Acute Ischemic Stroke Imaging and Thrombectomy Treatment, Dr. Jeremy J. Heit (11-3-22)
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Today we are honored to welcome Dr. Jeremy height for a
0:46
lecture on acute ischemic stroke Imaging and thrombectomy
0:49
treatment Dr. Hite is an associate
0:52
professor of radiology and neurosurgery in the
0:55
interim chief of neuroimaging and neuro intervention at
0:58
Stanford University. He is a practicing Diagnostic and
1:01
Interventional neuroradiologist who specializes
1:04
in the diagnosis and minimally invasive treatment of
1:07
ischemic and himrochix stroke
1:10
Dr. Heitz research seeks to understand the patho physiological
1:13
basis of cerebral vascular
1:16
disease in addition. His group is developing new minimally,
1:19
invasive image guided treatments at the end
1:22
of the lecture join Dr. Height in a Q&A session where he will
1:25
address any questions you may have on today's topic. Please remember to
1:28
use the Q&A feature to submit your questions we can get to as many
1:31
as we can before our time is up with that being said we
1:34
are ready to begin today's lecture Dr. Height. Please take
1:37
it from here.
1:38
Well, this should be a lot of fun. So thanks again to the
1:41
folks at MRI online for for inviting me to talk today.
1:44
I want to talk about acute stroke
1:47
Imaging which I think is of interest to the most of the audience here,
1:50
but also a little bit about how we treat patients with
1:53
ischemic stroke by thrombectomy. And I think you'll pretty quickly
1:56
appreciate that the Imaging is very intimately tied to
1:59
the procedure. And in fact, I would argue it
2:02
really is the first step of the procedure. So with that
2:05
let's go ahead and get started here are my disclosures.
2:10
And I'm going to briefly touch on sort of the underpinnings of
2:13
acute stroke physiology. And then how we image patients with
2:16
acute ischemic stroke, then we'll talk about the thrombectomy treatment
2:19
of stroke and some of the data the underpins US doing
2:22
these procedures and then I want to talk about stroke systems
2:25
of care and how the Radiology practices integrate into
2:28
the the transfer and evaluation of these patients and
2:31
then we'll really spend the end of it how to
2:34
reviewing some of the general Imaging triage of patients for thrombectomy treatment,
2:37
but let's start by talking about ischemic stroke.
2:40
So, you know, very briefly stroke happens when
2:43
you interrupt blood flow to the brain and that's what causes an ischemic stroke
2:46
and that can be due to blockage of an artery
2:49
in the brain such as this patient. We see here that there's the arrows
2:52
pointing to blockage of the first part of the middle cerebral artery,
2:55
which is a large artery that supplies the brain and
2:58
you can see that there's a lack of blood flow here to the MCA
3:01
territory in this patient and it could be due
3:04
to blockage of an artery in the neck. But what happens when you
3:07
do have a blockage of blood flow to the brain is it?
3:10
Result in permanent injury to the brain and that's shown here on
3:13
this ischemic stroke here on a diffusion weighted image. Now, if
3:16
you think about it, you don't necessarily have
3:19
all of the brain tissue that you've got
3:22
suddenly die. When you block an artery, right? You can have some tissue
3:25
that really is highly dependent on the nutrients that
3:28
are in the blood that die because you cut off that blood
3:31
supply and and that is kind of schematized here in red but very
3:34
often you can have a larger region of brain sort of
3:37
surrounding this area where you know, there's not enough blood flow
3:40
for the neurons here to maintain their ion gradients. They
3:43
don't function quite normally but there is enough collateral blood flow
3:46
that this tissue is still alive. It's just not functioning and
3:49
if you kind of fundamentally think about these two compartments you
3:52
have dead tissue and tissue at risk and these
3:55
are terms that we are also commonly assigned to
3:58
these two compartments which is the ischemic core and that
4:01
really refers to tissue. We think is likely to be irreversibly injured
4:04
and then the penumbra which refers to
4:07
the potentially salvageable tissue.
4:10
That if we're able to restore blood flow can go
4:13
back to normal and not go on to permanently dive.
4:16
So let's do a little thought experiment. So a patient comes into your
4:19
Ed and they're having an ischemic stroke and you're
4:22
looking at their symptoms and you know that they may look something kind
4:25
of like this. If you could take a picture of their brain, they've got some amount
4:28
of ischemic core that's dead. They've got some hopefully larger
4:31
amount of salvageable penumbra and what do
4:34
you want to do with this patient? Well, you want to reperfuse the brain you
4:37
want to open up that artery that is blocked because if
4:40
you restore blood flow to the brain, all of this blue penumbra
4:43
goes back to normal and the patients left with
4:46
the same amount of permanently and your tissue that they
4:49
had when they came in through your front door and that's really the
4:52
goal of what we're trying to do a stroke patient. So you could achieve this
4:55
reperfusion either with intravenous thrombolysis with
4:58
TPA or connect to place or with an Indo
5:01
vascular thrombectomy procedure to pull the blood clot out
5:04
that's blocking the artery to the brain. Now, if you're
5:07
not successful say the patient is not a candidate
5:10
for TPA or tnk or say that they're you
5:13
know, you're not able to to promptly
5:16
An endovascular thrombectomy. Well, what can happen in those situations
5:19
is that this penumbra will go on to permanently
5:22
die. And so now you can see this patient has
5:25
a much larger area of permanent infarction. And
5:28
obviously this patient is not going to do as well
5:31
as this patient. And so the really the
5:34
goal of all stroke treatment is to restore blood flow to the
5:37
brain and as timely a manner as possible.
5:40
So just a couple of real-world examples of this. This is
5:43
a gentleman who was treated at Stanford. He
5:46
was raking leaves in his front yard when he collapsed and
5:49
that was witnessed by his family. He was transferred initially
5:52
to an outside hospital and quickly transferred over to Stanford
5:55
given the severity of the symptoms and here's his diffusion
5:58
way to image from his arrival at Stanford. You can
6:01
see just the subtlest subtle hyper-intensity that's
6:04
in the caudate head on this diffusion weighted image.
6:07
He had a Mr. Profusion study that
6:10
shows you know, prolong blood flow into the
6:13
entirety of the left MCA territory. This is
6:16
someone that should be you know, a really good thrown back to me candidate and
6:19
here's his angiogram that shows you that M1 occlusion
6:22
in the cath lab and fortunately this was
6:25
revascular eyes. And so all the blood flow is very
6:28
quickly restored to his brain and so he had all
6:31
of this, you know large area of under perfusion
6:34
that could have gone on to die. But because blood
6:37
flow was restored he ends up with an
6:40
Parked that's basically the exact same size as what
6:43
he came in with and he did extremely well and was
6:46
able to leave the hospital a couple days later with minimal symptoms. So
6:49
that's that's what we want to have happen. Let's look
6:52
at this patient. So again, we can see a patient coming this
6:55
time with the right side at stroke and there's you know, a little bit larger
6:58
but still relatively small ischemic core that we're seeing
7:01
and the lentiform nucleus and in the caudate head on
7:04
the right side again, we see that there's Mr. Profusion
7:07
obtain so much larger penumbra here with prolonged blood
7:10
flow on this time to maximum math. This is another
7:13
good patient to take up for treatment. So here's the
7:16
angiogram
7:17
Again, we see an M1 occlusion this time on the right side
7:20
in this patient. And this was one of these very difficult clots
7:23
to remove. So we're pretty good at removing these
7:26
clots, but there is a good 10 to 15% of patients
7:29
where we just cannot open up the artery and
7:32
despite our best efforts. We could not open up this artery it
7:35
remain blocked and because of that all of this
7:38
tissue that the patient had that was at risk of infarcting did
7:41
in fact go on to permanently and fart and
7:44
so you can see that this is someone who's not going to do as well
7:47
in this patient did not do as well compared to the first patient
7:50
that I showed you in which blood flow to the brain was restored.
7:53
And so this is a very simple concept but
7:56
it really is something that we see every day and
7:59
simple is good. And if we just remember
8:02
we're trying to restore the blood flow to minimize the
8:05
amount of permanent ischemic injury to the brain. That's our
8:08
goal.
8:09
So with that you're already
8:12
getting a sense that Imaging is going to be really important
8:15
right? I showed you a bunch of examples already here of
8:18
where Imaging different compartments in the brain, but when
8:21
we think about the evaluation of a stroke patient, what are our
8:24
goals and I would argue that there's really kind of four goals that we're thinking about.
8:27
So first off we want to confirm that we
8:30
have the right diagnosis. We want to make sure that we're dealing within a patient
8:33
with an ischemic stroke. It could be a hemorrhagic stroke. It
8:36
could also be a stroke mimic and so we'd like to ideally rule
8:39
out stroke mimics. If we are able to we want
8:42
to make sure that we're identifying any contraindications to
8:45
revascularization and that could again be
8:48
by intravenous thrombolysis or by a throne back to
8:51
me procedure and then increasingly we're really thinking a lot
8:54
about identifying thrombectomy candidates and how we almost optimally
8:57
do that.
8:58
So when we talk about confirming the diagnosis, I
9:01
think that's something that's on all of our minds. That's Radiologists. We're
9:04
thinking about that all the time when we're looking at a
9:07
scan and it says, you know evaluate for a stroke and you know, we have two
9:10
modalities that are disposal. We have CT and MRI.
9:13
They both certainly work. I like this picture because it's
9:16
very easy to see the obvious stroke. It's quite large
9:19
and this patient on the diffusion weight at MRI, but on
9:22
the CT scan, it's more challenging. If you look though,
9:25
you can see that we have this hypodensity here that's in
9:28
the left insula. It's extending into the left lentiform nucleus,
9:31
but that relative drop in density compared to
9:34
the side. I think is more challenging to see and that's the advantage
9:37
of MRIs that the signal to noise is just much higher. It's much
9:40
easier to make the stroke diagnosis, but regardless, these
9:43
are two modalities and the Radiologists needs to be Adept and
9:46
interpretation of both of them.
9:48
So why do we typically do CT
9:51
in this country? Well, it's fast it's really
9:54
widely available. Pretty much every emergency department has a
9:57
CT scanner and it's relatively inexpensive compared to
10:00
to MRI and by Contrast MRI has
10:03
a reputation of being slower. It's certainly
10:06
not as always available and it is more expensive. The
10:09
machines are more expensive and they're they're more expensive to
10:12
to operate but I would make a slight
10:15
argument that these perceptions may not
10:18
quite be true and I would challenge you all to start to think
10:21
about that a little bit so I'm right can actually be done quite quickly. It is
10:24
increasingly available. You have to make a little
10:27
bit of effort to make it available for stroke patients all
10:30
times and it may actually be cost assist
10:33
efficient because a lot of times when you have a CT scan that doesn't
10:36
reveal a diagnosis. What do they do? Well, you go on and you
10:39
get an MRI, so if you can just go straight to the MRI, you're
10:42
gonna be able to answer more of those clinical questions and potentially there's
10:45
room for cost savings and that so this
10:48
is the
10:48
Most streamlined MRI protocol we use at Stanford
10:51
for triaging patients for thrombectomy. And I put
10:54
this up to show you that you can do this pretty quickly. What are
10:57
we doing here? Well, we have a diffusion weighted image to evaluate for how
11:00
significant the ischemic chorus. We have a
11:03
gradient Echo sequence where we're looking for the presence of any Hemorrhage
11:06
which could be a contraindication to treatment. It also can help you see
11:09
the thrombus in many cases. We have an MR angiogram
11:12
to evaluate where a large vessel occlusion is and
11:15
in this case, we have an M1 occlusion here on the left side. And then
11:18
we do perfusion imaging to identify the penumbra
11:21
and make sure that there is salvageable tissue. So these
11:24
are the scan times for each sequence. And if you add up the
11:27
scan time, it's just a little over five minutes and obviously there's some transition
11:30
time in between the two, you know, you've got a look image
11:33
but really you can do an MR pretty quickly and
11:36
around 10 minutes or less if you're really dedicated to
11:39
getting it done quickly and I would argue that that's pretty comparable
11:42
to CT in most patients
11:45
with an ischemic stroke. So Mr. Can certainly
11:48
be
11:48
quickly, and it's something to at least think about
11:51
So we also want to try to exclude stroke
11:54
mimics. And so these are three different patients who
11:57
were brought in for thought that they had an
12:00
ischemic stroke, but none of them does and so
12:03
let's look at each of these in turn. So this first one we've got a flare
12:06
image, you know, really? It doesn't look horribly remarkable.
12:09
I will tell you this patient is hemiplegic and
12:12
has a gaze preference so they certainly look like someone who has
12:15
a large vessel occlusion stroke. Maybe you
12:18
can see that there's some increased, you
12:21
know, T2 signal in the cortex in this patient.
12:24
But if you add an ASL to look at blood flow, we
12:27
see that there's extremely high blood flow to the cortex in the
12:30
right Hemisphere and this patient is actively seizing right. So
12:33
that's a stroke mimic. This is not someone that you want to give TPA to
12:37
This patient was brought in with what was thought to be a cute
12:40
weakness and then a little bit later you find out that it may have been
12:43
more of a slowly Progressive weakness, but here's their non-con CT
12:46
and we can certainly see areas of hypodensity in
12:49
the left MCA territory. There's some
12:52
Mass Effect on The ventricle, you might worry that you're looking at a
12:55
Subacute stroke that's you know already kind of the cats out
12:58
of the bag but it looks a little bit funny right? We've got some sparing of
13:01
tissue in the midst of the areas of hypodensity. Then
13:04
you want to look at the whole study and contrast can be
13:07
helpful because this is a patient with a secretory meningioma
13:10
where all of this edema and the patients
13:13
weakness are really due to this tumor that
13:16
just needs to be removed.
13:18
This last patient here came in with concern for
13:21
a posterior circulation stroke. They were having visual disturbances and
13:24
on the non-con CT. We see hypodensity and
13:27
the occipital lobes. It looks a little bit symmetric but
13:30
there is a little bit of sparing of the cortex over
13:33
the area of hypodensity and both of these regions and this
13:36
is actually a patient who is quite hypertensive. And
13:39
this is a case of press posterior reversible encephalopathy
13:42
syndrome. And so, you know, all of
13:45
these are stroke mimics and if you're not careful and you don't
13:48
look at the Imaging closely, you potentially could miss these diagnoses but
13:51
none of these patients is gonna benefit from intravenous
13:54
thrombolysis or thrombectomy. So if
13:57
we're able to identify the mimics that is good for the patients.
14:01
So what about contraindications to treatment? Well, there are a few.
14:04
So here's a patient who came in again with visual symptoms
14:07
concern for ischemic stroke in the Ed. Here's the
14:10
non-con CT and we're seeing a sort of heterogeneous
14:13
hypodense lesion here, you know,
14:16
you're getting the sense that doesn't really look like a stroke
14:19
and sure enough this ends up being a primary brain neoplasm.
14:22
This is a GBM certainly not something you
14:25
want to be doing giving TPA to as the presence
14:28
of an intra a parenchymal tumor is a contraindication this
14:31
middle patient here with someone who is altered came
14:34
in with some isolated weakness was thought to
14:37
maybe have a deep stroke. It's a non-con CT and we're
14:40
seeing little Foci of hyper density that certainly look
14:43
concerning for small areas of hemorrhage. And these are
14:46
Hemorrhage is related to mycotic aneurysms. So certainly
14:49
not a patient. You want to be giving TPA to important to
14:52
identify this contraindication this last
14:55
patient. This was a I can't make this up and investment banker
14:58
who tripped on the cobblestones in nantuck.
15:01
And actually had weakness on the left side of the body got
15:04
this head CT and you can get sensors a
15:07
little bit of trauma here and there is some hyper density
15:10
in the central sulcus here. And this is traumatic
15:13
subarachnoid hemorrhage. That was probably causing some
15:16
irritation may be a focal seizure to account for
15:19
the patient's weakness. So three contraindications to
15:22
treatment that you want to pick up and certainly are non-invasive
15:25
Imaging is helpful and identifying these contraindications.
15:28
All right. So increasingly we're
15:31
really concerned about identifying patients for
15:34
thrombectomy because these are patients who can really benefit from
15:37
that procedure and it's up to the radiologist to
15:40
work with the stroke teams to make sure that we're identifying these patients
15:43
correctly. And so generally, who are we looking
15:46
for? I would say that patients who are good. Thrombectomy candidates
15:49
fit these three criteria first off. They should
15:52
have a relatively small ischemic core.
15:55
All right, right. Now the evidence is that if patients
15:58
have less permanent injury.
16:01
More likely to do. Well that does not mean thrombectomy is
16:04
not going to benefit a patient who has a larger core it
16:07
probably does and we're we have
16:10
ongoing trials that may change this first point and the
16:13
next year or so the patient should also have some
16:16
salvageable tissue. All right, and that's evidenced by
16:19
a larger penumbra and that makes sense. Right? If
16:22
you're going to open up a blood vessel. You want to restore blood flow to
16:25
some amount of brain that's not dead because if
16:28
it's all dead, I don't see how restoring blood flow is
16:31
going to help that patient. And so the patient should have a
16:34
small core a larger penumbra and they should also have a
16:37
blood vessel that is amenable to end of vascular thrombectomy.
16:40
This is defined right now as a large
16:43
vessel occlusion, and that means a occlusion of
16:46
the internal crowded artery the first part of the middle cerebral artery
16:49
the first part of the anterior cerebral artery and
16:52
now we finally have evidence for the basil or intra
16:55
cranial vertebral arteries. This is
16:58
another area where I can probably give you this talk next year and the
17:01
Data may be new and different and we are increasingly going out into
17:04
M2 vessels and to more distal vessels within
17:07
the intracranial circulation. But right now
17:10
at least we should really be looking for patients who have a relatively
17:13
small amount of ischemic injury a larger penumbra
17:16
and a vessel that is amenable to thrombectomy meaning
17:19
a large vessel occlusion.
17:21
You can obviously identify those characteristics on
17:24
MRI or CT and so by CT. We
17:27
can you CTP to find the core we can use a non-con we'll
17:30
get into that in a minute. We can identify the number using
17:33
perfusion or patient symptoms and we can certainly
17:36
do a CTA to look for an lvo.
17:40
Okay. So let's take a second and
17:43
talk about Precision Imaging and I think this is
17:46
really important because there's really been an evolution and how we
17:49
use Imaging to guide stroke patient treatment. And this
17:52
is a relatively old church and I
17:55
kind of like colored the picture here to make it look old but
17:58
it is actually old and I put this up here because of the
18:01
clock and so for many many years the treatment of patients
18:04
with stroke was really governed by the clock how long has it
18:07
been since their symptoms started and basically you
18:10
would have a really short time window to offer
18:13
an active treatment to stroke patients. If you
18:16
were a patient who shows up within zero to three hours of your symptom
18:19
onset, you could get intravenous TPA if
18:22
you qualified based on your Imaging and then that
18:25
got extended out to four and a half hours with some additional
18:28
data all the FDA on label approval for
18:31
for TPA remain only at three hours. Most people will still give
18:34
it up to four and a half hours from symptom onset though, but
18:37
what's the problem with using the clock and let's talk?
18:40
About that for a second and this is a Nantucket. By the
18:43
way, if you haven't been it's a really lovely place to go. Well, here's the problem with
18:46
the clock. These are three different patients and they were
18:49
all last seen normal within 30 minutes of each
18:52
other and they're getting evaluated at six and a half to seven hours
18:55
from symptom onset.
18:56
So here's the MRA in each of these patients and
18:59
so we can see the each of them has an M1 occlusion
19:02
on the left side. They each have a very similar Stroke
19:05
Scale as well.
19:07
Here's their perfusion in it. And so each of them has a
19:10
pretty similar sized ischemic penumbra, right?
19:13
We're seeing that there may be some heterogeneity and
19:16
you know how severe the blood flow is on these T-Max Maps,
19:19
but we can see each of them has a perfusion delay into the
19:22
left MCA territory so far. They're looking really quite similar.
19:26
But when we look at their DWI and look at
19:29
the size of each of these patients, ischemic core, look at
19:32
the variability that we're seeing these first two patients have
19:35
pretty small ischemic cores, whereas this last patient has a
19:38
pretty large ischemic core. And so even though
19:41
all three of these patients had their symptoms starting at essentially the
19:44
same time. There's a market difference in
19:47
the size of their ischemic core when they're being evaluated for
19:50
potential treatment. And so if you're really relying on
19:53
the clock, you're not going to be able to sort out these three individuals
19:56
and you would either have to treat none of
19:59
them or treat all of them knowing that at least this patient is probably unlikely
20:02
to benefit from your treatment and this
20:05
was looked at in the diffuse 2 cohort and so
20:08
these are patients with known ICA or MCA collusions, and
20:11
they have a known symptom onset time. And so if
20:14
you graph their core based on when their symptoms
20:17
started and on the x-axis to the time of
20:20
Imaging evaluation, and then they're core volume by
20:23
DWI on the y-axis you can see
20:26
There's tremendous variability, right? You could be this patient
20:29
you're at 11 hours and you've got a super small core
20:32
or you could be this patient at a little bit more than two hours
20:35
with a Holo hemispheric infarction. And so there's
20:38
a lot of physiologic variability people have very
20:41
different abilities to tolerate an ischemic
20:44
Challenge and you always hope you're one of these patients but
20:47
the reality is when you're just looking at a patient without Imaging
20:50
you don't know where any individual patient lands in
20:53
the Spectrum and that's why Imaging is so so critical and
20:56
it really is a form of precision medicine. So what
20:59
we're really looking for is a favorable patient who's
21:02
got a small core a larger penumbra and
21:05
there should be some quantifiable difference that you're
21:08
seeing and of course the large vessel occlusion patients who
21:11
are less favorable really have what we call a matched
21:14
profile their core is the same size as their potentially
21:17
salvageable tissue. And so the treatment of these patients is
21:20
unlikely to offer a benefit and there's very good data to
21:23
support this concept.
21:26
So even though historically stroke treatment is
21:29
based on the clock. I think we're really moving into this era of
21:32
precision Imaging where we're using physiologic Imaging and
21:35
other Imaging techniques to really triage
21:38
our patients for treatment and that's really great for radiology. And
21:41
it's really important that we all understand that so that our
21:44
role in helping take care of these patients as well understood. Okay.
21:47
So let's pivot and talk now about thrombectomy. This
21:50
is what a thrombectomy looks like.
21:53
This is one of my patients. There is a right M1
21:56
occlusion shown here by the arrow. This is the thrombectomy
21:59
procedure being performed and then after a
22:02
successful thrombectomy, the blue arrow is showing you restoration of
22:05
flow into that that right MCA territory.
22:08
And so, you know, we do this procedure quite a
22:11
lot at Stanford and we do it because it is so tremendously impactful
22:14
and here's an slide that
22:17
just shows the evidence from the largest trials that have validated the
22:20
efficacy of thrombectomy. So this is again for internal credit
22:23
artery or M1 occlusions of The Middle.
22:26
Little artery and these are all randomized trials. All
22:29
of them are published in the New England Journal of Medicine. This dashed
22:32
line separates the early window trials from
22:35
the late window trials and we Define early as now zero
22:38
to six hours and then late window as 6 to 16 or
22:41
24 hours. So the trial names are here. The
22:44
medical arm is the blue and the red arm
22:47
is the throne back to me and the y-axis is what percentage
22:50
of patients had a good functional outcome. Meaning that they
22:53
are living independently three months after their procedure. And
22:56
if you see in each one of these trials there is
22:59
a market benefit of thrombectomy over
23:02
our standard medical therapy and the publication of these trials
23:05
is really led to a sea change in the care of these patients. And
23:08
in fact, the number needed to treat is only
23:11
two to three for these procedures and that's really quite impressive. So
23:14
for every two to three patients you treat one of
23:17
them will do well and just to contrast that with something you
23:20
might be more familiar with if you look at patients with an st
23:23
elevation Mi who go to you know, get
23:26
Into the cath lab for a coronary artery intervention with
23:29
an angioplastier stent placement. The number needed to treat for
23:32
that procedure is somewhere around 17. So this
23:35
is much much more effective than even coronary intervention
23:38
for St. Elevation Mi and we have certainly
23:41
built whole systems of our health care around the
23:44
care of those cardiac patients and that starts to make you
23:47
appreciate the importance of doing something similar that works really
23:50
well for our stroke patients. So how do we
23:53
triage these patients for thrombectomy and we've talked about this a
23:56
little bit more but let's delve into a little bit more detail. Okay. So
23:59
what do we need? Well we talked about right now. We're
24:02
treating patients with a large vessel occlusion. And so
24:05
that we need to have some sort of vessel Imaging in
24:08
most patients and that's really can be done by an MRN
24:11
angiogram or a CT angiogram. You can see the left M1 occlusion
24:14
in both of these patients. There should be some sort
24:17
of assessment for how much injury there
24:20
is to the brain at Baseline. All right. How big do you think the ischemic core
24:23
is so if you've got a diffusion way to
24:26
Great. We think that's a great estimate of you know, how big the core
24:29
is if you just have a non-contrast CT
24:32
great. We can look for hypodensity and make sure that we're
24:35
not seeing, you know, the whole entirety of the MCA territory being
24:38
hypodens, which would be consistent with probably an
24:41
irreversible infarct and then we can
24:44
use perfusion imaging to identify the presence of
24:47
a salvageable penumbra.
24:50
So we can also do perfusion imaging
24:53
to look at the core. Okay, so that's
24:56
a kind of a variation on the CT technique. And if
24:59
you're getting the penumbral Imaging you would also be getting the same
25:02
Imaging of the core from that same technique. However, you
25:05
really do not have to do perfusion in
25:08
early time Windows. It is perfectly acceptable to
25:11
do so and two of the randomized trials
25:14
did use perfusion to treat patients. So there's good
25:17
data for it, but you don't need to do it to
25:20
make a good treatment decision that's important to understand. Once you
25:23
get into those late time window patients Beyond six hours
25:26
both of the trials that suggested a benefit in
25:29
those patients did use perfusion imaging to identify at least
25:32
the ischemic core and you can discern whether there's a
25:35
salvageable penumbra either from profusion or from symptoms severity
25:38
that is mismatch from the size of their core.
25:42
All right. So that's our Imaging goals. That's kind of
25:45
what we're looking at. How do we start to integrate all of this into the
25:48
care and the workflow of patients with ischemic
25:51
stroke? So I'm going to kind of talk a little bit about some of the systems of
25:54
care that we have in this country and there's certainly variability worldwide. But
25:57
you know since I practice in the US, that's what
26:00
I thought I would talk about. So first off this slides a couple years old
26:03
now, but I put this up to show that Throne back
26:06
to me really remains a limited resource. There are
26:09
not neuron eventualists practicing absolutely everywhere. There
26:12
are still relatively few of us. And I
26:15
think we're getting closer to having the number be appropriately matched
26:18
to the number of patients that need us, but there's certainly a geographic difference.
26:21
If you live in a major metropolitan area
26:24
on the coast. There's likely a neuron
26:27
eventualist near you. But if you live in the center of the country, there are
26:30
a large areas where you could be quite a ways
26:33
away from a neuron evangelist that could offer your throne back
26:36
to me that's shown here by driving or flying time is what these
26:39
color overlays mean.
26:41
So the way patients tend to flow to neuron
26:44
eventualists and stroke care teams in this country is
26:47
they will have a stroke and they will be brought
26:50
into a hospital and usually their first brought to a primary
26:53
stroke center primary stroke centers are fabulous. They're
26:56
able to offer TBA or connect to
26:59
place and they're sort of the Frontline hospital system for taking
27:02
care of these patients, but in general they don't have
27:05
more comprehensive level of stroke care, which
27:08
is something you're going to get at a comprehensive stroke center. And
27:11
so if you are a patient with a large vessel occlusion who needs
27:14
a throne back to me, you're going to get transferred to a comprehensive
27:17
stroke center or a thrombectomy capable center
27:20
with Staffing who can perform the throne back to me
27:23
procedure. There's some very interesting work going on right now
27:26
a Rhode Island's really doing a lot of great work at Brown on potentially
27:29
by passing a primary stroke center for
27:32
patients who are found to have a large vessel occlusion in the field and
27:35
going direct to a comprehensive stroke center. And that seems
27:38
to actually potentially be very beneficial.
27:41
For the care of these patients and lead to improved outcomes. So
27:44
this is a very active area of research that I think
27:47
will lead to some changes in our practice in the coming years.
27:51
So at Stanford most of our patients here are transferred in
27:54
so about 85% of our patients are transferred from
27:57
primary stroke centers the number of patients who walk in
28:00
through our Ed with a stroke or who have a stroke while
28:03
they're in our hospital is a smaller proportion. It's around 15% last
28:06
time we looked at our numbers. So what I
28:09
want to do is kind of walk you through the different workflows for
28:12
each of these patients to give you flavor of how we do things that Stanford and
28:15
maybe that'll help you think about what you're doing your hospital
28:18
things you could do differently certainly probably do
28:21
things some things better than us, too. There's a whole bunch of ideas and
28:24
that's why we talk about it. So let's start if you present to an
28:27
outside hospital with the stroke what happens? Well, you go
28:30
into an Ed and you're found to have, you know
28:33
symptoms consistent with a large vessel inclusion you get
28:36
your valuation and that Ed thinks that you need
28:39
to throw back to me, but they don't have a neuron eventualist.
28:42
What they do is they call our Stanford Transfer Center and I
28:45
get paged you can see this happens at all kinds of times a
28:48
day and the Stanford's Transfer
28:51
Center will activate me our stroke neurology
28:54
attending and our stroke neurology fellow and the three
28:57
of us will get on the phone within five minutes and be connected to
29:00
the Ed doc at the referring hospital.
29:03
Do you hear about the patient at the same time that
29:06
we're taking that phone call? We actually launch our helicopter. We
29:09
just go ahead and say let's get the the ball rolling. Let's
29:12
start to arrange the patient transfer and so our life
29:15
flight will lift while we're on the phone and if
29:18
we accept the patient, they keep flying if we change our mind for
29:21
any reason they come back so they go and they pick up the
29:24
patient and here's now the helicopter returning to Stanford. This
29:27
was a stroke transfer where I was with three
29:30
of my four kids and the patients about to land and I'm doing a patient
29:33
transfer for the helicopter and a child
29:36
transfer with my life. So sometimes you got a multi-test but
29:39
it works really well and the helicopter.
29:42
Lands on the roof. And then what do you do? Well, you've got to really
29:45
expedite things we go straight from the roof of the hospital to
29:48
the Imaging suite and we want to go straight down
29:51
and we want to image our patient and that's what we will
29:54
do and here we can see we've got an image that shows no ischemic
29:57
core on this patient, but a large salvageable penumbra
30:00
and perfusion imaging this is a great stroke treatment
30:04
patient. They're clearly highly impaired and here is
30:07
the patient's angiogram in the
30:10
cath lab. So this is an anterior posterior view. So
30:13
you're looking right at the patient and the black is the contrast diet that
30:16
we've injected into the left internal credit artery and right
30:19
here. We see blockage of the first part of the middle cerebral
30:22
artery. So that's our Target. And what I'm going to do is show
30:25
you a few videos about how we do this storm back to me procedure. So
30:28
the first thing we do is we actually cross the clot with our equipment. Here's
30:31
a micro wire and a micro catheter. That's Traverse
30:34
the area of occlusion inside the middle cerebral artery and
30:37
this gives us a conduit to introduce them back to
30:40
me devices. So now we
30:42
Of the wired here. We are introducing a stent retriever device inside that
30:45
micro catheter and you can see that we're across
30:48
the clot with a little bit of device that will be past the
30:51
clot to make sure it helps to drag it out.
30:53
Next thing we do is we unsheath our stent
30:56
retriever device here. It is kind of opening up as we pull the micro catheter
30:59
out and this will pin the clot between the
31:02
outside of the stent Retriever and the inner wall of the artery and
31:05
the stent kind of pushes into the clot to
31:08
grip it.
31:09
Then what we can do is we could Advance this aspiration catheter
31:12
right up to the clot interface. And once
31:15
we get up to the claw interface, we can hook on suction
31:18
to really kind of suck the clot into this catheter and
31:21
pin it with the stent helping to drag it out.
31:24
Now. This is something that we've started doing
31:27
now with this is a balloon guide catheter that
31:30
arrests flow proximately so that as you're pulling the
31:33
cloud out the blood pressure is not pushing it away from you and this
31:36
really seems to be something that's helpful for more complete removal
31:39
of the clot and there's a lot of variations that
31:42
are going on and trying to determine what the optimal thrombectomy
31:45
procedure should look like, but this is something that
31:48
we do pretty commonly here after the balloons inflated. We
31:51
can remove the clot in this manner here. It is
31:54
being pulled out of the patient and you can see do a
31:57
nice slow pull the clot should be pinned right here if you're
32:00
lucky and then you can defeat the balloon and you
32:03
can do an angiographic run and
32:06
you can see that you go from a blocked vessel.
32:09
to Restoration of flow
32:11
All right, and then here's the lateral angiogram just to show
32:14
you that we've really revascularized the entirety of the
32:17
MCA territory in this patient. And that's exactly what
32:20
you want to see happen. And if you're successful, here's this
32:23
patient's initial perfusion. Imaging again. It
32:26
didn't call a core because of the thresholding but here's
32:29
where you would expect to see some infarct in the posterior insula the
32:32
fall of MRI confirms that that injury stays
32:35
about the same size.
32:37
This was the initial CTA where the M1 occlusion is located.
32:40
Here's the MRI after thrombectomy, you can see now the vessel
32:43
is wide open and then the profusion Imaging
32:46
goes in a normalizes on the arterial spin
32:49
label perfusion sequence. And so this is
32:52
the patient who did very well and this is an illustration of how
32:55
we would bring a patient in from an outside hospital to Stanford
32:58
for thrombectomy treatment. So in general a
33:01
stroke will be identified. Typically an outside hospital is going
33:04
to at least do a head CT make a decision about giving TPA
33:07
or TMK if they're eligible and then they're going
33:10
to do additional Imaging and clinical evaluation to determine
33:13
if there are neuro Interventional thrombectomy candidate if they
33:16
are you call a comprehensive stroke center and you request
33:19
transfer the patient gets transferred right now.
33:22
We do a lot of repeat Imaging because our
33:25
transfer times are often quite lengthy given the large geographic
33:28
area we cover this is something that other
33:31
places don't necessarily need to do if they can transfer patients quickly
33:34
and then the patient good and go for thrombectomy treatment.
33:38
All right. So how does that differ compared to a patient who
33:41
comes in through our emergency department? Well, here's the Stanford hospital
33:44
about a year ago or two years ago now, I guess from the
33:47
Christmas lights are up. So getting close to the holidays and a patient
33:50
will be brought by an ambulance into the Ed here
33:53
and ideally you get a heads up from the ambulance that this is
33:56
someone who may have a stroke and you can bypass the evaluation
33:59
area and go straight to the scanner and evaluate the
34:02
patient at the time your Expediting the
34:05
Imaging sometimes my fellows here
34:08
about these cases before I do and they shoot me a text. They look
34:11
like this and if you open up I just get the bat signal which is kind of
34:14
fun. And then other times we will just be activated through
34:17
our Transfer Center in a similar way and sometimes there
34:20
are a whole lot of patients with Strokes that we get activated for
34:23
and a single day but we're gonna do the same
34:26
thing. We want to keep our Imaging consistent. That's how we practice at
34:29
Stanford. So this is a 59 year old with afib who came
34:32
into our edu with the left facial group and was Hemi product
34:35
on the left side. And here's the patient.
34:38
Sign Imaging so a small estimated core on the perfusion here.
34:41
We can see that there's a larger penumbra surrounding
34:44
this small core and we can see that
34:47
there's a right M1 occlusion on the CTA. So this is
34:50
this is a go case we got a small core large penumbra and
34:53
a large vessel occlusion.
34:55
So here's the patient's first picture in
34:58
the cath lab where we're injecting the right internal credit artery and
35:01
you can see that sure enough on this patient there. Is
35:04
that right M1 occlusion. So we were
35:07
very quickly able to go up and aspirate
35:10
this clot out and here's the picture right after we
35:13
did that and now you can see that we've really restored all
35:16
the blood flow with that vessel being widely open
35:19
and that's what you're trying to do. And if you have a really
35:22
efficient system you can do this exceptionally fast
35:25
and the time in this patient from arterial puncture
35:28
to when we're able to completely restore the
35:31
blood flow here was four minutes. Okay, and not that's really really
35:34
quick that we're able to do that but with a highly trained
35:37
team and a very streamlined workflow, you can
35:40
potentially revasculars patients and really really
35:43
quick time frames. Sometimes it takes longer
35:46
and this is certainly I'm showing you the faster and of
35:49
things but I just want to point out that you can do this stuff very efficiently.
35:53
So this was the estimated core before we took the
35:56
patient and here is his follow PET CT the following
35:59
day and you could see there's no growth in the amount
36:02
of the core and this patient actually walked out of the hospital with only
36:05
the mildest official troops two days later and was
36:08
changed on and his anticoagulation regiment.
36:11
So here's a kind of a schematic
36:14
of our in-house stroke workflow. So again, we'd
36:17
like to get a heads up from the EMS if they are suspecting a
36:20
stroke they get put on the gurney and wield in straight
36:23
to the CT scanner. We're checking things like glucose. We do a non-con
36:26
to make sure there's no Hemorrhage if they are eligible. We
36:29
will you know, grab our IV send in lab work make it
36:32
just determination about TPA after
36:35
we've assigned a stroke scale and made sure we think it is a stroke while
36:38
the non-con is being interpreted and then if
36:41
they're severely impaired, you know, we will do a CTA and CTP to
36:44
determine whether they're potentially a throne back to
36:47
me Canada. So really you're kind of doing things overall relatively
36:50
similarly. It's just how they're getting to
36:53
The Imaging Suite that differs just slightly. So where
36:56
does that leave us? Well, we have a pretty good sense of
36:59
whom we should be treating. And again, this is a
37:02
moving Target. There are a lot of active studies going
37:05
on that are looking to continue to expand the indications for
37:08
thrombectomy. And I think we're going to continue to learn
37:11
more in the coming years, which is great because I
37:14
expect we'll be expanding our eligibility. We
37:17
know how to treat them pretty well. So we've got good
37:20
techniques. There's a lot of work on the Interventional side to sort
37:23
out. What's the best thing to do? But we've made a lot of progress and
37:26
we're getting better at having systems in place
37:29
to perform back to me quickly and there's still I think room to you know,
37:33
Interstate level and even perhaps a national level to really optimize
37:36
this
37:38
So what are the challenges and how can we leverage technology
37:41
to help us out? Well, after these late window Trials of
37:44
Dawn and diffuse 3. We suddenly had
37:47
a market increase in thrombectomy treatment
37:50
because now large vessel occlusions could be treated up to
37:53
16 to 24 hours since patients were last known
37:56
to be well, so that's suddenly opens up the floodgates of
37:59
people who could potentially be treated which is a great problem to
38:02
have and this is what happened afterwards to
38:05
our stroke volumes and just kept going up and up and
38:08
up but this creates some real workflow challenges, right? How do
38:11
we evaluate all these patients? Well, we're gonna
38:14
have to figure out a way to deal with this because you can't just
38:17
transfer everybody to these comprehensive centers without
38:20
having a better sense of whether they actually are potentially
38:23
a treatment Canada and that's really meant that
38:26
it's been a little bit more up to the Community Hospitals to help
38:29
identify who could be a treatment Canada. All
38:32
right, and that's at least going to be identifying the
38:35
presence of a large vessel Collision. We'll talk about this in a minute.
38:38
And then you'd be really great. If we have these long transfer times
38:41
because they're coming from far away if we can kind
38:44
of predict. Well, what's going to happen after we transfer it and then how
38:47
can we use automated Imaging and artificial intelligence to help
38:50
us manage this increasingly complex workflow. Well,
38:53
let's talk about the possibility of doing profusion Imaging
38:56
in the community. So you're still kind of
38:59
now asking Community Hospitals to ideally identify
39:02
a thrombectomy candidate, which means can they tell
39:05
us if there's a small core a salvageable penumbra and
39:08
a large vessel occlusion. Well, what used
39:11
to happen was an outside hospital with you
39:14
know, admittedly fewer resources in a place like Stanford,
39:17
they would be able to get a non-con CT and they would
39:20
be able to do Stroke Scale. And so you would be able to hear well, you
39:23
know, there's maybe some subtle hypodensity on the left
39:26
MCA territory and I've got a patient who's very severely impaired
39:29
symptomatically, so I'm inferring that. There's probably
39:32
a large vessel inclusion and that's okay, but
39:35
it turns out there are a lot of patients where you're getting fooled by.
39:38
Mimic or where you're looking at a chronic infarct
39:41
or where it just doesn't quite make sense. And so then
39:44
we started asking pay outside hospitals. Well, can you
39:47
at least get us a CTA so that you can really demonstrate that
39:50
they do have a large vessel inclusion because that's
39:53
the patient we want to bring over and potentially help. And so now this
39:56
is sort of the minimum that people should be doing
39:59
as a non-concy Tina CTA to help
40:02
us make a transfer decision along with of course a
40:05
clinical evaluation.
40:07
So what about if a community hospital is able
40:10
to do perfusion? Well, then you can say well we know what the
40:13
core looks like. We know if there's a salvageable penumbra.
40:16
So that's really helpful. And then if they're all doing
40:19
a CTA great, you can see that there's a large vessel occlusion. This
40:22
is a lot of Imaging for smaller hospitals
40:25
to do and and I think we all recognize that and
40:28
want to try to minimize that so what could you
40:31
do to simplify things? Well instead of using a
40:34
CTA to identify lvo. Could you use profusion to
40:37
identify the presence of an LDL and it
40:40
turns out that that may be a valid strategy. This is something that we're
40:43
interested in testing. And so if you look at these T-Max images,
40:46
I think anyone looking at this you can
40:49
probably discern that these are patients with large vessel occlusions,
40:52
or at least thrombectomy eligible occlusion. So
40:55
this first one, you know, the whole MCA territoring
40:58
the left side has a perfusion delay. So that's an M1
41:01
or potentially an internal credit artery occlusion.
41:04
This patient we can look at this and say well that's not the whole
41:07
MCA territory, but certainly disappear division
41:10
looks like it has a perfusion delay and that's often a good
41:13
Target for neuron eventualists, but we can discern that
41:16
there's an M2 Superior division occlusion. And in
41:19
this patient that perfusion delays most more posteriorly
41:22
located. So this is a patient with an inferior M2
41:25
occlusion. So all of these patients you can identify,
41:28
you know where their vessel occlusion is likely to be
41:31
and that's really helpful without even doing a CTA that
41:34
we can potentially discern the presence of that blockage. We
41:37
looked at this in a slightly different
41:40
form here, but we're able to identify with just perfusion
41:43
alone that we were extremely sensitive and specific for
41:46
making an accurate thrombectomy triage. You see
41:49
our sensitivity was 97% and our specificity was
41:52
almost 99% And so that was I think
41:55
good evidence at least in a retrospective manner that should
41:58
be validated prospectively.
42:01
Okay, so does this work in the real world? Well, we actually
42:04
have a lot of our partner hospitals that do perfusion and we're
42:07
able to see their Imaging via some of these remote
42:10
apps on our phone. And so but let's look at
42:13
this. How do we think about that? Well, what if you had this image here
42:16
and you're looking you're saying okay, they're telling you it's patient with
42:19
stroke symptoms. Well, it looks like there's a small core. It looks
42:22
like there's a salvageable penumbra so that certainly sounds
42:25
like thrombectomy maybe indicated but can we discern
42:28
that? There's an lvo. Well this perfusion pattern
42:31
here in green and the penumbra that really looks like
42:34
an M1 pattern and sure enough when a CTA is
42:37
obtained. This patient has a left and one occlusion so that
42:40
certainly was correct. How about this patient? You're
42:43
being described to patient with a modest Stroke
42:46
Scale around sex to eight and you
42:49
know, it sounds like they could have a large vessel occlusion. Here's their
42:52
perfusion imaging so there's no ischemic core that's being
42:55
identified and there's no penumbra.
42:58
So we would based on this say well, we don't
43:01
think they have a large vessel occlusion and sure enough. There's CTA was
43:04
normal. So you know that you don't need to activate your
43:07
cath lab team for this patient because there's not a large vessel
43:10
occlusion.
43:11
How about this patient? Well, number one. We know that we're
43:14
dealing with a patient with a quite large core and again
43:17
right now. I don't know that we have evidence that this patient would likely
43:20
benefit. I think that that'll be an area that we may
43:23
have evidence for soon. Even though there is a mismatch and
43:26
that's something we have to look into so, you know, they have
43:29
a large Baseline core. They may have some salvageable penumbra
43:32
and if we look at this perfusion pattern you see how medial and
43:35
hide this goes. That's something you often see in
43:38
a patient with an internal crowded artery occlusion and
43:41
sure enough. This patient has a right ICA occlusion with relatively
43:44
poor collaterals, which probably accounts for
43:47
the size of their infart. Here's another
43:50
patient you're being called about transferring and you
43:53
know, you can look at their Imaging and you say okay. I see that there's a core here.
43:56
I see that there's a penumbra but you know
43:59
what? I'm looking at these areas and they look like they're kind of
44:02
the same and even volumetrically, you
44:05
know, the core is being called as larger than the penumbra.
44:08
So even though you can look at this pattern and
44:11
It looks like there's you know, probably excuse me.
44:14
Probably a large vessel occlusion. This is someone with a match
44:17
deficit. That's probably not likely to benefit from a
44:20
thrombectomy procedure.
44:22
Okay, so can we use Imaging to predict the
44:25
future? This would be really great. Right? And how do we start to
44:28
think about that? Well, what if a patient you do the Imaging
44:31
at referring hospital and they're a candidate but are they still likely to be
44:34
a candidate after you transfer them?
44:36
Well collateral blood flow is really what determines
44:39
whether patient's ischemic core stays the
44:42
same size or whether it grows. If you have good collaterals, you
44:45
would expect that their core will stay similarly sized at
44:48
the outside hospital to what it would be after transfer to
44:51
a place like Stanford. Whereas patients with poor collaterals are
44:54
likely to experience core growth and may no longer be
44:57
a treatment candidate.
44:58
So we often think about collaterals based on CTA and
45:01
these are two different patients and you can see here that there are
45:04
very few collaterals. In fact, perhaps no
45:07
collaterals being identified in this patient. These are poor
45:10
collaterals, whereas this patient here has very
45:13
good collaterals past this M1 occlusion. And so
45:16
what you do is you say this is someone sorry.
45:19
This is someone that's likely to keep their core small
45:22
and still be a treatment candidate. Whereas this patient you'd be worried that
45:25
they're experiencing a very rapid growth in their ischemic core.
45:29
So if we have CTP, how do we judge whether
45:32
they have good collaterals? We don't
45:35
usually think about profusion and collaterals. So is there a way
45:38
to do that? Well one way to do that is to use something called
45:41
the hir or hypoperfusion intensity ratio. So
45:44
if you divide the volume of brain tissue with
45:47
a T-Max greater than 10 seconds divided by the volume of tissue
45:50
at the TMax greater than six seconds that gives you
45:53
hir what you want to have is less severe blood
45:56
flow delay. So you want to have a bigger denominator and so
45:59
patients with a lower HR are people
46:02
with presumably good blood flow delivery to the brain and
46:05
that implies the presence of good collaterals. And so
46:08
sure enough around an hir of 0.4 is
46:11
0.5 is a good threshold less than that.
46:14
Usually indicates favorable collaterals greater than that number
46:17
indicates relatively poor collaterals. So visually,
46:20
what does that look like? Well, you want to see less severe blood
46:23
flow. So a lot of red on a TMax map is bad
46:26
less red is good.
46:29
And so we've published several papers to really look at
46:32
this and it's now undergoing prospective validation. So
46:35
how do we leverage this in terms of predicting core
46:38
growth? Well, look at this patient 56 year old
46:41
male left hemiplegia right gaze preference Stroke Scale is 11.
46:44
We're not seeing a ischemic core being
46:47
measured by the automated software, but we're seeing a large right
46:50
MCA territory a number.
46:53
All right. This patient is located a hundred and
46:56
seventy five miles away from Stanford and Fresno. That's
46:59
a pretty long flight, but it's doable. So
47:02
let's delve into their penumbra a
47:05
little bit more and think about this hir. So here is sort of a you
47:08
know, looking in more detail at the severity of blood flow
47:11
delay and there is some red but there's a lot more tissue that's
47:14
not red. And this patient has an hir of 0.3. And
47:17
again, we're taking that team x 10
47:20
volume divided by the team X6 lime. So this divided by
47:23
that to get this 0.3 ratio. And so
47:26
if you look at this, can you predict core growth?
47:29
Well, we studied this. This is a paper on the Adrian Road
47:32
and annals of Neurology a few years ago. And this is
47:35
what we found in fact growth seem to be related
47:38
to what their hir is at the
47:41
referring hospital and right around 0.5. There really
47:44
is an inflection or patients after that experience a
47:47
pretty rapid growth in their scheme and core that often rendered them
47:50
not treatment candidates by the time they got to Standford.
47:53
All right. So here's the helicopter. It's about to
47:56
land on the roof. It's you know more than five hours after we
47:59
had that outside Hospital. Imaging we go straight down to the MRI
48:02
suite. This is what the outside Hospital CTP looks
48:05
like and here's our DWI at Stanford. So the
48:08
core is now 28 and if you look at this, it looks
48:11
like it's pretty well confined to this red area where the
48:14
most severe hypoperfusion was located but still
48:17
fortunately there is a large mismatch in
48:20
this patient. So this is someone that's still thrown back
48:23
to me Canada. They were taken to the cath lab and this internal
48:26
crowded artery occlusion was opened and
48:29
the patient had restoration of blood flow to the right cerebral hemisphere.
48:33
So we think that this
48:36
could potentially be very useful. So HR
48:39
is really measuring tissue level collateral blood flow and it's
48:42
it seems that it's going to be a very good predictive core
48:45
growth and this is really going on undergoing perspective validation
48:48
at stand for right now with Martin landsberg's Chris
48:51
to study.
48:53
Okay, so I want to now pivot toward the end and
48:56
just review some general stroke Imaging algorithms that
48:59
you might consider using and this is just meant to be a general
49:02
overview and it's really important that whatever Imaging
49:05
algorithm you set up at your Center. It is
49:08
something that you can do within your resources. That's
49:11
really really important. So again, we're looking for patients
49:14
with a large vessel occlusion a small core and a
49:17
large pin number. All right, but we can use a whole host of strategies to
49:20
identify these patients. So let's start with what I
49:23
would call the minimalist approach and that is a head
49:26
CT and a CTA and this was the approach that
49:29
was used by the Mr. Clean trial which was the first randomized trial
49:32
showing a benefit of thrombectomy in 2015.
49:35
And so it would do you would do something like this.
49:38
There's an 86 year old with left side of paralysis a very
49:41
high Stroke Scale. We have a non-con CT
49:44
and we have a CTA. So our CTA is
49:47
showing us an internal crowded artery inclusion on the right. So there is a large
49:50
vessel occlusion and on the left we're saying well, you know.
49:53
We don't see a huge amount of ischemic injury, like maybe there's
49:56
some subtle like loss of density here because
49:59
the cell loss of density here and the basal ganglia on
50:02
the right, but it doesn't look that bad. Maybe the internal capsule posterior lens
50:05
a little bit more hypoense, but certainly there's no large
50:08
area of obvious injury that seems to be favorable and
50:11
their symptoms are clearly much
50:14
more impaired than any hypodensity that we're seeing here. So
50:17
that's a good treatment candidate. Here's their AP
50:20
and lateral angiogram showing you internal crowded
50:23
artery inclusion. Just past the abhalmic artery and this
50:26
patient gets successfully revascularized and that's
50:29
a very valid treatment strategy and it works.
50:33
What if you want to be a little bit more discriminatory and
50:36
you want to include a little bit more nuanced information
50:39
about how much ischemic injury there
50:42
is on a head CT. Well, then you could talk about using aspects
50:45
as well as a CTA. And this was the approach
50:48
that was used by the ravasket trial which was also published in
50:51
the New England Journal of Medicine. And so aspects is
50:54
an attempt to quantify the
50:57
degree of ischemic injury on non-con CT. And so
51:00
this is from the folks that Alberta and what you do is you look at
51:03
these 10 stereotyped regions in the MCA territory
51:06
and you identify whether there is
51:09
significant hypodensity in each region. And if you
51:12
do have hyponency in a region, you remove a point and
51:15
there are 10 regions. So the best score you're going to get is 10,
51:18
but if you haven't aspects of six to 10
51:21
that is favorable for thrombectomy treatment, and so
51:24
here's a patient who's got a right M1 occlusion and
51:27
you want to window this to help you really discern the
51:30
presence of hypodensy and when you do that we
51:33
See that we've got hypodensity in the insula the lentiform nucleus
51:36
the caudate head and up into the M4 region.
51:39
Well, that's four points off. This aspects is
51:42
6 that is still favorable for treatment. Okay. Here's
51:45
another patient and 86 year old with left-sided paralysis.
51:48
Again, the high Stroke Scale here is the non-con CT
51:51
and when we look at this we say well
51:54
the M2 region looks hypotens the insula, the lentiform
51:57
nucleus looks typodens, and we've got an M1 occlusion. That's
52:00
someone favorable for treatment in the patient
52:03
did get a successful from Back To Me.
52:06
Okay, what if you want to incorporate some information about
52:09
collaterals and you could do that on CTA
52:12
or you could do a little more advanced collateral assessment
52:15
using multi-phase CTA and that's the
52:18
strategy that was used by the Escape trial another one
52:21
of the randomized trials that was published. And so how
52:24
does this work? Well you first are going to look at the head CT
52:27
and you're going to say okay. Well how much hypodensity is that is
52:30
there and there's a two patients where we see some hypodensity here
52:33
in the lentiform nucleus, maybe into the coding on
52:36
each patient, but overall looks like a high aspect score.
52:40
So what about the presence of an lvo? Both of these patients have
52:43
M1 occlusions this patient on the left this patient
52:46
on the right, but what about collaterals? Well, let's assess
52:49
the collateral. So this patient has very poor collaterals.
52:52
There's not a lot of contrast in the arteries past
52:55
this blockage and this patient over here has really good
52:58
collaterals, like very good filling past this blockage. And
53:01
so which one would you offer treatment to the one
53:04
with good collaterals? Okay, and this
53:07
patient goes on and gets treated successfully and that
53:10
also is a valid treatment strategy that was
53:13
worked very well in the Escape trial.
53:16
So we're getting into the more complex or Advanced sort of approach
53:19
and that's the use of perfusion imaging as well as
53:22
CT and geography and perfusion was actually used in
53:25
the bulk of the randomized trials that have been published. And so this was
53:28
in the early time Windows the Swift Prime and extend IA as
53:31
well as both late time Windows Dawn and diffuse 3.
53:34
And so that that will work something like this. This
53:37
is a patient of mine. She's an 81 year
53:40
old female with Aphasia and right-sided paralysis. She held her
53:43
Coumadin for a dental procedure and woke up with severe
53:46
stroke symptoms went to an
53:49
outside hospital was found to have these symptoms transferred to Stanford. And
53:52
here's MRI on admission to our hospital and we
53:55
can see a relatively small core on the diffusion weighted
53:58
image clearly a large penumbra here
54:01
and a pattern that looks like an ICA occlusion and sure
54:04
enough on the MRA. We see in ICA occlusion, but
54:07
clearly a mismatch here between these two the
54:10
core and the number which we quantify the course
54:13
seven the numbers 128 milliliters.
54:16
That's someone who's a good treatment candidate. So here we are treating the
54:19
patient and we see that I see
54:22
occlusion again just passed the ophthalmic artery and just passed
54:25
the anterior corital artery.
54:27
This is the clot that we removed from the patient and after
54:30
doing so we were able to restore flow
54:33
into that left anterior circulation territory. So,
54:36
you know a very good treatment a good restoration of
54:39
flow and here is the patient in the
54:42
cafeteria on the day of discharge, which is three days later and this
54:45
is my fellow former fellow Eric assessment who did the procedure
54:48
with me and I just want to point out that here's the patient.
54:51
So she looks fabulous and arguably and
54:54
better shape than her husband, and she really did remarkably. Well.
54:58
So I just want to end with a few words on
55:01
automated Imaging because this is something that is really going
55:04
on now and everyone should be aware of so AI is
55:07
here. These are some of the automated software platforms that you might have
55:10
seen you are able to get all kinds of information on
55:13
your phone, which is how the neuron eventualists and
55:16
strict neurology folks are really following these patients and triaging them.
55:19
So the Radiologists need to be aware of that you can window
55:22
things you can scroll things on your phone now, which is pretty
55:25
incredible. You can see on email whether a patient
55:28
has a mismatch and an ldo and you can
55:31
see when a patient looks like they should not be transferred even though they have
55:34
an lvo they may have a matched deficit or
55:37
a very large core. But automation is here. It's
55:40
helping already and that makes us a very exciting
55:43
time and stroke care. So just to wrap up this is a really fun
55:46
time to be taking care of stroke patients and it's a
55:49
really fun time to be Imaging them thrown back
55:52
to me is a very highly effective therapy for ischemic stroke due
55:55
to a large vessel occlusion and our stroke systems of care are really already.
55:58
Drink to this artificial intelligence is
56:01
here. That's really kind of showing up first in neuroradiology and
56:04
stroke care and I think is going to continue to expand in use
56:07
and here's just a view of the Stanford campus
56:10
from the helicopter when I when I joined them for a quick flight. It's
56:13
really beautiful here. So come visit the Bay Area sometime and
56:16
with that I will go ahead and stop my sharing
56:19
and I'm happy to answer any questions
56:22
that you all might have and
56:26
I'm going to navigate here the Q&A box. So
56:29
there's one
56:32
question here about how do we Define a small core?
56:35
And that is a bit of a moving
56:38
Target. So right now in the early window trials 50 MLS
56:42
to 70 MLS was used in the late window trials.
56:45
There was a sliding scale of core size that
56:48
went up to 70 MLS if you want to be as inclusive as
56:51
possible. What we do at Stanford is we Define the
56:54
core of 70 or less as favorable in greater
56:57
than 70. We we don't know and don't always offer treatment.
57:00
I suspect next year. We're gonna have data about
57:03
larger courses already been one trial published
57:06
out of Japan suggesting that large course can
57:09
help similarly acapca Strokes.
57:12
We just don't have a lot of data right now many people are starting to
57:15
consider treating them, but we don't have data from
57:18
randomized trials yet.
57:20
Another question here patients who
57:23
have recurrent stroke. Can you still treat them
57:26
with thrombectomy procedures so you can I
57:29
think you have to understand what's going on with the patient
57:32
and each situation can be variable. And so
57:35
for example, we had a patient a few years ago who are
57:38
one of my former fellows his first
57:41
three thrombectomy procedures. He did with me. We're
57:44
in the same patient within a 36-hour period She
57:47
had a new diagnosis of cancer and is
57:50
very hypercoagable and she kept throwing M1 clots on
57:53
the left side. And so we did a repeat, you know thrown back
57:56
to me three times in a row because her Imaging triage
57:59
every time still looked favorable and so
58:02
you can certainly still help those patients. You just have
58:05
to make sure you're taking to into account the clinical situation
58:09
of what you're doing.
58:12
So a question about hyperfine for
58:15
wake up stroke. So hyperfinds pretty interesting. We don't have
58:18
it at Stanford. I think that it would be very interesting to
58:21
have these sort of In-House Mrs. To to make
58:24
kind of triage decisions. I've just not familiar with how well
58:27
they perform but certainly you can get a DWI and
58:30
gain some information. I don't know how well other you
58:33
know sequences work on that scanner, but that would
58:36
be a very interesting way to potentially evaluate a
58:39
patient in your neuro ICU. For example, who may need a
58:42
throwback to me treatment.
58:45
So a question about chronic vessel occlusion on
58:48
CTN MRA being an issue for thrombectomy. This
58:51
can sometimes be difficult. Right a patient comes in
58:54
with a stroke and there's a large vessel occlusion and you don't
58:57
always know whether that is an acute occlusion or
59:00
a chronic occlusion. If they are
59:03
newly presenting with symptoms, I would
59:06
argue it's probably a good idea to operate under the
59:09
assumption that it is an acute occlusion. But again, you
59:12
can be wrong so you can sometimes leverage trip
59:15
tricks on the profusion to help you and so,
59:18
you know, if you're looking at Rapids MTT,
59:21
for example, which is less sensitive to
59:24
delays symmetry on the MTT map can often
59:27
indicate a more chronic inclusion. We have a paper under review about that
59:30
right now. Whereas if there's asymmetry in
59:33
the MTT that may indicate that it's an acute occlusion. But
59:36
sometimes you just need to say, you know, we don't know and take
59:39
the patient to the neuronovascular suite
59:42
and and see if you can discern based on the pattern.
59:44
Or whether you can cross it
59:47
successfully and find out that maybe you were tricked on the non-invasive Imaging.
59:52
A very timely question on posterior circulation stroke
59:55
care. So we finally have a
59:58
randomized data that doing a Basler artery
60:01
thrombectomy is beneficial. So the motion
60:04
attention trials were published within the last month and
60:07
they were both randomized trials in China and showed
60:10
a benefit for thrombectomy for basala artery occlusion,
60:13
as was asked a little bit early. We don't have data on PCA
60:16
occlusions that could be certainly a reasonable
60:19
thing. But it's it's an area where we don't have a lot
60:22
of evidence right. Now. The Imaging evaluation of
60:25
posterior circulation Strokes needs a little
60:28
bit more work. And that's one of my grants's asking that that question
60:31
but both of those positive trials use something
60:34
called the posterior circulation aspects and you had to
60:37
have a PC aspects of six or greater as well as a
60:40
CTA showing that you had a Basler artery occlusion or
60:43
occlusion of both intercranial vertebral arteries.
60:46
And so that's sort of the inclusion criteria that I
60:49
think is reasonable to be operating under right now.
60:52
But the stroke guidelines have not been updated to address that
60:55
at this time.
60:57
So I will there's a couple more and then I'll let you all go
61:00
for time. Our neuron inventional team. We currently have four
61:03
neuron eventualists. We have a three fabulous
61:06
nurse coordinators who help
61:09
operate our outpatient service, but we have a super busy inpatient
61:12
stroke team that includes, you know,
61:15
many many other folks in terms of a very robust drug neurology
61:18
team a stroke neurology fellowship program coordinators. It
61:21
takes a village to really do this this well,
61:24
and that's a really great question. And then
61:27
why don't I
61:30
For that you've got a good question. Nice to hear from you. There's
61:33
a lot of different terms for salvageable tissue that
61:36
can cause confusion so penumbra and
61:39
mismatched perfusion deficit. Yeah. So the I
61:42
think the terminology does get a little bit sloppy. So in general what
61:45
I would say is tissue at risk and penumbra are synonymous those
61:48
mean the same thing mismatch refers
61:51
to a core that is smaller than
61:54
a penumbra. So those two volumes
61:57
are mismatched if the core and the
62:00
penumbra are the same size, they are matched. And again,
62:03
that's a situation where I don't think it makes a lot
62:06
of sense to open up a large vessel occlusion. If the
62:09
core is already the same size as the salvageable tissue
62:12
perfusion deficit can refer to
62:15
any form of the penumbra certainly is
62:18
a perfusion deficit being could also have more mild profusion delays
62:21
that may reflect us to stenosis and the neck for
62:24
example
62:25
And then why don't
62:28
we end with one more question from Steven Wong here. Do I
62:31
put Stenson for intracranial arteries stenosis? So this this
62:34
is another very active and kind of tricky area a
62:37
lot of the best data are coming out of Korea and
62:40
Japan for how to handle patients with intracranial atherosclerosis. The
62:43
medical therapy is really critical. So initiation
62:46
of anti-platelet therapy is really important
62:49
in keeping these arteries open. I try to avoid acute
62:52
stunting if I can because I'd prefer to
62:55
not put metal in if I can get away with
62:58
not doing it. So I usually will try angioplasty if the
63:01
vessel is is continuing to go down after
63:04
a throne back to me. But if it doesn't respond
63:07
to angioplasty or if there's you know a dissection that
63:10
results placement of a stent is a reasonable
63:13
consideration that we have a little bit less data to
63:16
help us to guide that decision.
63:19
So last question
63:22
can MRI CT predict a stroke that might happen in
63:25
days.
63:25
Months not yet. You can that's a great
63:28
question. We can't quite predict the future that accurately but look there's
63:31
a lot of smart people on this call on this
63:34
zoom and I'm sure someone will come up with a good idea that we can
63:37
test in the future.
63:38
So, thanks again everybody. This was a lot
63:41
of fun and thanks again
63:44
to the folks at MRI online for for supporting it.
63:48
Dr. Hai, thank you so much for your lecture today and thanks to
63:51
all for your participation in our new conference a reminder
63:54
that you can access the recording of today's conference and
63:57
all our other previous named conferences by creating a free MRI online
64:00
account.
64:03
MRI online has launched a new stroke Imaging Focus membership plan
64:06
to help you gain access to help you gain confidence with stroke and
64:09
neurovascular. Imaging. Learn more at MRI
64:12
andline.com slash neurostroke. Be sure
64:15
to join us next week on Wednesday, November 9th at 12pm Eastern
64:18
time for a lecture with Dr. Donald Resnick on
64:21
the articular disorders of the peripheral. Skeleton
64:24
emphasis on morphology and Target
64:27
sites. You can register for that lecture MRI online.com and
64:30
follow us on social media for updates and reminders on upcoming
64:33
new conferences. Thanks again, and have a wonderful day.
Jeremy J. Heit, MD, PhD
Associate Professor of Radiology and Neurosurgery, Interim Chief of Neuroimaging and Neurointervention
Stanford University
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