Effect of carbachol on miniature end-plate potentials and currents of rat skeletal muscle

Experiments on rats showed that carbachol (10 µM) appreciably quickens miniature end-plate potentials in the soleus muscle kept in medium with potassium chloride concentration increased to 13 mM. Potentiation of spontaneous mediator release also took place when the membrane potential of the muscle fibers was clamped at the level of the potassium equilibrium potential. It is concluded that the presynaptic action of carbachol on synaptic liberation of acetylcholine from motor nerve endings is unconnected with depolarization of the postsynaptic membrane but takes place as a result of the direct effect of the mimetic on motor nerve endings.S. V. Kurashov Medical Institute, Ministry of Health of the RSFSR, Kazan'. Translated from Neirofiziologiya, Vol. 14, No. 2, pp. 185–189, March–April, 1982.     

A study of the time and frequency characteristics of the potentials evoked in the acoustical cortex

Evoked potentials in the auditory cortex of the cat are measured by applying auditory stimulations in the form of tone bursts of 700 Hz. Transient evoked potentials obtained in this way are transformed to the frequency domain using a Laplace Transform. The amplitude frequency characteristic obtained with this semi-empirical method depicts maxima of EEG-amplitude in frequency ranges of 10–13 Hz and 60–80 Hz. The correlation between the time course of evoked potentials and spontaneous activity of the brain and the efficiency of the method used are pointed out.     

Two patterns of bulbar neuronal response to microstimulation of locomotor and inhibitory brain stem sites

Synaptic responses (postsynaptic potentials and action potentials) were evoked in mesencephalic decerebellated cats by stimulating pontine bulbar locomotor and inhibitory sites (LS and IS, respectively) with a current of not more than 20 µA in "medial" and "lateral" neurons of the medulla. Some neurons even produced a response to presentation of single (actually low — 2–5 Hz — frequency) stimuli. The remaining cells responded to stimulation at a steady rate of 30–60 Hz only. Both groups of medial neurons were more receptive to input from LS. Lateral neurons responding to even single stimuli reacted more commonly to input from LS and those responding to steady stimulation only to input from IS. Many neurons with background activity (whether lateral or medial) produced no stimulus-bound response, but rhythmic stimulation either intensified or inhibited such activity. This response occurs most commonly with LS stimulation. Partial redistribution of target neurons in step with increasing rate of presynaptic input may play a major part in control of motor activity.Institute for Research into Information Transmission, Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 22, No. 2, pp. 257–266, March–April, 1990.     

Characterization of muscle spindle afferents in the adult mouse using an in vitro muscle-nerve preparation

We utilized an in vitro adult mouse extensor digitorum longus (EDL) nerve-attached preparation to characterize the responses of muscle spindle afferents to ramp-and-hold stretch and sinusoidal vibratory stimuli. Responses were measured at both room (24°C) and muscle body temperature (34°C). Muscle spindle afferent static firing frequencies increased linearly in response to increasing stretch lengths to accurately encode the magnitude of muscle stretch (tested at 2.5%, 5% and 7.5% of resting length [Lo]). Peak firing frequency increased with ramp speeds (20% Lo/sec, 40% Lo/sec, and 60% Lo/sec). As a population, muscle spindle afferents could entrain 1:1 to sinusoidal vibrations throughout the frequency (10-100 Hz) and amplitude ranges tested (5-100 μm). Most units preferentially entrained to vibration frequencies close to their baseline steady-state firing frequencies. Cooling the muscle to 24°C decreased baseline firing frequency and units correspondingly entrained to slower frequency vibrations. The ramp component of stretch generated dynamic firing responses. These responses and related measures of dynamic sensitivity were not able to categorize units as primary (group Ia) or secondary (group II) even when tested with more extreme length changes (10% Lo). We conclude that the population of spindle afferents combines to encode stretch in a smoothly graded manner over the physiological range of lengths and speeds tested. Overall, spindle afferent response properties were comparable to those seen in other species, supporting subsequent use of the mouse genetic model system for studies on spindle function and dysfunction in an isolated muscle-nerve preparation.     

Responses of muscle spindles of tenotomized and hypertrophied muscles to stretching and vibration

Responses of muscle spindles of tenotomized and hypertrophied muscles to stretching and vibration were investigated. During constant stretching of the muscles with a load of 100 g the spontaneous activity of the primary endings in the control muscle was 17±1.5 spikes/sec, in the hypertrophied muscle it was unchanged, and after tenotomy it was increased to 26±1.5 spikes/sec. The discharge frequency of the secondary endings was unchanged under these circumstances. Responses of primary and secondary endings of spindles of the tenotomized muscle during the dynamic and static phases of stretching were higher in frequency than responses of spindles of normal muscles. The discharge frequency of the primary endings in the hypertrophied muscle also was increased during both phases of stretching. Responses of secondary endings of the spindles of the hypertrophied muscle were indistinguishable under these circumstances from responses of normal muscles. Primary endings of spindles of tenotomized and hypertrophied muscles, just as normally, reproduced frequencies of vibration stimulation up to 2000 Hz, but some increase in the discharge frequency was observed in the secondary endings at this time.I. M. Sechenov Institute of Evolutionary Physiology and Biochemistry, Academy of Sciences of the USSR, Leningrad. Translated from Neirofiziologiya, Vol. 8, No. 3, pp. 311–317, September, 1976.     

Time coupling of skeletomotor discharges in response to pseudo-random transsynaptic and transmembrane stimulation

Firing pattern of skeletomotor neurones innervating triceps surae muscles in response to pseudorandom muscle stretching and white noise modulated transmembrane current stimulation was investigated in decerebrate cats. Pseudo-random muscle stretching (upper cut-off frequency 60 Hz, amplitude (standard deviation) ranging from 18.5 m to 40 m) was applied to triceps surae muscles. Membrane potential changes and action potentials of skeletomotor neurones were recorded intracellularly. White noise modulated current was applied through the same (recording) microelectrode. Sequences of ten identical 5 s periods of either muscle stretching or transmembrane current stimulation were applied. Skeletomotor neurones belonging to slow motor units (rheobase less than 8.5 nA) generated action potentials in response to both pseudo-random muscle stretching and transmembrane current stimulation, while firing threshold of those belonging to fast motor units could not be reached by the muscle stretches applied. Peri-spike averaging of muscle length and injected current records showed that the action potentials appeared at the peak of either depolarizing current wave or muscle stretching both preceded by a change in opposite direction (the spikes coinciding with the peak in muscle length PSA being actually elicited by muscle spindle action potentials triggered at the moment of the peak stretching velocity). Time coupling of action potentials occurred during both muscle stretching and transmembrane stimulation, being more tight in the latter case as well as when larger amplitudes of the stimuli were applied. It is supposed that discharges from muscle spindle primary endings phase-locked to small pseudo-random muscle length changes may, due to the time coupling of skeletomotor action potentials, provoke a synchronous firing of skeletomotor neurones, mostly of those belonging to slow motor units. Possible effects of such a firing pattern on the resulting muscle reflex contraction and the stretch reflex stability as well as a possibility of it being provoked by fusimotor discharges are discussed.     

Dynamics of potentials evoked in the auditory pathway and reticular formation of the cat. Studies during waking and sleep stages

Averaged evoked potentials in the inferior colliculus (IC), medial geniculate nucleus (MG) and reticular formation (RF) of chronically implanted and freely moving cats were measured using auditory step functions in the form of tone bursts of 2000 Hz. The most prominent components of the AEP of the inferior colliculus were a positive wave of 13 msec and a negative wave of 40–55 msec latency. The AEP of the medial geniculate nucleus was characterized by a large negative wave peaking at 35–40 msec. During spindle sleep and slow wave sleep stages changes in the AEPs of both nuclei occured.Transient evoked responses of the inferior colliculus, medial geniculate nucleus and reticular formation were transformed to the frequency domain using the Laplace transform (one sided Fourier transform) in order to obtain frequency characteristics of the systems under study. The amplitude characteristics of IC, MG. and RF obtained in this way revealed maxima in alpha (8–13 Hz), beta (18–35 Hz) and higher frequency (50–80 Hz) ranges. During spindle sleep stage a maximum in the theta frequency range (3–8 Hz) and during slow wave sleep maximum in the delta (1–3 Hz) frequency range appeared in the amplitude characteristics of these nuclei.The amplitude characteristics of the inferior colliculus and medial geniculate nucleus were compared with the amplitude characteristics of other brain structures. The comparison of AEPs and amplitude frequency characteristics obtained using these AEPs reveals that the existence of a number of peaks (waves) with different latencies in the time course does not necessarily indicate the existence of different functional structures or neural groups giving rise to these waves. The entire time course of evoked potentials and not the number and latencies of the waves, carries, the whole information concerning different activities and frequency selectivities of brain structures.Supported by Turkish Scientific and Technical Research Council Grant TAG-266.Presented in Part at the VIIIth International Congress of Electroencephalography and Clinical Neurophysiology in Marseilles, September 1–7, 1973.     

Effect of whole body vibration frequency on neuromuscular activity in ACL-deficient and healthy males

Whole-body vibration (WBV) has been shown to enhance muscle activity via reflex pathways, thus having the potential to contrast muscle weakness in individuals with rupture of the anterior cruciate ligament (ACL). The present study aimed to compare the magnitude of neuromuscular activation during WBV over a frequency spectrum from 20 to 45 Hz between ACL-deficient and healthy individuals. Fifteen males aged 28±4 with ACL rupture and 15 age-matched healthy males were recruited. Root mean square (RMS) of the surface electromyogram from the vastus lateralis in both limbs was computed during WBV in a static half-squat position at 20, 25, 30, 35, 40 and 45 Hz, and normalized to the RMS while maintaining the half-squat position without vibration. The RMS of the vastus lateralis in the ACL-deficient limb was significantly greater than in the contralateral limb at 25, 30, 35 and 40 Hz (P<0.05) and in both limbs of the healthy participants (dominant limb at 25, 30, 35, 40 and 45 Hz, P<0.05; non dominant limb at 20, 25, 30, 35, 40 and 45 Hz, P<0.05). The greater neuromuscular activity in the injured limb compared to the uninjured limb of the ACL-deficient patients and to both limbs of the healthy participants during WBV might be due to either augmented excitatory or reduced inhibitory neural inflow to motoneurons of the vastus lateralis through the reflex pathways activated by vibratory stimuli. The study provides optimal WBV frequencies which might be used as reference values for ACL-deficient patients.     

Effects of cholinergic compounds on spontaneous quantal transmitter release at the frog neuromuscular junction

The effects of nicotinic and muscarinic mimetics and lytics on spontaneous quantal transmitter secretion from the motor nerve endings were investigated during experiments on theRana temporaria sartorius muscle. Acetylcholine and carbachol reduced the frequency of miniature endplate potentials both in a normal ionic medium and in one with potassium ion concentration raised to 10 mM. Similar effects were produced by nicotinic agonists, namely nicotine, tetramethylammonium, and suberyldicholine, whereas muscarinic mimetics — methylfurmetide, oxotremorine, and F-2268 (L- and D-stereoisomers) — did not affect transmitter release. Neither d-tubocurarine, benzohexonium, nor atropine abolished the presynaptic effects of carbachol and acetylcholine. It is concluded that nicotinic cholinoreceptors are present at the frog motor nerve endings which modify spontaneous transmitter release and differ in their pharmacological properties from recognized N-cholinoreceptors of the motor and autonomic systems of the higher vertebrates.S. V. Kurashov Medical Institute, Ministry of Public Health of the RSFSR, Kazan'. Translated from Neirofiziologiya, Vol. 18, No. 5, pp. 586–593, September–October, 1986.     

Nonquantal acetylcholine release from motor nerve endings and denervation changes in rat muscle fiber membranes after axonal transport blockade

Microelectrode experiments on the rat diaphragm showed that application of colchicine, which disturbs axonal transport, to the motor nerve leads after 5 days to a decrease in resting potential and an increase in input resistance of the electrogenic membrane, disappearance of differences of input resistance between the postsynaptic and extrasynaptic membranes, the appearance of extrasynaptic sensitivity to acetylcholine, and the appearance of anode-break action potentials resistant to tetrodotoxin. Similar changes develop in the muscle membrane after division of the motor nerve. Application of colchicine to the nerve, unlike its division, does not cause cessation of contractile activity of the muscle or disturbance of quantal and reduction of nonquantal acetylcholine secretion in motor nerve endings, as reflected in the degree of hyperpolarization of the postsynaptic membrane (H effect) in response to the action of D-tubocurarine chloride on the muscle after inhibition of acetylcholinesterase. The results confirmed the view that neurotrophic control of the mammalian muscle fiber membrane is effected mainly by means of substances carried to the muscle by axonal transport. Synaptic acetylcholine, secreted from nerve endings in nonquantal form, does not play a leading role in neurotrophic control of the muscle membrane.S. V. Kurashov Medical Institute, Ministry of Health of the RSFSR, Kazan'. Translated from Neirofiziologiya, Vol. 16, No. 2, pp. 231–238, March–April, 1984.     

Effect of substances blocking calcium channels (verapamil,D-600, manganese ions) on transmitter release from motor nerve endings in frog muscle

Experiments on isolated frog nerve-muscle preparations showed that manganese ions (0.4–5.0 mM) inhibit evoked transmitter release by reducing the quantum composition of the end-plate potentials, and they intensify spontaneous transmitter release to a certain extent by increasing the frequency of miniature potentials. Verapamil (1 · 10^–6–5·10^–5 g/ml) and D-600 (2.5·10^–5 g/ml), by contrast with manganese ions, do not inhibit evoked release, but also intensify spontaneous release of the transmitter. All the agents tested prevent the potentiating effect of imidazole (3 mM). During repetitive stimulation, verapamil disturbs action potential generation in the motor nerve. Manganese ions had no such action. It is concluded that between the calcium channels of motor nerve endings and the calcium channels of heart muscle or the neuron soma there are molecular differences, expressed as sensitivity to the blocking action of verapamil and D-600.I. M. Sechenov Institute of Evolutionary Physiology and Biochemistry, Academy of Sciences of the USSR, Leningrad. Translated from Neirofiziologiya, Vol. 9, No. 4, pp. 415–422, July–August, 1977.     

Contribution of homosynaptic depression to stabilization of spinal cord potentials

The following were measured during experiments on spinal anesthetized cats: firstly, variations in the amplitude of dorsal root potentials produced by applying single or regular stimuli in 120–150 trails to hindlimb cutaneous nerves and dorsal surface of the spinal cord and secondly, numbers of extracellular discharges in neurons involved in generating these potentials. A reduction in the variation between these parameters was found when applying stimulation at the rate of 0.1–5.0 Hz. The authors attribute the effect observed to the influence of homosynaptic depression.Institute of Biology, State University Commemorating 300th Anniversary of Russian-Ukrainian Reunion, Dnepropetrovsk. Translated from Neirofiziologiya, Vol. 20, No. 2, pp. 180–185, March–April, 1988.     

Effect of ouabain on electrical activity of the isolated frog muscle spindle

Changes in electrical activity of the isolated frog muscle spindle were studied in Ringer's solution containing ouabain. The presence of ouabain in the solution increased the spontaneous firing rate of the receptors up to a maximum and then reduced it quickly to zero. The amplitude of the action potentials was reduced on the average to 40% of normal. Ouabain causes initial disappearance of the hyperpolarization phase of the receptor potential and a subsequent decrease in amplitude of its dynamic phase to zero. The decrease in amplitude of the receptor potential and action potential and also the changes in firing rate in the solution with ouabain depend on the frequency of their spontaneous activity. The changes observed can be explained by depolarization of the membrane of the nerve endings and the first node of Ranvier, developing as a result of blocking of the sodium pump by ouabain.Translated from Neirofiziologiya, Vol. 5, No. 6, pp. 576–582, November–December, 1973.     

Activity of single motor units in attention-demanding tasks: firing pattern in the human trapezius muscle

Activity of single motor units in relation to surface electromyography (EMG) was studied in 11 subjects in attention-demanding work tasks with minimal requirement of movement. In 53 verified firing periods, single motor units fired continuously from 30 s to 10 min (duration of the experiment work task) with a stable median firing rate in the range of 8–13 Hz. When the integrated surface EMG were stable, the motor units identified as a rule were continuously active with only small modulations of firing rate corresponding to low-amplitude fluctuations in surface EMG. Marked changes in the surface EMG, either sudden or gradual, were caused by recruitment or derecruitment of motor units, and not by modulations of the motor unit firing rate. Motor unit firing periods (duration 10 s-35 s) in low-level voluntary contractions (approximately 1%–5% EMG_max) performed by the same subjects showed median firing rates (7–12 Hz) similar to the observations in attention-related activation.     

Effect of adequate stimulation on the discharge pattern of an isolated frog muscle spindle

Discharges from an isolated frog muscle spindle during mechanical stimulation of varied amplitude, velocity, and shape were investigated. The firing rate during a linear increase in strength of the stimulus is determined by its amplitude, whereas the change in firing rate is determined by the rate of increase of amplitude. With sinusoidal stimulation the firing rate apparently reproduces stimulus shape, i.e., the muscle spindle is sensitive not only to amplitude and velocity, but also to acceleration of the stimulus. Sensitivity to acceleration is most probably due to the change in threshold of appearance of action potentials observed during variation of the speed of stretching.P. K. Anokhin Institute of Normal Physiology, Academy of Medical Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 8, No. 4, pp. 426–433, July–August, 1976.     

High frequency vibration conditioning stimulation centrally reduces myoelectrical manifestation of fatigue in healthy subjects

ObjectiveVibration conditioning has been adopted as a tool to improve muscle force and reduce fatigue onset in various rehabilitation settings. This study was designed to asses if high frequency vibration can induce some conditioning effects detectable in surface EMG (sEMG) signal; and whether these effects are central or peripheral in origin.Design300 Hz vibration was applied for 30 min during 5 consecutive days, to the right biceps brachii muscle of 10 healthy males aged from 25 to 50 years. sEMG was recorded with a 16 electrode linear array placed on the skin overlying the vibrated muscle. The test protocol consisted of 30% and 60% maximal voluntary contraction (MVC) as well as involuntary (electrically elicited) contractions before and after treatment.ResultsNo statistically significant differences were found between PRE and POST vibration conditioning when involuntary stimulus-evoked contraction and 30% MVC were used. Significant differences in the initial values and rates of change of muscle fibre conduction velocity were found only at 60% MVC.Conclusions300 Hz vibration did not induce any peripheral changes as demonstrated by the lack of differences when fatigue was electrically induced. Differences were found only when the muscle was voluntarily fatigued at 60% MVC suggesting a modification in the centrally driven motor unit recruitment order, and interpreted as an adaptive response to the reiteration of the vibratory conditioning.     

Seasonal variations in neuromuscular transmission in experiments on sectioned or curarized frog muscles

Evoked currents and endplate potentials in frog cutaneopectoral muscle subjected to section or curarization to prevent contraction were investigated in summer and winter conditions using different indirect stimulation rates (of 1 and 100 Hz), with animals maintained at different temperatures prior to trials (of between 5 and 20–25°C). Seasonal changes in amplitude, facilitation, and depression of postsynaptic response discovered in experiments involving curarized and uncurarized dissected muscles differed both quantitatively and qualitatively. These differences may be explained by assuming that sensitivity of the neuromuscular synapse to curare (presumably presynaptic) is liable to seasonal variation.A. A. Ukhtomskii Institute of Physiology, State University, Leningrad. Translated from Neirofiziologiya, Vol. 22, No. 6, pp. 745–751, November–December, 1990.     

Factors that determine the form of neuromuscular junctions of intrafusal fibers in the cat

The form of terminations of fusimotor (gamma) and skeletofusimotor (beta) axons on intrafusal fibers was analyzed in serial sections of 20 spindles of the cat tenuissimus muscle. Seven synaptic features were assessed either qualitatively or quantitatively from electron micrographs of transverse sections of 184 intrafusal and 30 extrafusal endings. Features were compared among endings that were terminations of gamma or beta axons on different types of intrafusal fiber at different distances from the spindle equator. These comparisons indicated that interactions of several factors, and not the motor axon alone, determine the form of motor endings. Intrafusal muscle fiber type is dominant to the motor axon in regulation of the number and depth of postsynaptic folds. Separation of the influence of the motor axon from the muscle fiber was less clear with respect to the size of ending. Complete expression of the muscle fiber-motor axon interaction reflected by the form of motor endings is dependent upon location of the ending relative to the sensory region. Both depth of the primary synaptic cleft and size of the soleplate of motor endings increased with increasing distance of the ending from the spindle equator. A system of classification of cat intrafusal motor endings that reflects the multiplicity of factors that determine the form of endings, and one that simplifies the current terminology, is proposed.     

Response characteristics of vibration-sensitive neurons in the midbrain of the grassfrog,Rana temporaria

Summary European grassfrogs (Rana temporaria) were stimulated with pulsed sinusoidal, vertical vibrations (10–300 Hz) and the responses of 46 single midbrain neurons were recorded in awake, immobilized animals.Most units (40) had simple V-shaped excitatory vibrational tuning curves. The distribution of best frequencies (BF's) was bimodal with peaks at 10 and 100 Hz and the thresholds ranged from 0.02 to 1.28cm/s² at the BF.Twenty-three neurons showed phasic-tonic and 11 neurons phasic responses. The dynamic range of seismic intensity for most neurons was 20–30 dB.In contrast to the sharp phase-locking in peripheral vibration-sensitive fibers, no phase-locking to the sinusoidal wave-form was seen in the midbrain neurons. The midbrain cells did not respond at low stimulus intensities (below 0.01–0.02 cm/s²) where a clear synchronization response occurs in saccular fibers.Six midbrain neurons had more complex response characteristics expressed by inhibition of their spontaneous activity by vibration or by bi-and trimodal sensory sensitivities.In conclusion, the vibration sensitive cells in the midbrain of the grassfrog can encode the frequency, intensity, onset and cessation of vibration stimuli. Seismic stimuli probably play a role in communication and detection of predators and the vibration-sensitive midbrain neurons may be involved in the central processing of such behaviorally significant stimuli.Abbreviation BF best frequency     

Responses of bulbar neurons to stimulation of locomotor and inhibitory sites in the cat brainstem

Bulbar locomotor and inhibitory sites were located in the pons of mesencephalic decerebellate cats. Rhythmic stimulation of locomotor sites through microelectrodes at the rate of 60 Hz elicited stepping movements in the forelimbs which were halted when the inhibitory sites were rhythmically stimulated. Neuronal response was elicited by single or paired stimulation of locomotor sites at the rate of 1.5 Hz or by applying a series of 2–4 stimuli spaced 2 msec apart to the inhibitory site. Medial neurons generated synaptic responses (postsynaptic potentials or action potentials) to stimulation of the inhibitory site twice as frequently as when the locomotor site was stimulated. Responses in lateral neurons, however, occurred twice as frequently to stimulation of the locomotor site, while IPSP were only observed half as often as EPSP in neurons of both groups. In neurons excited by stimulation of the locomotor site, stimulation of the inhibitory site did not normally produce IPSP. Possible mechanisms underlying the halt of locomotion occurring in response to stimulation of the inhibitory site are discussed.Information Transmission Institute, Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 18, No. 4, pp. 525–533, July–August, 1986.