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Download Ch 8 Neurons and Network properties part-1
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Transcript
Chapter 8 The Nervous System Organization of nervous system Central Nervous System Peripheral Nervous System Integration of CNS and PNS The Neuron is the Functional unit of the nervous system The “model” neuron Peripheral Nervous System Afferent Neurons Sensory Receptors send information to CNS Efferent Neurons Carry information to effector cells of the body PNS is divided into 1. Autonomic Division – Sympathetic branch – Parasysmpathetic branch PNS is divided into 2. Somatic Motor division – Controls skeletal muscle PNS divided into 3. Enteric division Glial cells of the PNS Schwann Cells Satellite Cells The PNS and Schwann Cell Nodes of Ranvier: Are not covered by myelin Central Nervous System Glial cells of CNS Astrocytes – Nutrition Ependymal – barrier Microgilia – Immune Oligodendrocytes – Myelin An overview of glial cells Remember the neuron… Communicates information throughout the body, but how? Another picture of vertebrate neuron By Action Potentials! Action Potentials are our nerve impulses. It’s all to do with communication. We can look at an action potential as an electrical event. First we remember how ions influence the membrane potential (Em) of a cell. Is the charge across this cell zero? Permeable only to K+ K+ Chemical gradient Electrical Force K+ Large non-diffusible anionic proteins Volt meter No! It is –90 mV! Why? Now let’s try to think about a living excitable cell… Resting Neuron Membrane Potential Volt meter Now what does the volt meter read? -70 mV at rest but the Em can change when a nerve is “excited”. But why do we care about these values? A change in Em results in NT release! But how does this change in charge occur so that the neurotransmitter can be released? A simple flow chart of electrical events Graded potentials Action potentials Neurotransmitter release Graded potentials decrease in strength as they spread out from the point of origin but may bring about an action potential. The end of Part 1
