ANAT2411-2022 - Nervous Tissue - Lecture Slides - RS.pdf

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ANAT2241

Histology: Basic & Systematic

Nervous Tissue

Dr. Reza Shirazi
Department of Anatomy, School of Medical Sciences
Faculty of Medicine & Health, UNSW Sydney
[email protected]

Image by Dr John Abramyan, University of Michigan

Resources

Recommended reading:
Textbook chapter (Wheather's online): Nervous System
Textbook chapter (Junqueira’s Basic Histology: Text and Atlas, 15e online): Nervous Tissue
Nervous System Online Support Page
University of Michigan Histology and Virtual Microscopy
Learning Resources
Chapman Histology
https://www.youtube.com/channel/UCvSvCkHjCbHn8aGd6OPno_A/featured

Learning Objectives
1. To describe the parts of the neuron
2. To understand the classifications of the neurons
3. To understand the synaptic communications
4. To know the basic histological features of glial cells

Nervous Tissue

Nervous tissue:
Distributed throughout the body as an
integrated communications network
Composed of:
1- Cells:
I.
Nerve cells/Neurons
II. Supporting cells/Neuroglial
cells

2- Extracellular matrix (ECM)
o Very small amount

Nerve cells/Neurons

Respond to environmental changes
(stimuli) by altering the ionic gradient
that exists across their plasma
membranes
Neurons are excitable or irritable cells:
• Cells that can rapidly change the
electrical potential (ionic gradient
across the cell membrane) in
response to stimuli (eg, neurons,
muscle cells, some gland cells)
Action potential (nerve impulse):
• Reversal of the ionic gradient as
membrane depolarization
(depolarization wave) spreading in
the neuron’s plasma membrane

Nerve cells/Neurons

The functional unit in both the CNS and
PNS

Composed of 3 parts:
1- Cell body (or perikaryon or soma)
2- Neurites (nerve fibers)
I.
Dendrites
II. Axon

Cell body (Perikaryon or Soma)

•

Containing the nucleus and most of
the cell’s organelles

•

Large, with a large, euchromatic
nucleus and well-developed
nucleolus indicating intense
synthetic activity

•

Serves as the synthetic or trophic
center for the entire neuron

•

Contains chromatophilic substance
called Nissl substance or Nissl
bodies:
o Large masses of free
polysomes and RER
o Basophilic
o Abundant in large nerve cells
such as motor neurons

Cell body (Perikaryon or Soma)

•

Golgi apparatus: located only in the
cell body

•

Mitochondria: can be found
throughout the cell and are usually
abundant in the axon terminals

•

Microtubules, actin filaments and
intermediate filaments in
perikaryon and its processes (axon
and dendrites):
o Neurofilaments (or
neurofibrils): intermediate
filaments

•

Contain inclusions of pigmented
material, such as lipofuscin

Dendrites

•

Numerous elongated processes

•

Extend from the perikaryon

•

Specialized to receive stimuli from
other neurons at unique sites
called synapses

•

Usually covered with many synapses

•

Become much thinner as they
branch

•

Contain dendritic spines in CNS:
o Dynamic membrane
protrusions along the small
dendritic branches

Axon

•
•

Axolemma: plasma membrane of
the axon
Axoplasm: cytoplasm of the axon

•

A single long process ending at
synapses

•

Specialized to generate and conduct
nerve impulses to other cells (eg,
nerve, muscle, and gland cells)

Axon

•

Originated from axon hillock of the
perikaryon

•

Initial segment:
o Just beyond the axon hillock
containing concentrated ion
channels that generate the
action potential

•

Undergo terminal arborization:
o Each small axonal branch ends
with a dilation called
a terminal bouton

Classification of the Neurons

Classified in many different ways:
Function:
• Sensory (afferent)
• Motor (efferent)
• Interneuron
Location:
• Cortical
• Spinal
Neurotransmitter:
• Glutamatergic
• Cholinergic
Morphology:
• Pyramidal
• Granule
• Mitral
OR
• Multipolar
• Bipolar
• Unipolar or pseudounipolar
• Anaxonic

Morphological Classification of the Neurons

1- Multipolar neurons:
•

One axon and two or more dendrites

•

The most common including all motor
neurons and most CNS interneurons

Classification of the Neurons

2- Bipolar neurons:
•

One dendrite and one axon

•

Comprise the sensory neurons of the
retina, the olfactory epithelium, and
the inner ear

Classification of the Neurons

3- Unipolar or pseudounipolar neurons:
•

A single process that bifurcates close to
the perikaryon, with the longer branch
extending to a peripheral ending and
the other toward the CNS

•

Include all other sensory neurons

Classification of the Neurons

4- Anaxonic neurons:
•

Many dendrites but no true axon

•

Found only in certain CNS interneurons

•

Do not produce action potentials, but
regulate electrical changes of adjacent
CNS neurons

Synapses

•

Sites where nerve impulses are
transmitted from one neuron to
another, or from neurons and other
effector cells

•

Transmission is unidirectional

•

Types of synapses:
o Chemical
o Electrical

Chemical Synapses

Components:
1- Presynaptic axon terminal
(terminal bouton):
• Contains mitochondria and
numerous synaptic vesicles from
which neurotransmitter is released
by exocytosis
2- Synaptic cleft:
• A 20- to 30-nm-wide intercellular
space
• Separates these presynaptic and
postsynaptic membranes
3- Postsynaptic cell membrane:
• Contains receptors for the
neurotransmitter, and ion channels
or other mechanisms to initiate a
new impulse

Morphological Types of Chemical Synapses

1- Axosomatic synapse
2- Axodendritic synapse
3- Axoaxonic synapse

Glial Cells

Support neuronal survival and activities
10 times more abundant than neurons in
the mammalian brain
Participating in the formation of neuropil
of CNS:
• Network of fine cellular processes
emerging from neurons and glial
cells
• The fibrous intercellular network of
CNS tissue superficially
resembles collagen by light
microscopy

(X200; H&E staining)
• N: neuronal cell body
• G: glial cell
• Np: neuropil

(X200; Gold chloride and hematoxylin staining)

Types of Glial Cells
Glial cells present in CNS:
1. Astrocytes
2. Oligodendrocytes
3. Microglia
4. Ependymal cells
Glial cells present in PNS:
1. Schwann cells
2. Satellite cells

Oligodendrocytes

•

Predominant glial cells in white
matter

•

Extend many processes, each of
which becomes sheetlike and wraps
repeatedly around a portion of a
nearby CNS axon

•

Forming myelin sheath

•

An axon’s full length is covered by
the action of many oligodendrocytes

•

Oligodendrocytes in routine light
microscope staining:
o Small cells with rounded,
condensed nuclei and
unstained cytoplasm

Astrocytes

Have a large number of long radiating,
branching processes
Two types:
1- Fibrous astrocytes:
• With long delicate processes
• Abundant in white matter
2- Protoplasmic astrocytes
• With many shorter processes
• Predominate in the gray matter

Functions of the Astrocytes

1- Extending processes that associate
with or cover synapses, affecting the
formation, function, and plasticity of
these structures
2- Regulating the extracellular ionic
concentrations around neurons
3- Extending fibrous processes with
expanded perivascular feet that cover
capillary endothelial cells and modulate
blood flow and help move nutrients,
wastes, and other metabolites between
neurons and capillaries
4- Forming a barrier layer of expanded
protoplasmic processes, called the glial
limiting membrane, which lines the
meninges at the external CNS surface
5- Filling tissue defects after CNS injury
by proliferation to form an astrocytic scar

Ependymal Cells

Columnar or cuboidal cells that line:
1- Fluid-filled ventricles of the brain
2- Central canal of the spinal cord
Characteristics of the apical ends of the
ependymal cells in some regions:
1- Cilia: facilitate the movement of
cerebrospinal fluid (CSF)
2- Long microvilli: likely involved in
absorption

Characteristics of the basal ends of the
ependymal cells in some regions:
1- No basal lamina
2- Elongated and extend branching
processes into the adjacent neuropil

Microglia

•

Consist of small cell bodies from
which radiate many long, branched
processes

•

Evenly distributed throughout
specific regions of gray and white
matter

•

Constitute the major mechanism of
immune defense in the CNS,
removing any microbial invaders and
secreting several immunoregulatory
cytokines

Schwann Cells / Neurolemmocytes

•

Counterparts to oligodendrocytes of
the CNS

•

Function:
o Form myelin sheathes in the
PNS
o Unlike an oligodendrocyte, a
Schwann cell forms myelin
around a portion of only one
axon

Satellite Cells of Ganglia

•

Form a thin, intimate glial layer
around each large neuronal cell body
in the ganglia of the PNS

•

Function:
o Trophic or supportive effect
on these neurons
o Insulating, nourishing, and
regulating neurons
microenvironments