Localization of a sum of acoustic signals in air by the northern fur seal]

The localization of a sum of acoustic signals by two northern fur seals in air depending on sound parameters was investigated using the method of instrumental conditioned reflexes with food reinforcement. It was found that sound perception of northern fur seal proceeds by the binaural mechanism. The time/intensity interchange coefficient was 570 microseconds/dB for series of clicks (with amplitude maximum at 1 kHz) and 250 microseconds/dB for tonal impulses with a frequency of 1 kHz. With click amplitudes being equal, the number of approaches of the animal to the source of the first signal reached a 75% level at a delay of the second signal 0.07 ms (the minimum delay); with a delay of 6 ms (the maximum delay) and more, the fur seal, probably hears two separate signals. The minimum delay depended little on the duration of tonal impulses (with a frequency of 1 kHz) and was 0.3-0.7 ms; the maximum delay was 9-11 ms for tonal impulses with a duration of 3 ms and 37-40 ms with impulse duration 20 ms. The precedence effect became apparent at a greater delay for smooth fronts of impulses than for rectangular fronts.     

Effect of single impulses on cochlear microphone potentials of the guinea-pig cochlea]

The influence of highly intensive single impulses on the cochlea of guinea pig was studied in an acute experiment. Very short impulses of less than or equal to 0.1 ms duration were produced by a sparknoise generator. The cochlear microphonics (CM) to a test stimulus (sinus tone, 3150 Hz) were recorded from the round window and measured prior to, during, and following impulse treatment. During the impulse treatment, the greatest amplitude reduction of CM occurred after the first impulse, while the further impulses caused a decreasing reduction. At first the number of impulses was varied: 1, 3, and 5 impulses were applied at intervals of 15 s each, at an impulse sound level of 164 dB sound pressure level re. 0.002 mubar (SPL). After these impulse treatments, in all cases a continual decrease of CM amplitudes up to a constant end value without recovery was found within a 2-hrs period of observation. The height of the end value depends on the number of impulses applied. Subsequently, at an exposure to 5 impluses the impulse sound level was stepwise reduced (164, 153, 144, 139 and 133 dB SPL). Again, a characteristic decrease of CM amplitudes was observed during the 2-hrs period of observation. The height of the end value is now dependent on the impluse sound level. Impulses of 164, 153 and 144 dB SPL cause a strong decrease of CM while the effect of impulses of 139 and 133 dB SPL is distinctly lower.     

Koinzidenzfilter mit kurzen Impulsen

Summary Coincidence filters consist of one or more threshold elements (e.g. neurons or monostable multivibrators, extended by multiple input gates). They permit the propagation of an impulse train applied to the input only if its repetition rate does not exceed an upper and a lower boundary value. The difference between the upper and the lower boundary value may be defined as the functional bandwidth of the coincidence filter. The functional bandwidth is one of the most interesting characteristic figures of a coincidence filter. By means of this definition, the coincidence filter may be described as a device selecting quickly those impulse trains the repetition rates of which lie within the functional bandwidthThe functional bandwidth depends on the parameters of the impulse trains and of the coincidence filter. This gives rise to the question, which minimal bandwidth could be realized by coincidence filters.On the initiation by Tischner the properties of coincidence filters operated by rectangular impulses have been investigated by Schie f and by Kosel. Rectangular impulses have the advantage, that moderate variations of the amplitudes do not disturb the coincidence. In this case however very small impulse durations are required for the realization of small bandwidth.In the present paper the operation of coincidence filters by non rectangular impulses has been considered. Having the shape of an excitatory post-synaptic potential of motoneurons, the impulses are completely determined by the rising phase and the falling phase. These impulses have been termed short impulses in contrast to the rectangular impulses, which are long, compared to the duration of their rising and falling phases. The width of the short impulses decreases with increasing measuring level. Close to the amplitude the width becomes very small, which theoretically provides a very small functional bandwidth. The practical realization of very small functional bandwidth is heavily limited by the big variations which will be caused by minute alterations of the amplitudes as introduced by noise. The variation of the functional bandwidth caused by 1% alteration of the amplitude has been termed the error factor. In the present paper some relationships between the following four quantities have been worked out: realizable functional bandwidth, tolerable variation of functional bandwidth, error factor, and given variation of the amplitudes and thresholds (noise).The short impulses have been piecewise approximated by analytical functions (parabolic and hyperbolic) which in general permits an analytical treatment of the problems.     

Postcatelectrotonic potentials and trace changes in the nerve fiber excitability

When cathode subthreshold impulse was turned off, excitable membranes of isolated nerve fibres and nervous trunk show postelectrotonic depolarisation (PED), that is a slow recovery of membrane potential to the resting level. PED of the single nodes of Ranvier and nervous trunk is registered not only in normal conditions, but also after complete block of sodium channels. The size and duration of nervous trunk PED under subthreshold depolarising current increase along with duration of applied depolarisation: when cathode current 1 ms in duration was used, they were 0.093 +/- +/- 0.004 mV and 7.123 +/- 0.576 ms, respectively; when current was 5 ms in duration, they were 0.189 +/- 0.005 mV and 23.212 +/- 1.186 ms, whereas a 10-ms depolarisation yields values of 0.220 +/- 0.011 mV and 68.721 +/- 3.389 ms. Application of the train of catelectrotonic impulses leads to PED built-up. As PED is found not only in normal conditions but also after complete block of sodium channels, it is reasonable to suggest that the most probable reason for PED is an outward potassium current.     

杨树木段内光肩星天牛幼虫数量的声学检测

光肩星天牛是重要的检疫性林木害虫,由于幼虫在树干内部取食,现有的方法很难检测到幼虫的为害情况。利用声音检测技术在室内对杨树木段中不同数量的光肩星天牛幼虫产生的声音信号进行检测,结果显示:不同数量光肩星天牛幼虫产生的声音信号在时域、频域方面均无显著差异,脉冲持续时间在3-6 ms范围内;信号的频率在7235.20-7924.20 Hz范围内,且主频为7725.00 Hz。但不同数量光肩星天牛幼虫产生的声音信号的脉冲个数之间存在显著的差异(P0.05),且脉冲个数与幼虫数量之间存在线性关系,即y=13.14x-3.55(R2=0.986),利用此数量关系可以在今后的检测中判断光肩星天牛幼虫的虫口数量和危害状况。     

Optimal parameters for electrical auricular defibrillation

In acute experiments on dogs the chest was opened and auricular flutter and fibrillation were induced. Current, energy and charge thresholds which eliminated this arrhythmia by the monopolar direct impulse of 1--15 ms duration were determined. The current and energy values that evoked the auricular defibrillation during direct application of the electrodes to them were minimal when the impulses of 8 ms were used: 113 +/- 13.7 mA and 10.4 +/- 2.6 mWs in elimination of the flutter, and 275 +/- 18.2 mA and 62.3 +/- +/- 9.0 mWsec in elimination of the fibrillation. The current that restored the nomotopic rhythm during direct auricular defibrillation was 50 times less than that determined during the transthoracic auricular defibrillation in dogs. The efficacy of direct auricular defibrillation indicated the necessity of the elaboration of an adequate method for its application in clinical practice.     

Firing properties of the soma and axon of the abdominal stretch receptor neurons in the crayfish (Astacus leptodactylus)

Action potentials (APs) and impulse responses in the soma and axon of the rapidly and slowly adapting (SA) abdominal stretch receptor neurons of the crayfish (Astacus leptodactylus) were recorded with single microelectrode current-clamp technique. Impulse frequency response to constant current injection was almost constant in the SA neuron while the response decayed completely in the rapidly adapting (RA) neuron. Mean impulse frequency responses to current stimulations were similar in the receptor neuron pairs. In the RA neuron additional current steps evoked additional impulses while a sudden drop in the current amplitude caused adaptation. Impulse duration was dependent on the rate of rise when current ramps were used. Adaptation was facilitated when calculated receptor current was used. Exposing the neuron to 3 mmol/l TEA or scorpion venom resulted in partly elongated impulse responses. SA neuron could continuously convert the current input into impulse frequency irrespective of previous stimulation conditions. Exposing the SA neuron to 3 mmol/l TEA or 1 mmol/l Lidocaine reduced impulse duration to large current stimulations. The SA neuron fired spontaneously if it was exposed to 5-10 mmol/l Lidocaine or 10(-2) mg/ml Leiurus quinquestriatus venom. The action potential (AP) amplitudes in the RA soma, RA axon, SA soma, and SA axon were significantly different between components of all pairs. Duration of the AP in the axon of the RA neuron was significantly shorter than those in the RA soma, SA soma, and SA axon. Diameter of the RA axon was larger than that of the SA axon. Non-adapting impulse responses were promptly observed only in the SA axons. The results indicate that the RA neuron is a sort of rate receptor transducing the rapid length changes in the receptor muscle while the SA neuron is capable of transducing the maintained length changes in the receptor muscle. The differences in firing properties mainly originate from the differences in the active and passive properties of the receptor neurons.     

Analysis of long-lived substates of the conductivity of single ion channels

Using the patch-voltage-clamp method kinetic parameters of single ionic channels were studied. It was found that the channels have long-lasting conductance substates along with the short-living ones. The conductance of a long-lasting substate fluctuates near an average sublevel in the boundaries of a restrict number (k) of elementary conductance steps. There is a direct relationship: the greater k, the longer is average duration (tau k) of the substate. For a given k the falling phase of tau k value distribution is approximately one-exponential. The substates of k-th order result in the multi-exponentiality of the ion current kinetics.     

Cognitive network interactions and beta 2 coherence in processing non-target stimuli in visual oddball task

Spatiotemporal dynamics of event-related potentials (ERP) evoked by non-target stimuli in a visual oddball experiment and the presence of coherent oscillations in beta 2 frequency band of decomposed EEG records from peristimulus period were investigated by means of intracranial electrodes in humans. Twenty-one patients with medically intractable epilepsy participated in the study. The EEG signal was recorded using platinum electrodes implanted in several cortical and subcortical sites. Averaged 2 s EEG records were analyzed. Task-specific EEG changes were found in each patient, ERPs were derived from 92 electrodes used (96 % of possible cases). In the majority of analysed cases, ERPs were composed of several distinct components, and their duration was mostly longer than 1 s. The mean onset of the first ERP component was 158+/-132 ms after the stimulus (median 112 ms, minimum value 42 ms, maximum value 755 ms), and large variability of these onset times was found in all the investigated structures. Possible coherence between neural activities of remote brain sites was investigated by calculating running correlations between pairs of decomposed EEG records (alpha, beta 1, beta 2 frequency bands were used, total number of correlated pairs was 662 in each frequency band). The record pairs exhibiting highly correlated time segments represented 23 % of all the investigated pairs in alpha band, 7 % in beta 1 band, and 59 % in beta 2 band. In investigated 2 s record windows, such segments were distributed evenly, i.e. they were also found before the stimulus onset. In conclusion, the results have implicated the idea that a lot of recorded ERPs was more or less by-products of chance in spreading a signal within the neuronal network, and that their functional relevance was somewhat linked with the phenomenon of activity synchronization.     

The lateralization of hemispheric control over pain-induced vocalizations in rats

Study was carried out on 232 white rats, male and female, fixed in a hammock and subjected to painful stimulation of the tail. The first impulse of pain vocalization was analyzed. The rats were divided into three groups--with intact brain, with inactivated left or right hemisphere. The first impulses of rats pain vocalizations may be divided into short screams with 40-140 ms duration and long squeals of 140-420 ms duration. Unilateral cortex inactivation led to a reduction of the latency, increase of the peak amplitude and change of the per cent both of the pain screams and pain squeals. After elimination of the left hemisphere as compared with that of the right one, a shorter latency and a greater per cent of the pain screams was observed and a smaller per cent of pain squeals. The obtained data testify to the dominance of the left hemisphere in the control of pain vocalizations in rats.     

The underwater and airborne horizontal localization of sound by the northern fur seal

The accuracy of the underwater and airborne horizontal localization of different acoustic signals by the northern fur seal was investigated by the method of instrumental conditioned reflexes with food reinforcement. For pure-tone pulsed signals in the frequency range of 0.5-25 kHz the minimum angles of sound localization at 75% of correct responses corresponded to sound transducer azimuth of 6.5-7.5 degrees +/- 0.1-0.4 degrees underwater (at impulse duration of 3-90 ms) and of 3.5-5.5 degrees +/- 0.05-0.5 degrees in air (at impulse duration of 3-160 ms). The source of pulsed noise signals (of 3-ms duration) was localized with the accuracy of 3.0 degrees +/- 0.2 degrees underwater. The source of continuous (of 1-s duration) narrow band (10% of c.fr.) noise signals was localized in air with the accuracy of 2-5 degrees +/- 0.02-0.4 degrees and of continuous broad band (1-20 kHz) noise, with the accuracy of 4.5 degrees +/- 0.2 degrees.     

Hypothalamic autostimulation in rats at low frequencies of stimulation on the basis of locomotion]

A study was made of the hypothalamic autostimulation of rats with the impulse stimulation frequency of from 30 to 7 cycles/sec. The animals' brain was stimulated in Skinner's chamber and on the basis of locomotion. The duration of a series of impulses established by the animal on the basis of locomotion grew with reduction of the frequency of stimulation impulses. The pauses between the series of impulses and the duration of the series were also prolonged with a voltage reduction. With the help of stimulation frequency of 7 cycles it was possible to choose such a current that the sum of the total duration of pauses lay within 0 divided by 10% of the total experimental time. The duration of individual pauses was less than 0.5 sec.     

Short latency vestibular evoked potentials (VsEPs) to linear acceleration impulses in rats

In this study, short latency (t<12.7 ms) vestibular evoked potentials (VsEPs) in response to linear acceleration impulses were recorded in 37 rats. A new technique (based on a solenoid) was used for generating linear force impulses that were delivered to the animal's head. The impulse had a maximal peak acceleration of 12 g. During the impulse, the displacement was 50 μm (at 4 g) and the rise time was 1.0 ms. A stimulation rate of 2/s was usually used. The VsEPs (averaged responses to 128 stimulations, digital filter: 300–1500 Hz) were recorded with electrodes on pinna and vertex, and were composed of 4–6 clear waves with mean amplitudes (for a 4 g stimulus) of 1–5 μV. The VsEPs were resistant to white noise masking, and were significantly suppressed (P<0.05) following bilateral application of a saturated KCl solution to the inner ear, showing that contributions of the auditory and somatosensory systems are negligible. The latency of the response decreased as a power law function of stimulus magnitude, and the amplitude of the first wave increased as a sigmoid function of stimulus magnitude. VsEP responses were still present at the lowest intensities attainable (0.06–0.4 g) and reached saturation at 9 g. The amplitude of the later components was reduced when stimulus rate was elevated to 20/s. These results suggest that VsEPs in response to linear accelerations are similar in their nature to VsEPs in response to angular acceleration impulses that were previously recorded. These VsEPs to linear accelerations are most likely initiated in the otolith organs.     

Effect of menthol on cold receptor activity. Analysis of receptor processes

The effect of menthol on the discharge pattern of feline nasal and lingual cold receptors was analyzed in order to elucidate the underlying sensory transducer mechanism. A repetitive beating activity and burst (grouped) discharges were observed in both cold receptor populations at constant temperatures and after rapid cooling. An analysis of the impulse activity revealed a cyclic pattern of impulse generation, which suggested the existence of an underlying receptor potential oscillation that initiates impulses in the afferent nerve when it exceeds a threshold value. The frequency and amplitude of the periodic impulse-inducing receptor processes were characterized by the burst frequency, which increased with warming, and by the average number of impulses generated during each cycle, which increased with cooling. Menthol at micromolar concentrations induced an acceleration of the burst frequency at higher temperatures, but reduced the burst frequency in the midtemperature range. At temperatures above 25 degrees C, menthol increased the number of impulses elicited during each cycle and induced bursting in previously repetitively discharging fibers. At low temperatures, menthol suppressed bursting and finally inhibited all cold receptor activity. The impulse pattern at constant temperatures and during the dynamic response to rapid cooling was comparably affected by menthol. Calcium application completely abolished the stimulating menthol effect. Since, in equal concentrations, menthol specifically impairs neuronal calcium currents, the results are consistent with the conjecture that in cold receptors, menthol reduces the activation of a calcium-stimulated outward current by an impeding effect on a calcium conductance, thereby inducing depolarization and a modification of bursting behavior. The data confirm the hypothesis of a calcium-controlled outward conductance being involved in the generation of cyclic afferent activity in cold receptors.     

Voltage-dependent gating of single gap junction channels in an insect cell line.

De novo formation of cell pairs was used to examine the gating properties of single gap junction channels. Two separate cells of an insect cell line (clone C6/36, derived from the mosquito Aedes albopictus) were pushed against each other to provoke formation of gap junction channels. A dual voltage-clamp method was used to control the voltage gradient between the cells (Vj) and measure the intercellular current (Ij). The first sign of channel activity was apparent 4.7 min after cell contact. Steady-state coupling reached after 30 min revealed a conductance of 8.7 nS. Channel formation involved no leak between the intra- and extracellular space. The first opening of a newly formed channel was slow (25-28 ms). Each preparation passed through a phase with only one operational gap junction channel. This period was exploited to examine the single channel properties. We found that single channels exhibit several conductance states with different conductances gamma j; a fully open state (gamma j(main state)), several substates (gamma j(substates)), a residual state (gamma j(residual)) and a closed state (gamma j(closed)). The gamma j(main state) was 375 pS, and gamma j(residual) ranged from 30 to 90 pS. The transitions between adjacent substates were 1/7-1/4 of gamma j(main state). Vj had no effect on gamma j(main state), but slightly affected gamma j (residual). The lj transitions involving gamma j(closed) were slow (15-60 ms), whereas those not involving gamma j(closed) were fast (< 2 ms). An increase in Vj led to a decrease in open channel probability. Depolarization of the membrane potential (Vm) increased the incidence of slow transitions leading to gamma j(closed). We conclude that insect gap junctions possess two gates, a fast gate controlled by Vj and giving rise to gamma j(substates) and gamma j(residual), and a slow gate sensitive to Vm and able to close the channel completely.     

大鼠背根节神经元后超极化中Ca^2＋激活K^＋电流的蜂毒明肽敏感成分 …

为了明确大鼠背根节(DRG)神经元中存在慢的Ca2+激活K+电流成分,本实验在新鲜分散的DRG神经元胞体上,采用全细胞电压箝技术,给予DRG神经元一定强度的去极化刺激,记录刺激结束后30 ms时的尾电流幅度.结果发现:(1)随着去极化时间从1 ms延长至180 ms时,尾电流幅度由9.3±2.8 pA逐渐增大至64.1±3.4 pA(P＜0.001);(2)当去极化结束后的复极化电位降低时,尾电流幅度先逐渐下降到零,然后改变方向,逆转电位约为-63 mV;(3)细胞外施加500μmol/L Cd2+或细胞内液中施加11 mmol/L EGYA时尾电流明显减小甚至完全消失;(4)尾电流中慢成分的幅度在细胞外给与200 nmol/L蜂毒明肽后,减小了约26.32±3.9%(P＜0.01);(5)细胞外施加10 mmol/L TEA,可明显降低尾电流中的快成分.结果提示,在DRG神经元后超极化中存在Ca2+激活K+电流的蜂毒明肽敏感成分--ⅠAiHP.     

A computer method for assessing the average rate of movement of Paramecium caudatum by a cross-sectional light beam

The possibility of using the motility of Paramecium caudatum for computer biotesting of toxic substances was studied. The method is based on measuring the number and duration of impulses that arise when protozoa chaotically moving in a layer 0.5 mm thick cross a red light beam (1 mm in diameter). It was found that, in the presence of Cu2+ ions and menadione bisulfite, a compound having prooxidant properties, the number of impulses decreased with a concurrent increase in the duration of impulses. The high correlation between the number of impulses and the reciprocal of impulse duration indicates that the motility of paramecium by the action of Cu2+ ions and menadione slow down, and even an immobilization of some of them occurs. The mean swimming velocity of protozoa was reduced by half within 20 min by the action of Cu2+ at a concentration of 90 microM (6 mg/l of Cu2+ ions) and within 80 min by the action of menadione bisulfite at a concentration of 50 microM. It was shown that the slowing down of motility, which indicates the presence of a toxicant in the medium, is a faster physiological reaction than cell death.     

Mechanism of blocking K+-channels with tetraethylammonium

Using the patch-voltage-clamp method action of tetraethylammonium on the fast (30 pS) and slow K+ channels was investigated. The slow K+ channels were presented by two types: with whole (30 pS) and decreased (20 pS) conductance. In all cases tetraethylammonium decreased the current magnitude and modified the channel kinetic parameters. Apparent blocking constants determined from the current decreasing are as 8-50 and 4-12 mM for the slow K+ channels with whole and decreased conductance, respectively, and 0.05-0.08 mM--for the fast K+ channel. The potential dependency of the blocking constants correlates with that of the channel conductance. Probability of the channel open state for the slow K+ channels decreases, and that for the fast K+ channel increases under application of tetraethylammonium. It is concluded that there are two sites of tetraethylammonium binding: the first site is into the channel pore, and the second one--into the regulatory centre responsible for the channel kinetic behaviour. Blocking of general conductance of the slow channels is accompanied by proportional decrease of the channel substate conductances without change of their number and cooperatively. Block of the fast K+ channel occurs without change of the channel elementary conductance but with decrease of the number of the channel substates and reversible violation of the channel transition cooperativity. The data are discussed from the point of the hypothesis on the channel clustery organization.     

Action of powerful ultrashort laser impulses on the permeability of the outer membrane of HeLa cells

It was shown that in HeLa cells, at the stationary growth phase, the permeability of the outer membrane for thymidine increased 1 h after irradiation with two ultrashort impulses (Nd3+: YAG laser, lambda = 266, 532 or 1064 nm, the impulse duration of 3 X 10(-11) s, I = 2 or 20 MW/cm2). The effect was dependent on the time interval between the impulses and virtually independent of the radiation wave-length. The maximum increase in the membrane permeability (by approximately 3 times) was noted after irradiation at 4-6 s intervals between the impulses.     

Tail currents in the myelinated axon of Xenopus laevis suggest a two-open-state Na channel.

Na tail currents in the myelinated axon of Xenopus laevis were measured at -70 mV after steps to -10 mV. The tail currents were biexponential, comprising a fast and a slow component. The time constant of the slow tail component, analyzed in the time window 0.35-0.50 ms, was independent of step duration, and had a value of 0.23 ms. The amplitude, extrapolated back to time 0, varied, however, with step duration. It reached a peak after 0.7 ms and inactivated relatively slowly (at 2.1 ms the absolute value was reduced by approximately 30%). The amplitude of the fast component, estimated by subtracting the amplitude of the slow component from the calculated total tail current amplitude, reached a peak (three times larger than that of the slow component) after 0.5 ms and inactivated relatively fast (at 2.1 ms it was reduced by approximately 65%). The results were explained by a novel Na channel model, comprising two open states bifurcating from a common closed state and with separate inactivating pathways. A voltage-regulated use of the two pathways explains a number of findings reported in the literature.