Autonomic Nervous System PDF

Summary

This document provides an overview of the autonomic nervous system. It details the basic structure and function of the sympathetic and parasympathetic nervous systems, and discusses how they communicate. The document also covers sensory and motor pathways.

Full Transcript

All right, so we are going to redo the autonomic nervous system recording here So
the first part we're just going to go over some basic information about the
autonomic nervous system, and then we're going to spend Time on the sympathetic
nervous system Okay, so learning objectives of course autonomic nervous system.
What is it? What does it do right? So this is going to control Involuntary
unconscious stuff going on inside your body right so not only are we going to
control that via motor But we also have some sensory innovation going on monitoring
what's going on in our bloodstream and also in terms of Visceral sensory or if our
organs get Inflamed or there's something extremely painful going on so it's going
to primarily work through motor Innovations so when we talk about the autonomic
nervous system We are primarily talking about that efferent innervation unless we
specifically talk about the efferent arriving innervation, right? So this is going
to impact smooth muscle, which is going to be the muscle that we find in our organs
modified cardiac muscle So our muscle of our heart is a little bit different than
the other muscle we have and then glandular cells Which will secrete and then
extrude the materials that they make whether that's directly into the blood supply
or? On into onto a certain surface or area our sensory is going to travel alongside
those motor pathways But of course they are going to the information is going to
travel in the opposite direction, right? So while motor comes out sensor is going
to travel the other way and when we talk about interim posterior Horns and anterior
and posterior roots sensory still will go through posterior structures motor will
go through the anterior structures Okay, how does it communicate?

This is quite simple and Straightforward but something that's very important to
keep in mind, right? So we are going to have a series of two neurons, right? So we
have a first set which is going to call be called pre ganglionic and then the
second is post ganglionic, right? So in this image here, we can see the neuron cell
body Remember that there's going to be many of these in its axon Axon then we'll
synapse on the second kind of set of neurons, which are our post ganglionic, right?
So we are talking about this communication here in terms of ganglionic, which will
then send that information to the effector organ So in this image we can see we're
going to have our pre ganglionic neurons right here for an example Coming through
and maybe going to our post ganglionic neuron right here and continuing on, right?
So it's always going to consist of two we're starting as those nerves Or the series
is coming out of the spinal cord the central nervous system We will see multipolar
and Unipolar neurons just like we saw in terms of our somatic sensory and motor
organization Pathways involved, right?

Pathways involved, right? So we talked about pre and post ganglionic pathways now
for motor innervation more specifically, right? Our pre ganglionic neurons really
are what we kind of have come to think about as lower motor neurons, right? So
before when we talked about somatic sensory and motor only our somatic motor We
talked about lower motor neurons as peripheral nerves We will still include
peripheral nerves in this But we would now add what we call splenchnic nerves as
well here So lower motor neurons is kind of what you can equate to these two
They're going to start in the central nervous system gray matter for our purposes,
right? Exit the central nervous system via that anterior root because it's motor
Sit-ups on autonomic ganglia which are going to be located in different places
Depending on which pathway we're looking at then our post ganglionic neurons are
going to be those that form These things that we call splenchnic nerves And then
they're going to travel send innervation to organs in the body or the skin Alright,
so in terms of our different divisions of the autonomic nervous system.

We do have sympathetic and parasympathetic Again, we're talking about these
efferent fibers unless we talk about sensory specifically So sympathetic is going
to be that fight or flight situation or pee, right? So we have another response
that we can call on which is to urinate on ourselves to make Enemies people who are
threatening us not want to come near us, right? so this is our flight our fight
response and Primarily this is going to regulate vessels.
So our arteries and our veins through vaso motion what we mean by this is that as a
Dilation or constriction of the arteries and of the arteries in our body, right? So
if we have it dilated we can send more blood To places which means more oxygen
supply or we can decrease What we're sending in order to you know, send other
places. So if we decrease the size of our Of our vessels, we're sending less of our
resources there Parasympathetic is basically just bringing our systems back into
homeostasis Which allows us to rest and digest so we can call this catabolic for
sympathetic anabolic state for parasympathetic All right, so we walk through this
We're going to go through these Again, kind of throughout the lectures here But we
want to think about what happens to the sympathetic and parasympathetic nervous
nervous systems in these locations So for the eyes if we have a sympathetic
response We are going to allow for people with dilation specifically when we're
talking about the eyes And that allows more light to come in to perceive our
surroundings more fully Our parasympathetic kind of response is going to bring our
pupils back to that normal constriction Items that we will look at in this block
that are related to this is going to be Are the ciliary muscles the ciliary muscle
within our eye that controls pupil dilation in terms of our skin? We can we are
going to do a few things that's going to We're going to increase Or allow ourselves
we're going to send Innovation to our erector pili muscles, so we cause goosebumps.

We are going to increase Pseudomotion was just sweating so sweat glands And we are
also going to I can't think about the third one right now But it'll come to me cuz
it's on a side here there's no parasympathetic response that goes to the skin
because that's just Stopping or letting these kind of run their course back to
parasympathetic state Lacrimal and salivary glands right the lacrimal gland is
going to allow us to create tears Salivary gland obviously allows us to create
saliva during our sympathetic nervous response.

We don't need to Spend our resources on these things so it's sympathetic is going
to decrease Activity of the structures parasympathetic rest and digest we want to
be able to create slides So we can eat is going to increase that The heart
sympathetic response we're going to increase heart rate And we are also going to
increase the amount of the volume of blood that we're passing through here, right?
Parasympathetic we're not going to bring everything back down Blood vessels this is
going to depend on the location So this is kind of a really kind of crucial concept
here blood vessels for example Two structures that will help us get away and run
away such as blood vessels supplying ours skeletal muscle Will increase in diem
diameter.

So it's going to be vasodilation, right? If we are in a sympathetic response, we
will vasoconstrict makes smaller our blood vessels The ones that are going to for
example our digestive system because we do not need to worry about Digesting food
while we are trying to survive so it depends on the region No sympathetic response
is just we just go back to our normal vascular diameter Lungs we want to be able to
bring in more oxygen to supply for example our skeletal muscles And so our lungs in
the same way are going to are the tubes that create our lungs can get bigger and
smaller, right? So bronchodilation our tubes are going to get bigger allowing more
oxygen to pass into our body more carbon carbon dioxide to go out versus
vasoconstriction Which isn't going to help us get away, right? So vasoconstriction
is going to belong over here in our Paris Bronchoconstriction, excuse me in our
parasympathetic kind of normal state, right? Digestive system we've already talked
about that our digestive system. We are going to decrease The amount of blood
through vasoconstriction going there parasympathetic We're going to allow that to
go back to its normal state and have pretty sizable, you know Good blood flow
through the digestive system The same is going to be related to the liver and the
gallbladder when we think of those as a collective digestive unit or accessory
organs But we can also increase the amount of for example a glucose that is Going
to come from these locations as well Okay Urinary system we do not need or want to
pay We don't want to pee while we run, right? We don't want to be urinating on
ourselves while you run or fight unless it's that specific response that we can
sometimes see in Juveniles and so forth, right? So urinary activity is going to
decrease Parasympathetic is going to allow that to increase the general system.
This is going to kind of fall outside the norm In terms of fight or flight, right?
So we use the the the terms point and shoot to help us Remember this point is going
to be for parasympathetic and meaning we're sending blood There's a dilation to our
erectile tissue, right? So erectile tissue is going to respond or be innervated by
our parasympathetic nervous system Sympathetic nervous system shoot for s is going
to allow ***********, right so it's a combination of these Systems of the autonomic
nervous system that allows for reproductive reproduction And then our super renal
gland this one special it's gonna have its own slide Our super renal gland is a
gland. Here's our a kidney. Hey, that's pretty good for me. I'm sitting above or
superior to the Kidney is our super renal gland.

This is going to secrete adrenaline so Adrenaline is going to allow us to have a
lot of energy quickly, right? And it's going to directly into the blood supply
secrete adrenaline.

So increase in terms of Really cool because the cortex of this of this organ is
actually Nervous system.

So pretty cool. It's another place neural crest cells will show up Okay, so our to
to kind of further talk about our two distinctions between sympathetic and
parasympathetic The sympathetic nervous system is also known as our thoracolumbar
System and this is really helpful and important to remind us of one of its unique
characteristics the nerves from the central nervous system carrying efferent motor
and sensory Will only leave a certain level of the spinal cord including the
thoracic and lumbar level So between t1 and l2 sometimes they go to the hoi down l3
in different resources These are the only locations that sympathetic fibers Can
leave the central nervous system to go where they need to go, right? And so we're
going to do a little drawing here to help with this System this organization
because it's Throughout my years of teaching this is very complex for students
because it's just weird Okay, so We will have really three different places.

We're going to provide innovation We'll talk about how we send in a region in
different ways So in terms of our dermatome We will have sympathetic response in
our skin that we already talked about, right? So Goosebumps or sweating and so
forth.

So these will travel Specifically with our spinal nerves.

So when we talk about This division of the sympathetic nervous system We're going
to recall those nerves that we learned in the last block So think about our
cervical plexus up here think about our brachial plexus our thoracic Organized
fashion and then our lumbosacral plexus This these axons will join up with those
spinal nerves to travel to where they need to go in the associated dermatomes Okay
cranial glands and thoracic organs are going to be innervated in another pathway
another kind of a distinctive pathway And we are going to have to travel in this
structure that we call the sympathetic trunk The sympathetic trunk is going to go
the entire distance of our of our torso up into our neck, right? torso and down the
pelvic cavity So the the main thing is we are going to send fibers from our
thoracic levels Our central nervous system is going to get on the sympathetic trunk
here those fibers They may have to travel up to reach our head and neck and upper
limb structures, right? Because there's no way for those fibers to get on up here
in the cervical region Or they may get on and travel down in our sympathetic trunk
to reach Aren't the nerves that are associated with or that provide innovation to?
Our pelvic organs here, right? So for these places, I should have probably added in
pelvic, but actually we're going to talk about that in terms of abdominal So ignore
that pelvic region thing So abdominal organs, which is what we want to talk about.
So abdominal pelvic organs together They are going to do another go through another
Organized pathway and we are going to start in that sympathetic trunk get on his
start in our central nervous system get on the sympathetic trunk pass on through in
synapse in Ganglia that are located in our abdomen So they had a unique and
individual pathway. So abdominal organs here are the weird things out That will do
something different Okay, so the parasympathetic nervous system is going to be also
called the cranial sacral division, right? because we have three excuse me for
cranial nerves and Really three vertebral levels are free Three spinal cord levels.

I'll contribute to this and that's it right? So cranial Sacral tells us this is
where our fibers are going to originate The way we innovate all of the organ stuff,
right is going to be through the vagus nerve So we are going to see the vagus nerve
a lot in the coming months Right this cranial nerves are going to be going to
specifically be three Seven nine and ten and we are going to revisit these when we
do our cranial nerve Stuff our lectures, right? Sacral spinal nerves specifically
s2 through s4 will be part of the parasympathetic nervous system Okay, these are
images to help contextualize these gross anatomical structures, right? So when we
talk about for example our sympathetic trunk and our paravertebral ganglia We're
gonna think way way deep in our thoracic cavity here and in our abdominal cavity so
we are looking at this image right here the heart and lungs have been taken out as
well as the The tissue covering and our posterior thoracic wall then we can see
this structure called the sympathetic trunk, which is also called the string of
pearls that is the entire structure then Individual structures the individual
ganglia that help create that sympathetic trunk are going to be the paravertebral
ganglia All right, because there's a pair one on either side ganglia Okay, we also
have something called pre vertebral ganglia These are going to be the ones that are
associated with the abdominal cavity Pre vertebral in front of the vertebra really
in front of the aorta is where we are going to find these ganglia So here around
our ciliac trunk.

We have more around our Superior mesenteric artery our renal arteries off to the
kidney and then our inferior mesenteric artery right here So these are going to be
named for these big important blood vessels that come off our descending abdominal
aorta Alright, we can see these structures again in this location right so in terms
of our location of our Parasympathetic ganglia from the cranial division we're
gonna find these in the head There are four that you need to know that are
associated specifically with parasympathetic Intervation we have our ciliary
ganglia.

This is gonna be located in our orbital cavity right behind the eye here. So Think
about back the orbit. We have that sphenoid and so forth The pterygopalatine
ganglia is right here it is actually sandwiched between our palatine bone that L-
shaped bone that makes up the back of our nasal cavity and The the pterygoid
processes of the sphenoid.

The the pterygoid processes of the sphenoid. This is actually the pterygopalatine
fossa We have our submandibular ganglion, which is pretty straightforward for where
it's at and then our otic I always kind of think of the ear for this one. Those are
all going to hold that that second Layer not layer second set of neurons in our
nervous system autonomic nervous system Okay, so we are now going to talk about The
differences between these two in terms of length. This is going to play into
Helping us understand our autonomic nervous system plexus, right? So we will in our
next lecture cover where these fibers sympathetic and parasympathetic Run next to
one another creating this network of nerves and we can see that in here So this
network of nerves that are surrounding these ganglia actually hold or contain both
sympathetic and parasympathetic So when we think about our sympathetic nervous
system, this is going to be our who a very wonky Spinal cord, but that's where it
is We're going to have our pre ganglionic fibers start out here and they're going
to travel a very short distance before they synapse on their On the post ganglionic
fibers, right?

So these are going to be either in that pair that that sympathetic trunk or the
prevertebral Ganglia either way the pre ganglionic fibers are short so we can think
about these short fibers That will synapse on our post ganglionic neurons Which are
going to be much longer because they have to travel to these individual organs,
right from either those pre vertebral or pair of vertebral ganglia in comparison
our parasympathetic trunk as our our parasympathetic Intervation is going to let's
draw this the brainstem here. For example, we're going to have our instead of We're
going to have in here our nice spinal cord Brain stem Nuclei in here where we'll
have our first neuron for seven neurons begin These are going to come out and
travel a long way Before they synapse in or on one of those four cranial ganglia So
maybe this is submandibular or otic and then it's going to have a short distance to
travel that information before it finds its target organ or reaches that target
organ So if we compare it, we're going to have a very long Preganglionic fiber,
which is actually just our cranial nerves for these certain ones, which will
synapse On a ganglia that's going to be either one of those four cranial nerves or
in the sacral portion Ganglia that are within or very close to the organs that they
innervate with a short fiber Why do we care? So when we look at this when we look
at these plexuses that we see in this image We will be able to note that these
plexuses based on their location are going to be made up of our our post ganglionic
sympathetic neurons and our Preganglionic parasympathetic Axons, I should say axons
instead of neurons, right?

right? So we're looking at different steps in these Systems when we look at those
plexuses Okay, so now we're going to move on to the sympathetic nervous system more
specifically All right, lots of learning objectives But I want to I want you to be
able to draw these out and notice specifically what I'm asking of you All right, so
just just take one step back for a moment We want to bring this into what we've
been learning about the nervous system in general So where do our upper motor
neurons actually start? So we know this from when we did our somatic motor and it's
going to be the same place, right? So think of our pre central gyrus that will be
found in the frontal Cortex or frontal lobes, right? so our pre central gyrus is
associated with motor because it's anterior and Just to help you kind of link back
to all that stuff And then we will have our hypothalamus Master autonomic control
center Playing a role in the diencephalon.

So we can get that all back together So while we're talking about these first and
second steps, we're ignoring kind of this first essential component So we start
here at the spinal cord level for our pre ganglionic neurons just to help you kind
of contextualize this All right.

So pre ganglionic neurons if you said this a few times now, they're also called
Pre-synaptic in case you see that term.

So those cell bodies Like we have said start in the spinal cord Specifically in the
gray matter because that is what gray matter is between the levels of t1 and l2 or
3 right because this is where we have these first Steps located these first neurons
located specifically.

Steps located these first neurons located specifically. We actually have an extra
little Extension of our gray matter called the lateral horn or the inter-medial
lateral column So these are only located in the spinal cord level here So if we go
up to c8 or c7 6 5 4 3 2 1 We will not see lateral horns because we don't have our
neurons there for sympathetic nervous system to start Okay Then motor neurons are
going to do what we expect them to do right do those anterior structures So here is
our in our lateral column here our lateral horn We are going to have that motor
neuron coming on out through that anterior root Join up with our spinal nerve,
which is really technically only there's a small part here get on and go through
our anterior root here After our anterior, sorry her anterior ramus in this
location We're gonna get on the structure at the sympathetic trunk, right?

We're gonna get on the structure at the sympathetic trunk, right? We're only
showing one level but really there's ganglia all the way down For this so this is
gonna happen at each level t1 throughout 2 or 3 Then we're gonna get on the
sympathetic trunk via the structure called the white ramus. So this is the white
ramus right here I mixed this up during lecture because the way we get off the
sympathetic trunk Is going to be through what we call the gray ramus. So white
ramus to gray ramus.

So Watergate was what Sabrina Suggested to help us remember which I will probably
use for a very long time. So Watergate White ramus we may once we get on the
sympathetic trunk This is where the pathways will differ everything will get on the
sympathetic trunk But it might do something different depending on what the target
is the target organ is We might travel up the sympathetic trunk.

We might travel down the sympathetic trunk And we might actually just get on the
sympathetic trunk at that level synapse and then leave When those fibers leave and
I'm going to change color here When those fibers get off the sympathetic trunk on
this gray ramus or via this gray ramus If it goes and joins up with the anterior
ramus here, it's going to do a crazy loop the loop It can also get off and go
through our posterior ramus specifically Only really to innervate the skin on our
back the along that midline there, right because that's our epaxial muscles Versus
a haphaxia muscles where we hug.

So just one more time. We're gonna have those fibers get on Our sympathetic trunk
via this white to ramus They may travel either way unless it's going to the
abdominal organs are going to synapse in Right before the exit. So if we're getting
on leaving immediately, we're gonna get on synapse leave via this gray ramus and
Most of the time do a nice loop loop here All right, that's assuming it's going to
skin if we are doing our Organs we are going to get off this sympathetic trunk and
go via these splenchnic nerves, but we'll see here in a minute All right post
ganglionic neurons.

All right post ganglionic neurons. I kind of already talked about them Cell bodies
for the post ganglionic neurons, right?

Cell bodies for the post ganglionic neurons, right? So where those pre ganglionic
neurons synapse are going to be located in either These individual structures that
help create or make up the sympathetic trunk which are going to be the pair of
vertebral pair of right on either side or These nerves will get on the sympathetic
trunk travel Leave a sympathetic trunk and in synapse on post ganglionic neurons in
our pre vertebral ganglia here, right? So so bodies are in these ganglia because
that's what ganglia are their neuronal cell bodies Gray matter outside the central
nervous system where we're going to meet those secondary that post ganglionic
neurons When we look at our pair of vertebral ganglia a little bit more
specifically How they're organized for the most part.

How they're organized for the most part. There's about one ganglia per level
Specifically and especially when we're in the thoracic region, but really between
that t1 to l2 or 3 Right, so that's going to be about this level here When we get
into the cervical level, so again, we can get on the sympathetic trunk at spinal
cord specific levels But our sympathetic trunk is going to run the entire length of
our vertebral column When we get up to our cervical levels, we only have usually
about three cervical ganglia Sometimes there's more so we have a really big one our
superior cervical ganglia our middle cervical ganglia and our inferior cervical
ganglia So they're organized a little bit differently Another landmark or important
structure is the ganglion in par is going to be at the most Inferior level here
rate in anterior to with the sacrum and the coccyx is going to be called the
ganglion in par All right post ganglionic neurons again Our pre vertebral ganglia
are going to be located like I said earlier anterior to pre in front of the
vertebral column and the aorta and be named for these large vessels that come off
the Or which are going to be called the ciliac trunk the superior and inferior
mesenteric arteries and the renal arteries So we will have in association with
those locations Ciliac ganglia. These are pre vertebral ganglia, right superior
mesenteric aortical renal ganglia and inferior mesenteric ganglia They are named
for the vessels and are Prevertible ganglia these will provide Innovation to or be
part of the pathway that supplies or abdominal pelvic organs specifically
Sympathetic divisions there are even more divisions beyond The autonomic division
the sympathetic and parasympathetic division and now we are going to look at These
two divisions of the sympathetic nervous system the parietal division and the
visceral division parietal is going to send sympathetic innervation to the skin
Visceral is going to send sympathetic innervation to the organs, right? If we're
talking about sensory, this is going to receive visceral sensory information from
the organs Which usually is going to have to be some sort of extreme Trauma or
Necrosis if necrosis is occurring we can feel that as sensory as well So going back
to the skin here, we're going to have our sweat glands our smooth muscles and our
vessels Our vessels have several layers one of those layers is smooth muscle and
then our erector pelae muscle All right, so we got to go way back to the integument
stuff When we look at that parietal division a little bit more specifically we're
going to use these terms, right? So know these terms and what they mean vasomotion
is going to be vasoconstriction of dilation, right?

So whether we need to Take blood away from the skin Perhaps since to send more
blood to our brain our heart and our skeletal muscle Pseudomotion is sweat right
and the pelo motion is going to be those erector pelae muscle contractions for
goosebumps These are all Things that can happen during a sympathetic response in
our skin like I said before These fibers are going to be associated with our spinal
nerves that we already know and the dermatomes that we know is that we Kind of
introduced right? So if I were to draw on here but a change not from blue to a
different color here we have our our Pre ganglionic neurons getting on the
sympathetic trunk right here And then they'll do that loop-to-loop fun thing and
then we will synapse right before we leave On that that sympathetic trunks aren't
going back a step Synapse on the sympathetic trunk and then go with our spinal
nerves to whatever level layer Level of a dermatome that they help provide right so
you want to think about the Sympathetic response in our arm is going to go through
the brachial plexus The sympathetic response in our trunk is going to go through
these individual spinal nerves that don't make plexuses Now this is where we may go
up and down travel up and down on the sympathetic trunk here, right? So if we need
to provide A sympathetic innervation to the skin on the legs. We are going to get
on the sympathetic trunk Then travel on it Before we do our loop-to-loop to get off
right and we're going to synapse in here before we get off because we don't have a
way to contribute to our most of our lumbosacral plexus Here and now it's we're
gonna I think draw this out Okay, so another way to kind of think about this
organization is we're at a town right here This is going to be pre-ganglionic Phil
Pre ganglionic Phil, but we want to go up here into head and neckville Head
neckville right these two little towns, but there's a river in between here Right,
so there's this river How do we get across the river or how do we get a car across
the river? Don't say fairy because I realize that that is another option, but we're
gonna say bridges, right? So we're gonna have bridges only in certain locations We
don't have enough money to build a lot of bridges and then we're gonna have a
highway over here that we want to meet This highway and we'll make this clear
already. We've got our median along the highway, which is gonna be our Sympathetic
trunk highway and our river which is just Imaginary for this purpose, right?

Imaginary for this purpose, right? So we want to get here to here But we only have
bridges From here down south into south, right? So this is bridge T1 we have
bridges t1 the whole way down to l2.

T1 we have bridges t1 the whole way down to l2. I want to get on the sympathetic
trunk from this town Cross this bridge then travel up this sympathetic trunk
highway to get to This other town, right?

This other town, right? So because we don't have bridges which are going to be our
white Ramai In or above t1 we will have to travel to get to the higher levels So
let's do this again for four legs. So if we have a town here This is where our pre
ganglionic fibers are going to start.

I have to cross this white Ramis bridge And get on this sympathetic highway and
travel south or inferiorly Before I can get off on the right spinal nerve to go to
legville So hopefully this analogy works.

This is why we have to travel sometimes on our sympathetic trunk because We don't
provide bridges in our cervical and lower lumbar and sacral regions from our spinal
cord Okay, hopefully that helps Okay, so our general pathway we've talked about
here a little bit already We're gonna do our lateral column here motor fibers are
gonna come here on pre ganglionic fibers.

We're gonna get on our Sympathetic trunk remember this is just one level. So we
have a lot of levels that this can happen I'm gonna get on through our white Ramis
here All right So our white Ramis if we are not traveling up or down to other
locations Then it's going to synapse on those post ganglionic fibers and then leave
Most of the time or some of the time we'll get go with our posterior a miss but
most of the time for this gun anterior But if we have to travel we'll get on the
sympathetic trunk We're gonna travel then we'll synapse at the level that we need
to leave and get off via that gray ring One way one helpful way to think about this
might be that our white Ramai will always carry pre Ganglionic Interaction and our
gray Ramai will always carry post This may or may not help.

All right, so Re-establishing reaffirming why we sometimes have to go up or down
When we're talking about a parietal distribution, right? We only can get on to the
sympathetic trunk here But the sympathetic trunk is going to provide innervation to
all of our body by joining with spinal nerves at all these levels So from t1 to l2
we're gonna get on if we're at the right level to go to that dermatome We're gonna
just synapse and get off or if we need to get on the sympathetic trunk and go to
the legs We're gonna use the lowest Ramai we're gonna get on Travel down then
synapse before we leave Okay, so that's what this is explaining here When we talk
about Let's see, what do I have here this just Explains if we are sending
innervation to these three different locations or these different locations here,
right? You will see gray right Ramai communicons.

This is an additional term that is sometimes used to Define these structures.

So gray Ramai or gray Ramai communicons as well So three possible ways to get this
innervation to the skin enter Synapse and leave enter sympathetic trunk ascend
enter sympathetic trunk descend And then leave with the appropriate spinal level.

I Think this says the same thing but uses a different picture it does. Yeah, so
just a little bit more specifics here All right Visceral division.

All right, here we go So visceral division means we are sending our sympathetic
innervation to the organs inside our body, right? We do have viscera of the head
Specifically, we really want to think about The pupil of the eye but also we're
going to bring in sensory information from Our carotid plexus from the blood that's
going through the big artery Sending blood to our head because we really want to
monitor the blood that's going to our head and fix it if something's wrong Right.

Right. So sympathetic fibers sensory are going to come from the head as well Our
thoracic viscera meaning our heart and our lungs And then our abdominal pelvic
viscera Everything below the diaphragm, right? The order from superior to inferior
In terms of where they are in our body will be helpful. For example our liver is
the most superior of these organs and the most superior Splenitic nerves that form
will go to that organ Versus our inferior structures are external and internal
genitalia Our urinary bladder will be from the most inferior portion of this
network All right So here we go What we can do if we look at The organs So let's
see so in terms of how we travel The innervation to the thoracic organs is going to
really follow the pathway That we see for our skin our parietal division But
instead of getting off the white getting off via the gray rheumus to travel with
spinal nerves It is going to get on the sympathetic trunk then leave via splenchnic
nerves These are for our abdomen, but that's what we're going to see in the
thoracic cavity. Those are going to be called cardiopulmonary splenchnic nerves We
will sometimes have to get on the sympathetic trunk and travel before we synapse
and Leave via those splenchnic nerves, right? So we might have to get on and travel
up or we get on at the appropriate level and travel directly out of there Then for
our abdominal pelvic structures We are going to do this thing where we get on the
sympathetic trunk may or may not travel to a different level At level or below But
we're going to travel on right on through Until these fibers get to our pre
vertebral ganglia, right? So we're going to pass through These ganglia of the
sympathetic trunk to our pre vertebral ganglia Then they will synapse on the post
The post ganglionic neurons to go to the organs, right?

The post ganglionic neurons to go to the organs, right? So only for a abdominal
pelvic viscera Fibers are going to pass through the sympathetic trunk without
synapsing For the skin in the thoracic organs, they will synapse in the sympathetic
trunk So head and neck viscera we're going to look at a little bit more
specifically because we're going to have our gray ramus Well, our splenchnic nerve
is going to have a really specific name. It's going to be called the cephalic
arterial branch, right? So to send information to our head and neck structures
We're going to get on the sympathetic trunk from the highest level here T1 of our
spinal cord, right? There's our on ramp our white ramus. We don't have remi up here
So we have to travel up We're going to travel on up here and then we are going to
synapse on our post ganglion neurons before we leave this sympathetic trunk or
Sorry, this splenchnic nerve also Which is going to carry our post ganglionic
fibers is specifically going to be called the cephalic arterial branch All right,
it's going to do important things. That's why it has a special name Okay Then when
we get into our our thoracic organs Some fibers are going to get on and travel up
to our superior cervical ganglia And then synapse before they leave Those are
specifically going to go to the heart So get on sympathetic trunk travel to one of
our cervical ganglia superiorly synapse and leave to the heart or they're going to
get on Sympathetic trunk Synapse immediately and then send innervation to both the
heart and the lung All right, so there's two different ways that we can do this
Sometimes we have to travel up So our our the contributing spinal cord level is
going to be t one to t five And then our contributing sympathetic trunk level is
going to be our our cervical ganglia All three of them and then t one to t five
Para vertebral ganglia This is going to be important because well, we can't survive
without our heart and our lungs And we need to know what provides them innervation
where it's coming from, right? So our superior cervical ganglia the whole way down
to t five They are all going to um send out cylindrical nerves To our heart All of
these levels which is good because if we get injured at one level, we still want to
make sure our heart is innervated Our lungs are specifically going to be innervated
by levels t one through t five of both our spinal cord and Those ganglia that are
associated at that level Right. So all of these are going to send innervation to
the heart only t one through t five to the heart and the lungs Okay Here we can see
these structures These structures are going I I really Think it's important to
think about these in reference just to muscles and other things that we already
know Here's our first rib Right here.

This is our anterior scalene muscle Here's our middle scalene muscle and we'd be
able to see our posterior Um, if we look behind this, right so our By our anterior
scalene muscle, it's a really nice landmark for our middle cervical ganglia right
here Going superior to that. Um, really we're at the top of our Middle scalene
muscle.

We will be able to find our superior cervical ganglia When the other direction or
inferior cervical ganglia is going to be In location of these really important big
vessels that send blood to our head and our neck Um head neck and upper limb,
excuse me, right? This is going to be called the subclavian Which is going to turn
into axillary artery and then brachial artery and these are going to send blood to
the head and neck And then we can see there the rest of these pair of vertebral
ganglia individually, right? This is a pair of vertebral ganglia That help create
or form this entire structure of the sympathetic trunk All right, so abdominal
pelvic viscera We know that these are going to take a different path Right, they do
not synapse in this sympathetic trunk like all the rest of it They are going to
synapse in our pre vertebral ganglia, but we still pass through sympathetic trunk
And we still are going to leave it like thoracic organs via these splenchnic nerves
So as you can see these fibers are going to get on pre ganglionic fibers are going
to get on the sympathetic trunk They're going to leave via these splenchnic nerves
And then travel to pre ganglionic or travel to our para prevertible ganglia synapse
on our Well post ganglionic neurons and then that'll go to innervate different
structures, right? So they're going to pass through to find their post ganglionic
fibers Okay We do have a small number of fibers that will get on the sympathetic
trunk and travel inferiorly Before they leave to their ganglia.

These are going to be specifically the sacral splenchnic nerves Sacral splenchnic
are part of the sympathetic We will also have pelvic splenchnic nerves that are
part of the parasympathetic race of sacral for sympathetic Parasympathetic for
pelvic.

Parasympathetic for pelvic. Those are important things to distinguish here All
right. We're going to look more specifically at these now So our four splenchnic
nerves that we will know are the greater lesser least lumbar splenchnic nerves The
whole thing is greater thoracic lesser thoracic so forth, right? And we are going
to have specific spinal cord levels that contribute to these These are important to
know in case of a spinal cord injury, right? So our greater thoracic splenchnic
nerve is going to be From levels t5 to t9, right?

From levels t5 to t9, right? So note again We did talk about t5 already helping
provide innervation to the thoracic organs It is also going to provide innervation
to our greater thoracic splenchnic nerve All right, so t5 to t9 are going to send
fibers to create our greater splenchnic nerve, right? Then lesser thoracic
splenchnic nerve is going to be t10 and 11 Least is t12 and lumbar are just the
lumbar ones, right? So one way to think about this is greater is going to have most
the most contributions Lesser is only two Least is only one contribution and lumbar
is just the lumbar ones, right? Again, we're only going to go down to the level of
t1 because that is where our on-ramps From the spinal cord are going to exist So
splenchnic nerves will then go on to synapse within those Prevertible ganglia that
we just saw that are named for those large vessels that they're next to We have our
greater splenchnic nerve synapsing in the ciliac ganglia Lesser is going to synapse
in the aortico renal ganglia And I know there's some variation in terms of what we
see here Least splenchnic nerve is going to synapse in superior mesenteric ganglia
and lumbar inferior mesenteric ganglia Right then our post-ganglionic fibers are
going to travel from there to these different organs Organized from superior to
inferior superior to inferior contributions Okay So taking one more step back what
we can do now is say spinal nerves T5 through T9 are going to send sympathetic
innervation to our superior most Organs which are the stomach the liver the
gallbladder pancreas and spleen, right? These are all very superiorly located in
our abdomen Right and they're going to do that through this pathway T5 through T9
spinal nerves to that greater splenchnic nerve Then into uh, and synapse on our
post-ganglionic fibers in the ciliac ganglion to provide innervation to these
organs Same thing with spinal nerves T10 and 11 They are going to provide
innervation to the kidney in the super renal glands Right through that lesser
splenchnic nerve which meets up with that aortico renal ganglion on either side Um
and send innervation to the kidneys.

Um and send innervation to the kidneys. So our really our ultimate goal is to know
which spinal nerve levels Are associated with which splenchnic nerves? And of
course the ganglion, but what they're providing innervation to right? So if we mess
up this part of the spinal cord, this is what's going to be impacted in terms of
our sympathetic nervous system and then Again, same thing for spinal nerve l1
through l 2 3 lumbar splenchnic nerves inferior mesenteric ganglion for post-
ganglionic fibers This is going to provide an innervation to our distal large
intestines ****** urinary bladder all these structures that are inferior When we
talk about proximal versus distal for the tubes in our bodies or whether that's our
gut tube or our our arteries and veins We're going to think about the distance that
that stuff inside of it has traveled, right? So this is going to be proximal to the
heart if we think about it as an artery versus distal even if this This tube is all
bundled up, right?

This tube is all bundled up, right? So it's how far the stuff has traveled All
right.

This is just I want to bring in What these are when we look at our ganglia our pre
vertebral ganglia again, this is going to be Defined by which large vessel that
they're going to be around here is our ciliac trunk.

here is our ciliac trunk. It's going to provide our vascular supply to those same
organs that are Celiac ganglia will send Post-ganglionic fibers too, right?

Post-ganglionic fibers too, right? Here's our superior mesenteric ganglia or
superior mesenteric artery Our renal arteries going to our kidneys on either side
They're going to send off blood vessels to our super renal gland as well And then
our inferior mesenteric ganglia is arteries way down here. And so that ganglia
that's next to it will be The inferior mesenteric ganglion. There's a lot of
variation in terms of the number and Really location of these ganglia, but we're
going to name them for what they're closest to in terms of those large vessels Um,
and then we have our exception this cool Cool coolest organ in the body. I don't
know. I like the spleen still But the super renal gland, right? So this is going to
be One of the big things that doesn't transverse sympathetic nervous system is to
Produce adrenaline to help us get out fast or fight.

Well, right? So our our our super renal gland The cortex the outermost layer is
actually Where our neurons in this or post ganglionic cell bodies are going to be
so this Pathway, we're going to start in that lateral horn We're going to come out
that anterior root We're going to go through that spinal nerve We're going to go
through the white rheumus to get on the sympathetic trunk Then we're going to leave
we still haven't synapse yet, right? Then we're going to go through pre-vertebral
ganglion still haven't synapse Take nerves go through plexuses to meet the the post
ganglionic neurons in The cortex here which are then going to send its fibers to
the medulla of this organ and tell it to do its thing Right. So this is a pretty
cool unique setup super long pre-ganglionic fibers Which are not the norm right for
for our sympathetic trunk Let's see.
Let's see. And so that's pretty cool We will find the neurons in here are actually
from not surprisingly hopefully neural crest cells Okay I want you to know this
meaning it's going to be on the exam, right? That's how I make sure you know things
um mass activation This means when our sympathetic nervous system is going to be at
its height in terms of activity, right? So we are going to simultaneously spark
innervation of Many many many organs in our body right through the pathways we just
talked about This is going to occur in an emergency crisis situation, right so we
could have sympathetic innervation occur Kind of separately individually, but when
we have this really extreme situations mass activation allows us to respond In this
way, right?

In this way, right? So we're going to have numerous things going on We are going to
have our adrenaline being pumped into Uh the body via this um this gland the
adrenal gland is going to have a vast vascular network so we can get a If we have
um, we can get adrenaline into the body system really quickly through our blood
supply Um, and it's going to cause all these things at once right heightened sense
of alertness Increased heart rate. So then big pupils for this one blood pressure
goes up respiration increases breathing rate increases And our pupils are going to
dilate. There we go. Um, so All this happens at once through this really fast
acting thing and it's pretty cool and then I have this Um better.

Um, I think uh moving meme. I don't know gif. That's what i'm looking for gif here
I think this ostrich head head is much better Yeah Okay histology and development.

I know it's your favorite, but don't worry. It's a lot of what we already talked
about Okay, so histology.

Um, we are looking at a sympathetic ganglion Meaning it's either those pre or
paravertebral ganglia.

Meaning it's either those pre or paravertebral ganglia. We've seen these before we
know what neurons look like, right? We know that they're really big We know what
the nuclei look like right so we can find these really big really big structures
really big cells So these are going to be the neurons Um, and then uh in addition
to our neurons We're going to have we're going to look and identify these little
cells that sit along The periphery of the neuronal cell body which are going to be
satellite cells These are going to be there to kind of help take care of and
support Our neurons, right?

So if they're dark staining on the periphery of these neurons, it is a satellite
cell We have also looked at nerves before right? We know what nerves look like we
know that we're going to look for kind of stringy like structures At least if
you're looking at a longitudinal section And we are going to look for the nuclei
which are these dark staining elongated structures, right? Specifically these are
going to be our neural lemocytes our Schwann cells because these are what wrap
around a nerve So here's our nerve and they're going to go around And we're going
to be able to see The the nuclei of these cells in this way, right?

The the nuclei of these cells in this way, right? So here are our neural lemocytes
Schwann cells In this specific type of ganglia, we're going to find there's
neurons. You can even see how big they are all over the place More towards the
center and our nervous tissue our axons More on the periphery Okay Development of
the sympathetic nervous system Again, we've kind of seen this view before but we've
added a few more structures. So here's our neural tube right here Our neural crest
cells have come off that neural tube to create the peripheral nervous system Here
it's setting up to become really our dorsal root ganglia but we also will have our
The cells that create our other ganglias now, we know that there are our cranial
ganglia, we know that we have Our prevertebral and paravertebral ganglia as well,
right? So they are going to migrate to their location So on either side of the
aorta for para or in front of the aorta for prevertebral And as they go and we'll
have the same process where we'll have our neuronal cell bodies Grow out their
axonal axon extensions to meet these structures And then our cell bodies growing
within these structures here are going to grow to Meet your effector organs, right?
So this is going to be our developing GI tract we have an extensive autonomic
nervous system there So you can see those fibers going to that location, right? So
in the same way that we talked about our somites we have our axons go out of our
neural crest cells or out of our neural tube to join up with dermatome Myotome not
the sclerotome as they migrate to form muscles in the body. We will see a similar
pattern from our autonomic nervous system and so specifically we're looking really
at the sympathetic nervous system here This is going to start really during week
five, right? So we've already folded we can now see that inside the body space the
intra embryonic coelom body cavity now okay, if we Go a little bit further in
development. So week five plus that's when we will see those axons growing out of
the neuronal cell bodies And really what they're going to do is they're going to
grow along that pathway that we've already talked about this entire lecture, right
so we are going to have those neuronal cell bodies grow out their axons Going to go
out that anterior ramus our anterior root assuming we're looking just at motor here
through that spinal nerve Onto our sympathetic trunk via that white ramus is going
to travel before Or stay there before either it's going to go to the skin or the
thoracic organs We're going to synapse in a sympathetic trunk ganglia Before we
exit if it's to the skin we're going to go off Via that gray ramus joined with the
spinal nerves our anterior posterior rhema to where we need to go or if it's a
thoracic Organ we're going to get on that white ramus these they're going to grow
into that white ramus and then Synapse at the right level and leave Growing out
those and creating those splenchnic nerves to the organs, right? And then if we're
in the abdominal pelvic organ stuff We're going to get on travel on a sympathetic
trunk or leave immediately go to our pre vertebral ganglia That's where we find our
set and we're going to connect to our developing Post-ganglionic neurons which are
sending and growing its axons out to the effector organ so this all just says The
axons are going to grow in the pathway that we have already talked about If it was
sensory, we will get to sensory it will come in Via these splenchnic nerves, for
example Synapse come on in we're going to go out on that gray ramus There post-
ganglionic fibers and go through the posterior structures if it's sensory, right?
So we'll talk about sensory later on a little bit All right. That's all I got for
you. I know this is hard and it is a lot Come talk to me during office hours. Ask
questions so we can talk this over. All right. Good luck, everybody