Nervous System MUIC Part 1 PDF 2024

Summary

This document is a presentation by Adisorn Ratanayotha on the nervous system. It covers topics such as organization, nervous tissue, central nervous system (CNS), peripheral nervous system (PNS), and autonomic nervous system (ANS), which are part of the ICBI 305 Human Anatomy I course at Mahidol University.

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September 21, 2024

Nervous System
ICBI 305 Human Anatomy I

Adisorn Ratanayotha
[email protected]
 Topics

After the session, students should be able to describe
Organization of the Nervous System
Nervous tissue: Structure and Function
Central nervous system (CNS)
Peripheral nervous system (PNS)
Autonomic nervous system (ANS)
 Topics

After the session, students should be able to describe
Organization of the Nervous System
①
Nervous tissue: Structure and Function
② Central nervous system (CNS)
Peripheral nervous system (PNS)
③
Autonomic nervous system (ANS)
 Topics

After the session, students should be able to describe
Organization of the Nervous System
①
Nervous tissue: Structure and Function
Central nervous system (CNS)
Peripheral nervous system (PNS)
Autonomic nervous system (ANS)
 7 The Nervous System
Nervous System

WHAT

What? As the primary control
system of the body, the nervous
How?
system provides for higher mental HOW
function and emotional expression,
maintains homeostasis, and Communication by
regulates the activities of the nervous system involves
muscles and glands. a combination of electrcial
and chemical signals.

WHY

Why? All body systems are
under the control or regulation
INSTRUCTORS
of the nervous system. If the nervous
New Building
systems stops functioning, the body
Vocabulary Coaching
can stay alive only with the
Activities for this
assistance of life-supporting
chapter are assignable
machines.
in

Elaine Marieb and Suzanne Keller. Essen als of Human Anatomy & Physiology, 12th Ed, 2018: p.225
ti
 Basic Functions of the Nervous System
226 Essentials of Human Anatomy and Physiology

1. Sensory input:
Central Perception
Nervous System of stimuli
Sensory input (brain and spinal cord)
from extl and intl environments.
Integration
Sensory receptor
2. Integration: Analysis and processing of
sensory info to generate
Peripheral Nervous System
(cranial and spinal nerves)
commands.
Motor output
3. Motor output: Commanding and
Brain and spinal cord regulating organ functions.
Effector
Figure 7.1 The nervous system’s functions.
Sensory Motor
Nervous system, together with endocrine system,
(afferent)maintain body homeostasis
(efferent)
(1) It uses its millions of sensory receptors to
monitor changes occurring both inside and out-
side the body. These changes are called stimuli,
Elaine Marieb and Suzanne Keller. Essen als of Human Anatomy & Physiology, 12th Ed, 2018: p226
ti
 Organization of the NS
n Anatomy and Physiology

nput
Central Nervous System
(brain and spinal cord)
1. Central nervous system (CNS)
- Brain
Integration

- Spinal cord
Peripheral Nervous System
(cranial and spinal nerves)
utput

Brain and spinal cord 2. Peripheral nervous system (PNS)
ystem’s functions.
Sensory
(afferent)
Motor
(efferent)
- Cranial nerves
- Spinal nerves
of sensory receptors to
ng both inside and out-
anges are called stimuli,

-
mation is called sensory
nd interprets the sensory
should be done at each
Sense Somatic Autonomic Ganglia (collection of neurons in PNS)
organs (voluntary) (involuntary)
d integration. (3) It then
ect, by activating muscles Skeletal Cardiac and
motor output. muscles smooth muscle,
glands

ervous system functions
ack loop (Chapter 1, p. 19). Structural Divisions
oop, a receptor receives
nds to the brain (control
egration); the brain then
and determines the appro- Parasympathetic Sympathetic
s to a motor response. ➔
Figure 7.2 Organization of the nervous system.
trate how these functions As the flowchart shows, the central nervous system Elaine Marieb and Suzanne Keller. Essen als of Human Anatomy & Physiology, 12th Ed, 2018: p.226
ou are driving and see a receives input via sensory fibers and issues commands
ti
 Organization of the NS
n Anatomy and Physiology

nput
Central Nervous System
(brain and spinal cord)
2. Peripheral nervous system (PNS)
- Sensory division
Integration

- Motor division
Peripheral Nervous System
(cranial and spinal nerves)
utput

Brain and spinal cord - Somatic (voluntary)
ystem’s functions.
Sensory
(afferent)
Motor
(efferent)
- Autonomic (involuntary)
- Sympathetic NS
of sensory receptors to
ng both inside and out-
anges are called stimuli,

-
mation is called sensory
nd interprets the sensory
should be done at each
Sense Somatic Autonomic Parasympathetic NS
organs (voluntary) (involuntary)
d integration. (3) It then
ect, by activating muscles Skeletal Cardiac and
motor output. muscles smooth muscle,
glands

ervous system functions
ack loop (Chapter 1, p. 19). Functional Divisions
oop, a receptor receives
nds to the brain (control
egration); the brain then
and determines the appro- Parasympathetic Sympathetic
s to a motor response. ➔
Figure 7.2 Organization of the nervous system.
trate how these functions As the flowchart shows, the central nervous system Elaine Marieb and Suzanne Keller. Essen als of Human Anatomy & Physiology, 12th Ed, 2018: p.226
ou are driving and see a receives input via sensory fibers and issues commands
ti
 PERIPHERAL NERVOUS SYSTEM CENTRAL NERVOUS SYSTEM PERIPHERAL NERVOUS SYSTEM
(Sensory division) (Brain and spinal cord) (Motor division)

SENSORY OR MOTOR OR
AFFERENT EFFERENT
NEURONE NEURONE

Sensory receptors Effector organs

Senses: Internal environment Somatic Autonomic
sight (autonomic) e.g.: (voluntary): (involuntary):
hearing chemoreceptors skeletal muscle cardiac muscle
smell baroreceptors smooth muscle
taste osmoreceptors glands
touch
Sympathetic Parasympathetic
division division

Anne Waugh and Allison Grant. Ross and Wilson Anatomy and Physiology in Health and Illness, 12th Ed, 2014: p.145
 Topics

After the session, students should be able to describe
Organization of the Nervous System
①
Nervous tissue: Structure and Function
Central nervous system (CNS)
Peripheral nervous system (PNS)
Autonomic nervous system (ANS)
 Nervous Tissue
8 Overview of the Nervous System

Principal cells the NS
Ventricle

Ependyma Microglial
cell
- Neuron
Tanycyte

- Neuroglia (supporting cells)
- Astrocyte CNS
Neuron - Oligodendrocyte
- Ependymal cell
Oligodendrocyte

- Microglia

Axon
- Satellite cell PNS
- Schwann cell
Astrocyte

Astrocyte foot processes

Perivascular
Pia mater pericyte
Capillary

David Felten, et al. Ne er’s Atlas of Neuroscience, 3rd Ed, 2016: p.8
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 CNS. Figure 49.9 provides an overview of the major types For suggested answers, see Appendix A.

Neuroglia. Figure 49.9 Glia in the vertebrate nervous system.
CNS PNS

VENTRICLE Neuron

Cilia

Lisa Urry, et al. Campbell Biology, 12th Ed, 2020: p.1090
Ependymal cells
Ependymal cells
line the ventricles
- of the
Line thebrain
brainand
have cilia that
ventriclescircu-
promote
- lation
Use cilia
of to
the
cerebrospinal fluid
circulate
that CSF
fills these Capillary
compartments.

Astrocytes (from the Greek astron, star) have Oligodendrocytes Microglia are Schwann cells
Astrocytes
numerous functions in the CNS. They facilitate
Oligodendrocytes
myelinate axons in
Microglia
immune cells in the
Schwann cells
myelinate axons
- Optimize the
information neuronal
transfer, environment.
regulate extracellular ion - Form
the CNS.myelin
Myelination - Actthat
CNS as phagocytes.
protect - Form
in myelin
the PNS.
concentrations, promote blood flow to greatly increases the against pathogens.
- Supporthelp
neurons,
ef cient neuron function.
form the blood-brain barrier, and
sheaths wrapping
conduction speed of - Engulf pathogens, sheaths wrapping
- Contribute
act to the
as stem cells blood-brain
to replenish barrier.
certain neurons. around
action nerve bers
potentials. foreign particles, around nerve bers
in the CNS. and cellular debris. in the PNS.
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 Astrocyte Nerve
Neuroglia
fibers

(a) Astrocytes are the most abundant (d) Oligodendrocytes have processes that form
and versatile neuroglia. myelin sheaths around CNS nerve fibers.
CNS PNS
Myelin sheath Satellite
Process of cells
Cell body of neuron
oligodendrocyte
Neuron Schwann cells
Microglial
Nerve (forming myelin sheath)
te
cell
fibers Nerve fiber

(d) Oligodendrocytes have processes that form
myelin
(b) sheaths
Microglial around
cells CNS nervethat
are phagocytes fibers. (e) Satellite cells and Schwann cells (which form
Oligodendrocytes
defend CNS cells. Schwann
myelin) surround cells
neurons in the PNS.

form Myelin sheath in CNS form Myelin sheath in PNS
Satellite
cells Fluid-filled cavity
Cell body of neuron Ependymal
Schwann cells cells
al (forming myelin sheath)
Brain or Elaine Marieb and Suzanne Keller. Essen als of Human Anatomy & Physiology, 12th Ed, 2018: p.228
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 Myelin Sheath
18 Overview of the Nervous System

CENTRAL NERVOUS SYSTEM PERIPHERAL NERVOUS SYSTEM
Protection, insulation
Sensory neuron Satellite

- CNS: Oligodendrocyte
cell body cells

Pia mater
Oligo-
dendrocyte
- PNS: Schwann cell
Chapter 4 / The Cells of the Nervous System 89

Schwann cells associated with
myelin sheaths of myelinated axons A Myelination in the central nervous system B Myelination in the peripheral nervous system
Capillary
Astrocyte
Boutons of association neurons synapsing Postganglionic neuron of Sc Cyt
with preganglionic autonomic neuron of sympathetic or parasympathetic
brainstem or spinal cord ganglion Oligodendrocyte

Ax

Ml IM

Oligo- OM
Schwann cells associated with Satellite cells SM
dendrocyte myelin sheaths of myelinated axons
1 µm

C Development of myelin sheath in the peripheral nervous system
Boutons of
association neurons 1 2 3 4
synapsing with somatic
Node of Ranvier
motor neurons of brain
or spinal cord
Axon

Inner
mesaxon

Axons terminating
on motor end plates of Outer
striated (voluntary) muscle mesaxon

Figure 4–13 Myelin insulates the axons of both central and become compact. (Reproduced, with permission, from Dyck
peripheral neurons. et al. 1984.)
1.15 MYELINATION OF CNS AND PNS AXONS A. Axons in the central nervous system are wrapped in several C. A peripheral nerve fiber is myelinated by a Schwann cell in
CLINICAL POINT
David Felten, etmyelination
Central al. Ne er’s Atlas
of axons of Neuroscience,
is provided 3rd
by oligodendroglia. Ed, 2016: p.18
The integrity of the myelin sheath is essential for proper neuronal func- Eric Kandel, et al. Principles of the Neural Science, 5th Ed, 2013: p.89
layers of myelin produced by oligodendrocytes. Each oligo-
dendrocyte can myelinate many axons. (Reproduced, with
several stages. In stage 1 the Schwann cell surrounds the axon.
In stage 2 the outer aspects of the plasma membrane have
Each oligodendroglial cell can myelinate a single segment of tion in both the CNS and the PNS. Disruption of the myelin sheath
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 some small fibres in the central nervous system are
unmyelinated. In this type a number of axons are
Myelin Sheath
embedded in one Schwann cell (Fig. 7.3B). The adjacent
Schwann cells are in close association and there is no
Insulates nerve bers, enhancing the speed of neural signal transmission

Schwann
cell Node of Ranvier
cytoplasm

Schwann
cell Myelin sheath
nucleus

Neurilemma

Nucleus of
Axon
Schwann cell

Myelin Neurilemma
sheath (sheath of
Schwann cell)

A B C Axolemma Axon

Figure 7.3 Arrangement of myelin. A.Unmyelinated ber
Myelinated neurone. B. Unmyelinated Myelinated
neurone. C. Length of myelinated axon. ber
Anne Waugh and Allison Grant. Ross and Wilson Anatomy and Physiology in Health and Illness, 12th Ed, 2014: p.146
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 Neuron
Chapter 11 Fundamentals of the Nervous System and Nervous Tissue 427

Dendrites
(receptive
regions)
Cell body
(biosynthetic center
and receptive region)
1. Cell body
- Nucleus, euchromatin, nucleolus
- Nissl body (rER), neuro lament, mitoch, etc
2. Process; nerve ber
Neuron
cell body

- Dendrite: Carries impulses toward the cell body
Dendritic
spine

-
Nucleus
Axon: Transmits impulses away from the cell body
- Axon hillock, Axon initial segment, Axon terminal
- Myelin
(b) sheath, node of Ranvier
Initial Axon
Nucleolus segment (impulse-generating

Neuronal properties
of axon and conducting
Chromatophilic region) Myelin sheath gap
substance (rough
endoplasmic Axon terminals
reticulum) Axon hillock Schwann cell (secretory
region)
- Irritability
Impulse

- Conductivity
direction
(a) Terminal branches
11
Figure 11.5 Structure of a motor neuron. (a) Illustration. (b) Digital reconstruction of
Elaine Marieb and Katja Hoehm.
a neuron Human Anatomy & Physiology, 11th Ed, 2019: p.427
(10003).
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 Neuron 2.1 The Cells of the Nervous System | 25

aNeuron, the vestibular area of the brain b Hippocampal neuron cNeuron, mouse DRG of the spinal cord

Cultured
d neuron, DRG of an embryonic rat e Pyramidal neuron, brain f Multipolar neuron cell body,
human cerebral cortex
Michael Gazzaniga, et al. Cogni
FIGURE ve Neuroscience:
2.2 Mammalian The Biology
neurons of the Mind,anatomical
show enormous 5th Ed, 2019: p.25
variety.
ti
 Neuron
Classi ed by the number of nerve bers

Unipolar
A Unipolar cell Bipolar
B Bipolar cell Pseudo-unipolar
C Pseudo-unipolar cell

Axon
terminals Dendrites
Dendrites
Peripheral axon
to skin and
muscle
Axon
Cell body

Single bifurcated
Cell body process

Dendrites Central
Axon
axon
Cell body
Axon terminals

Invertebrate neuron Bipolar cell of retina Ganglion cell of dorsal root

D Three types of multipolar cells
Eric Kandel, et al. Principles of the Neural Science, 5th Ed, 2013: p.25
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 Cell body process

Neuron
Dendrites Central
Axon
axon
Cell body
Axon terminals
Classi ed by the number of nerve bers
Invertebrate neuron Bipolar cell of retina Ganglion cell of dorsal root

D Three types of multipolar cells
Multipolar

Dendrites

Apical
dendrite
Cell body

Cell
body

Basal
dendrite

Dendrites Cell body

Axon Axon
Axon

Motor neuron of spinal cord Pyramidal cell of hippocampus Purkinje cell of cerebellum

Figure 2–3 Neurons are classified as unipolar, bipolar, or axons; one extends to peripheral skin or muscle, the other
multipolar
Eric Kandel, et al. Principles according
of the to the
Neural Science, 5thnumber
Ed, 2013:of processes that
p.25 to the central spinal cord. (Adapted, with permission, from
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 Neuron
Studying the Nervous System
Classi ed by neuronal function

Sensory (afferent) FIGURE 1.7 The knee-jerk
axon
response, a simple reflex circu
Muscle sensory Formally known as the myotatic
receptor 3A Cross section of spinal cord
reflex, this response illustrates se
eral points about the functional
Extensor
organization of neural circuits.
muscle 2B Stimulation of peripheral sensor
(a muscle stretch receptor in thi
2A case) initiates receptor potentia
1
that trigger action potentials tha
Flexor travel centrally along the afferen
muscle 3B axons of the sensory neurons. Th
information stimulates spinal mo
tor neurons by means of synapt
Motor (efferent) 2C Interneuron
4 axons contacts. The action potentials
triggered by the synaptic poten
- Sensory neuron
in motor neurons travel periphe
ally in efferent axons, giving rise
- Motor neuronmuscle contraction and a beha
ioral response. One of the purpo
- Interneuron es of this particular reflex is to he
maintain an upright posture in
Hammer tap 2A Sensory neuron synapses Motor neuron conducts the face of unexpected change
1 6th Ed, 2018: p.11
Dale Purves et al. Neuroscience, 3A
stretches tendon, with and excites motor action potential to (such as tripping).
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 1. Microtubules do not extend into the terminal.
2. The terminal contains numerous small bubbles of membrane, called

Neural transmission
synaptic vesicles, that measure about 50 nm in diameter.
Axon hillock
3. The inside surface of the membrane that faces the synapse has a par-
ticularly dense covering of proteins.
4. The axon terminal cytoplasm has numerous mitochondria, indicating a

42 PART ONE FOUNDATIONS Action potential & Synapse
high energy demand.
Axon
collaterals

Irritability ▲ FIGURE 2.15
appears as a swollenConductivity
disk (Figure 2.16). The terminal is a site where the
The axon and axon collaterals.axon The comes in contact with other neurons (or other cells) and passes in-
- Response to stimuli. Dendrites
axon functions like and
formation
a telegraph wire to on to them.- This
Transmits
point of nerve
contact is called the synapse, a word
dendritic derived
sites from the Greek, meaning “to fasten together.” Sometimes axons
spines
send electrical impulses to distant
- Converts stimuli into in the nervous system. The arrows signals
indi-many short branches
have to other
at their ends, cells.
and each branch forms a syn-
cate the direction of information flow.
nerve signals. apse on dendrites or cell bodies in the same region. These branches are
collectively called the terminal arbor. Sometimes axons form synapses
at swollen regions along their length and then continue on to terminate
elsewhere (Figure 2.17). Such swellings are called boutons en passant
Presynaptic
axon terminal
(“buttons in passing”). In either case, when a neuron makes synaptic
contact with another cell, it is said to innervate that cell, or to provide
innervation. Mitochondria
Synapse
The cytoplasm of the axon terminal differs from that of the axon in
several ways:
1. Microtubules do not extend into the terminal.
2. The terminal contains numerous small bubbles of membrane, called
Synaptic
synaptic vesicles, that measure about 50 nm in diameter. vesicles
Axon hillock
3. The inside surface of the membrane that faces the synapse has a par-
ticularly dense covering of proteins.
4. The axon terminal cytoplasm has numerous
Postsynaptic dmitochondria,
rit e
indicating a
end
high energy demand. Synaptic
cleft
Axon
Receptors
collaterals

▲ FIGURE 2.16
▲ FIGURE 2.15
Axon
The axon and axon
and axon collaterals
collaterals. The Axon terminal and synapse
The axon terminal and the synapse. Axon terminals form synapses with the
dendrites or somata of other neurons. When a nerve impulse arrives in the pre-
axon functions like a telegraph wire to synaptic axon terminal, neurotransmitter molecules are released from synaptic
send electrical impulses to distant sites vesicles into the synaptic cleft. Neurotransmitter then binds to specific receptorthe Brain, 4th Ed, 2016: p.42
in the nervous system. The arrows indi- Mark Bear, et al. Neuroscience: Exploring
proteins, causing the generation of electrical or chemical signals in the postsyn-
Two factors generate the resting membrane potential: differ- than the extracellular fluid. Negatively c
ences in the ionic composition of the intracellular and extracel- teins (not shown) help to balance the po
lular fluids, and differences Resting Membrane
in the permeability of the Potential
plasma +
cellular cations (primarily K ). In the
membrane to those ions. +
positive charges of Na and other cations
The resting state of a neuron −
chloride ions (Cl ). Although there are m
Voltmeter cose, urea, and other ions) in both fluids
the most important role in generating the
RMP ~ (-70) mV Membrane potential
Differences in Plasma
The electrical voltage difference
Membrane Pe
Plasma Ground electrode Next, let’s consider the differential perm
membrane between the inside and outside of the cell.
outside cell
1 1 1 1 1 brane to various ions (Focus Figure 11.
Microelectrode membrane is impermeable to the larg
inside cell proteins, very slightly permeable to sod
1 1 1 1 1 times more
Resting statepermeable to potassium tha
Axon
permeable
Outside to chloride
is positive, insideions. These restin
is negative.
the properties of the leakage ion chann
Potassium ions diffuse out of the cell alo
gradient much more easily than sodium
+
Neuron along theirs. K flowing out of the cell ca
+
Na+-K+ ATPase more negative inside. Na trickling into
K leakage channel
+ just slightly more positive than it would
Therefore, at resting membrane potentia
Figure 11.8 Measuring membrane potential in neurons. The and Katjaof
Elaine Marieb the Human
Hoehm. cell isAnatomy
due to& Physiology,
a much10th greater ability
Ed, 2016: p.419
 The big picture Action Potential (Nerve Impulses)
What does this graph show? During the course of an action potential
(below), voltage changes over time at a given point within the axon.
Voltage-gated Na+ Channel (NaV) Voltage-gated K+ Channel (KV)
2 Depolarization is 3 Repolarization is
caused by Na+ flowing caused by K+ flowing
into the cell. out of the cell.

+30 4 Hyperpolarization is
caused by K+ continuing

Membrane potential (mV)
3 to leave the cell.
0 Voltage-gated K+ Channel (KV)
2
ถูกกระ น

–55 Threshold

–70 1 1
1 Resting state. No ions move 4
through voltage-gated channels.
0 1 2 3 4
Na+-K+ ATPase Time (ms)
K+ leakage channel

Elaine Marieb and Katja Hoehm. Human Anatomy & Physiology, 10th Ed, 2016: p.424
ตุ้
 are so slight that they dissipate long before threshold
× time). Strongisstimuli
reached. away
depolarize thefrom its point
membrane to of
threshold isolated axon
origin. (If an channels is stimulated
and triggers an action potential there (Figure 11.11).
An AP is an all-or-none phenomenon: It either
quickly. Weakerhappens must beby
com-
stimuli an electrode,
applied for longertheperiods
nerve impulse
to will move the
Because away
areafrom thethe AP originated has just generated
where
pointflow.
of stimulus
Very weakinstimuli
both dodirectionsan along
AP, thethe axon.)channels
sodium In the in that area are inactivated and no
Action Potential (Nerve Impulses)
pletely or doesn’t happen at all. We can compare
provide the generation
the crucial amount of current
The big picture not trigger an AP because the local current flows they produce new AP is generated there. For this reason, the AP propagates
What does this graph show? During
11 the course
are so slight of an action
that they dissipate potential
long before threshold is reached. away from its point of origin. (If an isolated axon is stimulated
by an electrode, the nerve impulse will move away from the

Membrane potential (mV)
(below), voltage changes over time at a given
Depolarization → Outside becomes point within the axon.
at 2 ms negative, inside point becomes positive
An AP is an all-or-none phenomenon:
VoltageIt either happens com-
130 pletely or doesn’t happen at all. We can compare the generation of stimulus in both directions along the axon.) In the

Voltage 11 2 Depolarization is 3 Repolarization is Voltage

Membrane potential (mV)
at 0 ms Voltage
caused by Na+ flowing caused by +
K flowing
at 2 ms
at 4 ms
270 130 into the cell. out of the cell.

Voltage
Voltage
Recording at 0 ms
at 4 ms
electrode
270
22 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1111112221111111 1111111111122211
112 2 2 2 2 2 2 2 2 2 2 2 2 2 +230
222221112222222 2222222222211122 4 Hyperpolarization is
caused by K+ continuing

Membrane potential (mV)
Recording
electrode 3 to leave the cell.
112 2 2 2 2 2 2 2 2 2 2 2 2 2 2222221112222222 2222222222211122
221 1 111111111111
1 101 1 1 1 2 2 2 1 1 1 1 1 1 1
1111112221111111 1111111111122211
221 1 1 1 1 1 1 1 1 1 1 1 1 1 1111111111122211
112 2 2 2 2 2 2 2 2 2 2 2 2 2 2222221112222222 2222222222211122

AP propagation
(a) Time = 0 ms. Action potential has (b) Time = 2 ms. Action potential
1 1 2 2 2peak
2 2 reaches
2 2 2 2the
2 2recording
222
2
(c) Time = 4 ms. Action potential
2 2 2 2 2peak
211 12 2 2 2the
22 2 2222222222211122
not yet reached the recording has passed recording
electrode. 2 2 1 1 1electrode.
11111111111 1 1 1 1 1electrode.
12221 Membrane
1 1 1 1 1at1the 1111111111122211
recording electrode is still
Resting potential hyperpolarized.
Peak of action potential (a) Time = 0 ms. Action potential has
–55 Threshold
(b) Time = 2 ms. Action potential (c) Time = 4 ms. Action potential
not yet reached the recording peak reaches the recording peak has passed the recording
Hyperpolarization electrode. electrode. electrode. Membrane at the
–70 1 1 recording electrode is still
Figure 11.11 1 Resting state.ofNo
Propagation an ions move
action Resting potential
potential (AP). Recordings at three successive 4 hyperpolarized.
times as anthrough voltage-gated channels.
Nerve impulses move in one direction along the axon,
AP propagates along an axon (fromPeak
left to right).potential
of action The arrows show the direction
of local current flow generated by the movement of positive ions. This
Hyperpolarization 0 current brings
1 the
3 24
resting membrane at the leading edge of the AP to threshold, propagating the AP forward. Time (ms)
from the from the origin to the axon terminal.
Figure 11.11 Propagation of an action potential (AP). Recordings at three successive
times as an AP propagates along an axon (from left to right). The arrows show the direction
of local current flow generated by the movement of positive ions. This current brings the
resting membrane at the leading edge of the AP to threshold,
Elainepropagating
Marieb andthe AP forward.
Katja Hoehm. Human Anatomy & Physiology, 10th Ed, 2016: p.426
 Myelin Sheath & Nerve Conduction
A.
A. Myelinated
Myelinated fibers nerve bers
Site where action potential is reinitiated

Myelinated nerve bers
" ! "

! " !

Impulse
Transmit nerve signals faster
! " !
(Saltatory conduction)
" ! "

Node of Ranvier Axolemma

Myelin sheath
B.
B. Unmyelinated
Unmyelinated fibers nerve bers
Axoplasm

" " " " " " " " ! " " " " " " " " " " " " "
! ! ! ! ! ! ! ! " ! ! ! ! ! ! ! ! ! ! ! ! ! Unmyelinated nerve bers
! ! ! ! ! ! ! ! " #! ! ! ! ! ! ! ! ! ! ! ! ! Transmit nerve signals more slowly
" " " " " " " " ! " " " " " " " " " " " " "

Demyelination causes nerve bers to transmit signals much more slowly

David Felten, et al. Ne er’s Atlas of Neuroscience, 3rd Ed, 2016: p.26
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 Synapse
86
86 Chapter5 5
Chapter
Nerve impulses reach the axon terminal → Synapse

(A)(A)
Electrical synapse
Electrical
Electrical synapse
synapse (C)(C) Chemical synapse
Chemical
Chemical synapse
synapse

Microtubules
Microtubules Electrical synapse
Cytoplasm
Cytoplasm

- Specialized gap junction
Presynaptic
Presynaptic Presynaptic
Presynaptic
neuron
neuron neuron
neuron Synaptic
Synaptic vesicle
vesicle
Mitochondrion
Mitochondrion

- Connexon

Chemical synapse **
Gap
Gap
junction
junction
Postsynaptic
Postsynaptic
neuron
neuron
Postsynaptic
Postsynaptic
neuron
neuron - Neurotransmitters
(B)(B) IonIon current
current flows
flows through
through (D)(D) - Presynaptic neuron
connexon
connexon channels.
channels. Neurotransmitter
Neurotransmitter released
released
Synaptic
Synaptic
Presynaptic
Presynaptic
membrane
membrane
vesicle
vesicle fusing
fusing Presynaptic
Presynaptic membrane
membrane - Presynaptic terminals
- Presynaptic vesicles
Synaptic
Synaptic
Extracellular
Extracellular
cleft
cleft
- Synaptic cleft
Postsynaptic
Postsynaptic
- Postsynaptic neuron
neurotransmitter
neurotransmitter Postsynaptic
Postsynaptic
- Neurotransmitter receptor
Postsynaptic
Postsynaptic
Ions
Ions flow
flow through
through membrane
membrane
membrane
membrane Connexons
Connexons receptor
receptor
postsynaptic
postsynaptic channels.
channels.

FIGURE 5.1
FIGURE 5.1 Electrical
Electricaland chemical
and chemicalsynapses differ
synapses differ synapses,
synapses, there
there is no
is nointercellular continuity,
intercellular and
continuity, andthus nono
thus
fundamentally
fundamentally
Dale in in
Purves et al. their transmission
their
Neuroscience, 6thmechanisms.
transmission mechanisms.
Ed, (A)(A)
2018: p.86 AtAt direct flow
direct flowof of
current
current from
frompre- to to
pre- postsynaptic
postsynapticcell. (D)
cell. Syn-
(D) Syn-
electrical synapses,
electrical gap
synapses, junctions
gap occur
junctions between
occur pre-
between and
pre- and aptic
apticcurrent
current flows
flowsacross
across the postsynaptic
the postsynaptic membrane
membrane only
only
 the first time, the presence of synaptic vesicles in presyn- necessary to show that each fused vesicle produce
aptic terminals. Putting these two Chemical
discoveries Synapse
together,
Katz and others proposed that synaptic vesicles loaded
quantal event in the postsynaptic cell. This challe
met in the late 1970s, when John Heuser, Tom Re
with transmitter are the source of Neuro-muscular junction
the quanta. Subsequent colleagues correlated measurements of vesicle fus
the quantal content of EP
(A) Schwann cell (B)
neuromuscular junction
RestingResting