Dynamics of neuronal interaction in the human thalamic nucleus reticularis produced by significant and non-significant verbal stimuli

Dynamics of neuronal interaction recorded by microelectrodes were examined in 90 arrays of cells of the human thalamic reticular nucleus (Rt) during stereotaxic surgical procedures. Cooperative interaction between adjacent neurons was found to occur in neuronal arrays after presentation of verbal (or sensory-cum-acoustic) functionally significant stimulus (FSS) as well as at stages of initiation and performance of goal-directed movement. Specialized dynamics were noted in the pattern of interaction between neuronal arrays of two types (A and B) with irregular background activity and 2–5 Hz bursting rhythm (types A and B respectively). This dynamic local neuronal interaction correlates with the stage of significant verbal stimulus presentation and that of performing goal-directed movements. The matching transient correlation between activity of A and B cell arrays reflects matching operation of two sequences of regulatory and control processes involved in processing of functionally significant verbal (or sensory) information and performance of goal-directed movement.Institute of Chemical Physics, Academy of Sciences of the USSR, Moscow Institute of Neurosurgery, Academy of Medical Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 22, No. 4, pp. 451–459, June–July, 1990.     

Neuronal spike response produced in the feline thalamic reticular nucleus by instrumental conditioned reflex

Spike response was investigated in 156 units of the thalamic reticular nucleus (RN) during performance of the instrumental feeding reflex of lever-pressing. This response consisted of lead and lag phases. Latency of the lead phase of response varied between 10 and 100 msec and total duration of response between 50 and 250 msec; minimum latency of the lag phase: 100–300 msec. Initial response to a conditioning clicking sound was found in 27 units, of which 26 showed excitation and the remaining single unit an inhibitory-excitatory pattern. The lag stage of response associated with performance of conditioned lever-pressing was found in 134 neurons, of which 115 showed an excitatory pattern, 19 displayed inhibition and the remaining 22 units failed to respond. The lag phase of response preceded the onset of conditioned reflex movement (CRM) in 30 neurons. A total of 118 neurons responded between the onset of CRM and the point of lever-pressing. It was concluded that the RN plays a part in perception of the conditioned signal as well as producing and controlling performance of CRM.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 23, No. 1, pp. 8–18, January–February, 1991.     

Neuronal response in nucleus reticularis thalami and neighboring thalamic structures to natural stimulation during chronic experiments on cats

Spike response was investigated in 104 neurons of the nucleus reticularis thalami (R) and adjoining thalamic nuclei to acoustic, tactile, and visual stimuli during chronic experiments on cats. Of the test neurons, 29% responded to acoustic stimulation and 11% showed no preference in relation to different acoustic stimuli. Minimum latencies of response to sounds measured 12–37 msec in excitatory and 18–27 msec in inhibitory cells. Duration of excitation produced by acoustic stimuli reached 50–250 msec; inhibition lasted 27–190 msec. Most cells belonging to this nucleus were excited by different stimuli; the proportion of inhibitory neurons did not exceed 4–10%.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 21, No. 4, pp. 451–461, July–August, 1989.     

Neuronal response to sensory stimulation in the cat caudate nucleus

Neuronal response in the caudate nucleus to presentation of a wide variety of visual and other sensory stimuli was investigated in waking cats. Pronounced discrepancies in background activity of unknown origin as well as differing neuronal activity level were noted in adjacent sections of the nucleus. Of the neurons from which readings of response to sensory stimulation could be made, some reacted to presentation of exclusively visual and others to tactile stimuli; a third group responded to a combination of visual and somatic stimulation only. Response could only be produced in cells of all types by a high level of activity in the animal. Visual stimuli attracting the animal's interest proved to be the most effective form of stimulation. Ipsi- and contralateral sides of the animal's body were both represented in the caudate nucleus of each hemisphere. Neuronal response in the caudate nucleus may be compared with that produced by application of similar stimuli in cells belonging to different cortical areas.Institute for Research on Information Transmission, Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 22, No. 1, pp. 3–10, January–February, 1990.     

Effects of thalamic sensory relay nucleus stimulation on the jaw-opening reflex in response to tooth-pulp stimulation in the cat

The effects of stimulation of the thalamic sensory relay nucleus (TSRN, nucleus ventralis posteromedialis) on the jaw-opening reflex (JOR) in response to tooth pulp stimulation were compared with the effects of stimulation of the periaqueductal gray (PAG) and nucleus raphe magnus (NRM) in the cat. After stimulation of the TSRN, PAG and NRM, the JOR was inhibited. However, while the inhibitory effects of PAG and NRM stimulation lasted for more than 500 ms and were antagonized by the opiate antagonist, naloxone, the inhibitory effects of TSRN stimulation lasted for approximately 100 ms and were resistant to naloxone. These findings suggest that although TSRN stimulation exerts descending inhibitory effects on segmental nociceptive activity, similarly to PAG or NRM stimulation, the descending inhibitory pathways mediating the effect of TSRN stimulation may be largely distinct physiologically as well as pharmacologically from those mediating the effect of PAG and NRM stimulation.     

Neuronal responses of the reticular and anterior ventral thalamic nuclei to stimulation of the thalamic ventrolateral nucleus and motor cortex

Responses of 137 neurons of the rostral pole of the reticular and anterior ventral thalamic nuclei to electrical stimulation of the ventrolateral nucleus and motor cortex were studied in 17 cats immobilized with D-tubocurarine. The number of neurons responding antidromically to stimulation of the ventrolateral nucleus was 10.5% of all cells tested (latent period of response 0.7–3.0 msec), whereas to stimulation of the motor cortex it was 11.0% (latent period of response 0.4–4.0 msec). Neurons with a dividing axon, one branch of which terminated in the thalamic ventrolateral nuclei, the other in the motor cortex, were found. Orthodromic excitation was observed in 78.9% of neurons tested during stimulation of the ventrolateral nucleus and in 52.5% of neurons during stimulation of the motor cortex. Altogether 55.6% of cells responded to stimulation of the ventrolateral nucleus with a discharge of 3 to 20 action potentials with a frequency of 130–350 Hz. Similar discharges in response to stimulation of the motor cortex were observed in 30.5% of neurons tested. An inhibitory response was recorded in only 6.8% of cells. Convergence of influences from the thalamic ventrolateral nucleus and motor cortex was observed in 55.7% of neurons. The corticofugal influence of the motor cortex on responses arising in these cells to testing stimulation of the ventrolateral nucleus could be either inhibitory or facilitatory.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 10, No. 5, pp. 460–468, September–October, 1978.     

Neuronal mechanisms of motor signal transmission in the thalamic ventrooral nucleus in spasmodic torticollis patients

A microelectrode technique was used to study the neuronal mechanisms of motor signal transmission in the ventrooral internus nucleus (Voi) of the motor thalamus during voluntary and involuntary pathological (dystonic) movements in patients with spasmodic torticollis. Voi cell elements proved highly reactive to various functional (mostly motor) tests. An activity analysis of 55 Voi neurons detected during nine stereotactic operations revealed, first, a difference in neuronal mechanisms of motor signal transmission for voluntary movements that do or do not involve the affected axial muscles of the neck and for passive and abnormal involuntary dystonic movements. Second, a sensory component was found to play a key role in the mechanisms of sensorimotor interactions during voluntary and involuntary dystonic head and neck movements activating the axial muscles of the neck. Third, rhythmic and synchronized activity of Voi neurons was shown to play an important role in motor signal transmission during voluntary and passive movements. The Voi nucleus was directly implicated in the mechanisms of involuntary head movements and tension of the neck muscles in spasmodic torticollis. The results can be used to identify the Voi nucleus of the thalamus during stereotactic neurosurgery in order to select the optimal destruction or stimulation target and to reduce the postoperative effects in spasmodic torticollis patients.     

Characteristics of background unit activity in the nucleus reticularis of the human thalamus

Background firing activity was examined in 240 neurons belonging to the thalamic nucleus reticularis (Rt) in the unanesthetized human brain by extracellular microelectrode recording techniques during stereotaxic surgery for dyskinesia. The cellular organization of Rt was shown to be nonuniform, and distinguished by the presence of three types of neuron: one with arrhythmic single discharge (A-type, 40%), another with rhythmic (2–5 Hz) generation of short high-frequency (of up to 500/sec) burster discharges (B-type, 49%) and a third with aperiodic protracted high-frequency (of up to 500/sec) bursting discharges separated by "silent" intervals of a constant duration of 80–150 msec (i.e., C-type, 11%). Differences between the background activity pattern of these cell types during loss of consciousness under anesthesia are described. Tonic regulation of neuronal type was not pronounced but a tendency was noticed in the cells towards a consistent rise in firing rate, rhythmic frequency and variability, etc. in both A and B units, especially in the latter. Findings pointing to the absence of a direct relationship between rhythmic activity in the Rt and parkinsonian tremor were confirmed. Background activity in B-type cells was found to increase and then stabilize with a rise in the degree of tremor. The nature of regular bursting activity patterns in B and C neurons is discussed in the light of our findings.Institute of Chemical Physics, Academy of Sciences of the USSR, Moscow. Institute of Neurosurgery, Academy of Medical Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 19, No. 4, pp. 456–466, July–August, 1987.     

Deafferentation pain and stimulation of the thalamic sensory relay nucleus: clinical and experimental study

This report summarizes our clinical experience in which the effects of both thalamic sensory relay nucleus (TSRN) and periaqueductal gray (PAG) stimulation were tested in the same series of patients with various forms of pain. The clinical data indicated that neurogenic pain due to deafferentation at the level of the peripheral nerves or the spinal cord was often controlled by TSRN stimulation but not by PAG stimulation. We also review the results of our experimental investigations in cats which were undertaken in an attempt to clarify the neurophysiologic basis of such differential clinical effects of TSRN and PAG stimulation. It appeared that abnormal hyperactivity within the trigeminal medullary dorsal horn following retrogasserian rhizotomy was far more frequently inhibited by TSRN stimulation than by PAG stimulation.     

Neuronal response in the cat parietal association cortex to conditioned and non-conditioned acoustic stimuli

Neuronal response in the cat association cortex (area 5) to conditioned and non-conditioned acoustic stimulation was investigated. Numbers of neurons responding to a conditioned acoustic stimulus according to the traditional reflex pattern were twice as high. Numbers of inhibitory neuronal responses to the stimulus increased when instrumental reflex occurred. Neurons were found which only reacted to a conditioned acoustic stimulus in the absence of conditioned reflex movement occurring with instrumental food reflex. Although findings do not exclude the possibility of this cortical area contributing to the analysis of sensory signals and evaluation of their biological significance, it might be supposed that its main functional property lies in its involvement in the process of initiating behavioral response to a conditioned response.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 20, No. 5, pp. 637–645, September–October, 1988.     

Somato-dendritic synapses in the nucleus reticularis thalami of the rat

In the reticular nucleus of the rat thalamus, about 30% of the synapses are brought about by the perikarya of parvalbumin-immunopositive neurons, which establish somato-dendritic synapses with large dendrites of nerve cells of specific thalamic nuclei. Although the parvalbumin-immunopositive presynaptic structures bear resemblance to goblet-like or calyciform axonal endings, electron microscopic immunocytochemistry and in situ hybridization revealed that these structures are parts of the perikaryal cytoplasm studded with synaptic vesicles. In about 15% of the somato-dendritic synapses, axons are seen to be in synaptic contact with the parvalbumin-immunoreactive perikaryon. Double immunohistochemical staining revealed that the parvalbumin immunoreactive presynaptic perikarya and dendrites contained GABA. It is assumed that the peculiar somato-dendritic synaptic complexes subserve the goal of filtration of impulses arriving at the reticular nucleus from various thalamic nuclei, thus processing them for further sampling.     

Lack of effect of morphine and noxious stimuli on the Met-enkephalin content in the spinal dorsal horn and nucleus reticularis gigantocellularis of the rat

The Met-enkephalin contents in the dorsal horn of the lumbar enlargement and the nucleus reticularis gigantocellularis of the medulla oblongata of the rat were measured, using a sensitive and specific radioimmunoassay for Met-enkephalin, and the effects of morphine and noxious stimuli on the Met-enkephalin contents in these regions were examined. In this radioimmunoassay, the IC₅₀ and assayable limits for Met-enkephalin were 45 and 5 fmol/tube respectively, and the IC₅₀ for Leuenkephalin was 0.56 nmol/tube (0.008% cross reactivity between Met- and Leu-enkephalins). The contents of Met-enkephalin-like immunoreactivity in the dorsal horn of the lumbar enlargement and the nucleus reticularis gigantocellularis were not altered by either subcutaneous injection of morphine or thermal (hot plate) and chemical (formalin injection) noxious stimuli applied to the hind-paws.     

Distribution of neurons responding to sensory stimuli and organization of topic projections in the cat caudate nucleus

The distribution of neurons responding to presentation of different sensory stimuli was investigated during chronic experiments on cats. These showed that cells responding to somatic and visual stimulation were unevenly distributed and that areas with differing levels of activity within the same nucleus alternated. No single topic projection was identified within the structure reaching the entire nucleus. The findings were compared with those found during morphological research indicating heterogeneity in caudate nucleus structure, implying the existence of neuronal groupings (or striosomes) belonging to a topically organized projection from the animal's body.Institute for Research into Information Transmission, Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 22, No. 2, pp. 156–162, March–April, 1990.