Excitability of single firing human motoneurones to single and repetitive stimulation (experiment and model)

The activity of single motoneurones of m. flexor carpi ulnaris (FCU) was investigated by recording their motor unit (MU) action potentials during weak and moderate voluntary muscle contractions. The MU firing rate range was 4.5-15 imp/s. The excitability of motoneurones was tested with a number of single stimuli eliciting a monosynaptic H-reflex of low amplitude. Two different indices were defined which relate to motoneuronal excitability: the response index--the ratio of the number of responses of a motoneurone to the total number of stimuli, and the response time--the time after the last background MU discharge at which motoneurone is ready to respond to the excitatory volley. Both the response index and the response time were determined for single motoneurones at different levels of background activity. In the lower range of firing rates, the response index for all motoneurones decreased when increasing the firing rate, but it remained constant in the higher rate range. This kind of response seems to be a typical motoneuronal response to the stimulation with single stimuli. The data on the response time were used to study the excitability of the same single motoneurones to computer simulated repetitive stimulation (stimulation rate 40-100 imp/s). In this case, the excitability of each motoneurone was determined as an increment of its firing rate in response to the stimulation. For the lower firing rate range, the excitability for all motoneurones also decreased when the firing rates increased whereas a variety of slopes was obtained in the higher rate range.(ABSTRACT TRUNCATED AT 250 WORDS)     

Computer simulation study of the relationship between the profile of excitatory postsynaptic potential and stimulus-correlated motoneuron firing

This paper shows the results of computer simulation of changes in motoneuron (MN) firing evoked by a repetitively applied synaptic volley that consists of a single excitatory postsynaptic potential (EPSP). Spike trains produced by the threshold-crossing MN model were analyzed as experimental results. Various output functions were applied for analysis; the most useful was a peristimulus time histogram, a special modification of a raster plot and a peristimulus time frequencygram (PSTF). It has been shown that all functions complement each other in distinguishing between the genuine results evoked by the excitatory volley and the secondary results of the EPSP-evoked synchronization. The EPSP rising edge was best reproduced by the PSTF. However, whereas the EPSP rise time could be estimated quite accurately, especially for high EPSP amplitudes at high MN firing rates, the EPSP amplitude estimate was also influenced by factors unrelated to the synaptic volley, such as the afterhyperpolarization duration of the MN or the amplitude of synaptic noise, which cannot be directly assessed in human experiments. Thus, the attempts to scale any estimate of the EPSP amplitude in millivolts appear to be useless. The decaying phase of the EPSP cannot be reproduced accurately by any of the functions. For the short EPSPs, it is extinguished by the generation of an action potential and a subsequent decrease in the MN excitability. For longer EPSPs, it is inseparable from the secondary effects of synchronization. Thus, the methods aimed at extracting information about long-lasting and complex postsynaptic potentials from stimulus-correlated MN firing, should be refined, and the theoretical considerations checked in computer simulations.     

Modulation by dopamine of population spikes in area CA1 hippocampal neurons elicited by paired stimulus pulses

Extracellular recording techniques were used to study the effects of dopamine on postactivation excitability of rat area CA1 hippocampal neurons maintained in vitro. Population spikes were elicited by delivery of conditioning and test stimulus pulses to afferent fibers. The interval between the conditioning and test volley was set to separate delivery of stimuli by 10 to 80 msec. The effect of superfusion or microtopical application of dopamine (DA) on population responses to test stimulus pulses was studied. When paired stimulus volleys, separated by brief intervals (up to 40 msec), were delivered to afferent fibers, paired-pulse suppression (PPS) was indicated by the amplitude of the population spike elicited by the test volley being smaller than that elicited by the conditioning volley. When paired volleys were separated by longer intervals (40 to 80 msec), the response elicited by the test volley was larger in amplitude than that elicited by the conditioning volley, indicating paired-pulse facilitation (PPF). Following exposure to DA, the amplitude of the population response elicited by the conditioning volley was larger than the amplitude before exposure to DA. This effect was long-lasting, enduring for tens of minutes. However, when the amplitude of the conditioning population response was held constant, the PPS was decreased, indicating disinhibition. It is suggested that dopamine produces a long-lasting attenuation of an intervening inhibitory influence onto CA1 pyramidal neurons.     

Contrasting effects of the persistent Na+ current on neuronal excitability and spike timing

The persistent Na+ current, INaP, is known to amplify subthreshold oscillations and synaptic potentials, but its impact on action potential generation remains enigmatic. Using computational modeling, whole-cell recording, and dynamic clamp of CA1 hippocampal pyramidal cells in brain slices, we examined how INaP changes the transduction of excitatory current into action potentials. Model simulations predicted that INaP increases afterhyperpolarizations, and, although it increases excitability by reducing rheobase, INaP also reduces the gain in discharge frequency in response to depolarizing current (f/I gain). These predictions were experimentally confirmed by using dynamic clamp, thus circumventing the longstanding problem that INaP cannot be selectively blocked. Furthermore, we found that INaP increased firing regularity in response to sustained depolarization, although it decreased spike time precision in response to single evoked EPSPs. Finally, model simulations demonstrated that I(NaP) increased the relative refractory period and decreased interspike-interval variability under conditions resembling an active network in vivo.     

Analysis of firing behaviour of human motoneurones within 'subprimary range'.

Firing behaviour of human motoneurones within a low range of frequencies was studied during voluntary muscle contraction. It was found that, in contrast to the higher 'primary range', both excitability and inhibitibility of these motoneurones were significantly higher. As to their minimal firing rates, no correlation between them and the reciprocal values of afterhyperpolarization (AHP) duration was found. This suggests that AHP can hardly be regarded as the main factor controlling the behaviour of human motoneurones within the low-frequency range of firing and that this range (termed here 'subprimary range') should be kept apart from the 'primary range'.     

GABA and Prolonged Spinal Inhibition

TWO explanations have been provided for the relatively long latency and prolonged (often exceeding 100 ms) inhibition of firing of spinal motoneurones which is caused by repetitive impulses produced by electrical or natural stimulation^1–4 in muscle and cutaneous afferent fibres. This prolonged inhibitory process is exemplified by the reduction in the amplitude of monosynaptic excitatory synaptic potentials (EPSPs) and reflexes of extensor motoneurones by tetanic stimulation of group I afferents of flexor motoneurones². In contrast with “direct” inhibition, the prolonged inhibition is not reduced by strychnine but is diminished by Picrotoxin^4,6.     

Cholinergic modulation of neuronal spike reactions to dendritic and somatic application of excitatory acids

Acetylcholine effects on neuronal firing responses evoked by somatic or dendritic applications of excitatory amino acids were studied in slices of guinea-pig parietal cortex. Excitatory reactions initiated by dendritic activation were enhanced by acetylcholine wherever it was iontophoretically applied: either to soma or dendrites. The effect consisted in shortening spike response latencies and increasing response intensity and duration. The modified responses were recorded within 1-min interval after acetylcholine microinjections at a distance within 300 microns of the soma. Parameters of responses to somatic applications of excitatory amino acids were not significantly changed by acetylcholine. The results suggest that acetylcholine improves dendritic propagation rather than membrane excitability.     

Reliable Activation of Immature Neurons in the Adult Hippocampus

Neurons born in the adult dentate gyrus develop, mature, and connect over a long interval that can last from six to eight weeks. It has been proposed that, during this period, developing neurons play a relevant role in hippocampal signal processing owing to their distinctive electrical properties. However, it has remained unknown whether immature neurons can be recruited into a network before synaptic and functional maturity have been achieved. To address this question, we used retroviral expression of green fluorescent protein to identify developing granule cells of the adult mouse hippocampus and investigate the balance of afferent excitation, intrinsic excitability, and firing behavior by patch clamp recordings in acute slices. We found that glutamatergic inputs onto young neurons are significantly weaker than those of mature cells, yet stimulation of cortical excitatory axons elicits a similar spiking probability in neurons at either developmental stage. Young neurons are highly efficient in transducing ionic currents into membrane depolarization due to their high input resistance, which decreases substantially in mature neurons as the inward rectifier potassium (Kir) conductance increases. Pharmacological blockade of Kir channels in mature neurons mimics the high excitability characteristic of young neurons. Conversely, Kir overexpression induces mature-like firing properties in young neurons. Therefore, the differences in excitatory drive of young and mature neurons are compensated by changes in membrane excitability that render an equalized firing activity. These observations demonstrate that the adult hippocampus continuously generates a population of highly excitable young neurons capable of information processing.     

Some effects of superior laryngeal nerve stimulation on sympathetic preganglionic neuron firing

Repetitive electrical stimulation of afferent fibers in the superior laryngeal nerve (SLN) evoked depressant or excitatory effects on sympathetic preganglionic neurons of the cervical trunk in Nembutal-anesthetized, paralyzed, artifically ventilated cats. The depressant effect, which consisted of suppression of the inspiration-synchronous discharge of units with such firing pattern, was obtained at low strength and frequency of stimulation (e.g. 600 mV, 30 Hz) and was absent at end-tidal CO2 values below threshold for phrenic nerve activity. The excitatory effect required higher intensity and frequency of stimulation and was CO2 independent. The depressant effect on sympathetic preganglionic neurons with inspiratory firing pattern seemed a replica of the inspiration-inhibitory effect observed on phrenic motoneurons. Hence, it could be attributed to the known inhibition by the SLN of central inspiratory activity, if it is assumed that this is a common driver for phrenic motoneurons and some sympathetic preganglionic neurons. The excitatory effect, on the other hand, appears to be due to connections of SLN afferents with sympathetic preganglionic neurons, independent of the respiratory center.     

Synaptic integration in spinal motoneurones.

Spinal motoneurones receive thousands of presynaptic excitatory and inhibitory synaptic contacts distributed throughout their dendritic trees. Despite this extensive convergence, there have been very few studies of how synaptic inputs interact in mammalian motoneurones when they are activated concurrently. In the experiments reported here, we measured the effective synaptic currents and the changes in firing rate evoked in cat spinal motoneurones by concurrent repetitive activation of two separate sets of presynaptic neurons. We compared these effects to those predicted by a linear sum of the effects produced by activating each set of presynaptic neurons separately. We generally found that when two inputs were activated concurrently, both the effective synaptic currents and the synaptically-evoked changes in firing rate they produced in motoneurones were generally linear, or slightly less than the linear sum of the effects produced by activating each input alone. The results suggest that the spatial distribution synaptic terminals on the dendritic trees of motoneurones may help isolate synapses from one another, minimizing non-linear interactions.     

Detection and analysis of recurrent inhibition of firing motoneurons in man

During regular firing of "small" motor units, activated during weak voluntary contraction of the human soleus muscle, thick efferent fibers of n. tibialis were stimulated (a small M response was evoked, in which the small units did not participate). Peristimulus histograms of potentials of single motor units were constructed and the effect of stimulation on interspike interval duration was analyzed. The firing rate of the motor units was 4.5–7.6 spikes/sec. Stimulation of the nerve led to a sharp decrease in probability of their discharge or even complete temporary cessation of firing, i.e., it had a well marked inhibitory effect (lasting 10–20 msec). The latent period of inhibition (35–40 msec) was only a little longer than the latent period of the monosynaptic reflex of the soleus muscle. The effect of an inhibitory volley on duration of the interspike interval of the motor units depended on the time when the volley arrived during the interval. Lengthening of the interval was observed only if the inhibitory volley arrived in the second half or at the end of the interval. It is concluded that inhibition of firing of small motor units is due to Renshaw cells, activated on stimulation of axons of large motoneurons. The efficiency of a short (compared with the duration of the interspike interval) inhibitory volley reaching a motoneuron firing at low frequency characteristic of its adequate activation, is discussed.Institute for Problems of Information Transmission, Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 16, No. 1, pp. 88–96, January–February, 1984.     

Effects of Weak Environmental Magnetic Fields on the Spontaneous Bioelectrical Activity of Snail Neurons

We examined the effects of 50-Hz magnetic fields in the range of flux densities relevant to our current environmental exposures on action potential (AP), after-hyperpolarization potential (AHP) and neuronal excitability in neurons of land snails, Helix aspersa. It was shown that when the neurons were exposed to magnetic field at the various flux densities, marked changes in neuronal excitability, AP firing frequency and AHP amplitude were seen. These effects seemed to be related to the intensity, type (single and continuous or repeated and cumulative) and length of exposure (18 or 20 min). The extremely low-frequency (ELF) magnetic field exposures affect the excitability of F1 neuronal cells in a nonmonotonic manner, disrupting their normal characteristic and synchronized firing patterns by interfering with the cell membrane electrophysiological properties. Our results could explain one of the mechanisms and sites of action of ELF magnetic fields. A possible explanation of the inhibitory effects of magnetic fields could be a decrease in Ca²⁺ influx through inhibition of voltage-gated Ca²⁺ channels. The detailed mechanism of effect, however, needs to be further studied under voltage-clamp conditions.     

Human motoneuron firing behavior and single motor unit F-wave

In motor control studies, the F-wave (a recurrent discharge evoked by an axonal antidromic volley) widely used for obtaining information on motoneuron pool behavior. However, such F-wave using is a matter of discussion and still has been not validated experimentally. The aim of the present study was investigation of F-wave properties of single firing motor units (MUs) in healthy humans, the properties, which could give evidence for F-wave origin in motoneuron soma and, therefore, could be used for estimation of a relation between MU firing and motoneuron firing behavior. In total, 91 MUs in five muscles of six healthy subjects, during gentle voluntary contractions, were studied. Peri-stimulus time histograms of single MUs were plotted. None of them revealed statistically significant increasing in MU firing probability at the F-wave latency. Analysis of relationships between characteristics of motoneuron firing behavior (mean firing frequency and target interspike interval duration) and properties of F-waves showed their independence. At the same time, it was found that F-waves were recorded in MUs, whose axons possessed the marked supernormal period in excitability recovery cycle after a discharge. Thus, the present results are in contrast to that which should be expected if the F-wave originated in the motoneuronal soma and could provide evidence for motoneuron firing behavior.     

Static and dynamic properties of synaptic transmission at the cyto- neural junction of frog labyrinth posterior canal

The properties of synaptic transmission have been studied at the cyto-neural junction of the frog labyrinth posterior canal by examining excitatory postsynaptic potential (EPSP) activity recorded intraaxonally from the afferent nerve after abolishing spike firing by tetrodotoxin. The waveform, amplitude, and rate of occurrence of the EPSPs have been evaluated by means of a procedure of fluctuation analysis devised to continuously monitor these parameters, at rest as well as during stimulation of the semicircular canal by sinusoidal rotation at 0.1 Hz, with peak accelerations ranging from 8 to 87 deg.s-2. Responses to excitatory and inhibitory accelerations were quantified in terms of maximum and minimum EPSP rates, respectively, as well as total numbers of EPSPs occurring during the excitatory and inhibitory half cycles. Excitatory responses were systematically larger than inhibitory ones (asymmetry). Excitatory responses were linearly related either to peak acceleration or to its logarithm, and the same occurred for inhibitory responses. In all units examined, the asymmetry of the response yielded nonlinear two-sided input-output intensity functions. Silencing of EPSPs during inhibition (rectification) was never observed. Comparison of activity during the first cycle of rotation with the average response over several cycles indicated that variable degrees of adaptation (up to 48%) characterize the excitatory response, whereas no consistent adaptation was observed in the inhibitory response. All fibers appeared to give responses nearly in phase with angular velocity, at 0.1 Hz, although the peak rates generally anticipated by a few degrees the peak angular velocity. From the data presented it appears that asymmetry, adaptation, and at least part of the phase lead in afferent nerve response are of presynaptic origin, whereas rectification and possible further phase lead arise at the encoder. To confirm these conclusions a simultaneous though limited study of spike firing and EPSP activity has been attempted in a few fibers.     

The heterogeneity of the excitatory synaptic inputs in the spinal motor neurons of the frog Rana ridibunda

The synaptic responses induced in motoneurones by the stimulations of the dorsal root (DR), single afferent fibres and reticular formation (RF) were intracellularly recorded in the isolated frog spinal cord. It was shown that argiopine (the selective blocker of glutamate receptors of non-NMDA type) in concentrations ranging from 3.10(-7) to 1.10(-5) M effectively suppressed the di- and polysynaptic, but not the monosynaptic components of EPSP's induced by DR stimulation. The initial reaction to argiopine consisted of the increase of this monosynaptic component of EPSP. In the same concentrations range, argiopine reduced both mono- and polysynaptic EPSP, evoked by RF stimulation. 2-amino-phosphonovaleric acid (1.10(-4) M) did not affect, whereas the kinurenate (1--2.10(-3) M) completely blocked the amplitude of all kinds of synaptic responses. The various effects of argiopine on the responses induced by microstimulation of presynaptic nerve terminals were observed. The data obtained speak in favour of heterogeneity of monosynaptic excitatory inputs in the motoneurones of frog spinal cord. Being the glutamatergic by nature, the inputs differ in the properties of postsynaptic receptors. All of these receptors concerning to non NMDA-type can be divided to argiopine-sensitive and argiopine-resistant. The first seem to be involved in the monosynaptic connections of RF and the second--in those of primary afferents with motoneurones.     

Relationship between the discharge rate of a firing motoneuron and the effectiveness of excitatory la afferent volleys in man

The H-reflex was evoked after producing regular unit firing in the flexor carpi ulnaris set up by moderate voluntary isometric muscular contraction. The firing index was used to quantify the effectiveness of the monosynaptic afferent signal traveling to the firing motoneuron. An analysis was made of the 3.3–16.0 spikes/sec firing range characteristic of naturally occurring muscular contraction. Effectiveness of afferent signals for motor units in the "fast" muscles under study were found to depend on motoneuronal background firing rate; the former declined as the latter rose, as previously discovered during research into "slow" soleus muscle units [2]. Afferent signals were most effective for motoneurons belonging to the "fast" muscles over the entire range of firing rates. It was found from analyzing afferent signal efficacy in relation to its point of occurrence within the interspike interval that variations in motoneuronal excitability within this interval are the reason for this relationship.Institute for Research into Information Transmission, Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 19, No. 5, pp. 595–600, September–October, 1987.     

Impulse frequency encoding of the dynamic aspects of excitation

Like receptors, neurones of the mammalian CNS react to both the static and the dynamic features of the input signals. The quantitative aspect of the current-to-frequency transduction during input transients were analyzed in spinal motoneurones and in corticospinal neurones by the technique of injecting intracellularly either ramp of sine-wave currents. It was found that, in both types of neurones, the instantaneous firing frequency is linearly correlated, within definite ranges, both to the intensity and to the velocity of change of the input currents. By recording the isometric mechanogram of the muscle units innervated by the impaled motoneurones, it was disclosed that the motoneurones discharges produced by the ramp currents develop tension changes, whose average velocity is proportional to the ramp slope. For both types of neurones, results are consistent with the hypothesis that the major determinants of the double sensitivity, to the intensity and to the velocity, are the kinetics of the potassium conductance system responsible for the spike afterhyperpolarization.     

Increased efficacy of antidromic and orthodromic activation of cat alpha motoneurons upon arrival of coerulospinal volleys

The present study demonstrates the enhanced efficacy of impulse initiation among the hindlimb alpha motoneurons of flexor and extensor origins (n = 35) upon electrical stimulation of the locus coeruleus (LC) in decerebrate cats. When combined with the LC-evoked excitatory postsynaptic potential (EPSP), intracellular hyperpolarization-induced partial and total blocks of antidromic invasion were overcome, resulting in full-spike generation in all cells (n = 21). In three other cells, partial blocks, representing the motoneuron refractoriness resulting from double stimulation at close intervals, were relieved by the concomitant LC-EPSP. When an antidromic volley occurred at a time when the somadendritic (SD) membrane was near threshold, LC stimulation was shown to increase the probability of full-spike initiation as well as to shorten the initial segment (IS)-SD delay, suggesting a coerulospinal enhancement of the safety factor for IS-SD impulse conduction. When coincident with the LC-EPSPs, group Ia EPSPs of flexor and extensor origins were demonstrated to reach the threshold of discharging the cells (n = 4). In those cells exhibiting prominent depolarizing synaptic noise (n = 10), LC stimulation was sufficient to cause the cell to fire action potentials presumably by interacting with concomitant excitatory synaptic drive. The present results advocate that the descending LC excitatory drive has engaged in the action potential initiation process of the alpha motoneuron, facilitating its reaching the firing threshold during concurrent depressed membrane excitability as well as subthreshold converging inputs.     

Changes in the reflex excitability of spinal motor neurons in newborn infants during sleep and increases in environmental temperature

Reflex excitability of the spinal motor centres was studied in newborns by the monosynaptic testing (H-reflex) method during the rise of air temperature in the cunette up to 32 degrees and 34 degrees as compared to the control data obtained at 30 degrees C. It was shown that at temperatures of 32 degrees and 34 degrees C the reflex excitability of spinal motoneurones is lower than in the control. A narrowing of the range and a weakening of the stimuli were recorded at which the H-reflex could be elicited. The possible ways are discussed in which the surrounding temperature affects reflex excitability of the spinal motor centres.     

Simulation of vestibular semicircular canal responses during righting movements of a freely falling cat

The righting maneuver of a freely falling cat was filmed at 1000 pictures per second, and the head position about the roll axis was digitized from each film frame using a graphics input tablet. The head angular velocity and acceleration were computed from the roll axis position trajectory. Head acceleration trajectories approximated two periods of a damped sinusoid at a frequency of 26 Hz. Head acceleration peak amplitudes exceeded 120,000 deg/s². These trajectories were used as stimuli for the horizontal semicircular canals in a computer simulation of first-order afferent responses during the fall. Linear system afferent response dynamics, characterized in a previous study of the cat horizontal canal using pseudorandom rotations, provided the basis for linear predictions of falling cat afferent responses. Results showed predicted single afferent firing rates that exceeded physiological values; and variations in afferent sensitivities and phase were predicted among different neurons. Fast head movement information could be carried by ensemble populations of vestibular neurons, and a phase-locking encoding hypothesis is proposed which accomplishes this. Implications for central program versus peripheral vestibular feedback strategies for motor control during falling are presented and discussed.