Tracings were obtained for 1 hour in the fasting state and for another 1 hour after i.m. injection of morphine sulphate 0.15 mg/kg. The different types of spike bursts were compared before and after morphine injection. The control tracings showed that the spiking activity of the colon was made of 2 types: 1)- Rhythmic Stationary Spike Bursts (RSB), that were seen at only one electrode site; 2)- Sporadic Bursts, that were either propagating over all 4 electrodes (SPB) or non propagating (SNPB). Injection of morphine was followed by 1)- a considerable increase in the number of RSB from 107 +/- 43 bursts/hour (mean +/- SEM) to 491 +/- 23 bursts/hour; 2)- the complete disappearance of the SPB dropping from 7.3 +/- 2.0 bursts/hour to 0.3 +/- 0.2 bursts/hour; 3)- no significant change in SNPB (from 52 +/- 4 bursts/hour to 57 +/- 5 bursts/hour). These results indicate that 1)- stimulation of colonic smooth muscle activity by morphine seems to result from an increase in the number of rhythmic stationary bursts; 2)- however inhibition of colonic transit may be related to the decrease in the number of sporadic propagating bursts.