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Chapter 48 ~ Nervous System. The Nervous System Neurons Glial cells Soma Axon Dendrite Synapse Neurotransmitters Action potential Motor neurons Interneurons.

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Presentation on theme: "Chapter 48 ~ Nervous System. The Nervous System Neurons Glial cells Soma Axon Dendrite Synapse Neurotransmitters Action potential Motor neurons Interneurons."— Presentation transcript:

1 Chapter 48 ~ Nervous System

2 The Nervous System Neurons Glial cells Soma Axon Dendrite Synapse Neurotransmitters Action potential Motor neurons Interneurons Sensory neurons Myelin sheath Schwann cells Reflex arc http://outreach.mcb.harvard.edu/animations/synaptic.swf

3 Nervous systems Effector cells~ muscle or gland cells Nerves~ bundles of neurons wrapped in connective tissue Central nervous system (CNS)~ brain and spinal cord Peripheral nervous system (PNS)~ sensory and motor neurons

4 Structural Unit of Nervous System Neuron~ structural and functional unit Cell body~ nucelus and organelles Dendrites~ impulses from tips to neuron Axons~ impulses toward tips Myelin sheath~ supporting, insulating layer Schwann cells~PNS support cells Synaptic terminals~ neurotransmitter releaser Synapse~ neuron junction

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8 Simple Nerve Circuit Sensory neuron: convey information to spinal cord Interneurons: information integration Motor neurons: convey signals to effector cell (muscle or gland) Reflex: simple response; sensory to motor neurons Ganglion (ganglia): cluster of nerve cell bodies in the PNS Supporting cells/glia: nonconductiong cell that provides support, insulation, and protection http://msjensen.cehd.umn.edu/1135/Links/Animations/Flash/0016-swf_reflex_arc.swf

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10 Neural signaling Membrane potential (voltage differences across the plasma membrane) Intracellular/extracellular ionic concentration difference K+ diffuses out (Na+ in); large anions cannot follow….selective permeability of the plasma membrane Net negative charge of about -70mV http://bcs.whfreeman.com/thelifewire/content/chp44/4403s.swf http://outreach.mcb.harvard.edu/animations/actionpotential.swf

11 Neural signaling Excitable cells~ cells that can change membrane potentials (neurons, muscle) Resting potential~ the unexcited state of excitable cells Gated ion channels (open/close response to stimuli): photoreceptors; vibrations in air (sound receptors); chemical (neurotransmitters) & voltage (membrane potential changes) http://www.mind.ilstu.edu/curriculum/neurons_intro/flash_electrical.php?modGUI=232&compGUI=1827&itemGUI=3158 http://bcs.whfreeman.com/thelifewire/content/chp44/4402s.swf

12 Neural signaling Graded Potentials (depend on strength of stimulus): 1- Hyperpolarization (outflow of K+); increase in electrical gradient; cell becomes more negative 2- Depolarization (inflow of Na+); reduction in electrical gradient; cell becomes less negative

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14 Neural signaling Threshold potential: if stimulus reaches a certain voltage (-50 to -55 mV)…. The action potential is triggered…. Voltage-gated ion channels (Na+; K+) 1-Resting state both channels closed 2-Threshold a stimulus opens some Na+ channels 3-Depolarization action potential generated Na+ channels open; cell becomes positive (K+ channels closed) 4-Repolarization Na+ channels close, K+ channels open; K+ leaves cell becomes negative 5-Undershoot both gates close, but K+ channel is slow; resting state restored Refractory period~ insensitive to depolarization due to closing of Na+ gates

15 Neural signaling “Travel” of the action potential is self-propagating Regeneration of “new” action potentials only after refractory period Forward direction only Action potential speed: 1-Axon diameter (larger = faster; 100m/sec) 2-Nodes of Ranvier (concentration of ion channels) ; saltatory conduction; 150m/sec

16 Synaptic communication Presynaptic cell: transmitting cell Postsynaptic cell: receiving cell Synaptic cleft: separation gap Synaptic vesicles: neurotransmitter releasers Ca+ influx: caused by action potential; vesicles fuse with presynaptic membrane and release…. Neurotransmitter

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18 Signal transmission http://www.bayareapainmedical.com/neurtrns.html

19 Neurotransmitters Acetylcholine (most common) skeletal muscle Biogenic amines (derived from amino acids) norepinephrine dopamine serotonin Amino acids Neuropeptides (short chains of amino acids) endorphin http://www.blackwellpublishing.com/matthews/neurotrans.html

20 Nervous System Central Nervous System  Crainial Nerves  Spinal Nerves Peripheral Nervous System  Sensory (afferent) Division Sensing external environment Sensing internal environment  Motor (Efferent) Division Autonomic Nervous System  Sympathetic Nervous System  increase energy consumption  Parasympathetic Nervous System  conservation of energy Somatic Nervous System  voluntary, conscious control, muscles

21 Vertebrate PNS

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25 The Brain Meninges Cerebrospinal fluid Ventricles Brain Stem Medulla oblongata Pons midbrain Diencephalon Thalamus Hypothalamus Cerebellum

26 The Vertebrate Brain Forebrain  cerebrum~ memory, learning, emotion  cerebral cortex~ sensory and motor nerve cell bodies corpus callosum~ connects left (analytical) and right (creative) hemispheres  thalamus (main input/output from cerebrum); hypothalamus (hormone production)  Midbrain  inferior (auditory) and superior (visual) colliculi Hindbrain cerebellum ~coordination of movement medulla oblongata/ pons~autonomic, homeostatic functions

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28 Pituitary Gland Corpus Callosum

29 Cerebrum Cerebral hemispheres Cerebral cortex—”gray matter” Convolutions Cerebral lobes Frontal lobe— conscious thought and muscle control. Parietal Lobes— receive information from skin receptors. Occipital Lobe— receives visual input. Temporal Lobe—has areas for hearing and smelling.

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