Nervous Tissue and The Nervous System PDF

Summary

These lecture notes cover the nervous tissue and nervous system. They include anatomical and functional divisions, types of neurons, glial cells and nerve impulses.

Full Transcript

Nervous Tissue
and
The Nervous System
The Nervous System
the most complex system in the body
formed by a network of many billion nerve cells
(neurons), assisted by many more supporting cells called
glial cells two
Anatomically, the two major divisions:
Central nervous system (CNS)
1. brain
2. spinal cord
Peripheral nervous system (PNS) conducting impulses
to and from the CNS (sensory and motor nerves,
respectively) and ganglia that are small aggregates of
nerve cells outside the CNS.
1. cranial nerves
2. spinal nerves
3. peripheral nerves
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The Nervous System
Functionally, the two major divisions:
1. Sensory division (afferent)
Somatic – sensory input perceived consciously (eg,
from eyes ears, skin, musculoskeletal structures)
Visceral – sensory input not perceived consciously
(eg, from internal organs and cardiovascular
structures)
2. Motor division (efferent)
Somatic – motor output controlled consciously or
voluntarily (eg, by skeletal muscle effectors)
Autonomic – motor output not controlled
consciously (eg, by heart or gland effectors)

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 The Nervous System
Autonomic – motor output not controlled consciously (eg, by heart or gland effectors)

ANS have pathways involving two neurons:
1. a preganglionic neuron with the cell body in the CNS
2. postganglionic neuron with the cell body in a ganglion.

ANS has two divisions:
(1) The parasympathetic division
with its ganglia within or near the effector organs
maintains normal body homeostasis.

(2) The sympathetic division
has its ganglia close to the CNS
controls the body’s responses during emergencies and excitement.

ANS components located in the wall of the digestive tract are sometimes referred to as the
enteric nervous system. Nervous Tissue
 Development of the Neural Tissue : NEURULATION
The nervous system develops from the
outermost of the three early embryonic layers,
the ectoderm
begins in the third week of development
The notochord signals the ectoderm on the mid-
dorsal side of the embryo to thicken to form the
epithelial neural plate.
The sides of this plate fold upward and grow
toward each other medially, and within a few
days fuse to form the neural tube.
the neural crest separates from the
neuroepithelium and becomes mesenchymal.
Neural crest cells migrate extensively and
differentiate as all the cells of the PNS, as well as
a number of other non-neuronal cell types. Nervous Tissue
The Nervous System
Kinds of cells in the Nervous System
1. NEURONS
The functional unit of the nervous system
Usually has long processes
Neurons respond to environmental changes (stimuli) by altering the ionic gradient that
exists across their plasma membranes.
All cells maintain electrical potential, but cells that can rapidly change this potential in
response to stimuli (eg, neurons, muscle cells, some gland cells) are said to be excitable
or irritable.
Neurons react promptly to stimuli with a reversal of the ionic gradient (membrane
depolarization)

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 The Nervous System
Kinds of NEURONS in the Nervous System
SENSORY NEURONS
Afferent
stimuli from receptors throughout the body.
MOTOR NEURONS
are efferent
sending impulses to effector organs such as muscle fibers and glands.
Somatic motor nerves
Under voluntary control and typically innervate skeletal muscle
Autonomic motor nerves
control the involuntary unconscious activities of glands, cardiac muscle, and most smooth muscle.
Interneurons
establish relationships among other neurons, forming complex functional networks or Circuits in the CNS.
Interneurons are either multipolar or anaxonic and
comprise 99% of all neurons in adults.
In the CNS most neuronal perikarya occur in the gray matter, with their axons concentrated in the white matter.
In the PNS cell bodies are found in ganglia and in some sensory regions, such as the olfactory mucosa,Nervous
and axons
Tissueare bundled in ner
 The Nervous System
cells in the Nervous System
In the CNS most neuronal perikarya occur in the gray matter, with their axons concentrated in the white matter.
In the PNS cell bodies are found in ganglia and in some sensory regions, such as the olfactory mucosa, and axons are bundled
in nerves.

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The Nervous System
PARTS OF A NEURON
1. cell body (also called the perikaryon or soma)
which contains the nucleus and most of the cell’s organelles
and serves as the synthetic or trophic center for the
entire neuron.
2. Dendrites
the numerous elongated processes extending from the perikaryon
receive stimuli from other neurons at unique sites called synapses.
3. axon (Gr. axon, axis)
a single long process ending at synapses specialized to generate
and conduct nerve impulses to other cells (nerve, muscle, and
gland cells
may also receive information from other neurons
that mainly modifies the transmission of action potentials to those
neurons

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 The Nervous System
Neurons can be classified according to the number of processes extending from the cell body
1. Multipolar neurons
with one axon and two or more dendrites
the most common.
2. Bipolar neurons
with one dendrite and one axon
comprise the sensory neurons of the retina, the olfactory
epithelium, and the inner ear.
3. Unipolar or pseudounipolar neurons
Include all other sensory neurons, each have a single
process that bifurcates close to the perikaryon, with the
longer branch extending to a peripheral ending and the
other toward the CNS.
4. Anaxonic neurons
with many dendrites but no true axon, do not produce
action potentials, but regulate electrical changes of
adjacent CNS neurons
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Cell Body (Perikaryon or Soma)

contains the nucleus and cytoplasm, exclusive of the cell
processes
acts as a trophic center, producing most cytoplasm for the
processes.
Most cell bodies are in contact with a great number of nerve
endings conveying excitatory or inhibitory stimuli generated
in other neurons.
neuron has an unusually large, euchromatic nucleus with a
prominent nucleolus, indicating intense synthetic activity.
Cytoplasm
contains free polyribosomes and highly developed RER
Nissl substance, Nissl bodies
Basophilic chromatophilic substance that are regions with
concentrated RER and other polysomes
abundant in large nerve cells such as motor neurons

The Golgi apparatus is located only in the cell body, but
mitochondria can be found throughout the cell and are
usually abundant in the axon terminals.

Nervous Tissue
DENDRITES

are typically short, small processes
emerging and branching off the
soma
Usually covered with many
synapses, dendrites are the principal
signal reception and processing
sites on neurons.
The large number and extensive
arborization of dendrites allow a
single neuron to receive and
integrate signals from many other
nerve cells.

Nervous Tissue
AXONS

Most neurons have only one axon, typically
longer than its dendrites.
Axons of the motor neurons that innervate
the foot muscles have lengths of nearly a
meter
The plasma mem brane of the axon is called
the axolemma
The contents are known as axoplasm.
Axons originate from a pyramid-shaped
region of the perikaryon called the axon
hillock
branch less profusely than dendrites, but do
undergo terminal arborization
small axonal branch ends with a dilation ,
Terminal bouton that contacts another
neuron or non-nerve cell at a synapse to
initiate an impulse in that cell

Nervous Tissue
NERVE IMPULSES

A nerve impulse, or action potential, travels along an axon
like a spark moves along an explosive’s fuse.
an electro chemical process initiated at the axon hillock
when other impulses received at the cell body or dendrites
meet a certain threshold.
The action potential is propagated along the axon as a wave
of membrane depolarization produced by voltage-gated Na+
and K+ channels in the axolemma that allow diffusion of
these ions into and out of the axoplasm.
The xtracellular compartment around all regions of the
neuron is a very thin zone immediately outside the cell that
is formed by enclosing glial cells which also regulate its ionic
contents.
In unstimulated neurons ATP-dependent Na-K pumps and
other membrane proteins maintain an axoplasmic Na+
concentration only one-tenth of that outside the cell and a
K+ level many times greater than the extracellular
concentration.
This produces a potential electrical difference across the
axolemma of about –65 mV, with the inside negative to the
outside.
This difference is the axon’s resting potential.

Nervous Tissue
NERVE IMPULSES

When the threshold for triggering an
impulse is met, channels at the axon’s
initial segment open and allow a very
rapid influx of extracellular Na+ that
makes the axoplasm positive in relation
to the extracellular environment
Shifts (depolarizes) the resting potential
from negative to positive, to +30 mV.
after the membrane depolarization, the
voltage-gated Na+ channels close and
those for K+ open, which rapidly returns
the membrane to its resting potential.

occurs in less than 1 millisecond.

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SYNAPTIC COMMUNICATION

Synapses are sites where nerve
impulses are transmitted from one
neuron to another, or from neurons
and other effector cells.
ensures that transmission is
unidirectional
Synapses convert an electrical
signal (nerve impulse) from the
presynaptic cell into a chemical
signal that affects the postsynaptic
cell.
Most synapses act by releasing
neurotransmitters to either open or
close ion channels or initiate second
messenger cascades.
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SYNAPTIC COMMUNICATION

A synapse has the following components:
1. presynaptic axon terminal (terminal bouton)
contains mitochondria and numerous synaptic vesicles from
which neurotransmitter is released by exocytosis
contain a large number of synaptic vesicles containing
eurotransmitters, numerous mitochondria, and smooth ER
as asource of new membrane.
Upon arrival of a nerve impulse, voltage-regulated Ca2+
channels permit Ca2+ entry that triggers neurotransmitter
release into the synaptic cleft.
2. The postsynaptic membrane
contains the neurotransmitter receptors and mechanisms to
initiate an impulse at the postsynaptic neuron.
postsynaptic cell membrane contains receptors for the
neurotransmitter, and ion channels or other mechanisms to
initiate a new impulse.
At the presynaptic region the nerve impulse briefly opens
calcium channels, promoting a Ca2+ influx that triggers
neurotransmitter release by exocytosis
Immediately the released neurotransmitter molecules diffuse
across the synaptic cleft and bind receptors at the post
synaptic region.

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SYNAPTIC COMMUNICATION

Immediately the released neurotransmitter
molecules diffuse across the synaptic cleft and
bind receptors at the post synaptic region.
This produces either an excitatory or an
inhibitory effect at the postsynaptic
membrane:
Neurotransmitters from excitatory synapses
cause postsynaptic Na+ channels to open, and
the resulting Na+ influx initiates a
depolarization wave in the postsynaptic neuron
or effector cell
At inhibitory synapses neurotransmitters
open Cl- or other anion channels, causing
influx of anions and hyperpolarization of the
postsynaptic cell, making its membrane
potential more negative and more resistant to
depolarization. Nervous Tissue
 The Nervous System
GLIAL CELLS
Glial cells support neuronal survival and activities
ten times more abundant than neurons in the mammalian brain.
Like neurons most glial cells develop from progenitor cells of the embryonic neural plate.

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 The Nervous System
GLIAL CELLS
1. OLIGODENCROCYTES

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GLIAL CELLS
1. OLIGODENDROCYTES
Oligodendrocytes extend many processes, each of which
becomes sheet-like and wraps repeatedly around a portion
of a nearby CNS axon
most cytoplasm gradually moves out of the growing
extension, leaving multiple compacted layers of cell
membrane collectively termed myelin.
An axon’s full length is covered by the action of many
oligodendrocytes.
The resulting myelin sheath electrically insulates the axon
and facilitates rapid transmission of nerve impulses.
Found only in the CNS
are the predominant glial cells in white matter, which is
white because of the lipid concentrated in the wrapped
membrane sheaths.
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 The Nervous System
GLIAL CELLS
2. ASTROCYTES
Also unique to the CNS
have a large number of long radiating, branching
processes
Astrocytes originate from progenitor cells in the
embryonic neural tube
most numerous glial cells of the brain, as well as the
most diverse structurally and functionally.
Fibrous astrocytes are abundant in white matter
predominate in the gray matter.

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 The Nervous System
GLIAL CELLS
3. EPENDYMAL CELLS
are columnar or cuboidal cells that line the fluid-
filled ventricles of the brain and the central canal
of the spinal cord
In some CNS locations, the apical ends of
ependymal cells have cilia, which facilitate
the movement of cerebrospinal fluid (CSF), and long
microvilli, which are likely involved in absorption.

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 The Nervous System
GLIAL CELLS
4. MICROGLIA
Less numerous than oligodendrocytes or astrocytes
microglia are small cells with actively mobile processes
evenly distributed throughout gray and white matter
Microglial cells also constitute the major mechanism of
immune defense in the CNS,
removing any microbial invaders and secreting a number of
immunoregulatory cytokines.
from circulating blood monocytes,

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 The Nervous System
GLIAL CELLS
5. SCHWANN CELLS
sometimes called neurolemmocytes
are found only in the PNS
differentiate from precursors in the neural crest.
Schwann cells are the counterparts to
oligodendrocytes of the CNS
Have trophic interactions with axons and most
importantly forming their myelin sheathes.
However unlike an oligodendrocyte
A Schwann cell forms myelin around a portion of
only one axon.

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GLIAL CELLS
6. SATELLITE CELLS OF THE GANGLIA
Also derived from the embryonic neural cres
small satellite cells form a thin, intimate glial
layer around each large neuronal cell body in the
ganglia of the PNS
exert a trophic or supportive effect on these
neurons, insulating, nourishing, and regulating
their microenvironments.

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 The Central Nervous System
There are organized areas of white matter and gray matter
Differences caused by the differential distribution of lipid-rich
myelin.
main components of white matter are myelinated axons often grouped together as tracts, and the
myelin-producing oligodendrocytes.
Astrocytes and microglia are also present, but very few neuronal cell bodies.
Gray matter contains abundant neuronal cell bodies, dendrites, astrocytes, and microglial cells,
and is where most synapses occur.
Gray matter makes up the thick cortex or surface layer of both the cerebrum the cerebellum
most white matter is found in deeper regions.
Deep within the brain are localized, variously shaped darker areas called the cerebral nuclei, each
containing large numbers of aggregated neuronal cell bodies.

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 The Central Nervous System
1. cerebral cortex
six layers of neurons with different sizes and shapes.
most conspicuous of these cells are the efferent pyramidal neurons
Neurons of the cerebral cortex function in the integration of
sensory information and the initiation of voluntary motor
responses.
2. cerebellar cortex
coordinates muscular activity throughout the body and is organized
with three layers
a. A thick outer molecular layer has much neuropil and scattered
neuronal cell bodies.
b. thin middle layer consists only of very large neurons called Purkinje
cells
c. thick inner granular layer contains various very small, densely
packed neurons and little neuropil.

Nervous Tissue
 The Central Nervous System
3. Spinal Cord
the white matter is peripheral and the gray matter forms a deeper, H-shaped mass
The two anterior projections of this gray matter, the anterior horns, contain cell bodies of very large motor neurons
whose axons make up the ventral roots of spinal nerves.
The two posterior horns contain interneurons which receive sensory fibers from neurons in the spinal (dorsal root)
ganglia.
Near the middle of the cord the gray matter surrounds a small central canal, which develops from the lumen of the
neural tube, is continuous with the ventricles of the brain, is lined by ependymal cells, and contains CSF.

Nervous Tissue
 The Peripheral Nervous System
MENINGES
1. DURA MATER
thick external dura mater
consists of dense irregular connective tissue organized as an
outer periosteal layer continuous with the periosteum of the
skull, and an inner meningeal layer
Around the spinal cord the dura mater is separated from the
periosteum of the vertebrae by the epidural space, which
contains a plexus of thin-walled veins and loose connective
tissue
The dura mater may be separated from the arachnoid by
formation of a thin subdural space.

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 The Peripheral Nervous System
MENINGES
2. ARACHNOID
has two components:
(1) a sheet of connective tissue in contact with the dura mater
and
(2) system of loosely arranged trabeculae composed of collagen
and fibroblasts, continuous with the underlying pia mater
layer.
Surrounding trabeculae is a large, sponge-like cavity, the
subarachnoid space, filled with CSF.
The subarachnoid space communicates with the ventricles of
the brain where the CSF is produced.
The connective tissue of the arachnoid is avascular but larger
blood vessels run through it

Nervous Tissue
 The Peripheral Nervous System
The main components of the
peripheral nervous system (PNS)
1. Nerves
2. Ganglia
3. nerve endings.

Nerves are bundles of nerve fibers
(axons) surrounded by Schwann
cells and layers of connective
tissue.

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 The Peripheral Nervous System
NERVE FIBERS
are analogous to tracts in the CNS
containing axons enclosed within
sheaths of glial cells specialized to
facilitate axonal function
axons are sheathed by Schwann
cells, or neurolemmocytes

The sheath may or may not form
myelin around the axons,
depending on their diameter.

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 The Peripheral Nervous System
MYELINATED NERVE FIBERS
As axons are engulfed along their length by a series of
differentiating neurolemmocytes and become
myelinated nerve fibers.
The plasma membrane of each covering Schwann cell
fuses with itself at an area termed the mesaxon and a
wide, flattened process of the cell continues to extend
itself, moving circumferentially around the axon many
times
The multiple layers of Schwann cell membrane unite
as a thick myelin sheath. Composed mainly of lipid
bilayers and membrane proteins, myelin is a large
lipoprotein complex

Nervous Tissue
 The Peripheral Nervous System
MYELINATED NERVE FIBERS
the myelin sheath serves to insulate axons and
maintain a constant ionic microenvironment
most suitable for action potentials.
NODES OF RANVIER
Nodal gaps adjacent Schwann cells on an axon the
myelin sheath
the axon is only partially covered by interdigitating
Schwann cell processes.
The axolemma is exposed to ions in the interstitial
fluid and has a much higher concentration of
voltage-gated Na+ channels, which renew the
action potential and produce saltatory conduction
of nerve impulses,
Allows rapid movement from node to node.
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 The Peripheral Nervous System
UNMYELINATED NERVE FIBERS
the smallest-diameter axons of peripheral
nerves are still enveloped within simple folds
of Schwann cells
the glial cell does not form the multiple
wrapping of a myelin sheath
In unmyelinated fibers, each Schwann cell
can enclose portions of many axons with
small diameters.
nodes of Ranvier are not seen along
unmyelinated nerve fibers.
their impulse conduction is not saltatory and
is much slower than that of myelinated
axons.
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 The Peripheral Nervous System
GANGLIA
ovoid structures containing neuronal
cell bodies and their surrounding glial
satellite cells supported by delicate
connective tissue and surrounded by a
denser capsule.
serve as relay stations to transmit
nerve impulses
The direction of the nerve impulse
determines whether the ganglion will
be a sensory or an autonomic ganglion.

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 The Peripheral Nervous System
SENSORY GANGLIA
Sensory ganglia receive afferent impulses that go
to the CNS.
Sensory ganglia are associated with both cranial
nerves (cranial ganglia) and the dorsal roots of
the spinal nerves (spinal ganglia).
The large neuronal cell bodies of ganglia are
associated with thin, sheet-like extensions of
small glial satellite cells
relay information from the ganglion’s nerve
endings to the gray matter of the spinal cord via
synapses with local neurons.

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 The Peripheral Nervous System
AUTONOMIC GANGLIA
Autonomic ganglia are small bulbous dilations in
autonomic nerves, usually with multipolar
neurons.
Some are located within certain organs,
especially in the walls of the digestive tract,
where they constitute the intramural ganglia.
The capsules of these ganglia may be poorly
defined among the sacral portion of the spinal
cord.

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