Central Nervous System: The Brain and Spinal Cord

... Located in postcentral gyrus  Controls all sensation capabilities  Subdivided into: 1. Somatosensory cortex 2. Association cortex 3. Visual cortex 4. Auditory cortex 5. Olfactory cortex 6. Gustatory cortex 7. Vestibular cortex ...

Nervous System

... Parts of a Neuron Cell Body: Life support center of the neuron. Dendrites: Branching extensions at the cell body. Receive messages from other neurons. Axon: Long single extension of a neuron, covered with myelin [MY-uh-lin] sheath to insulate and speed up messages through neurons. Terminal Branches ...

Carrie Heath

... 12. What are the advantages for using the squid giant neuron for experiments rather than using mammalian neurons? 13. What structures make up the blood brain barrier and what is its function? 14. What are the three input vessels and the three output vessels to the Circle of Willis? Why is this consi ...

Human nervous system_Final

... Parasympathetic Nervous System: clams after arousal. A neuron or a nerve cell: 1) A neuron is a cell of the nervous system and has cell membranes and nucleus. Neurons contain cytoplasm, mitochondria and other organelles and carry out basic cellular processes, such as energy production, and informati ...

Chapter 14 Autonomic nervous system

... a. The receptors for these sensations are located in the skin, in connective tissue under the skin, in mucous membranes, and at the ends of the gastrointestinal tract. b. Nerve impulses generated by cutaneous receptors pass along somatic afferent neurons in spinal and cranial nerves, through the tha ...

Behavioral Neuroscience

... Parts of a Neuron Cell Body: Life support center of the neuron. Dendrites: Branching extensions at the cell body. Receive messages from other neurons. Axon: Long single extension of a neuron, covered with myelin [MY-uh-lin] sheath to insulate and speed up messages through neurons. Terminal Branches ...

Visual Field Defects - Northwestern Medical Review

... Normally damage to the brain cortex causes contralateral deficits in the extremities. This is not, however, true of the visual system. Unilateral damage to the visual cortex is manifested by characteristic partial loss of vision in both eyes. Neither of the eyes is able to see the contralateral visu ...

Mammalian Cerebral Cortex: Embryonic Development

... their terminal filaments (Fig. 2.1a, b). The neuroepithelial cells are attached to the pial surface by filaments with several terminal endfeet, which united by tight junctions, build the pia external glia limiting membrane (EGLM) and manufacture its basal lamina (Fig. 2.1a, b). The pial surface rep ...

Biology 30 NERVOUS SYSTEM - Salisbury Composite High School

... that must be reached before sufficient Na+ gates open to continue the action potential All or None Response – if the threshold level is not reached, the action potential will not occur at all. If the threshold is reached or exceeded a full action potential will result. ...

Neurons - Noba Project

... 1. Differentiate the functional roles between the two main cell classes in the brain, neurons and glia. 2. Describe how the forces of diffusion and electrostatic pressure work collectively to facilitate electrochemical communication. 3. Define resting membrane potential, excitatory postsynaptic pote ...

5. Electrical Signals

... • Nervous system: (the network of nerve cells and fibers which transmits nerve impulses between parts of the body) • Neurons: (a specialized cell transmitting nerve impulses) • Nerve cells: (cell which is part of the nervous system, neuron) • Spinal cord: (the cylindrical bundle of nerve fibres whic ...

English - Bernstein Center for Computational Neuroscience Berlin

... always knows its location. Each of these so-called “place cells” is particularly active when the rat is in a certain area, the cell “fires”. Thus, each site is coded by specific cells. However, in the corresponding region of the brain are also cells that do not fire, they are “silent”. This activity ...

Vision`s First Steps: Anatomy, Physiology, and Perception in the

... middle) and the ganglion cell layer (nearest to the center of the eye). Photoreceptor layer: light is transduced into electrical signals by photoreceptors: rods and cones. Cones are not sensitive to dim light, but under photopic conditions (bright light) they are responsible for fine detail and colo ...

Diseases of the Basal Ganglia

... along with their connected cortical and thalamic areas, are viewed as components of parallel circuits whose functional and morphological segregation is rather strictly maintained. Each circuit is thought to engage separate regions of the basal ganglia and thalamus, and the output of each appears to ...

Discriminative Auditory Fear Learning Requires Both Tuned

... thought to be important for sound discrimination. • The nonlemniscal stream has less selective neurons, which are not tonotopically organized, and is thought to be important for multimodal processing and for several forms of learning. ...

Chapter 2 - bobcat

... MRI is a noninvasive imaging technique that does not use xrays. The process involves passing a strong magnetic field through the head. The magnetic field used is 30,000 + times that of the earth's magnetic field. It's effect on the body, however, is harmless and temporary. The MRI scanner can detect ...

Module 18

... • The central focal point of the retina • The spot where vision is best (most detailed – visual acuity) • Only cones are found in the Fovea ...

pain - MEFST

... Sensations From the Body  The cell bodies of sensory neurons mediating pain are located in the dorsal root ganglia (first-order neurons).  The central axons (both Aδ and C fibers) of these sensory neurons reach the dorsal horn and branch into ascending and descending collaterals, forming the dorso ...

Introduction to Anatomy

... 4. neurolemma 5. nodes of Ranvier ...

BACOFUN_2016 Meeting Booklet - Barrel Cortex Function 2016

... measurements. However, the location and distance between pre- and postsynaptic cells and - in case of slicing experiments - the degree of truncation strongly influences the connectivity. When reproducing electronmicroscopic and in vitro slicing experiments in our model, we found that measurements ob ...

Materialy/06/Lecture12- ICM Neuronal Nets 1

... 1921: First attempt of McCulloch to model a brain 1943: First McCulloch’s publication of model of neuron 1947: McCulloch and Pitt described a behaviour of connected neurons 1949: Hebb designed a net with memory 1958: Rosenblatt described learning (“back propagation”) 1962: first neurocomputer ...

The master controlling and communicating system of the body Functions

... A brief reversal of membrane potential with a total amplitude of 100 mV Action potentials are only generated by muscle cells and neurons They do not decrease in strength over distance They are the principal means of neural communication An action potential in the axon of a neuron is a nerve ...

sensory receptor

...  Sensory receptors produce two kinds of graded ...

Shipp Visual memory Notes

... o Implies hippocampus is important in memory formation; IT cortex in memory consolidation. fMRI of human brain activity in learning face-house pairings[9] o Area FFA (Fusiform Face Area) supports face imagery; o Area PPA (Parahippocampal Place Area) supports house imagery; o Hippocampus (and anterio ...

Anatomy of Brain Functions

... The process of integration is the processing of the many sensory signals that are passed into the CNS at any given time. These signals are evaluated, compared, used for decision making, discarded or committed to memory as deemed appropriate. Integration takes place in the gray matter of the brain an ...

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Feature detection (nervous system)

Feature detection is a process by which the nervous system sorts or filters complex natural stimuli in order to extract behaviorally relevant cues that have a high probability of being associated with important objects or organisms in their environment, as opposed to irrelevant background or noise. Feature detectors are individual neurons – or groups of neurons – in the brain which code for perceptually significant stimuli. Early in the sensory pathway feature detectors tend to have simple properties; later they become more and more complex as the features to which they respond become more and more specific. For example, simple cells in the visual cortex of the domestic cat (Felis catus), respond to edges – a feature which is more likely to occur in objects and organisms in the environment. By contrast, the background of a natural visual environment tends to be noisy – emphasizing high spatial frequencies but lacking in extended edges. Responding selectively to an extended edge – either a bright line on a dark background, or the reverse – highlights objects that are near or very large. Edge detectors are useful to a cat, because edges do not occur often in the background “noise” of the visual environment, which is of little consequence to the animal.

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Feature detection (nervous system)