Neuron
578 views
35 slides
Jan 24, 2020
Slide 1 of 35
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
About This Presentation
Joints
Slide Content
NEURON
STRUCTURE
TYPES
( Rabbia Yousaf)
STRUCTURE
TYPES
( Rabbia Yousaf)
A nerve cell alongwith all its processes is a neuron.
Excitable cells that are specialized for the reception
of stimuli and the conduction of the nerve
impulse.
Found in the brain and spinal cord .
Do not undergo division and
replication.
Excitable cells that are specialized for the reception
of stimuli and the conduction of the nerve
impulse.
Found in the brain and spinal cord .
Do not undergo division and
replication.
Neuron Anatomy
Axon hillock
(trigger zone)
Soma (cell body)
Axon (transmits signals)
Axon terminals
(stimulate
another cell)
Dendrites (receive
signal)
Axon hillock
(trigger zone)
Soma (cell body)
Axon (transmits signals)
Axon terminals
(stimulate
another cell)
Dendrites (receive
signal)
DENDRITES function to receive the signal and
carry the nerve conduction toward the cell body.
SOMA(cell body) is where the nucleus,
ribosomes, and most organelles are located
AXON HILLOCK is the area on the soma where
the action potential of the neuron
builds up before it transmits the
signal down the axon.
carry the nerve conduction toward the cell body.
SOMA(cell body) is where the nucleus,
ribosomes, and most organelles are located
AXON HILLOCK is the area on the soma where
the action potential of the neuron
builds up before it transmits the
signal down the axon.
AXONfunction is to transmit signals. Some
cells have many axons, some have one, some
are short, and some are long.
AXON TERMINALS (also called synaptic
knobs) contain a neurotransmitter which,
when released, stimulates another cell.
cells have many axons, some have one, some
are short, and some are long.
AXON TERMINALS (also called synaptic
knobs) contain a neurotransmitter which,
when released, stimulates another cell.
A synapseis the site at which two neurons
communicate.
The neuron that conducts the signals towards the
synapse is called the presynaptic neuron.
The neuron that transmits the signals away from the
synapse is called the postsynaptic neuron.
Most neurons function as pre-synaptic and
post-synaptic neurons.
The neurons don’t physically touch each
other at the synapse. The space between
them is called the synaptic cleft.
communicate.
The neuron that conducts the signals towards the
synapse is called the presynaptic neuron.
The neuron that transmits the signals away from the
synapse is called the postsynaptic neuron.
Most neurons function as pre-synaptic and
post-synaptic neurons.
The neurons don’t physically touch each
other at the synapse. The space between
them is called the synaptic cleft.
Morphological
Functional
Functional
On the basis of number, length, and mode of
branching of the neurites.
1.Pseudounipolar
2.Unipolar
3.Bipolar
4.Multipolar
1.Golgi type I
2.Golgi type II
branching of the neurites.
1.Pseudounipolar
2.Unipolar
3.Bipolar
4.Multipolar
1.Golgi type I
2.Golgi type II
Possess a single process that extends from the
cell body and subsequently branches into an
axon and dendrite.
Present in spinal and cranial gangli.
cell body and subsequently branches into an
axon and dendrite.
Present in spinal and cranial gangli.
Possess a single process
Rare in vertebrates.
Mesencephalic neurons of trigeminal nerve
Amacrine cells of retina
Rare in vertebrates.
Mesencephalic neurons of trigeminal nerve
Amacrine cells of retina
possess an elongated cell body, from each end
of which a single neurite emerges
Examples of this type of neuron are found in
the retinal bipolar cells and the cells of the
sensory cochlear and vestibular ganglia.
of which a single neurite emerges
Examples of this type of neuron are found in
the retinal bipolar cells and the cells of the
sensory cochlear and vestibular ganglia.
have a number of neurites arising from the cell
body.
With the exception of the long process, the
axon, the remainder of the neurites are
dendrites.
Most neurons of the brain and spinal cord are
of this type.
body.
With the exception of the long process, the
axon, the remainder of the neurites are
dendrites.
Most neurons of the brain and spinal cord are
of this type.
have a long axon that may be 1 m or more in
length in extreme cases. The axons of these
neurons form the long fiber tracts of the brain
and spinal cord and the nerve fibers of
peripheral nerves. The pyramidal cells of the
cerebral cortex, the Purkinje cells of the
cerebellar cortex, and the motor cells of the
spinal cord are good examples.
length in extreme cases. The axons of these
neurons form the long fiber tracts of the brain
and spinal cord and the nerve fibers of
peripheral nerves. The pyramidal cells of the
cerebral cortex, the Purkinje cells of the
cerebellar cortex, and the motor cells of the
spinal cord are good examples.
Have a short axon that terminates in the
neighborhood of the cell body or is entirely
absent.
Numerous short dendrites give them a star-
shaped appearance.
They greatly outnumber the Golgi type I
neurons.
neighborhood of the cell body or is entirely
absent.
Numerous short dendrites give them a star-
shaped appearance.
They greatly outnumber the Golgi type I
neurons.
Neurons are grouped functionally according to
the direction the nerve impulse travels relative to
the CNS.
Sensory Neurons
Motor Neurons
Interneurons
the direction the nerve impulse travels relative to
the CNS.
Sensory Neurons
Motor Neurons
Interneurons
Sensoroy Neurons (afferent neurons)
Transmit impulses toward the CNS.
They originate in the PNS and terminate in the
CNS.
Motor Neurons (efferent neurons)
Transmit impulses from the CNS to effector
organs (muscles and glands).
They originate in the CNS and terminate in the
PNS.
Transmit impulses toward the CNS.
They originate in the PNS and terminate in the
CNS.
Motor Neurons (efferent neurons)
Transmit impulses from the CNS to effector
organs (muscles and glands).
They originate in the CNS and terminate in the
PNS.
Interneurons (association neurons)
connect sensory neurons to motor neurons
within the spinal cord and brain.
They originate and terminate in the CNS, and
form complex neuronal pathways.
They make up 99.98% of the neurons in the
body, reflecting the vast amount of
information processed in the CNS.
connect sensory neurons to motor neurons
within the spinal cord and brain.
They originate and terminate in the CNS, and
form complex neuronal pathways.
They make up 99.98% of the neurons in the
body, reflecting the vast amount of
information processed in the CNS.
Located only in the CNS
Several cell types
Do not conduct impulses-do not form synapses
with other cells.
Outnumber neurons.
Embedded in a web of tissue termed the
neuroglia.
They function to support and protect
neurons.
Several cell types
Do not conduct impulses-do not form synapses
with other cells.
Outnumber neurons.
Embedded in a web of tissue termed the
neuroglia.
They function to support and protect
neurons.
1.Astrocytes (Protoplasmic astrocytes & Fibrous
astrocytes )
2.Oligodendrocytes
3.Schwann cells
4.Microglia
5.Ependymal cells
astrocytes )
2.Oligodendrocytes
3.Schwann cells
4.Microglia
5.Ependymal cells
The largest of the neuroglial cells.
Have many processes with expanded pedicles
(vascular feet)
Surround blood vessels or contact the pia
mater.
Protoplasmic astrocytes reside mostly
in gray matter
Fibrous astrocytes reside mostly in
white matter
Have many processes with expanded pedicles
(vascular feet)
Surround blood vessels or contact the pia
mater.
Protoplasmic astrocytes reside mostly
in gray matter
Fibrous astrocytes reside mostly in
white matter
Form a protective sealed barrier between the
pia mater and the nervous tissue of the brain
and spinal cord.
They provide structural support for nervous
tissue.
They proliferate to form scar tissue after
injury to the CNS.
pia mater and the nervous tissue of the brain
and spinal cord.
They provide structural support for nervous
tissue.
They proliferate to form scar tissue after
injury to the CNS.
They are necessary for the survival of neurons.
Located in both gray matter and white matter
Produce myelin, a sheath that insulates and
protects axons in the CNS.
Each oligodendrocyte produces myelin for
several axons.
Located in both gray matter and white matter
Produce myelin, a sheath that insulates and
protects axons in the CNS.
Each oligodendrocyte produces myelin for
several axons.
Perform the same function in the PNS as
oligodendrocytes in the CNS; protect and
insulate neurons.
A myelin sheath consists of several Schwann
cell wrapped around a single axon.
oligodendrocytes in the CNS; protect and
insulate neurons.
A myelin sheath consists of several Schwann
cell wrapped around a single axon.
small, phagocytic neuroglial cells
Activated microglial cells become antigen-
presenting cells and secrete cytokines.
Activated microglial cells become antigen-
presenting cells and secrete cytokines.
Epithelial cells that line the neural tube and
ventricles of the brain.
They help in movement and formation of CSF
(choroid plexus formation).
ventricles of the brain.
They help in movement and formation of CSF
(choroid plexus formation).
hyperphysics.phy-
astr.gsu.edu/hbase/biology/nervecell.html
biology.tutorvista.com/cell/nerve-cell.htm
astr.gsu.edu/hbase/biology/nervecell.html
biology.tutorvista.com/cell/nerve-cell.htm
Tags
Categories
GeneralDownload
Download Slideshow Get the original presentation fileQuick Actions
Statistics
- Views 578
- Slides 35
- Favorites 1
- Age 2137 days
Related Slideshows
22
Pray For The Peace Of Jerusalem and You Will Prosper
RodolfoMoralesMarcuc
30 views
26
Don_t_Waste_Your_Life_God.....powerpoint
chalobrido8
32 views
31
VILLASUR_FACTORS_TO_CONSIDER_IN_PLATING_SALAD_10-13.pdf
JaiJai148317
30 views
14
Fertility awareness methods for women in the society
Isaiah47
28 views
35
Chapter 5 Arithmetic Functions Computer Organisation and Architecture
RitikSharma297999
26 views
5
syakira bhasa inggris (1) (1).pptx.......
ourcommunity56
28 views