Effects of temperature on a moth auditory receptor

Measurements of the thoracic temperature and recordings of the spike activity of the most sensitive auditory receptor (A1 cell) were made in Empyreuma pugione (Arctiidae, Ctenuchinae). The temperature range tested (19–36 °C) is relevant for the behavior and ecology of this species. Experiments were performed during the hours of maximal flying activity in the wild: sunrise and sunset. The thoracic temperature during rest reflects that of the surrounding air; there is an increase of 3–4 °C immediately after ceasing free flying in the laboratory. The spike activity of the tympanic organ was recorded with a stainless-steelhook electrode placed beneath the tympanic nerve in the mesothorax. The A1 cell activity was studied without acoustic stimulation (spontaneous) and in response to 35-kHz acoustic pulses of 20, 40, or 100 ms duration. At all of these durations A1 cell response to saturating stimulus was analysed, while with 40-ms pulses different stimulus intensities were used (20–90 dB SPL in 10-dB steps). The number of action potentials per pulse, mean spike rate, maximal instantaneous discharge, and latency period depend strongly on air temperature, while the variation coefficients of the interspike intervals during the responses were not temperature dependent and vary non-monotonically with stimulus intensity. During responses to a saturating stimulus, the stimulus duration does not affect the activation energy, calculated from an Arrhenius plot, of different physiological features. Adaptation, studied in the responses to 100-ms pulses, is also temperature dependent. This phenomenon has two components, each of which shows different activation energies, suggesting a different membrane origin. High stimulus intensity (90 dB SPL) significantly affects the activation energy of the action potentials and mean spike rate, while the activation energy, of the maximal instantaneous discharge and latency period do not show this strong dependency. The spontaneous A1 cell spike rate varies with temperature, as does the value of the mode of the relative frequency distribution of the interspike interval. The activation energy of the spike rates measured at A1 cell responses to saturating stimuli is in good agreement with that described in amphibian innerear hair cells. It is suggested that this moth auditory receptor cell also has mechanosensitive protein channels.Abbreviations AP/p action potentials per pulse - AP/s action potentials per second - CI confidence interval - E _a activation energy - ISI interspike interval - SD standard deviation - VC variation coefficient     

Background activity of neurons of the supraoptic hypothalamic nucleus in rats under conditions of vibrational stimulation and electromagnetic extrahigh-frequency irradiation

We analyzed background impulse activity of neurons of the supraoptic nucleus of the rat hypothalamus in the course of 15-day-long isolated action of generalized vibrational stimulation and combination of such stimulation with irradiation of the animal’s head with low-intensity extrahigh-frequency (EHF, millimeter-range) electromagmetic waves. The distributions of the neurons by the level of regularity and dynamics of spike trains, separate frequency ranges of impulsation, and pattern of interspike interval (ISI) histograms were estimated. We also calculated the mean frequency of discharges and coefficient of variation of ISIs. A trend toward decreases in the deviations of some parameters of neuronal spike activity generated by supraoptic neurons, which were evident within early time intervals of isolated action of vibration (5 to 10 days), was observed under the influence of EHF electromagnetic irradiation; thus, the latter factor probably exerts a sedative effect. Neirofiziologiya/Neurophysiology, Vol. 39, No. 6, pp. 433–442, November–December, 2007.     

Neural coding in antennal olfactory cells of tsetse flies (Glossina spp.)

Spike trains from individual antennal olfactory cells of tsetse flies (Glossina spp.) obtained during steady-state conditions (spontaneous as well as during stimulation with 1-octen-3-ol) and dynamic stimulation with repetitive pulses of 1-octen-3-ol were investigated by studying the spike frequency and the temporal structure of the trains. In general, stimulation changes the intensity of the spike activity but leaves the underlying stochastic structure unaffected. This structure turns out to be a renewal process. The only independently varying parameter in this process is the mean interspike interval length, suggesting that olfactory cells of tsetse flies may transmit information via a frequency coding. In spike records with high firing rates, however, the stationary records had significant negative first- order serial correlation coefficients and were non-renewal. Some cells in this study were capable of precisely encoding the onset of the odour pulses at frequencies up to at least 3 Hz. Cells with a rapid return to pre-stimulus activity at the end of stimulation responded more adequately to pulsed stimuli than cells with a long increased spike frequency. While short-firing cells process information via a frequency code, long-firing cells responded with two distinctive phases: a phasic, non-renewal response and a tonic, renewal response which may function as a memory of previous stimulations.      

Static response of infrared neurons of crotaline snakes—normal distribution of interspike intervals

Background discharges (static responses) of warm fibers in the pit organs (infrared receptive organs) of two species of crotaline snakes were recorded at various temperatures (water, 18-33 degrees C; air, 19-28 degrees C). Mean interspike intervals (means), standard deviations (SD), and coefficients of variation (CV) were calculated, and the goodness of fit of interspike interval histograms to a corresponding normal distribution (i.e., one having the same mean and SD) were tested. Means, SD, and CV were smallest at a certain temperature, which might be the optimum receptor temperature for the species. More than half of the histograms (22/42 for water, 7/10 for air) showed a normal distribution at a significance level of 0.01. This suggests that the spike intervals generated at the spike initiation site are constant, with some random error. Background discharges of three pure infrared secondary neurons from the lateral descending nucleus were analyzed in the same way and compared to the peripheral discharges. There were no histograms with a normal distribution in these central neurons, which might indicate that the constant interspike intervals which appear in the primary afferent fibers are not utilized for information processing at this level but occur only as part of a receptor mechanism which is still unknown. The discharge patterns of primary afferent fibers are also discussed in relation to the known discharge patterns of cold fibers in other animals.     

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.     

Properties of synaptic noise in tonically active human motoneurons

The objective of these experiments was to determine the amount of synaptic noise on the cell membrane at various intervals after an action potential in a motoneuron firing at a specified frequency. Sources of noise such as variations in the level of voluntary drive were minimized by selecting only segments of the spike train in which the unit was running within prescribed frequency limits. The level of the membrane potential of the motoneuron during these intervals was determined using two test “pulses” (compound Ia excitatory postsynaptic potentials) of known amplitude. This enabled the probability of the membrane potential falling within a voltage “window” of known size at known times after the preceding spike to be determined. The probability density histograms showed that the fluctuations of membrane potential about a target interspike trajectory (i.e., the membrane noise) increased with time after the preceding spike. These fluctuations in the membrane potential can be accounted for by a one-dimensional “random walk” model of membrane noise. This model explains the salient features of the interval histograms, such as positive skewness at low target frequencies. A quantitative test of the model demonstrated its applicability to the motor pools of tibialis and masseter.     

Transmission of spike trains by nerve fibers after near-threshold stimulation

Spike trains in group A nerve fibers were studied in anesthetized cats in response to stimulation of the hind-limb nerves by random (Poisson) and regular sequences of stimuli. In response to above-threshold stimulation spike trains in the nerve fibers were shown to differ from the stimulating trains purely in the absence of intervals less than 1–1.5 msec in duration, as a result of the presence of a refractory period. With near-threshold stimulation with an average frequency of over 10 per second, spike trains differed significantly from the stimulating trains, as reflected in histograms of interspike intervals, the shape of the intensity function, and the magnitude of the coefficient of correlation for successive intervals. It is postulated that changes in the structure of the spike trains conveyed by a nerve fiber are attributable to the presence of after-activity.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 8, No. 1, pp. 91–98, January–February, 1976.     

Influence of vibration on the spontaneous neuronal activity of the neurons of the superior vestibular nucleus

The results of vibration action (5, 10 and 15 daily) on spontaneous neuronal activity of superior vestibular nucleus were studied using software for biological signals. Average histograms and autocorrelograms were drawn up after computerized interspike interval analysis. The results have demonstated that neurons of superior vestibular nucleus have mean frequency 14.0 +/- 1.4 Hz. The results obtained suggest significant reconstruction of spontaneous impulse activity in neurons of the superior vestibular nucleus within postvibration period.     

Changes in impulse activity of neurons of the CA3 area of the hippocampus under the effects of neuromodulator neurotropin]

Neurotropin (Nippon Zoki Co, Ltd) effects on firing patterns of the CA 3 hippocampus neurons in rabbits under a 24-h food deprivation was studied. Neuronal firing was recorded in a state of hunger (40 neurons) and under neurotropin (27 neurons) injected through a catheter implanted into the lateral brain ventricles. Initially, in 20% of neurons histograms had a bimodal interspike interval distribution: 1.5-25 ms and 100-400 ms. Neurotropin (50 microliters) increased the baseline spike rate regularity of hippocampus neurons. Histograms had a monomodal interspike interval distribution. Neurotropin (70 microliters) inhibited firing patterns and histograms, had trimodal interspike interval distribution: 1.5-5 ms; 250-400 ms and 1000 ms. Thus, these data suggested the involvement of neuro-immuno-modulator mechanisms in organization of firing patterns in rabbits.     

The role of electrophysiological properties of neurons in mechanisms of discharge grouping in the cortex

Properties of intracellular discharges of pyramidal cells of layers II/III and V in rat neocortex were in detail studied in vitro. Neuronal firing was evoked by depolarizing 1-3-min current injection (0.1-1.0 nA) into the neurons (N = 80). The so-called spike sequences with regular increasing or decreasing interspike intervals were analyzed. Number of spikes in a sequence (5-30% of recorded total spike number) and oscillation amplitude of their afterhyperpolarization potential (0-1.5 mV) were significantly correlated with their mean firing frequency. The dependence of spike number in a sequence on the mean spike frequency was of biphasic character with the critical frequency in the range of 5-7 Hz. Cells with and without depolarization component during afterhyperpolarization had different morphological and electrophysiological properties, but the dependence of their spike number in a sequence on the spike mean frequency was of similar character. A possible role of the revealed characteristics of spike sequences in generation of cortical rhythms is discussed.     

Temporal pattern sensitive and nonsensitive responses in the cat's retinal ganglion cells

In order to characterize temporal pattern sensitivity in the cat ganglion cells, a new analysis technique by semi-Markov models which was developed in the previous papers (Tsukada et al., 1975–1977) was applied to input-output relations of the receptive-field. Three types of statistical spot stimuli positioned in the center region of receptive fields were used. Each type of stimulus has an identical histogram in the inter-stimulus intervals and therefore the same mean and variance, but different correlations between adjacent inter-stimulus intervals (Type 1, positive; Type 2, negative; and Type 3, independent processes). From the output spike trains of cat retinal ganglion cells to each stimulus, mean, variance, and histogram were computed. As the result of investigating these data, we could draw the following conclusion from the resultant output interval histograms. The receptive-field-center responses of cat ganglion cells can be classified into two groups (Types L and N) according to the difference of responsiveness to the three types of statistical spot stimuli. A Type L response has the same histogram in interspike intervals for all three stimuli, and is not sensitive to the temporal pattern, while a Type N response has three different forms depending on each type of stimulus showing high sensitivity to the temporal pattern. These results were also simulated by the Markov chain model and discussed with relation to neural coding and classification of ganglion cell types.     

Background neuronal activity in thenucleus supraopticus and its modifications under the influence of parathyroid hormone

In experiments on anesthetized cats, we found that i. v. injection of 5.0 U/kg of parathyroid hormone (PTH) results in modifications of the statistical parameters of the neuronal impulse activity in thenucleus supraopticus (SO) of the hypothalamus. Sliding frequency graphs, histograms of interspike intervals, autocorrelograms, and serial correlation coefficients were plotted and calculated before and after PTH injections; their comparison demonstrates that the hormone significantly modulates the temporal organization of spike trains generated by the neurons of this nucleus. We observed that PTH mostly activated SO neurons and diminished the level of spike grouping in their activity. The effect of PTH to a certain level depended on the initial frequency of background activity: an increase in the spiking frequency was typical of primarily dominating “low-frequency” neurons, while “high-frequency” units were mostly inhibited. The possible mechanisms of the observed modifications are discussed.     

Role of cAMP in dopamine effect on background and glutamate-induced neuronal activity in rat neostriatum

During acute experiments on rats immobilized with d-tubocurarine, the effects were compared of microiontophoretically applied dopamine and dibutyryl cAMP on background and glutamate-induced spike activity of neostriatalneurons. The algorithm of the analysis of extracellularly recorded spike activity included the plotting of a graph of mean frequency, assessing its stationarity, and producing histograms of interspike intervals and also correlation function. During these experiments it was shown that dibutyryl cAMP imitates the inhibitory but not the activating effect of dopamine on the spontaneous and glutamate-induced spike activity of neostriatal neurons.Institute of Biological Physics, Academy of Sciences of the USSR, Pushchino-on-Oka, Moscow Province. Translated from Neirofiziologiya, Vol. 17, No. 5, pp. 614–619, September–October, 1985.     

Temperature Effect on Proximal to Distal Gradient of Quantal Release of Acetylcholine at Frog Endplate

The conduction velocity of the nerve terminal, mean quantal content, and release latencies of uniquantal endplate currents (EPCs) were recorded in proximal, central, and distal parts of the terminal by extracellular pipettes located 5, 50, and 100 mm from the end of myelinated nerve trunk. The spike conduction velocity, minimal latency, modal value of the latency histograms, and time interval during which 90% of EPCs released (P₉₀) at distal, central, and proximal part of the frog nerve terminal have different temperature dependency between 10° and 28°C. As shown by the size and time-course of reconstructed multiquantal EPCs, the secretion synchronization, which is greatest in distal parts, compensates at least partly for the progressive slowing of spike conduction velocity in the proximodistal direction, in particular at lower temperatures.     

Partial phase synchronization of neural populations due to random Poisson inputs

We show that populations of identical uncoupled neurons exhibit partial phase synchronization when stimulated with independent, random unidirectional current spikes with interspike time intervals drawn from a Poisson distribution. We characterize this partial synchronization using the phase distribution of the population, and consider analytical approximations and numerical simulations of phase-reduced models and the corresponding conductance-based models of typical Type I (Hindmarsh-Rose) and Type II (Hodgkin-Huxley) neurons, showing quantitatively how the extent of the partial phase synchronization depends on the magnitude and mean interspike frequency of the stimulus. Furthermore, we present several simple examples that disprove the notion that phase synchrony must be strongly related to spike synchrony. Instead, the importance of partial phase synchrony is shown to lie in its influence on the response of the population to stimulation, which we illustrate using first spike time histograms.     

Dynamics of the noisy neural network

The dynamic features of interspike interval sequences and structures of spatiotemporal patterns of firing in a coupled noisy neural network are investigated. The system displays complex dynamics under periodic external stimuli. The dynamics is modulated by a periodic impulse-like synaptic current which relates to a global coupling interaction between neurons. The firings of the stimulated neurons are phase-locked to this current. In addition, the interspike interval histograms are studied for the case of frozen noise which does not change its value within a time interval once it has been distributed onto the network. It is found that the peaks in these histograms are located at integer multiples of the period of the external stimulus, and the heights of these peaks decay exponentially, which corresponds to the experimental results. Received: 12 April 1997 / Accepted in revised form: 7 May 1997     

Modifications of neuronal activity in the rat hypothalamic supraoptic nucleus after long-lasting vibrational stimulation

We analyzed the background impulse activity (BIA) generated by neurons of the rat hypothalamic supraoptic nucleus in the norm and under conditions of long-lasting vibrational stimulation (exposure 5, 10, or 15 days). Distributions of neurons by the level of regularity, dynamics of discharge trains, form of histograms of interspike intervals (ISIs), as well as distributions of neurons by the BIA frequency ranges, were studied. We also calculated the mean frequency of impulsation of the neurons under study and the coefficient of variation of ISIs. After vibrational influences, we found modifications of both the internal structure of the recorded spike trains and the mean frequency of impulsation within the entire studied group and different frequency subgroups. Neirofiziologiya/Neurophysiology, Vol. 38, No. 3, pp. 224–230, May–June, 2006.     

Structure of spike activity of cold thermoreceptors at its various levels

In acute experiments on anesthetized rabbits we investigated the spike activity of cold fibers of the infraorbital nerve during a steady decrease in skin temperature from 39 to 7°C at a rate of 0.8 ± 0.05°/min. Analysis of interspike intervals (ISI) in the firing of receptors demonstrated that in the investigated range of skin temperatures the ISI histograms changed significantly several times, reflecting a shift in the pattern of firing. In addition, the reactions of each cold thermoreceptor had individual aspects, which lays the foundation for discussion of the perception of various characteristics of the temperature stimulus of the set of thermoreceptors.I. P. Pavlov Physiology Institute, Russian Academy of Sciences, Saint Petersburg. Translated from Neirofiziologiya, Vol. 24, No. 5, pp. 559–566, September–October, 1992.     

Statistical Analysis of Motor Unit Firing Patterns in a Human Skeletal Muscle

A statistical analysis of the firing pattern of single motor units in the human brachial biceps muscle is presented. Single motor unit spike trains are recorded and analyzed. The statistical treatment of these spike trains is as stochastic point processes, the theory of which is briefly discussed. Evidence is presented that motor unit spike trains may be modelled by a renewal process with an underlying gaussian probability density. Statistical independence of successive interspike intervals is shown using scatter diagrams; the hypothesis of a gaussian distribution is accepted at the 99th percentile confidence limit, chi-square test, in 90% of the units tested. A functional relationship between the mean and standard deviation is shown and discussed; its implications in obtaining sample size are presented in an appendix.The results of higher order analysis in the form of autocorrelograms and grouped interval histograms are presented. Grouped interval histograms are discussed in the context of motor unit data, and used to confirm the hypothesis that a stable probability density function does not represent a good model of the data at this level of analysis.     

Acoustic response properties of single units in the torus semicircularis of the goldfish,Carassius auratus

Single units of the goldfish torus semicircularis (TS) were recorded in response to pure tones. Response areas (RA) were obtained by recording the number of spikes evoked by tones in a range of frequencies and levels within the units' dynamic range. RAs gave estimates of best sensitivity (BS), characteristic frequency (CF), most excitatory frequency at each level (BF), and Q_10dB. Peri-stimulus-time histograms (PSTH), interspike interval histograms (ISIH), and period histograms were obtained at various frequencies and levels to describe the units' temporal response patterns.The distribution of CF is nonuniform with modes at 155, 455, and 855 Hz. The distribution of the coefficient of synchronization to standard tones is also nonuniform, revealing a dichotomy between units with little or no phase-locking and those that phase-lock strongly. PSTHs for units without significant phase-locking vary widely and include patterns resembling those of the mammalian auditory brainstem. Compared with saccular afferents, torus units tend to have lower spontaneous rates, greater sensitivity, and sharper tuning. Unlike saccular afferents, BF is independent of level for most torus units. Some torus units are similar to saccular afferents while others reveal significant transformations of information between the periphery and the midbrain.Abbreviations BF best frequency - BS best sensitivity - CF characteristic frequency - ISIH inter-spike interval histogram - PSTH peri-stimulus-time histogram - RA response area - TS torus semicircularis