Reverberation of recent visual experience in spontaneous cortical waves

Spontaneous waves of activity propagating across large cortical areas may play important roles in sensory processing and circuit refinement. However, whether these waves are in turn shaped by sensory experience remains unclear. Here we report that visually evoked cortical activity reverberates in subsequent spontaneous waves. Voltage-sensitive dye imaging in rat visual cortex shows that following repetitive presentation of a given visual stimulus, spatiotemporal activity patterns resembling the evoked response appear more frequently in the spontaneous waves. This effect is specific to the response pattern evoked by the repeated stimulus, and it persists for several minutes without further visual stimulation. Such wave-mediated reverberation could contribute to short-term memory and help to consolidate the transient effects of recent sensory experience into long-lasting cortical modifications.     

Modulation of Visually Evoked Postural Responses by Contextual Visual,Haptic and Auditory Information: A ‘Virtual Reality Check’

Externally generated visual motion signals can cause the illusion of self-motion in space (vection) and corresponding visually evoked postural responses (VEPR). These VEPRs are not simple responses to optokinetic stimulation, but are modulated by the configuration of the environment. The aim of this paper is to explore what factors modulate VEPRs in a high quality virtual reality (VR) environment where real and virtual foreground objects served as static visual, auditory and haptic reference points. Data from four experiments on visually evoked postural responses show that: 1) visually evoked postural sway in the lateral direction is modulated by the presence of static anchor points that can be haptic, visual and auditory reference signals; 2) real objects and their matching virtual reality representations as visual anchors have different effects on postural sway; 3) visual motion in the anterior-posterior plane induces robust postural responses that are not modulated by the presence of reference signals or the reality of objects that can serve as visual anchors in the scene. We conclude that automatic postural responses for laterally moving visual stimuli are strongly influenced by the configuration and interpretation of the environment and draw on multisensory representations. Different postural responses were observed for real and virtual visual reference objects. On the basis that automatic visually evoked postural responses in high fidelity virtual environments should mimic those seen in real situations we propose to use the observed effect as a robust objective test for presence and fidelity in VR.     

Demonstrating the Potential for Dynamic Auditory Stimulation to Contribute to Motion Sickness

Auditory cues can create the illusion of self-motion (vection) in the absence of visual or physical stimulation. The present study aimed to determine whether auditory cues alone can also elicit motion sickness and how auditory cues contribute to motion sickness when added to visual motion stimuli. Twenty participants were seated in front of a curved projection display and were exposed to a virtual scene that constantly rotated around the participant''s vertical axis. The virtual scene contained either visual-only, auditory-only, or a combination of corresponding visual and auditory cues. All participants performed all three conditions in a counterbalanced order. Participants tilted their heads alternately towards the right or left shoulder in all conditions during stimulus exposure in order to create pseudo-Coriolis effects and to maximize the likelihood for motion sickness. Measurements of motion sickness (onset, severity), vection (latency, strength, duration), and postural steadiness (center of pressure) were recorded. Results showed that adding auditory cues to the visual stimuli did not, on average, affect motion sickness and postural steadiness, but it did reduce vection onset times and increased vection strength compared to pure visual or pure auditory stimulation. Eighteen of the 20 participants reported at least slight motion sickness in the two conditions including visual stimuli. More interestingly, six participants also reported slight motion sickness during pure auditory stimulation and two of the six participants stopped the pure auditory test session due to motion sickness. The present study is the first to demonstrate that motion sickness may be caused by pure auditory stimulation, which we refer to as “auditorily induced motion sickness”.     

Is central optokinetic nystagmus gravity-dependent?

Up-down asymmetry of vertical optokinetic nystagmus (OKN) has been attributed to a potential effect of gravity. This suggestion has been supported by some investigations in microgravity where a reverse of up-down asymmetry (downward OKN greater than upward OKN) was found. In joint Bulgarian-Russian space experiment "Labyrinth", the part "Optokinez" was devoted to central OKN and its gravity dependence. We aimed at answering questions: 1) Was central optokinetic nystagmus gravity dependent, in particular vertical OKN? If it was: 2) What happened with up-down asymmetry in adaptation period to weightlessness and re-adaptation period to gravity. Furthermore, in our recent study (3) on upright standing humans we found a consistent downward prevalence in central vertical OKN. Thus, a new question arises: What determines the direction of up-down OKN asymmetry?     

A Possible Mechanism of Blocking of Limbic Motor Seizure Reactions Induced by Activation of the Thalamic Reticular Nucleus

Experiments were directed toward elucidation of the role of the thalamic reticular nucleus (R) in the modulation of generalized seizure reactions under kindling conditions and of the mechanisms mediating the effects of stimulation of the above nucleus on seizure activity. It was shown that activation of the thalamic R in rats limits generalization of the seizure reactions both in the course of development of seizures of limbic genesis (evoked by stimulation of the hippocampus) and under conditions of the existence of a pre-formed epileptic nidus. Tetanic stimulation of the R in cats under conditions of acute experiments induced significant facilitation of IPSPs in thalamo-cortical neurons of the ventrolateral thalamic nucleus. This effect is rather long-lasting and may be considered a mechanism providing blocking of generalized seizures under kindling conditions. Neirofiziologiya/Neurophysiology, Vol. 37, No. 4, pp. 352–361, July–August, 2005.     

Neurosensory Mechanisms of Space Adaptation Syndrome

The results of studies on oculomotor reactions, both spontaneous and induced by visual and vestibular stimuli, that were performed during missions of Russian orbital complexes are described. It is demonstrated that abnormal sensorimotor reactions (spontaneous nystagmus; disturbance of the tracking function of the eyes; and decrease and increase in the tonic and dynamic vestibular excitability, respectively) are appropriate reactions of sensory systems during weightlessness. Abnormal sensorimotor reactions during spaceflights are individualized with respect to the strength, pattern of expression, time of development, and duration and dynamics of adaptation processes. Periods of adaptation (the initial, disintegration, and adaptation periods and alternation of compensation and decompensation periods) of sensorimotor functions to the conditions of weightlessness are determined. The possible mechanisms of neurosensory disturbances are described. These are otolith deafferentation, channel–otolith conflict, interlabyrinth asymmetry, intersensory mismatch, sensory deprivation, and suppression of vestibular afferent signals inadequate to new conditions.     

Velocity of head movements and sensory-motor adaptation during and after short spaceflight

To investigate to time course of sensory-motor adaptation to microgravity, we tested spatially-directed voluntary head movements before, during and after short spaceflight. We also tested the re-adaptation of postural responses to sensory stimulation after space flight. The cosmonaut performed in microgravity six cycles of voluntary head rotation in pitch, roll and yaw directions. During the first days of weightlessness the angular velocity of head movements increased. Over the next days of microgravity the velocity of head movements gradually decreased. On landing day a significant decrease of head rotation velocity was observed compared to the head movement velocity before spaceflight. Re-adaptation to Earth condition measured by body sway on soft support showed similar time course, but re-adaptation measured by postural responses to vestibular galvanic stimulation was prolonged. These results showed that the angular velocity of aimed head movements of cosmonauts is a good indicator of sensory-motor adaptation in altered gravity conditions.     

The interstitial nucleus of Cajal of the cat. II. Effects of kainic acid lesion on vertical optokinetic nystagmus and after-nystagmus

The effects of bilateral lesions of the interstitial nucleus of Cajal (INC) by ka?nic acid on vertical optokinetic nystagmus (OKN) and after-nystagmus (OKAN) were studied in four cats: in three cats, in the acute stage from 1 to 60 days after the lesions; in the fourth cat, they were studied 3 years after the lesions were made. Histological control of lesions showed that the whole INC was bilaterally destroyed in two cats of the acute group and only the upper part of INC in the third cat. In the chronic cat, the density of cell bodies in both INC was lower than normal. In the acute group, the cats exhibited a spontaneous downward eye drift in light and in darkness. During an upward optokinetic stimulation, the effect of INC lesions was dramatic: upward slow phases and downward quick phases of OKN were abolished. Sixty days post lesions, small upward slow eye movements were again observed. During a downward optokinetic stimulation, the defect was much less; in particular, after a slight impairment of downward slow phases, during the first days post lesions, they recovered quickly. The secondary optokinetic after nystagmus (OKAN II) ensuing a downward OKN was cancelled and did not reappear 60 days post lesions. In the chronic stage, three years after the lesions, during an upward optokinetic stimulation, the cat showed upward slow phases with velocities close to normal. However, upward slow phases were curved: the velocity at the end of the slow phases was lower than at the beginning. After an upward OKN (the direction of slow phases gives the direction of the OKN and OKAN), the ensuing OKAN was present but abnormal.     

Functional architectonics of neuronal antinociceptive mechanisms during the electroacupuncture method of reflex action

The peculiarities of neurone bioelectric activity of sensory thalamic nuclei under electroacupuncture (EAP) stimulation have been studied in acute experiments on cats. EAP stimulation has been established to change spontaneous and evoked activity of neurones of sensory thalamic nuclei, that testifies to the development of a new functional state. The functional state of the cortex, in particular the second somatosensory region has been shown to determine the nature of neurone activation of sensory thalamic nuclei during the EAP stimulation. Schemes of possible organization of functional pools realizing the mechanisms of inhibition of nociceptive signals on central neurones during EAP way of reflex stimulation are suggested.     

Do Gravity-Related Sensory Information Enable the Enhancement of Cortical Proprioceptive Inputs When Planning a Step in Microgravity?

We recently found that the cortical response to proprioceptive stimulation was greater when participants were planning a step than when they stood still, and that this sensory facilitation was suppressed in microgravity. The aim of the present study was to test whether the absence of gravity-related sensory afferents during movement planning in microgravity prevented the proprioceptive cortical processing to be enhanced. We reestablished a reference frame in microgravity by providing and translating a horizontal support on which the participants were standing and verified whether this procedure restored the proprioceptive facilitation. The slight translation of the base of support (lateral direction), which occurred prior to step initiation, stimulated at least cutaneous and vestibular receptors. The sensitivity to proprioceptive stimulation was assessed by measuring the amplitude of the cortical somatosensory-evoked potential (SEP, over the Cz electrode) following the vibration of the leg muscle. The vibration lasted 1 s and the participants were asked to either initiate a step at the vibration offset or to remain still. We found that the early SEP (90–160 ms) was smaller when the platform was translated than when it remained stationary, revealing the existence of an interference phenomenon (i.e., when proprioceptive stimulation is preceded by the stimulation of different sensory modalities evoked by the platform translation). By contrast, the late SEP (550 ms post proprioceptive stimulation onset) was greater when the translation preceded the vibration compared to a condition without pre-stimulation (i.e., no translation). This suggests that restoring a body reference system which is impaired in microgravity allowed a greater proprioceptive cortical processing. Importantly, however, the late SEP was similarly increased when participants either produced a step or remained still. We propose that the absence of step-induced facilitation of proprioceptive cortical processing results from a decreased weight of proprioception in the absence of balance constraints in microgravity.     

Changes in the functional state of spinal-cord cell structures under gravitational unloading

The functional properties of the spinal-cord structures of experimental rats under a 7-day gravitational unloading were assessed using the method of transcranial magnetic stimulation. Hypogravity was modeled by hanging the animals by their tails in an antiorthostatic position. The gastrocnemius muscle potentials evoked by magnetic stimulation of the efferent structures of the spinal cord were registered. We found that gravitational unloading causes significant changes in motor-potential parameters and the central motor transmission time. We propose that the cause of the revealed transformations is afferent inflow limitation, first of all the motor type, as well as adaptation of the central nervous system to new conditions of motor activity.     

Theta driving both inhibits and potentiates the effects of nicotine on dentate gyrus responses

The medial septal area of conscious rats was stimulated through previously implanted electrodes at a frequency of 7.7 Hz for 20 min each day for 7 days to evoke rhythmic slow activity in CA1 at a similar frequency to spontaneous theta. Two weeks later in the anaesthetized rats the effects of a single subcutaneous injection of nicotine (0.4 mg x kg(-1)) on fEPSPs, evoked in the dentate gyrus by separate stimulation of the MPP and LPP, were studied and compared with those obtained in controls. Nicotine increased the firing of locus coeruleus neurones and the slope of the fEPSPs evoked by LPP stimulation, but not by MPP stimulation. Prior theta driving considerably increased the effect of nicotine on the responses evoked by stimulation of the MPP and abolished the nicotine-induced potentiation of the responses evoked by stimulation of the LPP. The results are attributed to theta driving increasing the amount of noradrenaline released by nicotine and to noradrenaline producing a beta-adrenoceptor long-lasting potentiation at the medial perforant path synapse and a long-lasting depression at the lateral perforant path synapse.     

Electrical activity of the visual cortex under conditions of altered monoamine levels in the brain of animals

In experiments on 8 rabbits and 12 rats changes in electrograms of the visual cortex of alert animals were studied under photic stimulation in conditions of pharmacological action on monoamine (MA) brain systems. After injection of MA precursors (5-oxitriptophane and d, 1-dioxiphenylalanine) following phenomena were observed: a) decrease of the amplitude of the averaged evoked potentials to rhythmic photic stimuli (1-20 imp. sec.-1); b) an enhancement of fast (15-25 Hz) oscillations in the cortical spontaneous electrical activity and weakening and modification of the effects of the blockader of synthesis of MA-alpha-methyl-dioxiphenylalanine. Under light stimulation potentiation of MA precursors effects was observed in the frequency spectra of electrocorticograms. In the same conditions the specificity of action of cathecholamines precursor was revealed in the form of an increase of power of rhythms of 5-7 Hz and it; decrease in 2-3 Hz. Possible mechanisms of the revealed phenomena are discussed.     

Short-term depression at thalamocortical synapses contributes to rapid adaptation of cortical sensory responses in vivo

In vivo whole-cell recordings revealed that during repeated stimulation, synaptic responses to deflection of facial whiskers rapidly adapt. Extracellular recordings in the somatosensory thalamus revealed that part of the adaptation occurs subcortically, but because cortical adaptation is stronger and recovers more slowly, cortical mechanisms must also contribute. Trains of sensory stimuli that produce profound sensory adaptation did not alter intrinsic membrane properties, including resting membrane potential, input resistance, and current-evoked firing. Synaptic input evoked via intracortical stimulation was also unchanged; however, synaptic input from the somatosensory thalamus was depressed by sensory stimulation, and this depression recovered with a time course matching that of the recovery of sensory responsiveness. These data strongly suggest that synaptic depression of thalamic input to the cortex contributes to the dynamic regulation of neuronal sensitivity during rapid changes in sensory input.     

Antagonists of NMDA glutamate receptors selectively affect synaptic mechanisms of the nociceptive sensitization in the snail

The effects of N-methyl-D-aspartate (NMDA) glutamate receptor antagonists on the mechanisms of nociceptive sensitization were studied in LPl1 and RPl1 neurons of the semiintact preparation of a Helix lucorum snail. Application of sensitizing stimuli on the head part of the control preparation led to a depolarization of the membrane and increase in its excitability. A depression of responses of neurons evoked by tactile or chemical sensory stimulation during the short-term period and significant facilitation of responses during the long-term period of sensitization were observed. Sensitization performed under conditions of application of NMDA antagonists (AP5 or MK801) produced similar changes in membrane potential, membrane excitability, and neuronal responses evoked by tactile stimulation of the head or foot. However, the chemical stimulation of the head under these conditions evoked a significant depression of responses during the short- and long-term sensitization periods. The results suggest that the NMDA glutamate receptor antagonists selectively affect the plasticity induction mechanisms of the command neuron synaptic inputs, which mediate the chemical sensory stimulation from the snail's head.     

Effects of Near-Threshold Stimulation of the Vestibular Apparatus on Postural Responses Evoked by Displacements of the Visualized Surrounding

In healthy subjects in the relaxed upward stance and perceiving a virtual visual environment (VVE), we recorded postural reactions to isolated visual and vestibular stimulations or their combinations. Lateral displacements of the visualized virtual scene were used as visual stimuli. The vestibular apparatus was stimulated by application of near-threshold galvanic current pulses to the proc. mastoidei of the temporal bones. Isolated VVE shifts evoked mild, nonetheless clear, body tilts readily distinguished in separate trials; at the same time, postural effects of isolated vestibular stimulation could be detected only after averaging of several trials synchronized with respect to the beginning of stimulation. Under conditions of simultaneous combined presentation of visual and vestibular stimuli, the direction of the resulting postural responses always corresponded to the direction of responses induced by VVE shifts. The contribution of an afferent volley from the vestibular organ depended on the coincidence/mismatch of the direction of motor response evoked by such a volley with the direction of response to visual stimulation. When both types of stimulations evoked unidirectional body tilts, postural responses were facilitated, and the resulting effect was greater than that of simple summation of the reactions to isolated actions of the above stimuli. In the case where isolated galvanic stimulation evoked a response opposite with respect to that induced by visual stimulation, the combined action of these stimuli of different modalities evoked postural responses identical in their magnitude, direction, and shape to those evoked by isolated visual stimulation. The above findings allow us to conclude that the effects of visual afferent input on the vertical posture under conditions of our experiments clearly dominate. In general, these results confirm the statement that neuronal structures involved in integrative processing of different afferent volleys preferably select certain type of afferentation carrying more significant or more detailed information on displacements (including oscillations) of the body in space.     

Functional integration of the nervous tissue of the rat following xenotransplantation into the brain of a rabbit

Surviving grafts of the nervous tissue taken from the septum and hippocampus of rat embryos and xenotransplanted into the rabbit's brain were observed in 4 out of 6 animals 2-3 months after surgery. The grafts contacted the neocortex or hippocampus of the recipients. Extracellular recording of neuronal activity in the grafts revealed spontaneous discharges with normal patterns and without any signs of pathology. Electrical stimulation of the recipients' brain (contralateral hippocampus, mesencephalic reticular formation, posterior cingulate cortex) induced changes of spontaneous discharges in 41% of the units in the grafts. Diffuse tonic shifts of the level of discharge were usually observed, though driving effects (in two units) were also encountered. Reactions to sensory stimulation of the recipients were observed in 61% of grafted units. Excitatory and inhibitory reactions, tonic, phasic and specific on-effects were evoked mainly by auditory and somatosensory stimuli. The data show the possibility of integration of xenografted tissue with the brain of the recipient and of its participation in processing of sensory information.     

Effects of optokinetic stimulation on motor asymmetry in the goldfish

In goldfish fries, we examined the effect of the optomotor reaction (drive to swim toward moving images of vertical dark bars) on the behavioral motor asymmetry. Contralateral optokinetic stimulation of fishes (rotation of the bars against the direction preferred by fishes in their turnings) gradually smoothed and, later on, inverted the motor asymmetry, while the asymmetry underwent no modifications in the case of ipsilateral optokinetic stimulation (rotation of the bars in the direction similar to that preferred for turnings). Contralateral optokinetic stimulation also induced long-lasting inversion of the motor asymmetry of immobilized fishes deprived of the possibility to follow the movement of bar images. Ipsilateral optokinetic stimulation of fishes with the enucleation of the ipsilateral eye enhanced their motor asymmetry, while contralateral stimulation either did not modify the motor asymmetry of such individuals or inverted this feature. These data agree with the concept that, in fishes, one eye dominates and more actively provides tracking of the movement of bars, while another eye is a subdominant one. In general, we first found that the use of specific visual stimulation allows one to modify for a long time the behavioral motor asymmetry of the fishes, which, as is known, correlates with the morphofunctional asymmetry of Mauthner neurons (MNs). Visual information that activates MNs influences mostly the ventral dendrites of these neurons; thus, our findings allow us to believe that stimulations, which initiate the optomotor reaction, can serve as an adequate physiological model of natural visual stimulation of MNs (with projection of the respective influences on the ventral dendrites of the above cells). The use of such an experimental paradigm opens up new possibilities for studies of the role of these dendrites in the functions of MNs and of the plasticity of morphofunctional organization of these cells. Neirofiziologiya/Neurophysiology, Vol. 39, No. 2, pp. 133–145, March–April, 2007.     

The motion aftereffect as a universal phenomenon in sensory systems involved in spatial orientation. III. Aftereffect of motion adaptation in the somatosensory and vestibular systems

The motion aftereffect may be considered as a consequence of visual illusions of self-motion (vection) and the persistence of sensory information processing. There is ample experimental evidence indicating a uniformity of mechanisms that underlie motion aftereffects in different modalities based on the principle of motion detectors. Currently, there is firm ground to believe that the motion aftereffect is intrinsic to all sensory systems involved in spatial orientation, that motion adaptation in one sensory system elicits changes in another one, and that such adaptation is of great adaptive importance for spatial orientation and motion of an organism. This review seeks to substantiate these ideas.