Nervous System.pdf

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MC_101_: ANATOMY AND PHYSIOLOGY LECTURE
LECTURE 02: THE NERVOUS SYSTEM
PROFESSOR: Ms. Celisse Esguerra
1ST SEMESTER | A.Y 2022-2023

Your glands also. Your NS controls your glands so
LECTURE 00 that it secretes hormones or secretions (ex. Sweat
Hello ill jus put this after tomorrow :(( para lang rin glands)
makapag review na lahat
RECEIVING SENSORY INPUTS external and internal
·

DEFINITION OF NERVOUS SYSTEM Sensory receptors monitor numerous external and
A communication system, receiving signal from and internal stimuli
sending signals to different areas of the body Examples of Sensory Input or sensations via
At its most basic level, nervous communication ○ External Stimuli (outside the body)
occurs through electrical signals (arrow) that spread vision
over the cell membrane of neurons and cause hearing
changes at the synapse, the communication taste
junction between the neuron and its neighboring
cell.
smell
Helps coordinate body functions to maintain touch
homeostasis Pain
Homeostasis = balance Body position
Temperature
○ Internal Stimuli (inside the body)
blood pH
blood gases
Blood pressure
you usually don't feel
these unless they
become abnormal (ex.
hypertension)
these sensations are
picked up by what we
call as sensory receptors
— they receive stimulus

INTEGRATING INFORMATION with every action there is reaction Brain and Spine
·

,
a ;

means combining all the processed stimuli and in
return, initiates a response.
Remember the saying in physics = for every action,
there is an equal or opposite reaction?
○ Same goes with your nervous system
As seen in the picture, we have the CNS which consists of ○ Or since we’re comparing it to a
the brain and spinal cord, whereas the PNS (meaning away communication system, an example is
from the center) – consists of the nerves. when your talk over the phone. When your
caller asks you a question, you obviously
NERVOUS SYSTEM FUNCTIONS (CRIME) reply.
○ So the main organs responsible for
CONTROLLING MUSCLE AND GLANDS ·
cardiac Skeletal , smooth , glands
integration is your brain and spinal cord.
,

Nervous system controls major movements of the MAINTAINING HOMEOSTASIS balance -

body. It participates in controlling muscles such as
Homeostasis is balance.
cardiac and smooth and many glands.
Too much or too little of anything disrupts that
When stimulated, your skeletal muscles control your
balance and it obviously makes you sick.
body movements
So, how does take part in this nervous system?
What about when you eat?
○ Your nervous system has the ability to
○ You have smooth muscles in your GI tract.
detect, interpret, and respond to changes
So they contract as well to push what you
in the internal and external conditions.
eat down from your esophagus down to
your stomach and then towards your
intestines until you pass it out then you
defecate.
Next is your cardiac muscles = Your cardiac
muscles are continuously contracting to pump your
heart. If it stops contracting, you obviously die.

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 signals to your glands, specifically
your sweat glands and then your
sweat glands reuse all these
needs sweat to you skin. And
then it cools off your skin.

So, these are just one of the few ways, that your
nervous system controls your body so that it can
maintain homeostasis.

ESTABLISHING AND MAINTAINING MENTAL ACTIVITY
Your brain is responsible for memory, thinking, your
consciousness if you’re awake or asleep and your
mental health as well.

DIVISIONS OF THE NERVOUS SYSTEM
Example:
○ In mid-day when the sun is very high, your
body senses temperature. It sends signals
to your nervous system and it tells “hey it’s
too hot! You need to maintain a normal
range for your body temperature.”
Otherwise, what will happen? You might
get heat stroke.
So, what does your nervous system do about it?
○ It reacts by sending signals to your blood
vessels so they can dilate.
To draw,
○ sun above, skin below, blood vessels
underneath it, receptor on the side and
brain below.

CENTRAL NERVOUS SYSTEM (CNS) brain and spine

Consists of brain and spinal cord

PERIPHERAL NERVOUS SYSTEM (PNS) nerves and ganglia
Includes all nervous tissue outside CNS including
nerves and ganglia
Serves as the communication link between CNS
and various parts of the body
Carries information about different tissues of the
body to CNS and deliver commands to alter body
activities.

DIVISIONS OF THE PERIPHERAL NERVOUS SYSTEM (PNS)
So, what happens?
○ Your sensory receptors perceive heat SENSORY DIVISION afferent division towards the center
-
-

coming from the sun and then it sends Your sensory division is also called as afferent
signals to your brain. When your brain division.
perceives that sensation, it sends signals Afferent just means towards the center.
to your motor. What are your motors? In It conducts action potentials or signals from your
this case, it is your blood vessel so it is sensory receptors towards the peripheral nervous
smooth muscle. system and eventually to the central nervous
system.
So, what does it do? So, the afferent neuron is your sensory neuron.
○ It sends signals to your blood vessels so it Afferent (toward) division; conducts action
can dilate. potentials from sensory receptors to the CNS.
○ So why does it need to dilate? ○ Sensory neurons - neurons that transmit
So that the blood can easily pass action potentials from the periphery to to
through your blood vessels. the CNS
Faster. Because when it travels
faster through your blood vessel, MOTOR DIVISION efferent away from CNS ; effect
· -
or action

it dissipates the heat from your
efferent neuron, efferent, which means away from
body.
your central nervous system.
This has motor neurons.
What else?
It sends action potentials or signals from your CNS
○ Glands. When your body perceive that it is
to the effector organs.
very hot outside, what happens?
Efferent is the effect or the reaction
You perspire, you sweat. Why?
Efferent (away) division; conducts action potentials
Because when these receptors
from the CNS to effector organs
perceive signals that it is hot and
goes to your brain and brain send

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 ○ Motor Neurons - neurons that transmit CELLS OF THE NERVOUS SYSTEM
action potentials from the CNS toward the
periphery COMPOSITION OF NEURONS
Also called nerve
DIVISIONS OF MOTOR DIVISION cells
Receive stimuli,
SOMATIC NERVOUS SYSTEM CNS to sucletal muscle
·

conduct action potentials,
Transmits action potentials from the CNS to the transmit signals to other
skeletal muscles
neurons or effector organs
“Soma” – the word soma in Greek means body.
Remember your
Skeletal muscles is involve to your bodily
movements, your voluntary body movements. neurons are connected to
each other so they either
AUTONOMIC NERVOUS SYSTEM (NG cardiac smooth glands (self-governing ;voluntary
·
to , , receive stimulus or action
“Auto” means self-governing. potentials from other neurons
It transmits signals(action potentials) from your CNS or can also receive stimuli
to your cardiac muscles, smooth muscles, and your from other receptors.
glands.
Auto is self-governing, these are involuntary so this CELL BODY one nucleus
happens automatically. contains single
You don’t have conscious effort. This then divide nucleus.
further divided into sympathetic and Source of
parasympathetic. information for gene
Sympathetic - fight or flight system expression
Parasympathetic - rest and digest system Nucleus is
surrounded by rough ER,
ENTERIC NERVOUS SYSTEM intestines (independent (
·
mitochondrion and Golgi body
Unique subdivision; both sensory and motor that are floating in the side of
neurons contained within the digestive tract; can nucleus.
function without input from CNS and PNS
Enteric means intestines. DENDRITES receive and transmit information
-

It is very independent of your CNS and PNS. cytoplasmic extension from the cell body.
They are expanding from your cell body.
They usually receive information from other neurons
SUMMARY: and transmits the information to the cell body.

AXON
single long cell process. In the illustration, it is the
long yellow thing.
It starts from the axon hillock (the triangular end
part).
○ “Hillock” means hill so this looks like hills.
Axon are usually unbranched since they are a
single long process.
But sometimes they form what they call collateral
axon.
Let’s start with your sensory input: the light, sound,
○ So there is an extra axon. This works just
smell, touch, etc. sensory receptors which perceive
the same as an unbranched axon.
or receive those sensory input.
Axons can be surrounded by highly specialized
It sends the signals to your sensory divisions. This
insulating layer of cells called
is still in your peripheral ns.
○ Myelin sheaths — the transparent or
Once it receives the stimulus it sends the signal to
translucent purple ones that covers the
your CNS.
axon and they are insulators.
○ First to your spinal cord then to your brain.
Once CNS has processed this, it then
sends signals to your motor division. NOTE:
Your motor division has somatic and autonomic ns. When a neuron dies, it is no longer replaced
Somatic means soma which means body so it because it does not divide and does not multiply.
controls your body functions this means your
skeletal muscles which are responsible for body QUESTION: How does the neuron transmit signals?
movement.
Your autonomic, auto, is also further subdivided to
parasympathetic and sympathetic division. when a neuron dies, it’s no longer replaced,
○ It is responsible for involuntary movements
which involves cardiac, smooth muscles because it DOES NOT DIVIDE and MULTIPLY
and glands.
So what happens?, it affects the metabolism, heart
rate, breathing, etc.

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 So, it’s like unipolar but its not.
○ Uni means one.
○ So you have a single process extending
from your cell body.
○ It then divides into two processes. It
branches into two.
○ The cell body transmits action potentials to
that one process and then it splits into two
directions.
○ One goes to the CNS and one goes to
PNS.

QUESTION: How does this work
compared to the first two which has
dendrites connected to the cell
body?

Your peripheral axon in this, acts as a
Through action potentials. dendrite. It receives sensory information
What is action potential? and immediately transmit this as an
○ They are a change of the resting action potential to CNS. That’s why the
membrane potential. They are like sensory axonal branch it has a sensory
electrical impulses. receptor over there.
Example:
Once you touch your cheek, it starts with the
sensory receptor, sending signals to the dendrites
towards the neuron cells and then the axons of the
sensory neurons transmit action potentials towards
your CNS.
CNS must process this, then the motor neuron so
then it will then conduct action potential away
towards your muscle to the effector organ.
Take note that the axon may also conduct action
potential from one part of the brain to another.
Same to the spinal cord.

TYPES OF NEURONS The dorsal root- the swelling part. The green part in
This depends on either function or structure. the picture is the dorsal root ganglion is an example
What we discuss a while ago is based on their of pseudo-unipolar neuron.
function. So the axon divides into two branches – the
When it comes to the structure there are 3. peripheral branch, and the central branch
They are named after their number of processes. ○ The peripheral branch picks up sensation
from your skin, while the central branch
transmits the information to the PNS
(Spinal Cord and Brain).

TYPES OF GLIAL CELLS (NEUROGLIA)
Supportive cells of PNS and CNS
Non-neuronal cells of the neuroglia or glue nerve

CNS + PNS they do not conduct
-

More numerous than action potentials

neurons
Retain the ability to
divide
There are 4 Glial Cells in
MULTIPOLAR NEURONS -most ; has many dendrites
common but only one axon CNS while 1 in PNS
Multi means many. Glial cells are what we
So it has many dendrites and only one axon. Most call your neuroglia (or
neurons in your CNS and motor neurons are multi nerve glue) they are
polar supporting cells.
found in sensory organs (retina and naval cavity ( ○ Take note that they do not conduct action
BIPOLAR NEURONS -
can be

Bi means two, so you have one dendrite and one potentials.
axon. ○ They are just supportive cells because
This can be seen in sensory organs, most they enhance neuron function so they are
exclusively in your retina and nasal cavity. like boosters.
○ Retina - eyes (2) Neurons cannot divide but glial cells can divide.
○ Nasal cavity - nostrils (2) These are schwann, microglial, oligodendrocyte,
just to name a few.
PSEUDO-UNIPOLAR NEURONS dendrites -
no
more numerous than neurons since they can divide

Pseudo means resembling or imitating. It looks true
but it’s not.

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 IN CENTRAL NERVOUS SYSTEM:

ASTROCYTES -blood-brain barrier

They are major
supporting cells in the
CNS.
1. They
stimulate or inhibit the
signaling activity of nearby
neurons—that’s one
function.
2. they form the blood-brain barrier( a
permeability barrier—a barrier between
blood vessels and brain ).
Blood barriers are like filters that
permits specific substances to
enter your brain.
3. Another function, astrocytes also limit
further damage of your neural tissue so it
does not die.
However, it forms a scar—and
whatever is damaged can no
longer regenerate but that part of
the neural tissue will still not die.

EPENDYMAL CELL -

cells line the cavities in the brain that contains (OF

MYELIN SHEATHS
Myelin sheaths are specialized layers that are wrap
around the axons of some neurons formed by
It lines the fluid-filled cavities like the ventricles oligodendrocytes and Schwann cells.
L CNS L PNS

(third and fourth ventricles, which actually have They are repeatedly wrapped around the segment
Cerebrospinal Fluid). of an axon.
○ CSF is produced by your glial cells. It forms a series of tightly wrapped cell membranes
○ CSF is a fluid made of this cell and it helps so it looks like a croissant.
protect your brain and spinal cord from it prevents almost all iron movement across the cell
sudden impact or injury. membrane.
○ It’s like a cushion or helmet in fluid form. It also increases the speed and efficiency of the
○ Another is that it removes waste products action potential.
from your brain and it makes sure it is
clean so CNS can work properly. The node of Ranvier however, are gaps between
○ Ependymal cells have cilia that help move myelin sheaths.
the CSF through the CNS. ○ So obviously, they are not covered with
myelin, they are not insulated and they
MICROGLIAL CELL -
immune cells ; they remove bacteria and cell debris
allow ion movement.

This acts as immune
cells so it has immune functions.
They remove bacteria
and cell debris.

OLIGODENDROCYTES provides myelin sheet for in CNS axons

provide myelin to neurons in the CNS.
Myelin is an insulating material that surrounds the
axon.
Next is unmyelinated neurons.
IN PERIPHERAL NERVOUS SYSTEM:
○ They are axons without myelin sheaths
PNS that rest in the indentation of glial cells.
SCHWANN CELLS provides myelin sheets for axons in

Example:
Provides myelin that surrounds axons (only in PNS) ○ A small typical nerve that consists of axons
of multiple neurons usually contains
unmyelinated axons than myelinated.

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 CLINICAL PICTURE: MULTIPLE SCLEROSIS Polarized means: to divide into two opposing
Multiple sclerosis is an autoimmune disease--the groups (a positive and a negative). A small
immune system attacks the myelin sheaths and voltage difference is called potential.
destroys it. ○ You have 3 factors that generate the
The result is communication problem in brain and resting membrane potential:
organs. Because of this, patients have a loss of a higher concentration of
muscle function, they cannot walk properly, potassium inside the cell,
experience numbness, and feel paralyzed as well a higher concentration of sodium
because they cannot transmit action potential. outside the cell,
and cell membrane permeability
preference to your potassium as
compared to your sodium.

CELL TYPES DESCRIPTION
Neuron
Multipolar Many dendrites: 1 axon
Bipolar 1 dendrite: 1 axon
Glial Cells of CNS
Astrocytes BB Highly branched
Ependymal Cells CSF Epithelial-like
Microglia Immune Small, mobile cells
Oligodendrocytes Cell with process that can surround
CNS Myelin several axons
Glial Cells of PNS
Schwann Cell PNelinSingle cell surrounding axons

ORGANIZATION OF NERVOUS TISSUE
Nervous tissue varies in color due to the location
and arrangement of the parts of neurons and glial
cells.
Sometimes, it depends if they have myelin sheaths.

GRAY MATTER outside of the brain little myelin sheets
·
;

The gray matter consists of neuron cell bodies and ION CHANNELS
their dendrites where there is very little myelin. Basis of difference in membrane permeability
It is in the cortex or outside of the brain. Proteins embedded in cell membrane
Clusters of gray matter located deep within the Example of ion channels is your gated and leak
brain are called nuclei. channels.
In contrast to your peripheral nervous system, a Also, there is a fact that there are negatively
cluster of cell body is called ganglion or a swelling. charged molecules such as proteins inside the cell
that are too large to exit the cell that’s why the
WHITE MATTER has myelin sheet that's why it's
· white inside is more negative as compared to your
outside.
White matter are bundles of parallel axons with their
white myelin sheaths that’s why they are white.
TWO BASIC TYPES OF ION CHANNELS
In the CNS, it forms nerve tracts.
Remember, white tracts are conduction
LEAK CHANNELS always open potassium leak channels
·
;
pathways propagating action potentials from
one area of the CNS to another. It is truly channel’s that the resting membrane
And the PNS is bundles of axons plus your potential is established because it’s always open
connective tissue forms the nerves. that’s why it leaks.
Remember from high school chemistry what is the
rule, substances tend to go from higher
ELECTRICAL SIGNALS AND NEURAL PATHWAYS
concentration to lower concentration, that is how it
always is.
POLARIZED CELL MEMBRANE
Okay, from higher concentration gradient to lower
Uneven distribution of charge
concentration gradient.
RESTING MEMBRANE POTENTIAL Potassium contributes the most to the resting
Membrane potential is the difference in the membrane potential because there are 50 to 100
times more potassium leak channels than your
electrical charge between the inside and the outside
sodium.
of the cell/neuron
So, since there are more channels, it is easier for
The inside is usually negative, while the outside is them to just in and out of the cell membrane as
usually positive. That is when it is at rest. compared to your sodium.
So the unstimulated, unevenly distributed
charge is called the resting membrane potential. GATED CHANNELS
Take note that it is the time when your cell
Gated Channels only opened via a specific signal,
membrane is polarized.
that is why it is called gated, it has a gate. It does

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 not just let substances in and out like the leaky Now, remember because of the many potassium
channels. leaky channels, the positively charge potassium
○ Your chemically gated channels are goes outside the cell, why?
opened by neurotransmitters, or ○ Because it has a lower concentration
sometimes other chemicals, but mostly there, so it goes from higher concentration
your neurotransmitters. to lower concentration.
There’s a receptor on these gates ○ What happens?
one a neurotransmitter attaches The inside becomes more
to that receptor, it opens up. So, negative because your potassium
it’s like a hotel key, you tap it, and is going out, it’s a positive charge.
the door opens. Your However, since the opposite
neurotransmitter is the hotel key. charges attracts, again your
○ Another gated channel is the potassium has no choice but to
voltage-gated channel as compared to move back in.
your chemically gated channel that is What happens it just goes in and
opened by neurotransmitters, your out of the leaky channels.
voltage-gated channels are opened by a
change in your membrane potential. That’s Again, when we are talking about resting membrane
why it is voltage-gated, it's opened by the potential, everything is at rest, this is the norm.
change in the charge or the voltage of the There is a point of equilibrium since the potassium
membrane. is going out of the cell and its balanced by the
negative ions inside the cell in which it attracts the
When there is a change in the membrane potential, this is potassium to go back in.
also what we called the Depolarization ○ Think of these ions, as a negative and
polarized means its divided into two completely strict parent, you badly want to go out, it is
opposing roots, negative in positive out. in your nature, you can’t help it, that is just
how you are.
Depolarization means the difference decreases, so instead ○ So, you go from higher to lower
of all of this is negative inside and then everything is positive concentration, you want to go out.
outside it becomes mixed or the inside becomes more Whenever you are out, partying with your
positive, and the outside becomes more negative. friends, the negative ions pull you back
-
inside becomes more positive outside
,
becomes negative home.
How does this happen, how does depolarization ○ The strict parent, your negative parent and
happen? you have no choice but to follow.
Okay, remember you have sodium leak channel, ○ But then you will ask, but Doc if there’s
right? Even if there only a few, it has more potential also sodium leaky channels, even if there
to go inside the cell than backout because it goes only a few won’t then negatively charge
from higher concentration to lower concentration, ions prevent the sodium from going back
okay that is one. out.
Another is the inside of the cell is originally more
negative as opposed to the outside. What is the And also, you can’t go from lower concentration to
second factor? higher concentration right. Won’t there be
○ Opposite charges attract, so again your eventually become more potassium outside the cell
sodium which is positive is being sucked than inside if these keeps going on or there will be
inside your cell because it's negative more sodium ions inside the cell.
inside. To answer that question, you have the sodium
○ So what happens?, since more sodium is potassium pump to help.
going in, coming in the inside of the cell ○ To compensate for the potassium leakage,
becomes more positive than usual. the membrane has to make sure that there
is greater concentration of sodium outside
So the membrane no longer has that much and potassium in.
difference in charge, right? ○ You have to maintain that, that’s normal,
○ It becomes more depolarized. that’s the balance of this cell.
○ Due to this depolarization the channel
opens, the voltage-gated channels opens. When activated by the ATP Adenosine
Triphosphate, ATP is basically energy, so just
If your leak channels are responsible for imagine you prompt to pump into a socket or you
maintaining the resting membrane potentials, put batteries on it, it becomes activated.
opening your voltage-gated channels starts an With every 2 potassium ions that comes back inside
action potential. the cell, it pumps out 3 potassium ions.
○ It's no longer resting, it's already an action So, this how it compensates and helps the sodium
because you depolarized the membrane. ion to go back outside the cell where it has higher
concentration.
SODIUM-POTASSIUM PUMP Now remember this pump will only work when you
The reason why the inside of the cell is negative is have ATP or energy. Especially in neurons where it
because there is more negatively charge molecules requires 70% ATP.
like your proteins, they are impermeable in the Does it makes sense? That even if you are just
membrane. sitting and don’t move around much when you
study, you feel like you as if you become more tired
than usual is because posture frame consumes a
Impermeable means its not permitting to passed lot of energy ‘when its working.
through, so it stays inside. So again, to summarize this, leaky channels,
potassium is going out from higher concentration

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 but its pulled back in due to the negative charge of leaky channel are open because
the inside of the cell. they don’t have gates.
The sodium goes in the cell because it goes from So just think the leaky channels
higher concentration to lower concentration; at the are back door passes, so it is only
same time the positive charge of the sodium is for party staff.
attracted to the negative side of the cell. They can go inside more easily
So it is going to have a difficult time going back and earlier than the rest.
outside the cell because the force inside of the cell So they are hyped up, they carry
is very strong. positive vibes inside the house
Higher to lower concentration plus negatively because the potassium carries
charge pa siya; so this is controlled by your positive vibes inside the house.
sodium-potassium pump to help the sodium get out Then it is time to start the party, it
of the cell to maintain the normal balance. is already 7 pm.
That every 2 potassium it discharges, or it brings So upon stimulus, the cell is
out 3 sodium ions. So that is how you make sure to stimulated, upon the stimulus of
keep the resting membrane potential. the nerve cell or the muscle cell
with the neurotransmitter (hotel
ACTION POTENTIALS keys or the VIP tickets), it briefly
opens your sodium channels and
some sodium diffuses quickly into
the cell.
So only the VIP guests gets to go
inside because the door only
opens for a while.
This is what we call
local current when the
sodium channels
briefly open and some
sodium ions come in.

So the party gets more hyped because the VIP
guests arrived, more positive vibes so this local
current process the depolarization because it
makes the inside of the cell more positive or less
negative.

This depolarization in turn causes a local potential.
This usually occurs in your dendrites – or in your
soma.
○ If the depolarization isn’t strong enough,
the sodium channels close and this local
potential disappears.
So imagine:
○ Your VIP guests didn’t attract too much
attention – the party was a flop, ended
early and gates were closed.
○ However, if the depolarization is strong
enough because of the stimulus, more
sodium enters the cell because it keeps
the channels open.
○ The channels don’t close. The channels
are open until it reaches a threshold value.
This threshold is most often reached at the axon
Your muscles and nerve cells are excitable cells, as hillock.
long as there is a stimuli, the resting membrane ○ This is called your all or none law.
potential can change via the gated channels The action potential either occurs
It allows permeability of some substances which will or it doesn’t – depending on
previously de-permeable and then eventually it whether it reaches the threshold
produces an action potential because you So the party either flies or flops.
depolarized the cell. That’s what the all or none law
○ Let us apply what we learned a while ago means.
to explain action potential, let us also So more guests with positive vibes come in
compare this to a house party so that you because the gates were opened longer.
can understand better. ○ More depolarization
Situation, before the party the ○ More positive charge inside the cell
house is resting right? It is silent, ○ Because of this, it triggers the opening of
there has no guest, there is no your voltage-gated channels.
that much people.
So the house gates are closed Because the party was fun the staff says “Hey, hey
because the party has not started we need to open more gates!” So aside from the
yet. sodium-gated channels, the
So at the rest the voltage-gated sodium-voltage-gated channels also open.
channel were closed, only the

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 The inside of the cell becomes more and more
positive in a faster pace. So even your
sodium-potassium pump can’t complete.

During this time, however, your
potassium-voltage-gated channels also open.
○
The exit doors:
○ So you have guests with curfew so they
have to leave early. But there are just a
few of these doors opening.
○ More guests are still coming in. This
occurs until it reaches a brief time when
the inside of the cell is now more positive
than the outside.
1. This stimulus causes or initiates the depolarization
○ Because of this, the cell thinks: “Oops, this
of the cell. If the depolarization is not strong
is too much. Full house na”
enough, it will have failed initiations.
○ So what happens? The cell membrane
This is what we call the “all or none law”
now then closes your sodium channels to
stop more sodium from entering.
2. However, if it reaches the threshold, the
○ During this time, they are not letting other
depolarization will become higher and higher
guests in. More potassium channels are
because more sodium ions are coming in. So the
opening.
inside of the cell becomes more positive.
Remember, it didn’t open at the
same time as the sodium
3. Until it reaches the peak where the inside of the cell
channels. What happens here is:
is now more negative than the outside of the cell.
Potassium ions goes
What happens?
outside where there is
Your sodium-ion channels start to close
lesser potassium
and then more potassium ions start to
concentration
open.
What happens then?
Since there are no more sodium ions going
○ The inside of the cell becomes more
in, the inside of the cell will become less
negative again.
positive or more negative
○ Kasi labas na siya nang labas eh
At the same time, the inside of the cell will
○ All the positive potassium ions are already
again be more negative because positive
going outside, and none of the sodium ions
potassium ions are going out of the cell
are going in
○ And this is what we call
○ This occurrence repolarizes your cell.
repolarization because you’re
○ Cell membrane goes back to its resting
trying to put the membrane
membrane potential
potential back to its resting state.
○ Depolarization and repolarization
constitute an action potential
4. However, there is also a short period of time where
Everything that happened in this
hyperpolarization occurs. Because more and more
party is the action potential.
potassium are going out of the cell.
At the end of
5. But then again, this becomes balanced and goes
repolarization, the
back to its resting state once the potassium ions
charge on the cell
become closed.
membrane briefly
becomes more
ACTION POTENTIAL UNMYELINATED AXON
negative than the
Action potentials are conducted slowly in
resting membrane
unmyelinated axons, and more rapidly in
potential.
myelinated axons.

UNMYELINATED AXONS slower -

You call this hyperpolarization.
It is beyond the resting membrane potential. Naked ones
Nasobrahan because the potassium channels were Here we can see that in this part of the axon, the
open. cell membrane stimulates local currents in the
adjacent part of the cell membrane.
Elevated permeability of this potassium lasts only a Local current
very short time. This hyperpolarization is also only ○ Is when the sodium flows into the cell.
for a short time. ○ It’s that brief period where the sodium
channels were open. So it depolarizes that
Do take note that ALL action potentials have the part.
same magnitude. So a stronger stimulus does not ○ That part in return, produces an action
produce a stronger action potential but it produces potential and then that new part again
more action potentials. stimulates local currents in the next part
and depolarizes it. This goes again and
Stronger stimulus = more action potentials. It again.
increases the frequency of the potential generation. This is what we call as
(continuous conduction).

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 Because the action is ○ Sodium ions come in which makes it more
continuously conducted or positive and then it depolarizes this area
passed along the axon. resulting in another action potential.
○ Again it bumps positive ions in the myelin
MYELINATED AXONS faster
·

sheets (second rectangle), and then it
The action potential is propagated faster. reaches another node. And, it jumps from
The myelin sheath acts as an insulator. It does not one node to another.
have ion channels which means depolarization cant
occur in this area SYNAPSE

If you see the orange one above, that area is the
Node of Ranvier. It produces an action potential
because it does not have any myelin. Once there is
an action potential in that space, the sodium ions
bump other positive ions until this wave depolarizes
the next node over here.
Neuronal synapse is a junction where the axon of
one neuron interacts with another neuron or effector
organ.
The end of the action forms a presynaptic terminal.
The membrane of the next neuron forms the
Since this node has ion channels, it causes local postsynaptic membrane, with a synaptic cleft in
current through extracellular fluid and then through between.
the cytoplasm of the next axon in the next node, ○ Cleft - means a division, fissure, or a split
causing another action potential.
○ So it sort of jumps from node to another The round ones in the presynaptic terminals are
node. called vesicles.
○ This is called your saltatory conduction ○ within the synaptic vesicles there are
Saltatory = to leap neurotransmitters.
○ note: action potentials are being conducted
Advantages of Myelinated axon; along the axon, once it reaches the end of
○ Because of the jumping of action the axon (or the presynaptic terminal), the
potentials, conduction velocity is voltage-gated channels of the calcium
increased. Through the ions are conducted opens.
along the cell membrane just to produce There is a new ion involved here, calcium, the influx
an action potential. of calcium causes the synaptic vesicles to latch on
○ Note: Ions are only conducted in the nodes the cell, and then release the neurotransmitters via
and not where there is myelin. exocytosis.
○ Because of this, lesser energy is required
for the sodium potassium pump to
The neurotransmitter then crosses the cleft and
binds to the receptor molecule over the
maintain iron distribution
postsynaptic neurons.
○ Sodium potassium pump requires ATP but
in the areas (internode) where there is ○ Note: Neurotransmitters are like keys to
myelin it doesn't have any channels. the channels. The receptors are the lock.
Ligand-gated channels for sodium, potassium,
As compared to unmyelinated all the areas will chloride are delegated to the postsynaptic
need ATP because of the ion channels. membrane and then they either open or close, they
So, having myelinated also conserves energy. are either stimulated or inhibited by the
neurotransmitters.

Do neurotransmitters always activate action potential?
No. It depends on what type of neurotransmitter it
is, and what type of receptor there is.
If the neurotransmitter opens sodium channels
depolarization occurs because it causes the inside
cetamine to be more positive or less negative.
If the potassium or chloride channel opens it
hyperpolarizes because your chloride ions which
are negative contain and the positive potassium
ions go out. so both of them go down their
concentration gradient. Therefore, the action
potential is generated.

When there is an action potential (on the first circle), From the chapter of the cells extra cell uni-ions
myelin sheets (first rectangle) don't have ion (means outside of the cell), sodium, calcium,
channels, positive charges are getting bumped until chloride
they reach the area (second circle), this area has ○ intracellular ions are mainly your
ion channels. potassium, few sodium, few chloride, but
What happens? mostly the negative ion proteins.

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 Simplest reflex act don't include interneurons
Neurotransmitters don't usually remain in the ○ When you touch something hot, the heat
synaptic class indefinitely, it doesn't stay there. stimulates pain receptors in skin. Thus,
Thus their effect on postsynaptic membranes are producing an action potential towards your
short in duration. These substances are either sensory neurons (at the back).
rapidly broken down by enzymes. ○ This conducts an action potential to the
○ ex. Enzymatic degradation - these happen spinal cord where it synapses with the
also in the synaptic or they are transported interneurons and then towards the motor
back into the presynaptic terminal. neuron, conducting action potentials to the
flexor muscles (in the upper limb). These
MOST COMMON NEUROTRANSMITTERS limbs then react by contracting and pulling
Acetylcholine (Ach) the hand away from the hot object.
Norepinephrine ○ Reflex arc doesn't go up the CNS.

Acetylcholinesterase - enzyme that breaks down NEURONAL PATHWAY (CONVERGING)
the acetylcholine and these products go back to the 2 or more presynaptic to one
postsynaptic
presynaptic terminal for recycling.
○ Aside from being broken down by
enzymes, Norepinephrine can also be
actively transported back into the
presynaptic terminal. So this transfer of
your transmitter occurs rapidly countless
times per second and these are affected
by numerous diseases on drugs.
○ so these are very fast

REFLEX
involuntary reaction in response to a stimulus
applied to the periphery and transmitted to the CNS.
A converging pathway - simple pathway in which
○ This allows a reaction faster than two or more neurons synapse with the same
conscious thought. postsynaptic neuron
react to stimuli more quickly than conscious thought This allows information transmitted in more than
occur in the spinal cord or brainstem(rather than the one neuronal pathway to converge into a single
higher brain centers) pathway.

REFLEX ARC NEURONAL PATHWAY (DIVERGING)
↑ presynaptic to 2 postsynaptic

A reflex arc is the neuronal pathway by which a
reflex occurs.
basic functional unit of the nervous system because
it's the smallest, also the simplest pathway capable
of receiving a stimulus and then giving a response.

A diverging pathway - (also a simple pathway) an
axon from one neuron divides and synapses with
more than one other postsynaptic neuron.
This allows information transmitted in one neuronal
pathway to diverge into two or more pathways.

SUMMATION
A single presynaptic action potential usually doesn't
cause efficient postsynaptic local potential to reach
a threshold, it's too weak. So obviously a single
1. A sensory receptor presynaptic action can't achieve a threshold and
2. A sensory neuron can't produce an action potential.
3. Interneurons (in some reflexes, located between
and dominacating with two other neurons that's why How to achieve a threshold?
it's called interneurons) ○ Many presynaptic action potentials are
4. A motor neuron needed, this is what you call summation.
5. An effector organ (muscle or glands)

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 ○ Multiple subthreshold local potentials are
added or integrated to cause a local
potential enough to trigger an action
potential.

SPATIAL SUMMATION multiple inputs
-

Occurs when the local potentials come from
different locations of the postsynaptic neurons.
Multiple locations
For example, converging pathways

TEMPORAL SUMMATION single input but fired rapidly
-

It occurs when the local potential overlaps in time,
like when a single input fires rapidly. The local
Cervical, Thoracic, Lumbar, Sacra
potentials then overlap briefly. Gray matter is a collection of neuronal cell bodies.
The result of this summation depends on the type of It looks like an 'H' or a butterfly.
signal given whether it is stimulatory or inhibitory. ○ Posterior horn that contains interneuron
Only one location but action potentials fired rapidly. ○ Anterior horn contains Somatic motor
neuron
○ Lateral horn is responsible for Autonomic
THE NERVOUS SYSTEM
Nervous System (ANS)
○ Central canal, the hole in the middle, is
CENTRAL NERVOUS SYSTEM
where your cerebral spinal fluid flows from
Brain (located in skull) your brain. (CSF the fluid that protects
spinal cord (located in vertebral column or spine) your brain)
PERIPHERAL NERVOUS SYSTEM White matter is superficial.
Nerves and ganglia outside the brain and spinal ○ consistent of myelinated axons (white
cord because of myelin sheets.
○ 12 pairs of Cranial nerves Divided into three columns
○ 31 pairs of spinal nerves ○ Dorsal -posterior column
○ Ventral - anterior column
SPINAL CORD ○ Lateral - contains ascending and
Extends from foramen (hole, opening) magnum descending tracts
(bake) to hole
means Tract - there are axons in your (CNS)
○ foramen magnum is located at the base If it's in PNS the name is different.
of the skull ↳ big
○ extends to the second lumbar vertebra and Ascending tract/pathway - up towards the brain
ends in the conus (looks like a cone) Descending tract/pathway - going away from the
medularis. brain
○ filum terminale - long tail or strand (part
of the spinal cord).

Cervical, Thoracic, Lumbar, Sacral, Coccyx
communicates with the body through Spinal nerves.

SPINAL CORD

DIVERGING PATHWAYS from sensory neurons to ascending path (brain
·

For the muscle contraction to occur a stimulus must
be present. This stimulus is picked up by the pain paying
receptors and activates the sensory fibers and the
sensory neurons carries the action potential
towards the spine. The axons of the sensory
neurons branch within the spinal cord.
One branch produces a reflex by synapting in
interneuron, then interneuron synapses to motor
neurons without any stimulus coming from the
brain, because it occurs without conscious talk This
produces a jerking movement of the muscle away
from the stimulus.
Other branch carries action potentials synapses
with the ascending neuron where it ascends
towards the brain and the pain is perceived.

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 Reflex- if the sensory neurons synapses it diverges Arise from numerous outlets (form the root where
(one in the interneuron and one in the ascending they are located)
tract, towards the brain) Spinal nerves allow movements and if it's damaged
it can cause paralysis.
CONVERGING PATHWAYS from drain to motor (descending)
neuron Dorsal and Ventral roots join to form the Spinal
When the interneuron synapses with the motor nerve.
neuron to produce an action from the muscle (reflex ○ Dorsal root ganglion (swelling)
arc); there are also signals coming from the ○ contains cell bodies Pseudounipolar
cerebral cortex, this controls the conscious sensory neurons
movement. These neurons also synapses with the Pseudounipolar axons have a peripheral branch
same motor neuron, this is coming from the axons and an ascendal branch. This axon originated in the
from the descending tracts. periphery or the side of the body and it passes
○ Motor neuron - can be stimulated by either through the spinal nerves up to the sensory neuron
conscious thought or reflex arc. to the dorsal root and to the posterior horn where it
synapses to the interneuron. Interneuron synapses
REFLEXES to motor neurons pass through the ventral root out
tomonosynaptic
A stretch reflex occurs when muscles contract in to the spinal nerve towards the effector organ.
response to a stretching force applied to them. (Reflex arc)
The knee-jerk reflex, or patellar reflex is a classic If it passes into the white matter it either descends
example of a stretch reflex. or ascends in your spinal cord. (where the
Withdrawal reflex, or flexor reflex descending and ascending tracts are)
↳ poly synaptic The Dorsal area picks up the outside stimulus
(sensory neurons), located in the back portion of the
spinal cord)
○ ex: When someone wants to catch your
attention they tap you on the shoulder from
your back. And then you sense their
presence.
The motor neurons are located towards the Ventral
or the anterior portion of the cord.
⑪ ○ ex: By shaking hands as a greeting, you
offer your hand forward.
Arise along the spinal cord from union of dorsal
roots and ventral roots.
Contain axons sensory and somatic neurons called
mixed nerves
Located between vertebra (spine)
Categorized by region of vertebral column from
which it emerges (C for cervical)
KNEE-JERK REFLEX 31 pairs
patellar (knee) ○ 8 pairs of Cervical roots
leg bone (femur, long bone in the leg) ○ 12 pairs of Thoracic roots
quadriceps femoris - rior
anterior of thigh muscles, ○ 5 pairs of Lumbar roots
flexor muscles ○ 5 pairs of Sacral roots
flexor muscles: ○ 1 pair of Coccygeal roots
○ Semitendinosus ○ Organized in 3 plexuses
○ Semimembranosus
○ long and short head of biceps femoris
(located in posterior)

Once the patellar ligament is tapped with a hammer
the interior muscles and its tendon stretched. Then
reflex occurs.
When quadriceps femoris muscle contracts it
becomes shorter and then it lifts the lower leg
forward.
○ when you tap your leg, you see your lower
leg kick (knee-jerk reflex)
Clinically, this is used as physical activity to test if
the CNS is functional (descending neurons
converge then synapse with the neurons of the DERMATOMES
stretched reflex your inteneuron to modulate the
activity for posture, coordination, etc.)
What happens when you fall? And received a blunt
trauma on your back. It becomes inflamed then
causes damage to the spinal cord tissue. If the
spinal cord tissue is damaged you lose all reflexes
below the level of injury. Once it recovers it
becomes hyper excitable.

SPINAL NERVES
Exits at cauda equina (looks like a tale)

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 (sensory innervation in the skin )
C1 is the only spinal nerve that doesn't have
sensory distribution to the skin.
How do dermatomes supply the skin?
○ bend forward, stand in all force

SPINAL PLEXUSES (GRADE)
In these plexuses neurons from different spinal
nerves and segments intermingle.
For sensory neurons provide sensory innervation
from the skin in that area,