The rhombencephalic "locomotor region" in turtles

Electrical stimulation (10–20 µA, 20–30 Hz) of the rhombencephalon in decerebrate turtles can induce cyclic coordinated limb movemnts. The "locomotor region" is a strip, oriented in the rostro-caudal direction, which coincides in its location with the lateral reticular formation. Both in the medial and in the lateral reticular formation extracellular ipsilateral and contralateral synaptic responses of single neurons evoked by stimulation of the "locomotor region," (10–30 µA, 2 Hz), were recorded. Usually these responses had latent periods of between 3 and 12 msec (mode 5–6 msec). Excitation of the "locomotor region" thus leads to extensive spread of activity in the rhombencephalon. The possible mechanisms of this spread are discussed.Institute of Problems in Information Transmission, Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 12, No. 4, pp. 382–390, July–August, 1980.     

Unit responses in the "locomotor strip" of the cat hindbrain to microstimulation

Synaptic responses of single units in the "locomotor strip" of the hindbrain were recorded extracellularly. Short-latency responses appeared in neurons of the rostral part of the strip to stimulation of the "locomotor region" of the mesencephalon. Neurons of the caudal part of the strip responded to microstimulation of its other regions, including rostral. If the distance between the neuron and point of stimulation was under 2–3 mm, short-latency (1.2–1.6 msec) responses could be observed. The thresholds and latent periods of the responses increased when the distance apart increased. Polysynaptic responses with a latent period of 3–4 msec could be potentiated by an increase in the frequency of stimulation up to 30–40 Hz. It is suggested that axons of the "locomotor strip" are oriented in the rostrocaudal direction for a distance of 2–3 mm and give off collaterals which run toward neighboring neurons. The strip may be an integrative center, "intercalated" between the rostral portions of the brain stem and spinal cord.Deceased.Institute for Problems in Information Transmission, Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 10, No. 5, pp. 510–518, September–October, 1978.     

Responses of medullary neurons to microstimulation of the "locomotor strip" in cats

Synaptic responses of medullary neurons to stimulation of the bulbar locomotor strip with a current of about 20 µA were studied by an extracellular recording method in mesencephalic cerebellectomized cats. The mean latent period of response of 177 neurons was 3.2 msec. Neurons in which synaptic responses appeared were located in both the lateral and the medial parts of the reticular formation, but short-latency responses were recorded predominantly in the lateral part. In response to a single stimulus 32% of neurons generated a discharge of 2–4 spikes. "Respiratory" neurons were not excited by stimulation of the locomotor point. The results indicate that neurons of the locomotor strip may have an excitatory action not only on each other, but also on neurons located medially. The possible mechanisms of the spread of activity to the superior cervical segments of the spinal cord are discussed.Institute for Problems in Information Transmission, Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 13, No. 3, pp. 275–282, May–June, 1981.     

Neurons of upper cervical segments responding to stimulation of the bulbar locomotor strip

Synaptic responses of single neurons to stimulation of the bulbar "locomotor strip" were recorded extracellularly from superior cervical segments in mesencephalic cats. With a strength of stimulation of about 30 µA these responses usually had a latent period of 2–7 msec and they arose in neurons located at a depth of between 2 and 4 mm from the dorsal surface (Rexed's laminae V–VIII). These neurons could not be excited antidromically by stimulation of the lumbar or lower cervical segments. However, antidromic responses could be evoked by stimulation of a region located 3–5 mm caudally to the site of recording. It is suggested that neurons of segments C2 and C3 excited by stimulation of the locomotor strip are components of a cell column along which activity spreads polysynaptically in the direction of spinal stepping generators.Institute for Problems in Information Transmission, Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 11, No. 3, pp. 245–253, May–June, 1979.     

Responses of upper cervical spinal neurons in cats to stimulation of the brain-stem locomotor region at different frequencies

Synaptic responses of neurons in segments C₂ and C₃ to stimulation of locomotor points in the medulla or midbrain were recorded extracellularly in mesencephalic cats. Neurons generating responses with an index of 0.4–0.6 to stimulation with a frequency of 2 Hz maintained this same index at frequencies of 20–60 Hz. The discharge index of many neurons during stimulation at 2 Hz was low, and it increased to 0.4–0.6 when high-frequency stimulation was used. More than half of the cells were excited by stimulation of both ipsilateral and contralateral locomotor points; one-quarter of the neurons responded to stimulation of locomotor points in both medulla and midbrain. The cells studied were located 1.8–4.2 mm from the dorsal surface of the spinal cord. The mean latencies of responses with an index of not less than 0.5 lay within the range 2–30 msec, with a mode of 2–8 msec. Considerable fluctuations of latent period were observed for long-latency responses. The possibility that the neurons studied may participate in the transmission of activity from the locomotor region of the brain stem to stepping generators in the spinal cord is discussed.Institute for Problems of Information Transmission, Academy of Sciences of the USSR, Moscow. M. V. Lomonosov Moscow State University. Translated from Neirofiziologiya, Vol. 15, No. 4, pp. 355–361, July–August, 1983.     

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.     

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.     

Synaptic responses of medullary neurons of turtles to stimulation of the locomotor region

Responses of medullary neurons to microstimulation of the locomotor region by a current of up to 30 µA were studied by intracellular recording in turtles. The resting potential recorded in these neurons was from 22 to 42 mV. Depolarization PSPs (EPSPs) were recorded in 43 neurons, hyperpolarization PSPs (IPSPs) in 12, and mixed in 36. Synaptic discharges were observed in 29 neurons. Of these cells 11 generated action potentials without visible PSPs. The latent period of the PSPs was most frequently between 2 and 8 msec. The time from the beginning of the EPSP to the beginning of the action potential was 1–3 msec if the response index was high, but in the case of weaker stimulation, it began to fluctuate strongly and lengthened. Unitary EPSPs were recorded in 15 neurons and IPSPs in three. Their amplitude was 0.6–0.8 mV, from 2 to 12 times less than the depolarization threshold (1–7 mV). These results, together with those obtained previously by extracellular recording of medullary unit activity in turtles and cats, are used to discuss the possible mechanism of spread of locomotor activity.Institute for Problems in Information Transmission, Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 14, No. 2, pp. 122–129, March–April, 1982.     

Mathematical model of activity of spinal generators producing rhythmic movement

Different organizational arrangements of scratching and locomotor rhythm generators were simulated by a computer-aided mathematical model. A functional group of neurons (a hemicenter constructed on the basis of a stochastically arranged neuronal network) served as the basis for the generator. Several organizational arrangements of scratching and locomotor rhythm generators are considered: two hemicenters with reciprocal inhibitory connections and tonic excitatory influences on both; two hemicenters with inhibitory-excitatory connections and tonic excitatory influences on only one of these; circular structures consisting of more than two functional groups of neurons with excitatory and inhibitory connections between them. All these arrangements would allow for generation of rhythmic activity with a similar time course to that of scratching and locomotor rhythm. It was found that the transition from locomotor to scratching rhythm could be based on fairly simply organized effects on generator neurons. Principles possibly guiding the construction of spinal generators of scratching and locomotor movements are discussed.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 20, No. 5, pp. 586–597, September–October, 1988.     

Neurons determining passive defensive response in the pteropod mollusk Clione limacina

Neurons responding to tactile stimulation of the head with bursts of action potentials of short latency followed by passive defensive response were found in the pedal ganglia and identified as Pd13. Stimulation of one Pd13 neuron leads to inhibition of the entire locomotor generator. A whole set of neurons, identified as P2, 3, 4, and 5, activated solely by intensive tactile stimulation of the head, were found in the pleural ganglia. Stimulating one such neuron also induces inhibition of the entire locomotor generator. These pleural cells are synaptically connected with Pd13 neurons and one EPSP in Pd13 unit corresponds to each action potential in the pleural cell. This connection has a facility for potentiation, subsequently replaced by habituation. In this way, pleural neurons also introduce Pd13 neurons into the inhibitory trend when activated by intensive tactile stimulation. Application of cerucal and ergotamine (dopaminergic receptor blockers) suppresses the inhibitory effect of the Pd13 neuron and pleural cells, thus indicating dopamine involvement in the inhibitory processes occurring in passive defensive reaction.Institute of Higher Nervous Activity and Neurophysiology, Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 21, No. 5, pp. 685–694, September–October, 1989.     

Electrophysiological study of serotoninergic neuron Cl in the pteropod mollusk Clione

Functional characteristics of cerebral serotoninergic neuron Cl, axons of which terminate at the buccal ganglia [7], were investigated in the pteropod molluskClione. Stimulating neuron Cl induced activation of the feeding rhythm generator located in the buccal ganglia — an effect arising after a long latency and persisting for some tens of seconds once stimulation had ended. Neuron Cl receives feedback from buccal ganglion cells and this brings about periodic modulation in ganglia activity during the generation of feeding rhythm. Activity of neuron Cl is correlated with operation of the locomotor rhythm generator located in the pedal ganglia. The firing rate of Cl neurons increased upon activation of the locomotor generator (whether spontaneous or induced by stimulating certain command neurons). The correlation found between workings of the locomotor generator and activity of Cl neurons is thought to be one of the manifestations of feeding synergy involving simultaneous activation of the locomotor and buccal apparatus.Institute for Research on Information Transmission, Academy of Sciences of the USSR, Moscow. M. V. Lomonosov State University, Moscow. Translated from Neirofiziologiya, Vol. 23, No. 1, pp. 18–25, January–February, 1991.     

Efferent projections of mesencephalic locomotor neurons in the cat

Efferent neuronal projections of the mesencephalic locomotor region were investigated in cats using a horseradish peroxidase retrograde axonal transport technique. It was found that neurons located within the locomotor area form ascending and descending projections to many structures of the spinal cord and the brain but that short-axon connections running to the reticular formation of the midbrain and the medulla predominate. Small numbers of long-axon fibers may merge into the locomotor strips of the medulla and the spinal cord. The locomotor regions of the two halves of the midbrain are interlinked.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 18, No. 1, pp. 117–125, January–February, 1986.     

Influence of the pteropod mollusk pedal ganglia locomoter system on anatomically isolated neurons

It was established during experiments on pedal ganglia generating locomotor rhythm isolated fromClione limacina, a pteropod mollusk, that this rhythm was irregular in 30% of preparations; i.e., the locomotor generator worked in bursts which alternated with periods of regular activity. Locomotor bursts were produced by excitation in command neurons located within the pedal ganglia. Single neurons were extracted from the ganglia in these preparations generating locomotor bursts by means of an intracellular microelectrode; their somata were then placed in their original sites amongst the ganglia cells. A total of 35 neurons were isolated showing changed activity during bursts. Nine of these cells renewed their erratic activity (linked to locomotor bursts) following reinsertion into the ganglion. Neurons which had initially shown an excitatory pattern during bursts continued to be excited; the same was true for inhibitory types. These observations indicate that the command neurons governing generator operation can act on target cells when morphological contact with them has been suppressed.Institute for Research into Information Transmission, Academy of Sciences of the USSR, Moscow; M. V. Lomonosov State University. Moscow. Translated from Neirofiziologiya, Vol. 18, No. 6, pp. 756–763, November–December, 1986.     

Activation of orientation selectivity mechanisms in neurons of the cat visual cortex by a moving visual "noise" field

A relationship was established between the response of neurons of the cat visual cortex and the direction of movement in the visual "noise" field and of a slit of light. It was shown that a shift in the preferred direction of movement in the "noise" field in relation to that of the slit was found in orientationally selective neurons only. It was concluded that the "noise" field, which is a stimulus lacking an orientation component, does activate mechanisms of neuronal orientation selectively.V. Kapsukas State University, Vilnius. Translated from Neirofiziologiya, Vol. 17, No. 5, pp. 596–601, September–October, 1985.     

Statistical characteristics of unit activity in spinal locomotor centers

A statistical analysis of unit activity in spinal locomotor centers was undertaken on immobilized thalamic cats at rest and during generation of efferent discharges. Activation of the spinal locomotor generator was accompanied by shortening of interspike intervals in the spike sequences of neurons and a decrease in their fluctuations. Histograms of interspike intervals became more symmetrical under these circumstances and there was a considerable increase in the number of neurons whose activity showed regular fluctuations on autocorrelation histograms. Spike trains at rest were characterized by dependence of successive intervals, which increased during efferent discharge generation. The possible mechanisms of modification of the time structure of unit activity in spinal locomotor centers during their activation are discussed.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 12, No. 2, pp. 192–198, March–April, 1980.     

Neuronal activity of the lateral vestibular nucleus of the guinea pig evoked by tilting the animal about the longitudinal axis during locomotion

In experiments on decerebrate guinea pigs, the impulse activity of neurons of the lateral vestibular nucleus evoked by tilting the animal about the longitudinal axis was investigated under conditions of spontaneous and mesencephalon stimulation-evoked locomotor activity. In most investigated neurons, locomotor activity led to changes in their responses to adequate vestibular stimulation. The dominant reaction was intensification of such responses, which was observed in almost all vestibulospinal neurons and in 2/3 of cells not having descending projections. Responses were suppressed only in 1/4 of the neurons not projecting to the spinal cord. The changes in the evoked responses had an amplitude character; the lag of the changes in the discharge frequency relative to the acceleration that caused them was constant. It is suggested that intensification of dynamic reactions of vestibular neurons during locomotion provides maintenance of the animal's equilibrium during movements in space by various gaits and along different trajectories.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 23, No. 5, pp. 541–549, September–October, 1991.     

Influence of adequate vestibular stimulation on locomotor activity in the guinea pig forelimb muscles. Tilting in relation to the longitudinal axis

The influence of adequate vestibular stimulation occurring as the animal tilted around longitudinal axis on locomotor activity of the forelimb muscles was investigated during experiments on guinea pigs decerebrated at precollicular level. Locomotor activity was produced by electrical stimulation of the mesencephalic locomotor region. An increase in extensor EMG activity was observed when the animal shifted its weight onto the limb ipsilateral to the tilt during the "standing" phase and a reduction in flexor activity during the swing phase. The reverse of these changes was seen in the activity of antagonist muscles in the contralateral limb. It was found that changes in muscular locomotor activity exceeded those observed during animal movements by 60–40° in the extensors and 40–20° in the flexors during cyclic sinusoidal tilting in the 0.02–0.4 Hz range. The mechanisms underlying vestibular control of locomotor activity are discussed.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 19, No. 4, pp. 534–541, July–August, 1987.     

Postsynaptic neuronal response of a cat sensorimotor cortex during evoked and self-sustained rhythmic "spike and wave" activity

Intracellular correlates of complex sets of rhythmic cortical "spike and wave" potentials evoked in sensorimotor cortex and of self-sustained rhythmic "spike and wave" activity were examined during acute experiments on cats immobilized by myorelaxants. Rhythmic spike-wave activity was produced by stimulating the thalamic relay (ventroposterolateral) nucleus (VPLN) at the rate of 3 Hz; self-sustained afterdischarges were recorded following 8–14 Hz stimulation of the same nucleus. Components of the spike and wave afterdischarge mainly correspond to the paroxysmal depolarizing shifts of the membrane potential of cortical neurons in length. After cessation of self-sustained spike and wave activity, prolonged hyperpolarization accompanied by inhibition of spike discharges and subsequent reinstatement of background activity was observed in cortical neurons. It is postulated that the negative slow wave of induced spike and wave activity as well as slow negative potentials of direct cortical and primary response reflect IPSP in more deep-lying areas of the cell bodies, while the wave of self-sustained rhythmic activity is due to paroxysmal depolarizing shifts in the membrane potential of cortical neurons.I. S. Beritashvili Institute of Physiology, Academy of Sciences of the Georgian SSR, Tbilisi. Translated from Neirofiziologiya, Vol. 18, No. 3, pp. 298–306, May–June, 1986.     

Neural control of heartbeat in the pteropod mollusk Clione limacina

The heart of the pteropod molluskClione limacina is innervated by the median nerve arising from the left abdominal ganglion. Five neurons sending axons to the heart have been identified in theClione central nervous system with retrograde cobalt or Lucifer yellow staining. Neuron H1 located in the left pedal ganglion produced an excitatory effect on heart beat. Stimulation of three neurons, H2–H4, situated in a compact group in the medial region of the left abdominal ganglion, led to inhibition of cardiac contraction, while H5, located in the caudal region of the left abdominal ganglion, did not affect heart beat. The activity of efferent cardiac neurons (ECN) was found to be related to the operation of the locomotor rhythm generator. Spontaneous or reflex depression of the latter was found to inhibit neuron H1 and activate units H2–H4. The behavior of these ECN accounts for the positive correlation between heart operation and locomotor activity inClione limacina.Institute of Research on Information Transmission, Academy of Sciences of the USSR, Moscow, M. V. Lomonosov State University, Moscow. Translated from Neirofiziologiya, Vol. 21, No. 2, pp. 185–192, March–April, 1989.     

"Timer" and "scanner" neurons in the cat visual cortex with low stimulus-background contrast

The response pattern and orientation detection of "timer" and "scanner" neurons were investigated in awake, immobilized cats with reduced contrast (2.3 and 10.0) between the light stimulus and the background. These two divisions had already been made [3, 5] at a high contrast level of 100. During this action, all scanners were found to retain their properties: they did not change into timers. The number of timers, however, dropped to 40% of their original total. The relationship between the properties of neurons belonging to these groups remained as it was during maximum contrast: with timers, response began and peaked earlier; it was also of higher frequency and briefer, while its capacity for orientation detection was far inferior to that of scanners. The neurons leaving the timer group following a reduction in contrast manifested a pattern somewhere between timer and scanner cells, resembling the latter in a number of parameters. Findings confirmed the deduction that both timer and scanner neurons are present and operate consistently under a wide range of conductions in the cat visual cortex; the former fulfill the functions of synchronizers and the latter of directional filters which are rearranged in time [5].Institute of Higher Nervous Activity and Neurophysiology, Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 18, No. 6, pp. 805–812, November–December, 1986.