Effects of Somatosensory Stimulation on Dream Content in Gymnasts and Control Participants: Evidence of Vestibulomotor Adaptation in REM Sleep

Somatosensory stimulation of the leg muscles in REM sleep appears to perturb virtual orientation in dream experiences. According to our model of vestibulomotor adaptation (Sauvageau, Nielsen, & Montplaisir, 1996), the dreaming mind attempts to compensate for such destabilizing stimulation by increasing eye movement activity or by modifying dream content, among other possible reactions. Effective compensation may be more easily achieved by participants who are adapted to the disruptive stimulation or who possess highly developed vestibulomotor skills. To examine this possibility, we studied the effects of Somatosensory stimulation on the dreams of 6 gymnasts and 6 control participants aged 9 to 16 years. Results provide some support for the expectations that 1) imposed Somatosensory information is processed by the central nervous system in REM sleep, 2) unilateral stimulation induces an upset in virtual orientation, 3) gymnasts are more resistant to these disruptive effects of stimulation than are control participants, and 4) because of long-term adaptation, the dream content of gymnasts does not differ markedly from that of controls. Though preliminary and in need of replication, the findings are compatible with the notion that the developed vestibular skills of gymnasts protects them to some extent from the effects of a disruptive Somatosensory stimulus during sleep.     

Self versus Environment Motion in Postural Control

To stabilize our position in space we use visual information as well as non-visual physical motion cues. However, visual cues can be ambiguous: visually perceived motion may be caused by self-movement, movement of the environment, or both. The nervous system must combine the ambiguous visual cues with noisy physical motion cues to resolve this ambiguity and control our body posture. Here we have developed a Bayesian model that formalizes how the nervous system could solve this problem. In this model, the nervous system combines the sensory cues to estimate the movement of the body. We analytically demonstrate that, as long as visual stimulation is fast in comparison to the uncertainty in our perception of body movement, the optimal strategy is to weight visually perceived movement velocities proportional to a power law. We find that this model accounts for the nonlinear influence of experimentally induced visual motion on human postural behavior both in our data and in previously published results.     

Rapid muscle force reactions during regulation of rhythmic movement

It was shown by experiments with human forearm rhythmic movements that summary force, stiffness and viscosity of musculature quickly increased during the action of external unshocked disturbance. These effects limited the movement trajectory changes during latent interval preceding nervous reactions.     

New approach of the cardio-vascular depressive mechanism during lateral hypothalamic stimulation.

Paraventricular nucleus stimulation acts directly on the alpha- and beta-adrenoreceptors in heart and arterioles, eliciting arterial hypotension and cardiac chronotropism and inotropism decrease. Efferent pathways follow sympathetic nervous fibres through the medulla and the thoraco-lumbar ganglionic chain. The role of the alpha- and beta-adrenoreceptors in these depressive reactions is discussed.     

Functional disturbances in the nervous structures of the respiratory tract in rats following nitrogen dioxide inhalation

The functional state of rat's airway smooth muscle was not changed after nitrogen dioxide inhalation for 30 days. The smooth muscle contraction increased only at second stimulation of preganglionic nervous fibers. Removal of mucosa or Novocain blockade of receptors decreased control smooth contraction at nerve and muscle fiber stimulation but the repeated stimulation of nerve increased the muscle contraction. The processing of trachea and bronchus preparations by prednisolon (1-10 microg/ml) decreased muscle reactions to 12% only at nerve stimulation. Prednisolon didn't change reactions of preparations with removed or blockaded receptors induced by nerve stimulation, but prednisolon (10 microg/ml) increased contraction at muscle stimulation. The relax effect of prednisolon on airway smooth muscle realizes via tracheobronchial receptors. High doses of prednisolon may direct effect on muscle increasing its contraction.     

Visual illusions induced by electrical stimulation of the labyrinth

In normal subjects, electrical stimulation of the labyrinth with surface electrodes located on the mastoid process induced illusions of shifting of a fixed point of light in darkness similar to the oculogyral illusion induced by rotatory vestibular stimulation. Monoaural anodal stimulation of the right labyrinth induced apparent shift of the target to the left; with cathodal stimulation, it shifted to the right; threshold current was 0.35–0.6 mA. When the current strength increased, the amplitude and rate of apparent movement of the target increased approximately linearly. With binaural, bipolar stimulation, the illusory movement of the target was toward the site of the cathode and the threshold decreased by 1.5–2.5 times. With binaural, monopolar stimulation, the target seemed to shift along the vertical and the threshold current was 1.4–3.0 mA. Eye movement appeared at substantially higher currents than those resulting in apparent movement of the target. It is suggested that visual illusions are linked not to vestibular eye-movement reactions, but to the effect vestibular signals have on the spatial perception system.Institute of Problems of Information Transmission, Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 23, No. 3, pp. 321–327, May–June, 1991.     

小鼠自主活动实验中的评价指标

目的为神经精神药物研究中动物自主活动评价提供科学客观、规范灵敏的指标评价体系。方法选用经典的镇静药物力月西、兴奋药咖啡因,以及镇静安神临床疗效肯定的中药远志及人参,研究对小鼠水平自主活动指标,包括周边区、中央区及总区域的运动、静息状态等评价指标的影响。结果总路程、平均速度、运动总时间、周边区运动路程、周边区运动时间与小鼠的兴奋状态成同向变化,静息总时间、周边区静息时间与小鼠的兴奋状态成反向变化。以上7个指标能准确、有效的评价小鼠的行为学改变。结论总路程、平均速度、运动总时间、周边区运动路程、周边区运动时间、静息总时间、周边区静息时间为评价小鼠自主活动客观灵敏的有效指标。     

Function of otolith organ in goldfish revealed from analysis of eye movement induced by acceleration.

An otolith organ on ground behave as a detector of both gravity and linear acceleration, and play an important role in controlling posture and eye movement for tilt of the head or translational motion. On the other hand, a gravitational acceleration ingredient to an otolith organ disappears in microgravity environment. However, linear acceleration can be received by otolith organ and produce a sensation that is different from that on Earth. It is suggested that in microgravity signal from the otolith organ may cause abnormality of posture control and eye movement. Therefore, the central nervous system may re-interprets all output from the otolith organ to indicate linear motion. A study of eye movement has been done a lot as one of a reflection related to an otolith organ system. In this study, we examined function of otolith organ in goldfish revealed from analysis of eye movement induced by linear acceleration or the tilt of body. We analyzed both torsional and vertical eye movements from video images frame by frame. For tilting stimulation, torsional eye movements induced by head down was larger than that induced by head up for larger tilt angle than 30 degrees. In the case of linear acceleration below 0.4 G, however, no clear differences were observed in both torsional and vertical eye movement. These results suggest that body tilt and linear acceleration may not be with equivalent stimulation to cause eye movement on the ground.     

Inhibitory processes in neuronal reactions of the auditory cortex in the cat undergoing dichotic stimulation

In experiments on anaesthetized cats, studies have been made of intracellular and extracellular responses of single units in the auditory cortex during dichotic stimulation simulating sound source motion. Responses of some cortical units exhibit strong dependence on the signal parameters related to spatial and directional characteristics of simulated sound source motion. Profound inhibition was invariably revealed at the beginning of sonic stimulation as well as during certain moments of its movement. The role of inhibition in formation of cortical reactions to sound source motion is discussed.     

The role of endogenous bioregulators in formation of cardiogenic reflex effects on circulation

The possible role of endogenous endothelium-derived bioactive substances in organization of cardiogenic depressor reflexes under cardiac receptor stimulation (by veratrine and bradykinin) was investigated in acute experiments on anesthetized rats. The results have shown that endothelium-derived bioactive substances take part in forming of the cardiogenic depressor reflex humoral components of nervous response or nervous modulators. These data contribute to understanding of the role of endogenous endothelium-derived bioactive substances (prostacyclin) and different NOS isoforms in mechanisms of depressor reflex development and species differences in their involvement in reflex vasomotor reactions.     

Qualitative differences in the reactions of the spinal nerves of the frog Rana temporaria during chemical stimulation of the skin

Studies have been made on total impulse activity in the skin nerves of the frog during application of acid solutions as well as during tactile stimulation. It was shown that the reactions to various stimuli differ with respect to their pattern and amplitude of integrated response curve which reflects changes in the frequency of total impulsation. In responses to test solutions and tactile stimulation, different units may be involved which specifically react to each of the stimuli. This specificity of single elements is also revealed during changes in the evoked total activity resulting from superficial skin anaesthesia. Possible nature of peripheral structures involved in these reactions is discussed.     

Comparative pathology of higher nervous activity

In experiments with defensive behaviour, using multiparametric recording of indices, studies have been made on the origin and development of pathological disturbances in the higher nervous activity of insectivores, carnivores and primates during presentation of difficult conditioned reflex problems or extreme stimulation. It was found that elaboration of absolute differentiation retarded conditioned reactions with a delay of 25 s in insectivores is a difficult task which results in pathological changes in the higher nervous activity. In hedgehogs, neurotic changes are immediate, all the investigated indices being affected. In carnivores, especially in primates, the onset of evident pathological changes is preceded by a long preneurotic period, i.e. a stage of self-regulation. In pathological process, more corticalized forms of the nervous activity are initially involved. Common features and differences in the development of pathological changes in the higher nervous activity among mammals are discussed.     

Probing neural circuitry and function with electrical microstimulation

Since the discovery of the nervous system's electrical excitability more than 200 years ago, neuroscientists have used electrical stimulation to manipulate brain activity in order to study its function. Microstimulation has been a valuable technique for probing neural circuitry and identifying networks of neurons that underlie perception, movement and cognition. In this review, we focus on the use of stimulation in behaving primates, an experimental system that permits causal inferences to be made about the effect of stimulation-induced activity on the resulting behaviour or neural signals elsewhere in the brain.     

Nonsomatotopic Organization of the Higher Motor Centers in Octopus

Hyperredundant limbs with a virtually unlimited number of degrees of freedom (DOFs) pose a challenge for both biological and computational systems of motor control. In the flexible arms of the octopus, simplification strategies have evolved to reduce the number of controlled DOFs [1], [2] and [3]. Motor control in the octopus nervous system is hierarchically organized [4] and [5]. A relatively small central brain integrates a huge amount of visual and tactile information from the large optic lobes and the peripheral nervous system of the arms [6], [7], [8] and [9] and issues commands to lower motor centers controlling the elaborated neuromuscular system of the arms. This unique organization raises new questions on the organization of the octopus brain and whether and how it represents the rich movement repertoire. We developed a method of brain microstimulation in freely behaving animals and stimulated the higher motor centers—the basal lobes—thus inducing discrete and complex sets of movements. As stimulation strength increased, complex movements were recruited from basic components shared by different types of movement. We found no stimulation site where movements of a single arm or body part could be elicited. Discrete and complex components have no central topographical organization but are distributed over wide regions.     

Neuronal correlates of changes in the defensive behavior of Helix lucorum L. during ontogeny

In experiments on the isolated nervous system, responses of the same command neurones of avoidance behaviour to electrical stimulation of the intestinal nerve were compared in adult snails (Helix pomatia) and in snails 1-20 days old. Dynamics of spike reactions of the command neurones to rhythmic nerve stimulation differed in adult and newborn snails. In the neurones of young snails, no sensitization, common in the adult animals, was observed. Study of excitatory input in the command neurones during rhythmic nerve stimulation suggests independence of habituation of synaptic input amplitude and spike response sensitization, because dynamics of habituation coincided in the young and adult snails while spike response underwent sensitization only in adult animals.     

深部脑刺激作用机制的探讨

深部脑刺激器（deep brain stimulator）,也经常被称为脑起搏器,是可植入人体设备,并连续不断地传送刺激脉冲到深部脑组织的特定区域,即所谓的深部脑刺激（deep brain stimulation,DBS）.迄今为止,深部脑刺激是治疗严重顽固抗药性运动障碍疾病（如帕金森病,原发性震颤及肌张力异常等）的最有效的外科治疗手段之一.此外,广大的科研工作者也不断地探索应用DBS治疗其他神经及精神异常（如,癫痫和强迫症）的新的临床应用.尽管应用DBS治疗运动障碍非常有效,并也迅速被探索性地应用到其他神经障碍治疗中,但其作用机制仍然不是十分清楚,成为学者们争论的热点.DBS治疗效果的作用机制通常有两种基本的观点：高频刺激抑制学说及高频刺激兴奋学说.基于最近发表的关于中枢神经系统内的高频刺激效应的资料、数据及相关评论,两种机制共存并发挥作用的DBS作用假说被提出,认为DBS通过施加高频刺激干扰并控制了核团病理性紊乱随机活动,同时施加兴奋性刺激到其他基底节的网络,以实现对帕金森病的治疗.     

Lateral dynamic balance reactions to circular translation of the visual field

Lateral sway of subjects in spontaneous dynamic balance conditions on a seesaw platform was measured during a visual stimulation monocularly produced by a rotating glass covered with a prism membrane. Prism rotation induced the perception of a circular translation of the whole visual field and an ocular pursuit movement. Therefore, the retinal slip that occurs in normal pursuit was cancelled. Strong stereo-typed postural reactions were observed in a direction that depended upon both the vertical visual field deviation and the eye stimulated: upper position of the right visual field induced a leftward sway resulting from an extension of the right hemibody; symmetrical reactions occurred for the left stimulation. The results suggest that the postural reactions recorded depend on the isolated oculomotor activity and, in addition, on retinal afferences corresponding to the temporal crescent of the stimulated side, which orientates the postural reaction on the homolateral lower limb muscles.     

Neocortex neuron reactions caused by stimulation of the substantia innominata in cats

We investigated neuronal impulse activity in the sensorimotor cortex after substantia innominata (SI) stimulation in cats during the execution of an instrumental conditioned response consisting of placement of a paw on a pedal coupled with alimentary reinforcement. Stimulation of the SI was initiated 1 or 3 sec prior to conditioned stimulation. Background activity of the neurons was inhibited during stimulation of the SI. Preliminary stimulation of the SI one second in advance caused an increase of reactions linked to a subsequent conditioned stimulus and a conditioned-response movement in 32% of the neurons; a 3-sec lead caused increases of such reactions in 33% of neurons. In some cells which originally did not react to the conditioned excitation, a clear reaction did manifest after stimulation. Moreover, stimulation of the SI with a 1-sec lead caused inhibition of impulse reactions in 6% of the cells; with a 3-sec lead, it caused inhibition of impulse reactions in 33% of the cells. The spread of latencies of conditioned-response actions decreased 2- to 3-fold in this case. We discuss the possibility that acetylcholine, which is released by the terminals of cholinergic neurons of the SI, has a facilitating influence on the impulse activity of neocortical neruons.Bogomolets Institute of Physiology, Ukrainian Academy of Sciences, Kiev. Translated from Neirofiziologiya, Vol. 24, No. 1, pp. 11–20, January–February, 1992.     

Advances in functional electrical stimulation (FES)

This review discusses the advancements that are needed to enhance the effects of electrical stimulation for restoring or assisting movement in humans with an injury/disease of the central nervous system. A complex model of the effects of electrical stimulation of peripheral systems is presented. The model indicates that both the motor and sensory systems are activated by electrical stimulation. We propose that a hierarchical hybrid controller may be suitable for functional electrical stimulation (FES) because this type of controller acts as a structural mimetic of its biological counterpart. Specific attention is given to the neural systems at the periphery with respect to the required electrodes and stimulators. Furthermore, we note that FES with surface electrodes is preferred for the therapy, although there is a definite advantage associated with implantable technology for life-long use. The last section of the review discusses the potential need to combine FES and robotic systems to provide assistance in some cases.     

Participation of mesencephalic structures in vocal reactions]

Electrical stimulation and ablation of the midbrain structures in hens and one-day old chickens have revealed the structures (ICO, MLD, MLV, IPC and IMC) involved in the formation of vocal reactions. The paper outlines the functional characteristics of the structures and their dissimilarities which are determined by the type of their units. In the course of individual development of the hens, there is an increase of excitability and lability of the nervous processes in the examined structures.