Cellular Injury Mechanisms PDF

Summary

This document discusses the mechanisms behind cellular injury, focusing on examples like cell membrane damage and mitochondrial damage. It also touches upon the role of reactive oxygen species (ROS).

Full Transcript

[00:00:01]
>> Let's take a look at some of the mechanisms behind cellular injury
and how the cells respond to this. I've mentioned the term injurious
stimulus or cellular injury on a few different occasions, and there's
lots of different types of mechanisms that will cause a cellular
injury. So that's what we're going to talk about here.
[00:00:24]
And it's important to recognize that some of these don't necessarily
occur in isolation, a lot of them can all occur at the same time. What
we'll start with here is the one that I gave in the earlier example of
cell membrane damage. So as an example right here, here's our cell
membrane damage.
[00:00:45]
This might be something that we actually get from weight training. So
as you're doing weight training and you're lifting heavy weights and
you're lowering them, the cell membrane actually might be getting
damaged a little bit with each lift. It might be like a little
microscopic damage. And again if it's pretty minor, it might be more
of a stressor than an injury.
[00:01:07]
But if I take that baseball bat and hit the cell again, you're hit a
muscle again just as that example, that's going to cause membrane
damage. And so the point here is that, plasma membrane has an
important function to it. It's going to help regulate what's going in
and out of the cell.
[00:01:28]
And if we damage that membrane somehow, that's going to mean we're not
going to be able to regulate what's going in and out of the cell as
well. And stuff is going to start leaking out, and stuff that
shouldn't be going in might come in. And so that's going to be one
potential injurious mechanism.
[00:01:46]
And so what you could see here is, if we've got the loss of cell
components, some stuff might leak out of cells. We might start
digesting some stuff in the cells. And again, this is one mechanism of
injury is cell membrane damage. So just as as one example, we'll see
another type that can happen, and this is protein misfolding or DNA
damage.
[00:02:16]
So think about if somebody has been exposed to radiation for example,
where some of these different carcinogens that exist, stuff molecules
or chemicals that cause cancer. Why do they cause cancer? Because
they're ultimately damaging DNA. So that's an example of some sort of
an injurious stimulus. So we could say UV radiation, as an example, or
certain chemicals like carcinogens, okay?
[00:02:54]
So that's what those are going to do, okay? Just as an example,
another thing that we can have is we might have a mitochondrial
damage. And so what we're going to see here is the mitochondria, as
you know the powerhouse of the cell, they're going to be really
important. And if for any reason something happens to the
mitochondria, if the mitochondria become damaged, that's going to have
a whole host of negative effects, and it's going to potentially injure
the cell.
[00:03:26]
So again, mitochondria are responsible for making the ATP inside the
cell, and if we have anything that's going to damage the mitochondria,
okay, that's going to mean we're not going to be able to make as much
ATP. And if we're not making as much ATP, that's what we see here, we
see a decrease in ATP.
[00:03:45]
We don't have the energy to carry out normal cellular functions, and
that's what says here by multiple downstream effects. So if we're not
able to make as much ATP as we normally would be able to, then other
things in the cell aren't going to work. Maybe we're not able to make
proteins as well, okay, maybe we can't repair our DNA damage that we
have.
[00:04:06]
Again, there's always going to be some level of DNA damage that's
going to be happening, and there's going to be repair that's going to
happen. But if we don't have the sufficient ATP to power that process,
then that's not going to work. So again, what I'm saying here, just as
an example, mitochondrial damage can decrease our ATP levels, and that
can lead to other effects, like protein problems and maybe our cell
membrane won't be able to be maintained.
[00:04:30]
Okay, that's what I said before. When these things don't happen in
isolation, they can have multiple different effects, that's what I
mean by this. So if we damage our mitochondria, can't make ATP, some
of these other things might also happen, okay? Okay, the other thing
that can happen with mitochondrial damage is this, this increase in
ROS.
[00:04:49]
And so that's going to be a concept we're going to talk about
separately in a little bit. And ROS = reactive. Oxygen species that's
what ROS means here and that is a fancy term for oxygen-free radicals.
And we're going to talk about what that means separately. The point
will be this though, that any time that we have mitochondrial damage,
it might increase these reactive oxygen species or these oxygen free
radicals.
[00:05:33]
And that will have lots of different effects that will damage our
different lipids. Those lipids make our cell membrane, it'll damage
our proteins, or damage our DNA. So you can see how this mitochondrial
damage can also cause cell membrane damage. It could also cause these
things, again, these things can happen by themselves.
[00:05:52]
The membrane damage, the DNA folding damage, those can happen by
themselves. But if we have mitochondrial damage, it can also cause
these other things to also happen, okay? One other cellular injury
mechanism, that we have, I won't talk about too much here, is this
entry of calcium into the cell, okay?
[00:06:11]
If we get too much calcium into the cell for any reason, that could be
because the cell membrane isn't working properly. Or there's some kind
of change in the ion channels, or there's just a different diffusion
gradient, basically that's going to be another injurious mechanism.
You can see it's going to impact mitochondrial permeability, but it's
going to also activate multiple different enzymes inside the cell.
[00:06:34]
A lot of different enzymes are dependent on Cclcium levels, and so
it's going to have some downstream effects. But just to go full
circle, back in that very first slide, we talked about cell injury and
injurious mechanisms. What we're doing here is we're expanding and
saying, what are some of those different cell injury mechanisms?
[00:06:55]
What are those different injurious stimuli and these are some of those
examples. So one common clinical cause of cell injury, cell death,
potentially organ death potentially whole body death is ischemia. So
ischemia whenever we see that term, ischemia this is going to mean
insufficient Oxygen delivery, I'm going to write O2 for oxygen, To a
tissue.
[00:07:36]
So ischemia is insufficient oxygen delivery to a tissue. And so you
can think about if somebody has a heart attack, there's a big blockage
in one of their arteries. And so their cardiac muscle is not getting
enough oxygen, so their heart is undergoing ischemia. If somebody has
a stroke, there's a clot in a blood vessel in the brain somewhere.
[00:07:57]
That tissue in the brain that's not getting blood going to it is
experiencing ischemia. So those are just some examples of ischemia. So
with ischemia what we see here, here is a clot that is stuck in a
blood vessel, okay? So that means that the mitochondria isn't getting
oxygen to it, so we're not getting enough blood, we're not getting
enough oxygen, so the mitochondria can't do its job.
[00:08:23]
This means it's got less oxidative phosphorylation or energy
production, aerobically, so we're going to have less ATP. And ATP is
essential to so many different functions in the cell. So now that
sodium, potassium pump can't work, and so we have all these other
effects. We won't worry about the specifics of what they are, but we
will end up with different imbalances in different ions in the cell.
[00:08:47]
We're going to have more ATP is going to be made anaerobically by
glycolysis. So this is going to use up glycogen, it's going to change
our pH balance in the cell. A change in pH balance is going to cause
further damage in the cell, okay? There's going to be some other
issues with ribosomes, and eventually we're going to have less protein
synthesis.
[00:09:06]
So you can see this downstream effect, because we have this one clot
here, and now we're not getting oxygen to the mitochondria. We have
all these other downstream effects, and that's what this second
diagram is showing here. We start off with low oxygen levels and now
because we have less ATP coming in, all these different things happen.
[00:09:25]
We have phospholipids are being lost, lipids are being broken down.
Some of the cytoskeleton that's damaged and before you know it, the
whole membrane is damaged. And so again, this is just one example of
an injurious stimuli all resulting from lack of oxygen going to the
tissue. Now we have membrane damage, and as we saw previously,
membrane damage is its own form of injury.
[00:09:48]
So it started off with insufficient oxygen and we'll say, the
mitochondria is not doing what it needs to do, so this can't happen.
And now we have a second type of cellular injurious stimulus, we've
got membrane damage. So all these things compound upon each other.
Ultimate way that cells respond to stress can vary, okay?
[00:10:14]
And so we're going to start by looking at this, this is our normal
cells. Here`s four normal, happy, healthy cells. It doesn't matter
what kind of cells they are, all in homeostasis. And so the one
example that we already talked about is one response to cellular
stress is hypertrophy.
[00:10:31]
So we talked about that with weight training hypertrophy. So anytime
you see hyper, that means something is getting bigger or an increase.
And anytime you see the word trophy that has something to do with
size, so hypertrophy means an increase in cell size. So we start off
with four cells, we still have four cells.
[00:10:57]
But they're all bigger and great example of this is weight training,
weight training gives us bigger muscles. We put stress on the cells
and now we get bigger muscles as a result of it. The cells themselves
are getting bigger, Wwe don't have more of those cells. They're just
getting bigger, same thing can happen with obesity.
[00:11:17]
We, Basically start putting more lipids into the cells, into our
adipose cells, and they get bigger. And there's lots of different
types of pathological processes which can cause hypertrophy. The
opposite of hypertrophy is atrophy, okay? So it's a different type of
cell stress and atrophy. Again, we've got that trophy that has
something to do with size, a means, usually anytime we see a means
without, okay?
[00:11:49]
So we hear something like acellular that means without cells. Or we
hear of an asexual organism or something that produces asexually, it
means without sexual reproduction. Anything we see a means without,
atrophy, maybe the a doesn't make a whole lot of sense there. It's not
like without cells, but it's a shrinking of cells, okay?
[00:12:08]
So this is the opposite of hypertrophy, the cells shrink. So again, if
you have a lot of sedentary behavior, if you're not contracting your
muscles, okay? Such as maybe if somebody is in a coma, or somebody has
their arm in a cast, or whatever, they're not contracting their
muscles.
[00:12:25]
Or maybe they've got a neurologic disease where they can't contract
their muscles, the cells, instead of getting bigger, they're going to
get smaller. So that's atrophy but again, you can see it's still the
same number of cells. There's still all four, they're just smaller,
okay? Another type of response is hyperplasia, anytime you see plasia,
that means number of cells.
[00:12:53]
So hyper, we already said, means increase, and plasia is number of
cells. So hyperplasia is an increase in the number of cells. So that
could be one response to cellular stress is we might have an increase
in the number of cells, or we might even have a combination of both.
[00:13:14]
We might have hypertrophy and hyperplasia, both the number of cells
increase and how big they are, that changes, okay? So that could be
another adaptation that happens to stress and then we could also have
something called metaplasia. Metaplasia is a different stress response
where you can see both we have a change in the number of cells, so
there's some hyperplasia involved in this.
[00:13:44]
So I'll just draw a little line here but the cells also, they don't
quite look the same. You can see original cells here were kind of
mostly square, but these are starting to be a slightly different
change in shape. There's some kind of structural change to the cells,
okay?
[00:14:01]
And that's what metaplasia is. It's like just this in, there's a
change in the size, but there's also some a little bit subtle changes
in the shape of the cells. And eventually with prolonged cell stress,
these can become dysplasia. Where now these cells don't look anything
like the original, there's some that might have hypertrophied a little
bit.
[00:14:21]
There's some that have atrophied in size, the cell shapes looks
different. And so this is dysplasia here. And so dysplasia is
something that you'll hear in terms of like with cancer, you'll hear
about dysplastic cells, cancer, there's all these abnormal changes to
the tissue and a tumor might be big because there's lots of cells.
[00:14:43]
So there's that hyperplasia component, but they could also have this
dysplasia component too, where the cells don't look anything like the
original cells. So that's what we talk about when we talk about
dysplasia. This slide is a nice little summary slide that brings a lot
of these concepts together it's very similar to that first slide that
we had.
[00:15:03]
We're just weaving in a few extra things here. So anytime we've got
stress to the cells of the body, we've got our stress, there's going
to be some sort of altered functional demand, okay, in the case of
weight training we're putting more stresses upon the muscles. We're
requiring greater mechanical stimuli, and maybe we'll be able to adapt
and maintain that level of stress.
[00:15:27]
So maybe this is some sort of adaptation, okay? Or we might have some
sort of reversible cell injury, and regardless if it's reversible, we
get back to normal so our stress is maintained. And we could have all
these possible adaptations to do this change in stress. We might have
atrophy, or we might have any of these other things we talked about on
the previous slide, hypertrophy, hyperplasia.
[00:15:57]
Metaplasia or display or dysplasia, but if we remove the stressor, so
if we remove whatever was causing the stress, if we get rid of that
stimulus, we're probably going to return back to normal. Okay, so
again, think about it. If somebody has done a lot of weight training
and has had a lot of muscle hypertrophy.
[00:16:17]
And then they stop training, what's going to happen to the muscles?
The muscles are going to get smaller, they're going to go back to
normal. If somebody's been doing the opposite, if they've been doing a
bunch of sedentary behavior and they've had a lot of atrophy, but now
they start getting back to a normal level.
[00:16:31]
So you had somebody that was in a cast and now you take the cast off
and they start moving around again. The cells are going to get back to
normal. If there's some sort of other injurious response, some sort of
chemical stimulus or ultraviolet radiation or something like that that
was causing maybe some metaplasia or dysplasia.
[00:16:49]
And we take away that stimulus, that stress was removed, we're going
to return back to normal function. So again, just a nice little, we
talk about some of these different adaptive responses, and we talk
about what happens if we are under stress. And then if we move them, a
lot of those adaptive responses go away.

[00:00:01]
>> To understand health and disease, we need to have a strong
understanding of, cellular stress, cellular injury, and cellular
death, and how all of these relate to one another. Is the general
paradigm that will describe how cells respond to stressors placed upon
them. So we're going to start off with our normal cell, our normal
healthy cell, that is in a state of homeostasis or equilibrium,
everything is functioning as normal.
[00:00:37]
And what could happen is if we can place some sort of stressor upon
it, and there's lots of different types of stressors. This could be
something like exercise, so if we are lifting weights and contracting
our muscles and applying this force onto our muscles, that self is
stressful.
[00:01:00]
And as anybody that's ever lifted weights knows, that stress that we
put upon the cell will maybe result in some changes to the cell. In
the short term, we might get a little bit sore, we'll talk about that
in detail another point, but eventually it's going to lead to
adaptation, adaptation is a good thing, okay?
[00:01:19]
If we've put a lot of stress upon a cell, it's going to to adapt to
it, in the case of strength training, we put physical forces upon the
cell and eventually we adapt. How do we adapt? By getting bigger
muscles, we develop more contractile proteins, so that's one possible
thing that we could do.
[00:01:38]
Stress a cell, and it adapts, and that's good, okay? However, if we
place too many stressors upon a cell, before they have a time
sufficient, time to adapt, or the cells don't have the resources that
they need to fully repair either the cells. Or the extracellular
matrix that they surround, if we can't adapt for some reason, then
we're going to have an injury, okay?
[00:02:09]
And an injury is obviously something that there's something bad that
has happened, we're either impairing the structure of the cell, or
function of the cell, okay? That is in injury, now, we talked about if
we put stressors upon the cell and we fail to adapt, or if we just
have a downright injurious stimulus.
[00:02:32]
So, it's one thing if I go and do a bunch of weight training and maybe
I do too much fit beyond the ability to adapt. It's a very different
thing If I just take a muscle and I hit it with a hammer or baseball
bat as hard as I can, that's just going to be blatantly injuring the
cells, okay?
[00:02:49]
So some things are going to be stressors, and some things are going to
be injurious stimuli. Either way, we're going to result in an injury
in this concept of cell injury. Now, two things can happen from here,
we can have a reversible injury. And again, that's going to be mild
and transient, transient just means temporary.
[00:03:11]
And so it reverses, and eventually it gets back together, now it goes
back to normal homeostasis. Now again, we have to differentiate
between Normal homeostasis and adaptation. If I go and I lift weights,
and my muscles are going to adapt to that, and now my muscles are
stronger than before, that's adaptation.
[00:03:33]
If I lift weights, and I'm doing way too much, and over-exerting
myself, and I'm not giving my muscles a chance to adapt. Maybe I'm
actually not going to have much of an adaption, I'm just going to get
injury and eventually it's going to be reversible, and I'm going to go
back to my normal healthy self, okay?
[00:03:51]
Same thing with an injurious stimuli, if I take an injurious stimuli
like hitting my muscles with a baseball bat, or something like that,
that's not a way to train. We're not going to get bigger muscles by
just, clubbing ourselves with a baseball bat. It's just going to cause
injury, and best case scenario it's this reversible injury and we go
back to as good as we were before.
[00:04:12]
So again that's something that's important to recognize, stressors
will cause adaptation. Injuries, if they're reversible, best case
scenario, we go back to where we started, okay? So, that's the
difference between, stress that leads to adaptation, versus a
reversible injury, a reversible injury just gets us back to where we
started.
[00:04:32]
However, that's in the case of mild and temporary injuries, if we have
something that's really severe, and really potentially progressive,
that can result in an irreversible injury. The cells structure, and or
function, is permanently altered, and so it's irreversible. And from
there, we could go down two general pathways, we could have something
called necrosis.
[00:04:59]
Which is one type of cell death, or we could have apoptosis, which is
a different type of cell death, okay? Necrosis is going to be a little
bit more we'll call it messy, there's going to to be cell membranes,
kind of exploding and leaking out stuff. And it's a lot of times it
might require some kind of clinical intervention to clean it up.
[00:05:27]
Apoptosis, you might have heard of it as programmed cell death, where
there's going to be a series of events where the cell just kind of it
implodes, or self destruction. You think of that way, and it's a
little bit cleaner of a phenomenon for lack of a better term, don't
get too caught up in the difference between necrosis and apoptosis
right now.
[00:05:47]
Just recognize that they are different types of cell death, and they
are going to to come after an irreversible injury. One important
factor that's going to determine whether an injury is reversible, and
leads back to a normal, healthy, functional cell, back in homeostasis
or irreversible is the duration of injury.
[00:06:12]
And so that's what this figure here shows, on the x-axis, we have
duration of injury, and this is just as a general model. This is going
to to be different for each type a tissue, it's going to be different
for different types of injurious stimuli. So we're not saying that
this x axis represents seconds or days or weeks or anything.
[00:06:29]
It just depends, just kind of tryna share the concept here, and on the
y axis here, we've got the magnitude of effect, and so, as an example,
we'll talk about something like a crush injury. Imagine that you're
going rock climbing, and a boulder falls on your leg and starts to
crush the muscles in it.
[00:06:54]
And you could probably imagine, that if we got a bunch of friends with
you, and they see this happen. And they see your muscles get crushed
by this boulder, which again, is an unfortunate situation, but it does
happen. And if your friends all quickly band together and lift that
heavy boulder off of your leg, is your muscle going to be lingered?
[00:07:16]
Yeah, but if that boulder was only crushing those muscles on your leg,
for a few seconds, or maybe even a few minutes. You're probably going
to to have something that's a little bit more reversible of a cell
injury. However, if this boulder is stuck on your leg for three or
five days, you could probably imagine that there's going to to be a
lot more damage that's going to to continue to happen during that time
period.
[00:07:42]
And it's going to be an irreversible injury, and so that's an example
of how the duration of injury is going to affect the ultimate outcome.
If you're able to try to reverse your eliminate injurious stimuli
quickly, it has more chances of becoming reversible, if not, it's
going to be more likely Irreversible.
[00:08:03]
Same thing if you think about something like a myocardial infarction,
or a heart attack. If the cardiac muscle is starved of oxygen for a
few seconds, it might get injured, but it can recover. If it's starved
of oxygen for an hour, it's going to be a lot less likely to recover,
so that's the idea behind that.
[00:08:21]
That's the first general idea, of, time is going to to determine if an
injury is reversible or irreversible. And then just a little bit more
on that, is once we cross this line into irreversible injury. So
again, it's going to to be dependent on cell function if we're able to
intervene pretty quickly.
[00:08:41]
So if we're able to intervene, very quickly in the cycle a few seconds
or maybe, a few minutes depending on the injurious stimulus, okay?
Maybe there's only a slight decrease in cell function, but after a
certain period of time. We're going to be getting to a point where the
cell function is so far down that the cell is not able to maintain its
homeostasis, and it's going to start dying.
[00:09:02]
And so what this has just meant to show here is that at the early
stages of, if you've had an injury that has been long enough to be
irreversible, but not necessarily ongoing for a really prolonged time.
There might be some sort of biochemical alterations that lead to cell
death, and you might not even see any immediate signs of cell death.
[00:09:34]
But eventually, the longer the injury has gone on, over time, we're
going to start seeing changes on electron microscope. And eventually,
under a light microscope, you'll see cellular changes, and eventually,
if something is really severe and really prolonged, you're going to to
see gross morphological changes. So something that's visible to naked
eye, and so this is more important from a pathology perspective for a
pathologist.
[00:09:57]
This is going to help give a little bit more of an idea about how long
an age Injury took to happen, how severe it was. But again that's just
the basic concept of, how cell injuries might be reversible or not and
how it's related to the timeline of injury.
[00:10:20]
This is just meant to be a brief overview of necrosis versus
apoptosis, again, these are two different pathways of cell death. And
again, just a general overview to get an appreciation, we have with
necrosis here's our normal cell. And there's some sort of injury that
happens to it, and we'll say it's reversible injury well, then it'll
recover.
[00:10:44]
But if this injury is so severe, there's so much disruption that it's
going to happen, then we're going to get to this point of a
progressive, irreversible injury. And what you can see in this diagram
here, is there's inflammatory cells that come in, we'll talk about
inflammatory inventory cells separately in the course.
[00:11:03]
So there's going to be a lot of inflammation that's going to be
happening, and then the cells can be breaking down. There's going to
be a bunch of stuff leaking out of it, and it's going to look a very
certain way under a microscope, and that's going to be our necrosis.
And again, anytime we see inflammation, inflammation is going to a lot
of times be associated with some sort of clinical manifestation.
[00:11:26]
You might there might be some pain, there might be a greater risk of
infection. So anytime we've got death by necrosis, it's going to be,
for lack of a better word, messier. And we might be more likely to
need some kind of clinical intervention to clean it up, okay?
[00:11:46]
So that's just the idea behind that, if somebody has gone hiking in,
mountain climbing or something and gets a gang. And they get frostbite
and their fingers or their nose become gangrene, gangrene is one four
minute necrosis and that's it's going to have to be treated by
somebody. Otherwise, there's going to be a risk of infection, there
might be some amputations and stuff that happen.
[00:12:08]
That's necrosis, it's messy, apoptosis is going to happen, we've got
this normal cell. There's some sort of injury that happens to it, and
what we see here, again, don't get caught up in the details, but it's
going to look different, it's going to look different under a
microscope than this. And there's going to to be this whole
programming inside the cell, that's going to to be this organized
breakdown of the cell.
[00:12:33]
And eventually, it's going to to come in and be eaten by a phagocyte,
which is just one type of immune cell we'll talk about. We'll talk
about some macrophages and stuff, a little bit later, so it's going to
be some sort of immune system cell that comes and eats it up.
[00:12:47]
But it's going to be a different immune process than necrosis, okay?
And so this is just kind of, you've got the cell breaking itself down
kind of, just self destructing itself. But it's not going to have as
much leaking out and you've got, a different immune response happening
to clean up the debris.
[00:13:07]
And so a lot of times, the immune system is kind of doing the cleaning
up, as a general statement, there's no intervention necessary that's
to clean up the mess from cell death. Now that might have some sort of
clinical consequences that might need to be addressed, but there's not
a mess that's an inflammatory mess that's left behind.
[00:13:31]
Again, just as a broad general statement of, apoptosis versus
necrosis.