Neuronal activity related to spontaneous and capsaicin-induced rhythmical jaw movements in the rat

Intraoral capsaicin induced rhythmical jaw movements (RJM) in anesthetized rats. Neurons in the trigeminal spinal nucleus caudalis or the cortico-peduncular (CP) axons were extracellularly recorded. Capsaicin excited dose-dependently most caudalis neurons, which were activated by stimulation of the oral cavity and/or the tooth pulp and activated during spontaneous or induced RJM. Ten of 55 CP axons were antidromically activated by stimulation of the contralateral trigeminal motor nucleus. All antidromic and 29 other CP axons discharged prior to the spontaneous RJM, but most of them did not during capsaicin-induced RJM. These neuronal activities possibly initiate spontaneous RJM although the activities of caudalis neurons are necessary for capsicin-induced RJM.     

Investigation of habituation reaction of neurons of the cat motor cortex

The neuronal and total surface activity of the cortical representation of the motor analyzer in the region of the posterior sigmoid gyrus of the cat brain in response to rhythmical light, sound, and electrical stimuli and their complexes was analyzed. Two groups of neurons were found, of which the first is characterized by a gradual decrease in the number of peaks in the response and by their subsequent disappearance and the second by the absence of a discharge in response to stimulation and by its development before the application of the next stimulus. The first group was comprised of neurons which do not have background activity and the second was made up of neurons with a background activity of 0.4–3.7 imp/sec. This reorganization of the activity of cortical neurons in response to rhythmical stimulation is considered to be a habituation phenomenon.A. A. Zhdanov Leningrad State University. Translated from Neirofiziologiya, Vol. 3, No. 3, pp. 245–251, May–June, 1971.     

The effect of electric stimulation of different regions of the cerebral cortex on the alimentary reaction in rabbits]

The influences of different parts of the neocortex on the rabbit alimentary behaviour produced by stimulation of the hypothalamic "alimentary centre" were studied in chronic experiments on rabbits with electrodes implanted in different formations of the limbic system and the midbrain. It has been found that electrical stimulation of the frontal and anterior parietal cortical areas raised the threshold of the evoked alimentary reaction. Inhibitory influences of the frontal areas proved to be stronger and more prolonged than those of the anterior parietal area. Electrical stimulation of the posterior parietal and occipital cortical areas decreased the threshold of the evoked alimentary reaction. Coagulation of the dorsal hippocampus eliminated the inhibitory influences of the neocortex, while coagulation of the mesencephalic reticular formation discontinued the facilitating influences of the neocortex on the alimentary reaction.     

Neuronal responses evoked in the bulbar respiratory center by stimulation of the anterior ventral and mediodorsal thalamic nuclei

The effects of rhythmical low- and high-frequency stimulation of specific nonsensory anterior ventral and associative mediodorsal thalamic nuclei (AV and MD, respectively) on the activity of neuronal units in the medullary ventral respiratory nucleus were studied in acute experiments on anesthetized, spontaneously breathing cats. Both inhibitory and excitatory influences on spike activity of inspiratory and expiratory neurons were found, with suppression effects being markedly predominant. Thresholds for inspiratory neuronal responses were lower as compared with those for expiratory cells. Electrical AV stimulation mainly produced an inhibitory effect on the activity of nonspecific reticular neurons (without respiratory activity), whereas during MD stimulation activating effects on these neurons dominated. Possible mechanisms underlying the realization of thalamorespiratory influences are discussed.Neirofiziologiya/Neurophysiology, Vol. 25, No. 3, pp. 218–223, May–June, 1993.     

Interdigitated paralemniscal and lemniscal pathways in the mouse barrel cortex

Primary sensory cortical areas receive information through multiple thalamic channels. In the rodent whisker system, lemniscal and paralemniscal thalamocortical projections, from the ventral posteromedial nucleus (VPM) and posterior medial nucleus (POm) respectively, carry distinct types of sensory information to cortex. Little is known about how these separate streams of activity are parsed and integrated within the neocortical microcircuit. We used quantitative laser scanning photostimulation to probe the organization of functional thalamocortical and ascending intracortical projections in the mouse barrel cortex. To map the thalamocortical projections, we recorded from neocortical excitatory neurons while stimulating VPM or POm. Neurons in layers (L)4, L5, and L6A received dense input from thalamus (L4, L5B, and L6A from VPM; and L5A from POm), whereas L2/3 neurons rarely received thalamic input. We further mapped the lemniscal and paralemniscal circuits from L4 and L5A to L2/3. Lemniscal L4 neurons targeted L3 within a column. Paralemniscal L5A neurons targeted a superficial band (thickness, 60 μm) of neurons immediately below L1, defining a functionally distinct L2 in the mouse barrel cortex. L2 neurons received input from lemniscal L3 cells and paralemniscal L5A cells spread over multiple columns. Our data indicate that lemniscal and paralemniscal information is segregated into interdigitated cortical layers.     

Paradoxical REM sleep promoting and permitting neuronal networks

Since its electrophysiological identification in the 1950's, the state of REMS or PS has been shown through multiple lines of evidence to be generated by neurons in the oral pontine tegmentum. The perpetration of this paradoxical state that combines cortical activation with the most profound behavioral sleep occurs through interplay between PS-promoting (On) and PS-permitting (Off) cell groups in the pons. Cholinergic cells in the LDTg and PPTg promote PS by initiating processes of both forebrain activation and peripheral muscle atonia. Bearing alpha1-adrenergic receptors, cholinergic cells, which likely project to the forebrain, are excited by NA and active during both W and PS (W/PS-On), when they promote cortical activation. Bearing alpha2-adrenergic receptors, other cholinergic cells, which likely project to the brainstem, are inhibited by NA and thus active selectively during PS (PS-On), when they promote muscle atonia. Noradrenergic, together with serotonergic, neurons, as PS-Off neurons, thus permit PS in part by lifting their inhibition upon the cholinergic PS-On cells. The noradrenergic/serotonergic neurons are inhibited in turn by local GABAergic PS-promoting neurons that may be excited by ACh. Other similarly modulated GABAergic neurons located through the brainstem reticular formation become active to participate in the inhibition of reticulo-spinal and raphe-spinal neurons as well as in the direct inhibition of motor neurons. In contrast, a select group of GABAergic neurons located in the oral pontine reticular formation and possibly inhibited by ACh turn off during PS. These GABAergic PS-permitting neurons release from inhibition the neighboring large glutamatergic neurons of the oral pontine reticular formation, which are likely concomitantly excited by ACh. In tandem with the cholinergic neurons, these glutamatergic reticular neurons propagate the paradoxical forebrain activation and peripheral inactivation that characterize PS.     

The role of vestibular afferent input in systemic interactions of cortical areas in the human brain

To investigate the role of vestibular afferent input in systemic interactions between cortical areas of the human brain, the dynamics of interregional cortical interactions has been studied in patients with cervical dystonia during their therapy by the removal of the transtympanic chemical vestibular receptor. It has been found that even unilateral vestibular dereception leads to a profound reorganization of systemic interactions between remote cortical areas, particularly, the anterior and posterior associative areas in both hemispheres. Relationships indicating the role of vestibular input in the organization of integrative brain activity have been found, which confirms its systemic role.     

Convergence of visceral afferent impulses on hypothalamic neurons during vagal and splanchnic nerve stimulation

Responses of posterior and anterior hypothalamic neurons to stimulation of the vagus, splanchnic, and sciatic nerves, and also to photic stimulation were studied by extracellular recording of spike activity in cats anesthetized with chloralose and immobilized with succinylcholine. Most responding neurons of the posterior and anterior hypothalamus did so to stimulation of both vagus and splanchnic nerves. The responses of these polysensory neurons to stimulation of visceral afferents of parasympathetic nerves were identical in sign and mainly excitatory in type. The absence of a reciprocal character of the response to stimulation of "antagonistic" autonomic nerves and the marked polysensory convergence are evidence of the nonspecific "reticular" character of activation of most of the neurons in the posterior and anterior hypothalamus.L. A. Orbeli Institute of Physiology, Academy of Sciences of the Armenian SSR, Erevan. Translated from Neirofiziologiya, Vol. 9, No. 2, pp. 165–170, March–April, 1977.     

Temporal-to-spatial dynamic mapping,flexible recognition,and temporal correlations in an olfactory cortex model

 This paper proposes temporal-to-spatial dynamic mapping inspired by neural dynamics of the olfactory cortex. In our model the temporal structure of olfactory-bulb patterns is mapped to the spatial dynamics of the ensemble of cortical neurons. This mapping is based on the following biological mechanism: while anterior part of piriform cortex can be excited by the afferent input alone, the posterior areas require both afferent and association signals, which are temporally correlated in a specific way. One of the functional types of the neurons in our model corresponds to the cortical spatial dynamics and encodes odor components, and another represents temporal activity of association-fiber signals, which, we suggest, may be relevant to the encoding of odor concentrations. The temporal-to-spatial mapping and distributed representation of the model enable simultaneous rough cluster classification and fine recognition of patterns within a cluster as parts of the same dynamic process. The model is able to extract and segment the components of complex odor patterns which are spatiotemporal sequences of neural activity. Received: 16 October 2001 / Accepted in revised form: 7 February 2002     

The destruction of perikaryas of the mesencephalic reticular formation and the posterior hypothalamus does not cause major disorders of awakening in the cat

Ibotenic acid microinjections have been realized at the level of the mesencephalic reticular formation and the posterior hypothalamus in 7 cats. This technique has led to a quasi-total destruction of cell bodies in the two areas (including the histaminergic neurons). 2 to 3 days after such lesions, there were no major effects on behavioral waking. These results do not favor the hypothesis of the existence of a waking system at the level of the mesencephalic reticular formation and/or posterior hypothalamus.     

Isocortical Hyperemia and Allocortical Inflammation and Atrophy Following Generalized Convulsive Seizures of Thalamic Origin in the Rat

1. Generalized convulsive seizures can be elicited by a single unilateral microinjection of the cholinergic muscarinic agonist, carbachol, into the specific sites of the thalamus including ventral posterolateral and the reticular thalamic nuclei. The implication of the thalamic specific and reticular neurons is reviewed and discussed.2. On the basis of the c-fos regional expression and well-known efferent and afferent pathways linking these regions, a neuronal network relating the limbic, thalamo–striatal–cortical, and central autonomic systems, was constructed.3. The pattern of Fos immunoreactivity associated with long-lasting isocortical vasodilatation elicited by generalized convulsive seizures in anesthetized rat following cholinergic stimulation of the thalamus can be attributed to both the electrocortical activity and the long-lasting increase in cortical blood flow. We propose that the sustained cerebral cortical blood flow response during convulsive epileptic seizures may implicate intracerebral vasodilatory and vasoconstrictory neural mechanisms. Double-labeled NADPH-d and Fos-positive neurons implicated in maintaining the sustained isocortical vasodilatory response were found in the anterior lateral hypothalamic area. Inhibition of these neurons prevented the increase in cortical blood flow despite an increased metabolic demand manifested by the ictal electrocortical activity.4. Medial temporal lobe atrophy, including hippocampus, amygdala, and parahippocampal gyrus (piriform and entorhinal cortices) are the most common pathology in man. However the origin of medial lobe atrophy remain uncertain. Our results provide evidence that the allocortical microvascular inflammation may be in origin of the neurovascular degenerative processes leading to atrophy.     

Comparative analysis of the role of the second and first somatosensory cortical areas in somatic responses of the medullary reticular formation in rats

Evoked potentials and unit activity in the medullary reticular formation were investigated in unanesthetized, curarized rats during cold blocking or after extirpation of the cortical representation of one of the stimulated limbs. Local cooling or extirpation in area SII, unlike blocking of area SI, leads to a small (up to 30%) decrease in amplitude and a very small change (up to 10 msec) in the temporal parameters of evoked potentials arising in the reticular formation in response to electrodermal stimulation of the contralateral limb, whose representation in the cortex was blocked. Predominance of corticofugal influences from SI over those from SII was discovered both in experiments with evoked potentials and during analysis of somatic spike responses of reticular formation neurons. Corticofugal control over activity of the medullary reticular formation in rats exerted by neuronal mechanisms of somatosensory areas SII and SI thus differs both qualitatively and quantitatively.I. M. Sechenov Institute of Evolutionary Physiology and Biochemistry, Academy of Sciences of the USSR, Leningrad. Translated from Neirofiziologiya, Vol. 15, No. 1, pp. 42–49, January–February, 1983.     

The transmission of coded information over neuronal systems exemplified by the motor rhythmic dominant

Functional organization of neurons in rabbit's sensorimotor cortex was studied before and within several days after formation of the rhythmical dominant focus. Functional reorganization of neurons in cortical microareas took place during actualization of the dominant. The number of functional interneuronal relations within neuronal pairs of a certain type could be increased in comparison with the control values and decreased within pairs of another type. As a result, the total percent of the interneuronal correlations in cortical microareas in the control animals and rabbits with the acting dominant was approximately equal. The total percent of correlations between neurons of the adjacent cortical areas during the actualization of the dominant was significantly higher than in the control due to increased number of correlations with participation of small and medium-sized neurons. A possibility of information circulation about the "stimulus image" in the closed chain of neurons was exemplified by the real micronetwork. The data suggest the reverberation of encoded information between adjacent microareas of the sensorimotor cortex within several days after application of the stimulus, which has formed the excitation focus.     

Effective Connectivity of Depth-Structure–Selective Patches in the Lateral Bank of the Macaque Intraparietal Sulcus

Extrastriate cortical areas are frequently composed of subpopulations of neurons encoding specific features or stimuli, such as color, disparity, or faces, and patches of neurons encoding similar stimulus properties are typically embedded in interconnected networks, such as the attention or face-processing network. The goal of the current study was to examine the effective connectivity of subsectors of neurons in the same cortical area with highly similar neuronal response properties. We first recorded single- and multi-unit activity to identify two neuronal patches in the anterior part of the macaque intraparietal sulcus (IPS) showing the same depth structure selectivity and then employed electrical microstimulation during functional magnetic resonance imaging in these patches to determine the effective connectivity of these patches. The two IPS subsectors we identified—with the same neuronal response properties and in some cases separated by only 3 mm—were effectively connected to remarkably distinct cortical networks in both dorsal and ventral stream in three macaques. Conversely, the differences in effective connectivity could account for the known visual-to-motor gradient within the anterior IPS. These results clarify the role of the anterior IPS as a pivotal brain region where dorsal and ventral visual stream interact during object analysis. Thus, in addition to the anatomical connectivity of cortical areas and the properties of individual neurons in these areas, the effective connectivity provides novel key insights into the widespread functional networks that support behavior.     

The entrainment of rhythmically discharging reticulospinal neurons of the eel by sensory nerve stimulation

Recordings made from decerebrated, paralyzed eels (Anguilla anguilla) producing rhythmical spinal motoneuronal activity showed that around 65% of identified reticulospinal units, belonging to the inferior reticular division, discharged rhythmically. The reticulospinal bursts, lasting from 300 up to 3000 ms, were in time with spinal motoneuronal bursting activity. In different fish the modal cycle period varied between 2 to 4 s and burst duration and firing frequency of each neuron showed large changes from cycle to cycle. Burst responses similar in form to those occurring spontaneously were evoked from reticular neurons when the ophthalmic nerve was stimulated regularly (intervals of 1 to 10 s) but the cycle period, firing frequency and burst duration were now more predictable. For stimulation intervals between 2 and 5 s, each ophthalmic nerve stimulus was normally followed by a burst from the reticulospinal neuron. The cycle period of the reticular rhythm then became equal to the interstimulus interval and the reticulospinal unit was entrained by the stimulus. Beyond this range of interstimulus intervals, complete entrainment was lost. We suggest that regular sensory input provides a powerful stabilising influence to rhythmically active motor systems in the brainstem and spinal cord.     

Intercentral reticulo-cortical relations of brain electrical activity during "animal hypnosis" in rabbits

The electrical activity of the right and left sensorimotor and premotor cortical areas and right and left medulary reticular formation was recorded during "animal hypnosis" in rabbits. In this state, the spectral power of potentials (predominantly, in the delta-range) recorded from the left reticular formation was higher than that recorded from the right side. The value of the function of coherence between the right and left reticular recordings was decreased to 0.1-0.2 in the whole frequency range. The tight-side intrahemispheric coherence between the activities recorded from the sensorimotor cortex and reticular formation was higher than respective left-side values, whereas the coherent relations between the activities recorded from the reticular formation and premotor cortex were not changed (as compared to nonhypnotic state).     

Statistical analysis of unit activity in the cat motor cortex

Activity of 366 neurons in the motor area of the biceps brachii muscle was studied in chronic experiments on cats during an instrumental placing response. Of these cells, 59 received afferentation from the skin, joints, or deep structures of the limb participating in movement. Of 160 neurons which changed their discharge during the placing response, 52 (32.5%) had a peripheral input. Three types of motor cortical neurons are described: I) changing their discharge frequency before movement began, II) after movement began, and III) before and during movement. Positive correlation (r=0.3926) was found between the presence of a peripheral input for the neurons studied and changes in discharge frequency during the placing response. Correlation between the presence of a concrete input in the neurons and the type to which they belonged was studied.M. V. Lomonosov Moscow State University. Translated from Neirofiziologiya, Vol. 11, No. 3, pp. 201–207, May–June, 1979.     

Localization of alcohol and aldehyde dehydrogenases in the human spinal cord and brain

Location of aldehyde dehydrogenase (AldDG) and alcohol dehydrogenase (ADG) has been studied in 38 nuclei of the human brain. Neurons with a high AldDG activity predominate in the nucleus of the descending root of the trigeminal nerve, motor nuclei of the craniocerebral nerves (trigeminal, facial, abducent, blocking, sublingual, supraspinal), motor nuclei of the anterior horns of the spinal cord, lateral vestibular nucleus, posterior nucleus of the vagus nerve, pedunculopontine nucleus, superior salivary nucleus, and in the nucleus of Westphal-Edinger-Jacobovich. Neurons with a moderate AldDG activity predominate in the superior olivary complex, nucleus of the lateral loop, parabrachial (pigmented) mesencephalic nucleus and reticular lateral nucleus. A low enzymatic activity is specific for neurons of the pons proper, inferior vestibular nucleus, trapezoid body of the inferior olivary complex, dentate nucleus of the cerebellum, reticular nucleus of the tegmen of Bekhterev's pons and posterior nucleus of Gudden's suture. A high ADG activity is revealed in piriform neurons of the cerebellar cortex. Functional importance of ADG and AldDG activity in the brain is discussed.     

Connections of thalamic nucleus lateralis posterior with suprasylvian cortex in cats

Cats were immobilized with D-tubocurarine. Responses of 231 neurons of the thalamic nucleus lateralis posterior to cortical stimulation in areas 5b and 21 of the suprasylvian gyrus were studied. Responses of 34 neurons were antidromic, indicating the existence of a direct projection of this nucleus to the cortical areas studied. This projection was most extensive in area 5b. The long latencies (up to 60 msec) of the antidromic responses of some neurons indicate that axons of certain neurons of thalamic nucleus lateralis posterior conduct excitation very slowly (0.3 m/sec). Orthodromic responses with latencies of 2–3 msec to cortical stimulation point to the presence of direct pathways from cortex to nucleus. The flow of afferent impulses into the nucleus from area 5b is stronger than from area 21. Convergence of impulses from these areas was observed on 44% of neurons of the nucleus. Cortical stimulation of areas 5b and 21 evoked postsynaptic inhibition in most neurons of the nucleus. It is concluded that two-way direct connections exist between nucleus lateralis posterior of the thalamus and the suprasylvian cortex.     

A crossed projection from the optic tectum to craniocervical premotor areas in the brainstem reticular formation. An anterograde and retrograde tracing study in the mallard (Anas platyrhynchos L.)

The optic tectum in birds receives visual information from the contralateral retina. This information is passed through to other brain areas via the deep layers of the optic tectum. In the present study the crossed tectobulbar pathway is described in detail. This pathway forms the connection between the optic tectum and the premotor area of craniocervical muscles in the contralateral paramedian reticular formation. It originates predominantly from neurons in the ventromedial part of stratum griseum centrale and to a lesser extent from stratum album centrale. The fibers leave the tectum as a horizontal fiber bundle, and cross the midline through the caudal radix oculomotorius and rostral nucleus oculomotorius. On the contralateral side fibers turn to ventral and descend caudally in the contralateral paramedian reticular formation to the level of the obex. Labeled terminals are found in the ipsilateral medial mesencephalic reticular formation lateral to the radix and motor nucleus of the oculomotor nerve, and in the contralateral paramedian reticular formation, along the descending tract. Neurons in the medial mesencephalic reticular formation in turn project to the paramedian reticular formation. Through the crossed tectobulbar pathway visual information can influence the activity of craniocervical muscles via reticular premotor neurons.