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NERVOUS SYSTEM

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Title: NERVOUS SYSTEM


1
NERVOUS SYSTEM
2
NERVOUS FUNCTIONS
  • Bodys master controlling and communicating
    system
  • Three functions
  • Sensory input
  • Gathers information from sensory receptors
  • Integration
  • Processes and interprets sensory input
  • Motor output
  • Activates effector organs to cause a response

3
Nervous System Organization
4
ORGANIZATION
  • Two Principal Parts of the System
  • Central nervous system (CNS)
  • Brain and spinal cord
  • Integrating and command center
  • Interprets sensory input
  • Dictates motor responses
  • Peripheral nervous system (PNS)
  • Nerves extending from brain and spinal cord
  • Carry impulses to and from the CNS

5
PERIPHERAL DIVISIONS
  • Two Functional Subdivisions of the PNS
  • Sensory division
  • afferent division
  • Nerve fibers conveying impulses to the CNS
  • Somatic afferent fibers convey impulses from the
    skin, muscles, and joints
  • Visceral afferent fibers convey impulses from
    visceral organs
  • Motor division
  • , efferent division
  • Nerve fibers conveying impulses from the CNS

6
ORGANIZATION
7
HISTOLOGY
  • Nervous system consists mainly of nervous tissue
  • Highly cellular
  • e.g., lt20 extracellular space in CNS
  • Two principal cell types
  • Neurons
  • Excitable nerve cells that transmit electrical
    signals
  • Supporting cells
  • Smaller cells surrounding and wrapping neurons
  • Neuroglia

8
NEURONS
  • Nerve cells
  • Structural units of nervous system
  • Billions are present in nervous system
  • Conduct messages throughout body
  • Nerve impulses
  • Extreme longevity
  • Can function optimally for entire lifetime
  • Amitotic
  • Ability to divide is lost in mature cells
  • Cannot be replaced if destroyed
  • Some (very few) exceptions
  • e.g., stem cells present in olfactory epithelium
    can produce new neurons
  • Stem cell research shows great promise in
    repairing damaged neurons
  • High metabolic rate
  • Require large amounts of oxygen and glucose

9
Neurons
Dendrites of another neuron
Axon of anotherneuron
10
Collins I4 lines
  • Based on the diagram, what do you think each part
    does to receive and pass along an impulse toward
    the brain

11
Agenda11/3/11 Day 1
  • Take more notes
  • HW- vocab

12
NEURONS
  • Generally large, complex cells
  • Structures vary, but all neurons have the same
    basic structure
  • Cell body
  • Slender processes extending from cell body
  • Plasma membrane is site of signaling

13
NEURON CELL BODY
  • Most neuron cell bodies are located in the CNS
  • Protected by bones of skull or vertebral column
  • Clusters of cell bodies in the CNS are termed
    nuclei
  • Clusters of cell bodies in the PNS are termed
    ganglia

14
NEURON CELL BODY
  • Major biosynthetic (control) center of neuron
  • Other usual organelles present except CENTRIOLES
  • -Why?
  • What do centrioles do?

15
NEURON PROCESSES
  • Extend from the neurons cell body
  • Two types of neuron processes
  • Dendrites
  • Axons

16
NEURON PROCESSES
  • Typical Dendrite
  • Short, slender, branching extensions of cell body
  • Generally hundreds clustering close to cell body
  • Most cell body organelles also present in
    dendrites
  • Main receptive / input regions
  • Large surface area for receiving signals from
    other neurons
  • Convey incoming messages toward cell body

17
NEURON PROCESSES
  • Typical Axon
  • Single axon per neuron
  • The axon forms from the narrowing of the cell
    body. The region between the large cell body and
    the axon is the axon hillock
  • Sometimes very short
  • Sometimes very long
  • e.g., axons controlling big toe are 3 4 feet
    long

18
NEURON PROCESSES
  • Typical Axon
  • Single axon may branch along length
  • Axon collaterals extend from neurons at 90o
    angles
  • Usually branches profusely at end
  • 10,000 or more terminal branches is common
  • Distal endings termed axonal terminals

19
NEURON PROCESSES
  • Typical Axon
  • Conducting component of neuron
  • Generates nerve impulse
  • Transmits nerve impulses away from cell body
    towards the
  • axonal terminals

20
NEURON PROCESSES
  • Typical Axon terminal
  • Axonal terminals are secretory component of
    neuron
  • Sequence of events
  • Signal reaches terminals
  • Membranes of vesicles fuse with plasma membrane
  • Neurotransmitters released
  • Neurotransmitters interact with either other
    neurons or effector cells
  • Excite or inhibit

21
VocabularyEither in flash card form OR in list
  • CNS
  • PNS
  • Neuron
  • Stimulus
  • Afferent division
  • Efferent division
  • neuroglia
  • Amitotic
  • Dendrite
  • Cell body
  • Axon
  • Axon terminal
  • Ganglia
  • Nuclei (in terms of clusters)

22
Collins I2 lines
  • What is the difference between the PNS and the
    CNS?

23
Agenda11/4/11 -- Day 2
  • Remember quiz 11/9
  • Take notes
  • Complete labeling and coloring of neuroglia
  • HW-complete ALL vocab terms

24
MYELIN SHEATH
  • Whitish, fatty covering the axons of many neurons
  • Protects and electrically insulates fibers
  • Increases speed of nerve impulse transmission
  • Some axons and all dendrites are unmyelinated

25
MYELIN SHEATH
  • In PNS, Schwann cells Continually wrap around the
    axon of a neuron
  • Result is many concentric layers of plasma
    membrane surrounding the axon
  • Thickness depends on number of wrappings
  • Nucleus and most of cytoplasm exist as a bulge
    external to the myelin sheath

26
Myelin sheath and schwann cells
Node of Ranvier
Schwann Cells
27
MYELIN SHEATH
  • Adjacent Schwann cells on axon do not touch each
    other
  • Gaps in sheath occur at regular intervals
  • Nodes of Ranvier
  • Axon collaterals can emerge at these nodes

28
MYELIN SHEATH
  • In CNS, there are both myelinated and
    unmyelinated axons
  • Oligodendrocytes, not Schwann cells, form CNS
    myelin sheaths
  • Numerous processes that can coil around numerous
    (up to 60) axons at once

29
NEUROGLIA
  • Nerve glue
  • Six types of small cells associated with neurons
  • 4 in CNS
  • 2 in PNS
  • Several functions
  • Supportive scaffolding for neurons
  • Electrical isolation of neurons
  • Neuron health and growth

30
CNS NEUROGLIA
  • Astrocytes
  • Microglia
  • Ependymal cells
  • Oligodendrocytes

31
CNS NEUROGLIA
  • Astrocytes
  • Anchor neurons to capillary blood supply
  • Facilitate nutrient delivery to neurons
  • (blood ? astrocyte ? neuron)

32
CNS NEUROGLIA
  • Microglia
  • Small ovoid cells thorny looking
  • Transform into macrophage
  • Phagocytize microorganisms, debris
  • (Cells of immune system cannot enter the CNS)

33
CNS NEUROGLIA
  • Oligodendrocytes
  • Wrap processes tightly around thicker neuron
    fibers in CNS
  • Makes Myelin sheath
  • Insulating covering

34
CNS NEUROGLIA
  • Ependymal Cells
  • Line central cavities of brain and spinal cord
  • Many are ciliated
  • Beating helps circulate cerebrospinal fluid
    cushioning brain and spinal cord

35
PNS NEUROGLIA
  • Schwann cells
  • Surround and form myelin sheaths around larger
    neurons of PNS
  • Functionally similar to oligodendrocytes

36
PNS NEUROGLIA
  • Satellite cells
  • Surround cell bodies of PNS ganglia

37
HW- Vocab Terms
  • Myelin sheath
  • Schwann cells
  • Nodes of ranvier
  • Oligodendrocytes
  • Neuroglea
  • Astrocyte
  • Microglia
  • Ependymal cell
  • Satalite cell

38
MYELIN SHEATH
  • White matter
  • Regions of the brain and spinal cord containing
    dense collections of myelinated fibers
  • Gray matter
  • Regions of the brain and spinal cord containing
    mostly nerve cell bodies and unmyelinated fibers

39
NEURON CLASSIFICATION
  • Structural classification based upon number of
    processes
  • Multipolar neurons
  • Bipolar neurons
  • Unipolar neurons
  • Functional classification based upon direction
    nerve impulse travels
  • Sensory (afferent) neurons
  • Motor (efferent) neurons
  • Interneurons (association neurons)

40
NEURON CLASSIFICATION
  • Unipolar neurons
  • Single short process
  • Process divides into proximal and distal branches
  • Distal process often associated with a sensory
    receptor
  • Peripheral process
  • Central process enters CNS
  • Most are sensory neurons in PNS
  • Structural Classification
  • Multipolar neurons
  • Three or more processes
  • Most common neuron type in humans
  • (gt 99 of neurons)
  • Bipolar neurons
  • Two processes axon and dendrite
  • Found only in some special sense organs
  • e.g., retina of eye
  • Act as receptor cells

41
Classification of neurons by shape
42
NEURON CLASSIFICATION
  • Functional Classification
  • Sensory (afferent) neurons
  • Transmit impulses toward CNS
  • From sensory receptors or internal organs
  • Most are unipolar
  • Cell bodies are located outside CNS
  • Motor (efferent) neurons
  • Carry impulses away from CNS
  • Toward effector organs
  • Multipolar
  • Cell bodies generally located in the CNS
  • Interneurons
  • a.k.a., association neurons
  • Lie between motor and sensory neurons in neural
    pathways
  • Shuttle signals through CNS pathways where
    integration occurs
  • gt 99 of neurons in body
  • Most are multipolar
  • Most are confined within the CNS

43
NEUROPHYSIOLOGY
  • Neurons are highly irritable
  • Responsive to stimuli
  • Response to stimulus is action potential
  • Electrical impulse carried along length of axon
  • Always the same regardless of stimulus
  • The underlying functional feature of the nervous
    system

44
ION CHANNELS
  • Plasma membranes contain various ion channels
  • Passive channels (leakage channels)
  • Always open
  • Active channels (gated channels)
  • Ligand-gated channels
  • Open when specific chemical binds
  • Voltage-gated channels
  • Open and close in response to membrane potential
  • Mechanically-gated channels
  • Open in response to physical deformation of
    receptor
  • e.g., touch and pressure receptors

45
MEMBRANE POTENTIALS
  • A voltage exists across the plasma membrane
  • Due to separation of oppositely charged ions
  • Potential difference in a resting membrane is
    termed its resting membrane potential
  • -70 mV in a resting neuron
  • Membrane is polarized

46
MEMBRANE POTENTIALS
  • Neurons use changes in membrane potentials as
    signals
  • Used to receive, integrate, and send signals
  • Changes in membrane potentials produced by
  • Anything changing membrane permeability to ions
  • Anything altering ion concentrations
  • Two types of signals
  • Graded potentials
  • Short-distance signals
  • Action potentials
  • Long-distance signals

47
MEMBRANE POTENTIALS
  • Graded Potentials
  • Short-lived local changes in membrane potential
  • Either depolarizations or hyperpolarizations
  • Cause current flows that decrease in magnitude
    with distance
  • Magnitude of potential dependent upon stimulus
    strength
  • Stronger stimulus ? larger voltage change
  • Larger voltage change ? farther current flows

48
MEMBRANE POTENTIALS
  • Graded Potentials
  • Triggered by change in neurons environment
  • Change causes gated ion channels to open
  • Small area of neurons plasma membrane becomes
    depolarized (by this stimulus)
  • Current flows on both sides of the membrane
  • moves toward and vise versa

49
MEMBRANE POTENTIALS
  • Graded Potentials
  • Inside cell ions move away from depolarized
    area
  • Outside cell ions move toward depolarized area
  • ( and ions switch places)
  • Membrane is leaky
  • Most of the charge is quickly lost through
    membrane
  • Current dies out after traveling a short distance

50
MEMBRANE POTENTIALS
  • Graded Potentials
  • Act as signals over very short distances
  • Important in initiating action potentials

51
MEMBRANE POTENTIALS
  • Action Potentials
  • Principal means by which neurons communicate
  • Brief reversal of membrane potential
  • Total amplitude of 100 mV (-70 ? 30)
  • Depolarization followed by repolarization, then
    brief period of hyperpolarization
  • Time for entire event is only a few milliseconds
  • Events in generation and transmission of an
    action potential identical between neurons and
    skeletal muscle cells

52
ACTION POTENTIALS
53
ACTION POTENTIALS
  • Not all local depolarizations produce action
    potentials
  • Depolarization must reach threshold values
  • Brief, weak stimuli produce sub threshold
    depolarizations that are not translated into
    nerve impulses
  • Stronger threshold stimuli produce depolarizing
    events

54
ACTION POTENTIALS
  • Action potential is all-or-nothing phenomenon
  • Happens completely or doesnt happen
  • Independent of stimulus strength once generated
  • Strong stimuli generate more impulses of the same
    strength per unit time
  • Intensity is determined by number of impulses per
    unit time

55
ACTION POTENTIALS
  • Multiple Sclerosis (MS)
  • Autoimmune disease mainly affecting young adults
  • Myelin sheaths in CNS are gradually destroyed
  • Interferes with impulse conduction
  • Visual disturbances, muscle control problems,
    speech disturbances, etc.
  • Some modern treatments showing some promise in
    delaying problems

56
SYNAPSE
  • Nerve impulse reaches axonal terminal
  • Voltage-gated Ca2 channels open in axon
  • Ca2 enters presynaptic neuron
  • Neurotransmitter is released via exocytosis
  • Vesicles fuse with axonal membrane
  • Neurotransmitter binds to postsynaptic receptors
  • Ion channels open in postsynaptic membrane
  • Result is excitation or inhibition

57
SYNAPSE
  • Binding of neurotransmitter to its receptor is
    reversible
  • Permeability affected as long as neurotransmitter
    is bound to its receptor
  • Neurotransmitters do not persist in the synaptic
    cleft
  • Degraded by enzymes associated with postsynaptic
    membrane
  • Reuptake by astrocytes or presynaptic terminal
  • Diffusion of neurotransmitters away from synapse

58
NEUROTRANSMITTERS
  • More than fifty neurotransmitters identified
  • Most neurons make two or more
  • Can be released singly or together
  • Classification by Structure
  • Acetylcholine (ACh)
  • Biogenic amines
  • Amino acids
  • Peptides
  • ATP
  • Dissolved gases
  • Classification by Function
  • Excitatory/Inhibitory
  • Direct/Indirect
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