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10.1: Introduction Cell types in neural tissue:
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. Cell types in neural tissue: Neurons – transmit impulses Neuroglial cells – many other functions Dendrites Cell body Nuclei of neuroglia Axon © Ed Reschke
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Divisions of the Nervous System
Central Nervous System (CNS) Brain Spinal cord Peripheral Nervous System (PNS) Cranial nerves Spinal nerves
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Divisions Nervous System
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. Central Nervous System (Brain and Spinal Cord) Peripheral Nervous System (Cranial and Spinal Nerves) Brain Cranial nerves Sensory division Sensory receptors Spinal cord Spinal nerves Motor division Somatic Nervous System Skeletal muscle Autonomic Nervous System Smooth muscle Cardiac muscle Glands (a) (b)
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10.1 Clinical Application Migraine
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10.2: General Functions of the Nervous System
Sensory Function Sensory receptors gather information Information is carried to the CNS Integrative Function Sensory information used to create sensations, memory, thoughts, decisions Motor Function Decisions are acted upon Impulses are carried to effectors Divisions of motor functions of PNS Somatic – transmits impulses to skeletal muscles Autonomic – transmits impulses to smooth muscles, cardiac muscle, and glands
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10.3: Description of Cells of the Nervous System
Neurons vary in size and shape They may differ in length and size of their axons and dendrites Neurons share certain features: Dendrites – receiving ends A cell body – contains nucleus An axon – transmits impulses and releases neurotransmitters to another neuron or effector
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Neuron Structure Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. Chromatophilic substance (Nissl bodies) Dendrites Cell body Nucleus Nucleolus Neurofibrils Axon hillock Impulse Axon Synaptic knob of axon terminal Nodes of Ranvier Myelin (cut) Nucleus of Schwann cell Axon Schwann cell Portion of a collateral
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Myelination of Axons Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. Axons which are tightly wrapped by neuroglial cells are termed myelinated. White Matter Contains myelinated axons Considered fiber tracts Gray Matter Contains unmyelinated structures Cell bodies, dendrites Dendrite Unmyelinated region of axon Myelinated region of axon Node of Ranvier Axon Neuron cell body Neuron nucleus (a) Enveloping Schwann cell Schwann cell nucleus Longitudinal groove Unmyelinated axon (c)
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10.2 Clinical Application Multiple Sclerosis
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10.4: Classification of Cells of the Nervous System
Neurons vary in function They can be sensory, motor, or integrative neurons Neurons vary in size and shape, and in the number of axons and dendrites that they may have Due to structural differences, neurons can be classified into three (3) major groups: Bipolar neurons Unipolar neurons Multipolar neurons
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Classification of Neurons: Structural Differences
Multipolar neurons 99% of neurons Many processes Most neurons of CNS Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. Dendrites Peripheral process Bipolar neurons Two processes Eyes, ears, nose Axon Direction of impulse Unipolar neurons One process Ganglia of PNS Sensory Central process Axon Axon (a) Multipolar (b) Bipolar (c) Unipolar
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Classification of Neurons: Functional Differences
Sensory Neurons Afferent Carry impulse to CNS Most are unipolar Some are bipolar Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. Central nervous system Peripheral nervous system Cell body Dendrites Sensory receptor Interneurons Link neurons Multipolar Located in CNS Cell body Axon (central process) Axon (peripheral process) Sensory (afferent) neuron Interneurons Motor (efferent) neuron Axon Effector (muscle or gland) Axon Motor Neurons Multipolar Carry impulses away from CNS Carry impulses to effectors Axon terminal
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Types of Neuroglial Cells in the CNS
1) Astrocytes CNS Scar tissue Aid metabolism of certain substances Induce synapse formation Connect neurons to blood vessels Part of Blood Brain Barrier 3) Microglia CNS Phagocytic cell 4) Ependyma or ependymal CNS Ciliated Line central canal of spinal cord Line ventricles of brain 2) Oligodendrocytes CNS Myelinating cell
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Types of Neuroglial Cells in the PNS
1) Schwann Cells Produce myelin found on peripheral myelinated neurons Speed up neurotransmission 2) Satellite Cells Support clusters of neuron cell bodies (ganglia)
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Types of Neuroglial Cells
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. Fluid-filled cavity of the brain or spinal cord Neuron Ependymal cell Oligodendrocyte Astrocyte Microglial cell Axon Myelin sheath (cut) Capillary Node of Ranvier
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Neuroglia and Axonal Regeneration
Neurons cannot divide If cell body is injured, the neuron usually dies If a peripheral axon is injured, it may regenerate
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10.5: The Synapse Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. Nerve impulses pass from neuron to neuron at synapses, moving from a pre-synaptic neuron to a post-synaptic neuron. Synaptic cleft Impulse Dendrites Axon of presynaptic neuron Axon hillock of Postsynaptic neuron Axon of presynaptic neuron Cell body of postsynaptic neuron Impulse Impulse
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Synaptic Transmission
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. Direction of nerve impulse Neurotransmitters are released when impulse reaches synaptic knob Synaptic vesicles Axon Presynaptic neuron Ca+2 Ca+2 Synaptic knob Cell body or dendrite of postsynaptic neuron Mitochondrion Synaptic vesicle Ca+2 Vesicle releasing neurotransmitter Axon membrane Neurotransmitter Synaptic cleft Polarized membrane Depolarized membrane (a)
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Animation: Chemical Synapse
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10.6: Cell Membrane Potential
A cell membrane is usually electrically charged, or polarized, so that the inside of the membrane is negatively charged with respect to the outside of the membrane (which is then positively charged). This is as a result of unequal distribution of ions on the inside and the outside of the membrane.
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Distribution of Ions Potassium (K+) ions are the major intracellular positive ions (cations). Sodium (Na+) ions are the major extracellular positive ions (cations). This distribution is largely created by the Sodium/Potassium Pump (Na+/K+ pump) but also by ion channels in the cell membrane.
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Resting Potential Resting Membrane Potential (RMP):
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. Resting Membrane Potential (RMP): 70 mV difference from inside to outside of cell It is a polarized membrane Inside of cell is negative relative to the outside of the cell RMP = -70 mV Due to distribution of ions inside vs. outside Na+/K+ pump restores High Na+ Low Na+ Impermeant negative ions High K+ Low K+ Cell body Axon Axon terminal (a) If we imagine a cell before the membrane potential diffusion of potassium ions out of the cell exceeds is established, concentration gradients are such that diffusion of sodium ions into the cell, causing a net loss of positive charge from the cell. + + + – + – – – + + + – – – + + – – – – – – – + + – – + + + + – + + – + –70 mV (b) The net loss of positive charges from the inside of the cell has left the inside of the cell membrane slightly negative compared to the outside of the difference (an electrical “potential difference”) is membrane, which is left slightly positive. This measured as –70 millivolts (mV) in a typical neuron, and is called the resting membrane potential. + + – – + + – High Na+ – Low Na+ Na+ – + – + Pump + – + – K+ + – – – Low K+ High K+ + + + – + – – + + – + – –70 mV is now aided, and potassium diffusion opposed, by the negative charge on (c) With the membrane potential established, sodium diffusion into the cell the inside of the membrane. As a result, slightly more sodium ions enter the cell than potassium ions leave, but the action of the sodium/potassium pump balances these movements, and as a result the concentrations of these ions, and the resting membrane potential, are maintained.
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Local Potential Changes
Caused by various stimuli: Temperature changes Light Pressure Environmental changes affect the membrane potential by opening a gated ion channel Channels are 1) chemically gated, 2) voltage gated, or 3) mechanically gated Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. Gate-like mechanism Protein Cell membrane Fatty acid tail (a) Channel closed Phosphate head (b) Channel open
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Local Potential Changes
Environmental changes can cause gated ion channels to open As ions then flow through the membrane, the membrane potential changes If membrane potential becomes more negative, it has hyperpolarized If membrane potential becomes less negative, it has depolarized Graded (or proportional) to intensity of stimulation reaching threshold potential Reaching threshold potential triggers voltage gated channels to open, causing an action potential Subthreshold depolarization will not result in action potential
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Action Potentials At rest, the membrane is polarized (RMP = -70)
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. Na+ Na+ Na+ Na+ Na+ Na+ Na+ Na+ Na+ Na+ Na+ K+ K+ K+ K+ K+ K+ K+ K+ –0 Threshold stimulus reached (-55) K+ K+ K+ K+ K+ K+ K+ K+ –70 Na+ Na+ Na+ Na+ Na+ Na+ Na+ Na+ Na+ Na+ Na+ (a) Sodium channels open and membrane depolarizes (toward 0) Na+ Na+ Na+ Na+ Na+ Na+ Na+ Na+ Na+ channels open K+ channels closed K+ Na+ Na+ Na+ K+ K+ K+ K+ K+ Threshold stimulus K+ K+ –0 K+ K+ K+ Na+ Na+ Na+ K+ K+ K+ K+ K+ –70 Potassium leaves cytoplasm and membrane repolarizes (+30) Na+ Na+ Na+ Na+ Na+ Na+ Na+ Na+ Region of depolarization (b) K+ K+ K+ Na+ Na+ Na+ Na+ Na+ Na+ Na+ Na+ K+ channels open Na+ channels closed K+ Na+ Na+ Na+ K+ K+ K+ K+ K+ –0 Brief period of hyperpolarization (-90) K+ Na+ Na+ Na+ K+ K+ K+ K+ K+ –70 K+ K+ K+ Na+ Na+ Na+ Na+ Na+ Na+ Na+ Na+ Region of repolarization (c)
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Action Potentials Trigger zone at first part of axon contains many voltage gated sodium channels Voltaged gated Na+ channels open in response to threshold As Na+ moves in the membrane depolarizes until it reaches +30 mV (action potential) Na+ channels close and K+ channels open K+ moves out and membrane repolarizes As membrane potential drops below -70mV, the membrane is hyperpolarized Active transport reestablishes the resting potential of -70mV as Na+ and K+ concentrations are maintained
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Action Potentials +40 Action potential +20 –20 Resting potential
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. +40 Action potential +20 –20 Resting potential reestablished Membrane potential (millivolts) –40 Resting potential –60 –80 Hyperpolarization 1 2 3 4 5 6 7 8 Milliseconds
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Animation: Action Potential Propagation in Myelinated Neurons
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Action Potentials A nerve impulse is the propagation of action potentials down the length of an axon. Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. Region of action potential + + + + + + + + + + + – – – – – – – – – + + – – – – – – – – – + + + + + + + + + (a) + + + + + + + + + – – – + + – – – – – – Direction of nerve impulse – – – + + – – – – – – + + + + + + + + + (b) + + + + + + + + + – – – – – – – + + – – – – – – – – – + + – – + + + + + + + + + (c)
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All-or-None Response If a neuron axon responds at all, it responds completely – with an action potential (nerve impulse) A nerve impulse is conducted whenever a stimulus of threshold intensity or above is applied to an axon All impulses carried on an axon are the same strength
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Refractory Period Absolute Refractory Period
Time when threshold stimulus does not start another action potential Relative Refractory Period Time when stronger threshold stimulus can start another action potential
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Impulse Conduction The speed of impulse conduction varies on different types of neurons. Myelinated axons transmit impulses through saltatory conduction, which is faster than impulses along unmyelinated axons. Thick axon fibers transmit faster impulses than thin axon fibers.
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Animation: Action Potential Propagation in Myelinated Neurons
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Animation: Action Potential Propagation in Unmyelinated Neurons
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Animation: The Nerve Impulse
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Factors Affecting Impulse Conduction
10.3 Clinical Application Factors Affecting Impulse Conduction
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10.7: Synaptic Transmission
This is where released neurotransmitters cross the synaptic cleft and react with specific molecules called receptors in the postsynaptic neuron membrane. Effects of neurotransmitters vary. Some neurotransmitters may open ion channels and others may close ion channels. Chemically gated ion channels respond to neurotransmitter, creating synaptic potentials.
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Neurotransmitters
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Neurotransmitters
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Neuropeptides Neurons in the brain or spinal cord synthesize neuropeptides. Some neuropeptides act as neurotransmitters. Other neuropeptides act as neuromodulators (substances which alter a neuron’s response to a neurotransmitter or block the release of a neurotransmitter) Examples of neuropeptides include: Enkephalins Beta endorphin Substance P
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Opiates in the Human Body
10.4 Clinical Application Opiates in the Human Body
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10.8: Impulse Processing The way the nervous system processes nerve impulses and acts upon them reflects the organization of neurons and axons in the CNS
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Neuronal Pools Groups of interneurons that make synaptic connections with each other Interneurons work together to perform a common function Each pool receives input from other neurons Each pool generates output to other neurons Facilitation may occur
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Convergence Neuron receives input from several neurons
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. Neuron receives input from several neurons Incoming impulses represent information from different types of sensory receptors Allows nervous system to collect, process, and respond to information Makes it possible for a neuron to sum impulses from different sources 2 1 3 (a)
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Divergence One neuron sends impulses to several neurons
Can amplify an impulse Impulse from a single neuron in CNS may be amplified to activate enough motor units needed for muscle contraction Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. 4 6 5 (b)
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10.5 Clinical Application Drug Addiction
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Important Points in Chapter 10: Outcomes to be Assessed
10.1: Introduction Describe the general functions of the nervous system. Identify the two types of cells that comprise nervous tissue. Identify the two major groups of nervous system organs. 10.2: General Functions of the Nervous System List the functions of sensory receptors. Describe how the nervous system responds to stimuli. 10.3: Description of Cells of the Nervous System Describe the parts of a neuron.
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Important Points in Chapter 10: Outcomes to be Assessed
Describe the relationships among myelin, the neurilemma, and the nodes of Ranvier. Distinguish between the sources of white matter and gray matter. 10.4: Classification of Cells of the nervous System Identify structural and functional differences among neurons. Identify the types of neuroglia in the central nervous system and their functions. Describe the role of Schwann cells in the peripheral nervous system. 10.5: The Synapse Explain how information passes from a presynaptic to a postsynaptic neuron.
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Important Points in Chapter 10: Outcomes to be Assessed
10.6: Cell Membrane Potential Explain how a cell membrane becomes polarized. Describe the events leading to the generation of an action potential. Explain how action potentials move down an axon. Compare impulse conduction in myelinated and unmyelinated neurons. 10.7: Synaptic Transmission Identify the changes in membrane potential associated with excitatory and inhibitory neurotransmitters. Explain what prevents a postsynaptic cell from being continuously stimulated.
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Important Points in Chapter 10: Outcomes to be Assessed
10.8: Impulse Processing Describe the basic ways in which the nervous system processes information.
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Quiz 10 Complete Quiz 10 now! Read Chapter 11.
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