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Neurons and Glia

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Neurons and Glia Chapter 2 Pg 32-57 Obstacles to Study Cells are too small to see. To study brain tissue with a microscope, thin slices are needed but the brain is ... – PowerPoint PPT presentation

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Title: Neurons and Glia


1
Neurons and Glia
  • Chapter 2
  • Pg 32-57

2
Obstacles to Study
  • Cells are too small to see.
  • To study brain tissue with a microscope, thin
    slices are needed but the brain is like jello.
  • Formaldehyde used to fix or harden tissue early
    in 19th century.
  • Brain tissue is all the same color
  • Nissl stain revealed cell bodies
    cytoarchitecture
  • Golgi stain revealed parts of the neuron.

3
Golgi stain shows cell structure
4
Brodmann Areas
  • Different areas of the brain with different
    functions have different kinds of neurons.
  • Brodmann mapped the areas based on the kinds of
    cells found
  • Cytoarchitectonic method
  • 52 functionally distinct areas identified by
    number.

5
Ramon y Cajals Principles
  • Neuron doctrine neurons are like other cells.
  • Principle of dynamic polarization electrical
    signals flow in only one, predictable direction
    within the neuron.
  • Principle of connectional specificity
  • Neurons are not connected to each other, but are
    separated by a small gap (synaptic cleft).
  • Neurons communicate with specific other neurons
    in organized networks not randomly.

6
Neuronal Circuits
  • Neurons send and receive messages.
  • Neurons are linked in pathways called circuits
  • The brain consists of a few basic patterns of
    circuits with many minor variations.
  • Circuits can connect a few to 10,000 neurons.

7
Parts of the Neuron
  • Soma the cell body
  • Neurites two kinds of extensions (processes)
    from the cell
  • Axon
  • Dendrites
  • All parts of the cell are made up of protein
    molecules of different kinds.

8
How Neurons Communicate
  • An all-or-nothing electrical signal, called an
    action potential, travels down the axon.
  • The amplitude (size) of the action potential
    stays constant because the signal is regenerated.
  • The speed of the action potential is determined
    by the size of the axon.
  • Action potentials are highly stereotyped (very
    similar) throughout the brain.
  • At the end of the axon (terminal button),
    neurotransmitter is released, which may start an
    action potential in another neuron.

9
The Synapse
  • The synapse is the point of contact between
    neurons.
  • Axon terminal button makes contact with some part
    of an adjacent neuron.
  • Synaptic vesicles containing neurotransmitter
    open when there is an action potential.
  • Neurotransmitter may enter the adjacent neuron
    unused neurotransmitter is reabsorbed (reuptake).

10
Dendrites
  • Dendrites function as the antennae of the neuron,
    receiving input from other neurons.
  • Dendrites are covered with synapses.
  • Each synapse has many receptors for
    neurotransmitters of various kinds.
  • Dendritic spines specialized dendrites that
    isolate reactions at some synapses.

11
Dendritic Spines
12
How to Tell Axons from Dendrites
  • Dendrites receive signals axons send them.
  • There are hundreds of dendrites but usually just
    one axon.
  • Axons can be very long (gt 1 m) while dendrites
    are lt 2 mm.
  • Axons have the same diameter the entire length
    dendrites taper.
  • Axons have terminals (synapses) and no ribosomes.
    Dendrites have spines (punching bags).
  • Dont be fooled by the branches both have them.

13
Ways of Classifying Neurons
  • By the number of neurites (processes)
  • Unipolar, bipolar, multipolar
  • By the type of dendrites
  • Pyramidal stellate (star-shaped)
  • By their connections (function)
  • Sensory, motor, relay interneurons, local
    interneurons (Golgi Type II neurons)
  • By neurotransmitter by their chemistry

14
Parts of the Soma (Cell Body)
  • Nucleus stores genes of the cell (DNA)
  • Organelles synthesize the proteins of the cell
  • Cytosol fluid inside cell
  • Plasmic membrane wall of the cell separating it
    from the fluid outside the cell.

15
Organelles
  • Mitochondria provide energy
  • Microtubules give the cell structure
  • Rough endoplasmic reticulum produces proteins
    needed to carry out cell functioning
  • Ribosomes produce neurotransmitter proteins
  • Smooth endoplasmic reticulum packages
    neurotransmitter in synaptic vesicles
  • Golgi apparatus Part of the smooth endoplasmic
    reticulum that sorts proteins for delivery to the
    axon and dendrites

16
Kinds of Cells
  • Neurons (nerve cells) signaling units
  • Glia (glial cells) supporting elements.
  • Miscellaneous other cells
  • Ependymal cells form the lining of the
    ventricles, also aid brain development
  • Microglia remove debris left by dead or
    degenerating neurons and glia.
  • Veins, arteries, and capillaries in the brain.

17
Functions of Glia
  • Separate and insulate groups of neurons
  • Produce myelin for the axons of neurons
  • Scavengers, removing debris after injury
  • Buffer and maintain potassium ion concentrations
  • Guide migration of neurons during development
  • Create blood-brain barrier, nourish neurons

18
Kinds of Glia
  • Oligodendrocytes surround brain spinal cord
    neurons and give them support.
  • In white matter, provides myelination
  • In gray matter, surround cell bodies
  • Schwann cells provide the myelin sheath for
    peripheral neurons (1 mm long).
  • Astrocytes absorb potassium, perhaps nutritive
    because endfeet contact capillaries (blood
    vessels), form blood-brain barrier.
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