Spontaneous phasic activity in the brain: differences between waves in lateral geniculate and central lateral nuclei across sleep states

The brain is vulnerable to oxidative damage due to its high oxygen consumption. This Study investigate the effects of cadmium on the lateral geniculate body of developing male wistar rats and ameliorative potential of Moringa oleifera seed oil and walnut oil extracts. Seven groups of five animals each were used in this experiment. Group A received 3ml of 0.9% normal saline; group B received 2.5mg/kg bw of 3CdSO4.8H2O, group C received 5mg/kg bw vitamin C & 6mg/kg bw vitamin E, group D received 5mg/kg bw vitamin C & 6mg/kg bw vitamin E + 2.5mg/kg bw Cd, group E received 2.5mg/kg bw Cd + 4mg/kg bw Moringa oleifera oil, group F received 2.5mg/kg bw Cd + 4mg/kg bw walnut oil, while group G received 2.5mg/kg bw Cd + 2mg/kg bw walnut + 2mg/kg bw Moringa oleifera oil concomitantly for 3weeks. Parameter tested includes LDH, G6PD in brain tissues, SOD and GPx enzymes in brain homogenates and serum and cresyl fast violet stain in the brain tissues. Cd administration significantly increased SOD, GPx, LDH and decreased G6PD level in brain tissue and decreased their activity in serum when compared with Group A control rats. There was marked reduction and lost in the distribution of nissl substances of the studied tissues of Cd administered animals. However, administration of vitamin C & E, walnut and Moringa oleifera oil restored damaged tissues. Walnut and Moringa oleifera seed oil therefore attenuated the oxidative damage and morphological changes induced by cadmium in the lateral geniculate body of the brain of the young male wistar rats.Key Words: Lateral geniculate body, Antioxidant, Histochemical, Cadmium, Oxidative Damage

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MORPHOLOGY AND FUNCTION OF THE AUTONOMOUS NERVOUS SYSTEM

Актуальні проблеми сучасної медицини Вісник Української медичної стоматологічної академії ◽

10.31718/2077-1096.20.1.212 ◽

2020 ◽

Vol 20 (1) ◽

pp. 212-217

Author(s):

A.P. Stepanchuk

Keyword(s):

Spinal Cord ◽

Nervous System ◽

Autonomic Nervous System ◽

Abdominal Cavity ◽

Nerve Cells ◽

Autonomous Nervous System ◽

Autonomic Nervous ◽

Lumbar Spinal ◽

The Brain ◽

Lateral Nuclei

The autonomic nervous system consists of the sympathetic and parasympathetic divisions. The central part is represented by supra-segmental and segmental centres. Parasympathetic segmental centres in the brain are accessory nucleus of the oculomotor nerves, superior salivary nucleus of the facial nerve, inferior salivary nucleus of the glossopharyngeal nerve and dorsal nucleus of the vagus nerve. In the spinal cord, these are the intermediate lateral nuclei. Sympathetic segmental centres in the brain are absent, and in the spinal cord, intermediate-lateral nuclei are located in the lateral horns in the eighth cervical, all thoracic and 1-2 lumbar spinal segments. The peripheral part of the autonomic nervous system is represented by pre-nodal and post-nodal branches, paravertebral, prevertebral and terminal nodes and plexuses. The intramural part of the autonomic nervous system lies in the larger part of a wide and narrow-loop net and represented with a large number of nerve cells different by their shapes and sizes and clustered as intramural nodes, or individual nerve cells included along the net loops. The autonomic plexuses of the abdominal cavity are topographically divided into celiac, superior and inferior mesenteric, abdominal aortic, mesenteric, superior and inferior hypogastric region.

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Circuitry of the Lateral Geniculate Nucleus

Handbook of Brain Microcircuits ◽

10.1093/med/9780190636111.003.0008 ◽

2017 ◽

pp. 87-98

Author(s):

S. Murray Sherman

Keyword(s):

Functional Connectivity ◽

Lateral Geniculate Nucleus ◽

Excellent Model ◽

Brain Circuits ◽

Lateral Geniculate ◽

Retinal Input ◽

The Brain

The circuitry of the thalamus is among the most thoroughly studied and best understood exemplars of functional connectivity in the brain. This chapter shall focus on the A laminae of the cat’s lateral geniculate nucleus (LGN), which represents the relay of retinal input to the cortex, because this has proved to be an excellent model for the thalamus. There are two major payoffs for understanding this circuit: the basic plan revealed by LGN circuitry seems to be applied throughout the thalamus, with some relatively minor modifications, so this provides general insights into overall thalamic functioning; and many circuit principles first appreciated in the LGN apply to other brain circuits.

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Review Lecture - Behavioural analysis of the monkey’s visual nervous system

Proceedings of the Royal Society of London Series B Biological Sciences ◽

10.1098/rspb.1972.0087 ◽

1972 ◽

Vol 182 (1069) ◽

pp. 427-455 ◽

Cited By ~ 62

Keyword(s):

Lateral Geniculate Nucleus ◽

Striate Cortex ◽

Visual Space ◽

Dorsal Lateral Geniculate Nucleus ◽

Anterior Portion ◽

Lateral Geniculate ◽

Early Results ◽

Negative Effect ◽

Occipital Lobes ◽

The Brain

1. Introduction Of the three million or so nerve fibres that stream into the primate brain, about two million originate in the eyes. Of these fibres, about one-and-a-half million are in the geniculo-striate system, so named because it connects the eyes with a region of the thalamus known as the dorsal lateral geniculate nucleus and that nucleus with the striate cortex (also known as area 17 or area OC, figure 1) in the occipital lobes. About half, therefore, of all the inputs to the brain are fibres of retinal origin having relatively direct and concentrated access to the cerebral cortex. One may be allowed some surprise, therefore, to find that David Ferrier claimed in 1886 that monkeys subjected to large occipital lobectomies (figures 2, 3) were unaffected by this drastic interruption of such a massive afferent channel. He said 'I removed the greater portion of both occipital lobes at the same time without causing the slightest appreciable impairment of vision. One of these animals within 2 h of the operation was able to run about freely, avoiding obstacles, to pick up such a minute object as a raisin without the slightest hesitation or want of precision, and to act in accordance with its visual experience in a perfectly normal manner’ (Ferrier 1886, p. 273). Ferrier went on to say that ‘Horseley and Schäfer inform me that their results of removal of the occipital lobes entirely harmonize with mine as to the completely negative effect of this operation’ (p. 276), which is a curious claim because two years later Schäfer was locked in a most bitter dispute with Ferrier over just this point, and their argument is merely the most extreme example of the lack of agreement about the functions of the visual cortex in animals that has persisted over the years. We now know, with the benefit of hindsight, that there may have been an uninteresting explanation of these early results of Ferrier’s, because not all of the fibres from the lateral geniculate nucleus project to the lateral surface of the brain. Some of the striate cortex ─ that part which responds to stimulation of the most peripheral parts of the retinae ─ is buried in the calcarine fissure on the medial aspect of the brain, and the most anterior portion of this may be spared even after a complete occipital lobectomy (figure 1). Were Ferrier’s animals using an intact part of their visual space?

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Effects of brain stem parabrachial activation on receptive field properties of cells in the cat's lateral geniculate nucleus

Journal of Neurophysiology ◽

10.1152/jn.1995.73.6.2428 ◽

1995 ◽

Vol 73 (6) ◽

pp. 2428-2447 ◽

Cited By ~ 48

Author(s):

D. J. Uhlrich ◽

N. Tamamaki ◽

P. C. Murphy ◽

S. M. Sherman

Keyword(s):

Receptive Field ◽

Brain Stem ◽

Spontaneous Activity ◽

Lateral Geniculate Nucleus ◽

Visual Stimuli ◽

Visual Responses ◽

Burst Stimulation ◽

Lateral Geniculate ◽

Almost All ◽

The Brain

1. The lateral geniculate nucleus is the primary thalamic relay for the transfer of retinal signals to the visual cortex. Geniculate cells are heavily innervated from nonretinal sources, and these modify retinogeniculate transmission. A major ascending projection to the lateral geniculate nucleus arises from cholinergic cells in the parabrachial region of the brain stem. This is an important pathway in the ascending control of arousal. In an in vivo preparation, we used extracellular recordings to study the effects of electrical activation of the parabrachial region on the spontaneous activity and visual responses of X and Y cells in the lateral geniculate nucleus of the cat. 2. We studied the effects of two patterns of parabrachial activation on the spontaneous activity of geniculate cells. Burst stimulation consisted of a short pulse at high frequency (16 ms at 250 Hz). Train stimulation was of longer duration at lower frequency (e.g., 1 s at 50 Hz). The firing rate of almost all geniculate cells was enhanced by either pattern of stimulation. However, the burst pattern of stimulation elicited a short, modulated response with excitatory and inhibitory epochs. We found that the different epochs could differentially modulate the visual responses to drifting gratings. Thus the temporal alignment of the brain stem and visual stimuli was critical with burst stimulation, and varied alignments could dramatically confound the results. In comparison, the train pattern of stimulation consistently produced a relatively flat plateau of increased firing, after a short initial period of more variable effects. We used the less confounding pattern of train stimuli to study the effects of parabrachial activation on visual responses. 3. Our main emphasis was to examine the parabrachial effects on the visual responses of geniculate cells. For most visual stimuli, we used drifting sine wave gratings that varied in spatial frequency; these evoked modulated responses from the geniculate cells. Parabrachial activation enhanced the visual responses of almost all geniculate cells, and this enhancement included both increased depth of modulation and greater response rates. 4. Our results were incorporated quantitatively into a difference-of-Gaussians model of visual receptive fields in order to study the parabrachial effects on the spatial structure of the receptive field. This model fit our data well and provided measures of the response amplitude and radius of the receptive field center (Kc and Rc, respectively) and the response amplitude and radius of the receptive field surround (Ks and Rs, respectively).(ABSTRACT TRUNCATED AT 400 WORDS)

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Dual response modes in lateral geniculate neurons: Mechanisms and functions

Visual Neuroscience ◽

10.1017/s0952523800007446 ◽

1996 ◽

Vol 13 (2) ◽

pp. 205-213 ◽

Cited By ~ 113

Author(s):

S. Murray Sherman

Keyword(s):

Action Potentials ◽

Thalamic Nuclei ◽

Burst Mode ◽

Lateral Geniculate ◽

Dual Response ◽

Voltage Dependent ◽

Low Threshold ◽

Response Modes ◽

New Evidence ◽

The Brain

AbstractRelay cells of the lateral geniculate nucleus, like those of other thalamic nuclei, manifest two distinct response modes, and these represent two very different forms of relay of information to cortex. When relatively hyperpolarized, these relay cells respond with a low threshold Ca2+ spike that triggers a brief burst of conventional action potentials. These cells switch to tonic mode when depolarized, since the low threshold Ca2+ spike, being voltage dependent, is inactivated at depolarized levels. In this mode they relay information with much more fidelity. This switch can occur under the influence of afferents from the visual cortex or parabrachial region of the brain stem. It has been previously suggested that the tonic mode is characteristic of the waking state while the burst mode signals an interruption of the geniculate relay during sleep. This review surveys the key properties of these two response modes and discusses the implications of new evidence that the burst mode may also occur in the waking animal.

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