Interactive Transcript
0:00
Thank you for attending the lecture today.
0:03
Um, Dr.
0:04
Lorenz will be reviewing introduction to coronary CT Angi.
0:09
Um, as usual, we encourage you to turn on your cameras
0:13
and, um, let us know if you have any questions or comments.
0:15
You can use the hand raise emoji in Slack,
0:19
or you can just ask Dr.
0:20
Lorenz directly, or if you're more comfortable,
0:22
you can put your questions in the chat.
0:24
So, Dr. Lorenz, whenever you're ready.
0:27
Okay, so I've got about 53 minutes
0:30
and, um, there is a PowerPoint presentation,
0:33
which is available to you, Dr.
0:34
Fontes and I, uh, one of the cool things, uh,
0:37
about the military is there is no payment
0:42
for extra personality.
0:44
You just get slung into a place and you get to work it out.
0:47
So, cardiology, radiology, if you did your fellowship,
0:50
you went to great places, um, then guess what,
0:53
you're on the cardiac imaging.
0:55
And so that's something fantastic.
0:57
Uh, some programs, of course, are very, very strict, um,
1:02
in terms of pathways
1:03
or, uh, specialists taking care of certain things such
1:06
as cardiac imaging, cardiology
1:08
or cardiac imaging or radiology.
1:10
Um, good things and bad things, of course, with that.
1:12
So, multidisciplinary multispecialty, um, in the military
1:17
where we both worked together
1:18
and when we created this, um, PowerPoint presentation.
1:22
So outline for today is we're gonna go through some
1:24
of the very, very nuts
1:25
and bolts, um, of, of, uh, cardiac imaging acquisition
1:30
and reporting, and some things
1:31
that we threw in there in terms of just
1:34
to keep you thought process wise on how
1:37
to deploy a cardiac imaging program.
1:40
This is just a starting spot.
1:41
In fact, I was just looking at some of our, um, um,
1:44
text group threads,
1:46
and we're already talking about, um, how to deploy out, uh,
1:49
systolic only acquisition, which allows you then
1:52
to have no nurse and, um, you know, NTG paste
1:56
and no medication for heart rate optimization.
1:59
Um, so you can deploy that at essentially
2:01
autonomous imaging centers.
2:03
And so the cardiologist, radiologists, all of us are kind
2:06
of inputting on that and how we can do it.
2:07
So by no means is this definitive.
2:10
This is just starting spot.
2:12
I also have two, um, um, articles that I wanted
2:16
to review just because they,
2:17
they are just cornerstone articles, and so we'll get, so
2:20
unless there's any, uh, questions the moment,
2:22
then we will get started.
2:24
And, uh, looks like I got my little chat message up here
2:27
so we can see how this goes.
2:29
But for many of you, you're, you have had an introduction
2:34
to coronary, um, angiography in terms of seeing, um,
2:38
angiography acts with acquisition for the vascular tree,
2:41
either of carotid neuro neurovascular,
2:44
and abdominal and lower extremity.
2:46
So the idea of an anatomic based assumption
2:51
that from a linear standpoint, that the higher the degree
2:55
of stenosis from zero to 100%
2:58
correlates may not be causative,
3:00
but correlates anatomically
3:04
to a stenosis percentage that you can deliver in a tree
3:08
of decision making to a clinician as to how
3:12
to best deploy resources is essentially
3:14
what coronary imaging
3:16
and coronary functional, um, decisions are made on.
3:20
So the anatomy base of zero to 100%.
3:25
Um, and of course the interval breakdown of
3:28
that is essentially what we've done
3:30
for many generations in other angiographic evaluations
3:34
of the, the human body, that part's not different.
3:38
The names obviously the nomenclature
3:40
and some of the other components are a little bit different
3:43
in the nitty gritty interpretation of it.
3:46
I'll also side note that anatomy was not, interestingly,
3:50
the first way of evaluating cardiac, uh,
3:54
cardiac disease.
3:55
It was actually the opposite, which is functional.
3:58
And, uh, interestingly functional did not turn out
4:02
to be the best way of evaluating coronary disease.
4:05
Um, it's not very specific
4:08
or potentially sensitive, um, to, based on the type of
4:12
detector, um, or image acquisition, um, to nailing out
4:16
what is the root cause.
4:18
So although functionality was
4:21
used primarily in cardiac imaging
4:23
and cardiac imaging disease, um, the methodology to do
4:28
that was not very good, uh, for a very long time
4:31
until CT based, um, has come along to kind
4:34
of nail out the anatomy portion of it.
4:36
But interestingly, functional is how you treat it still.
4:41
So are we gonna come to a point
4:42
where the functional treatment is still the
4:45
best case cost-effective?
4:46
Um, may, you know, something
4:48
that avoids major adverse cardiac events?
4:51
We don't know yet. There's actually some really good studies
4:53
that are going out there right now.
4:54
If the diagnostic of anatomy first
4:59
trends out to be that the diagnostic, uh,
5:02
in clinical treatment of anatomy first is best, particularly
5:05
as we move into preventative medicine.
5:07
So I can't wait to see your comments on that.
5:10
But in the interim, let's just dive into this PowerPoint
5:12
real quick and just, um, kind
5:14
of go through a few little things.
5:15
So what factors, of course, many factors play into role.
5:18
What kind of scanner do you have?
5:20
What kind of scanner constraints in terms of the cost
5:22
of the scanner, where it's located,
5:24
where your patient's located, and what kind of deployment?
5:27
Cardiac imaging for acute coronary disease.
5:30
Um, so such as, um, you know, uh, a urgent care center
5:34
or, um, you know, a a another type
5:36
of facility like an ER facility.
5:38
What kind of patient related factors?
5:40
And these are probably the biggest thing.
5:42
And by patient related, of course, we're talking morphologic
5:45
such as how big your patient is, BMI, um,
5:49
or sometimes if your patients are more male
5:52
or more female, contrast related factors, of course,
5:55
play a role into this too.
5:58
So the right fit, right patient is always the big thing.
6:00
There's several different guidelines that kind of go
6:03
through this in detail.
6:05
I would highlight, um, hopefully you can see my screen here,
6:08
the, the 2021, um,
6:10
chest pain guideline is probably the better one
6:13
in really breaking it down.
6:14
Now, even further than that, I have my cheat sheet.
6:18
I have cheat sheet for academic, one for outpatient center,
6:21
and then autonomous, um, imaging patient centers.
6:24
Uh, we have one specifically for Texas
6:27
because there's a little bit of a larger BMI in that area.
6:29
And then, um, I also read for several LA locations on both
6:34
of our US coasts, so New York and, um, California
6:37
and West Coast and stuff.
6:38
And that's not the same BMI,
6:40
but there is an absolute importance on
6:44
arriving at the right BMI for, um, milli amper penetration
6:48
and obviously dosing.
6:51
Okay, contraindications. Let's just get these out quick.
6:54
You, as the subject matter expert, are the one who can say
6:57
what is allowed, not allowed.
6:59
Although these are guidelines,
7:00
there is no real strict rule on it.
7:03
Even the a UC criteria guidelines don't really
7:08
tie your hands behind your back
7:10
and say, you are not allowed to do this.
7:11
They're guidelines, you as the performative, um,
7:15
and physician gets to decide this.
7:18
But as usual, in use of radiation contrast, um,
7:23
size, the patient and, um, the current fitness
7:26
of the patient that is pregnant, not pregnant, postpartum,
7:28
whatever is really going to deliver
7:31
what is the appropriate acquisition.
7:33
So of course, um, there are some things related to pregnance
7:37
and, and possibly a pregnant.
7:39
I would advise you to consider that most
7:42
of the Millie Seaver acquisitions right now are just
7:46
fantastically low in the normal acquisition comparatively
7:50
to, um, nuclear
7:52
or some other methodologies such as, um,
7:54
invasive coronary angiography.
7:55
So don't discount CT comparatively
7:58
unless you're looking at an Appleton apple,
8:01
milli seavert temple resolution.
8:03
This is probably the bigger one.
8:05
Really, we need something that's gonna be able to, um,
8:09
acquire something on an individual
8:11
who has an optimized heart rate.
8:14
Now for my current machines, um, you know,
8:17
this is second generation 2.5 ish, so not naone
8:20
or photon counting, but something a little bit, uh, less so,
8:24
uh, Siemens force sort of level stuff.
8:26
Um, canon equian, uh,
8:30
GE has some apex, um, things.
8:32
Those can definitely have a,
8:34
a larger range from obviously 50, um,
8:37
to about 75 depending on what kind
8:40
of iterative reconstructions
8:41
and algorithmic reconstructions are available there.
8:44
Poor image quality, hate to tell you this,
8:47
but you're going into a field where there's gonna be motion.
8:50
This thing is moving. Um, the heart
8:52
and the pulsatile nature of the coronary arteries, um, is
8:56
that there's gonna be motion.
8:58
And so I'm gonna, we're gonna teach you on how to take
9:00
that motion and potentially learn how to discount more
9:04
of the, um, the larger components of motion.
9:07
But obviously the acquisition should be the,
9:09
the best starving place for that.
9:12
Um, unable to receive vasodilatory medications such as,
9:16
um, nitroglycerins.
9:18
There are of course some medications that could be involved
9:21
with that and may not be the, the best,
9:24
uh, situation for you.
9:26
Um, do, do, do contrast contraindications, anaphylaxis,
9:30
higher risk for contrast induced nephropathy.
9:33
Uh, I mean, we not really in that area anymore
9:37
where there's a high, uh, molar, you know, concentration of,
9:41
of, of a type of iodine that causes that.
9:43
In fact, in usually the a CR pushes something, um,
9:48
early in the spring American cardio, uh, college
9:51
of radiology, and then by summer fall they retract that
9:55
and say, well, well, you know, it, it may not.
9:58
But essentially contrast
10:00
and contrast related contraindications to other organs,
10:03
solid organs such as the,
10:04
the kidneys hasn't really burned out.
10:06
So I try to not think about that as being a consequence
10:11
of not doing the exam.
10:12
We're talking chest pain just like we do for pulmonary em.
10:15
Um, embolism evaluation.
10:17
It's sort of one of the things you're just gonna do.
10:19
So you try to optimize the factors, right?
10:22
So a little bit more about optimization.
10:24
There are some really important things to kind
10:26
of consider here, but I think the most important one is
10:29
that the patient is appropriately prepared
10:32
that there are some things that they're going to need to do
10:34
before in the morning of.
10:36
So, uh, drink fluids, that's a big thing, particularly
10:39
for our older crowd because the vessels can get smaller
10:41
and there is of course a microvascular disease differential
10:45
if you are of a, you know, female
10:47
or, uh, potentially even younger
10:49
that you might wanna worry about.
10:51
But for the most of the part,
10:52
you want a bigger fatter vessel.
10:54
And, and sometimes that has to do with blood volume.
10:56
Now, I'll tell you that most of the healthy individuals,
10:58
the body's pretty smart, so it's not gonna leave all that
11:02
blood volume in the primary space, um, for you just
11:07
because you wanted big plumpy, um, coronary arteries.
11:10
Um, it's actually gonna move it out
11:11
and there's gonna be an excretion thing
11:13
that you're gonna work with.
11:14
So that theory doesn't really hold too much.
11:18
I think the main one probably is gonna be
11:20
as medications that could do it.
11:21
Caffeinated products potentially can contra, uh, indicate,
11:25
you know, some of the, the blood pressure medications.
11:29
Um, yeah, that's a possibility.
11:30
But I think one of the hard
11:33
and fast ones is maybe va vasodilatory medications
11:36
that are already in use.
11:39
Okay, well, just so that we're all on the same page here,
11:42
um, for most of my facilities, um, anything above a GFR
11:46
of 45 is good to go.
11:48
I think you start getting into this gray range when you're
11:51
about 30, um, or less,
11:53
and that's probably not too much of a stretch.
11:56
Maybe have a conversation
11:57
or have at least, um, some, uh, chronicity of, uh, reduce,
12:02
um, renal function.
12:04
Um, before, you know,
12:06
you start just diving into the contrast.
12:07
Now, how much contrast are we using?
12:09
We'll get into that one there,
12:10
but essentially we're just looking at somewhere around, um,
12:14
60 to 80 milliliters of a 300, um, milligram,
12:19
uh, or a 300 density of an iodinated contrast.
12:25
Okay? Procedural medications.
12:27
This is probably one of the better slides to keep in mind,
12:30
one of them, which is
12:31
because the optimization of heart rate really makes
12:34
or breaks everything, and this is just no matter the expense
12:38
of the scanner, no matter the, uh, technical capability
12:41
of your technicians
12:43
or your nurse, if you cannot get a very good heart rate
12:47
optimization, so 50 to 70, somewhere around there,
12:50
you're gonna have problems in the interpretation
12:52
port portion of it.
12:53
So as this slide indicates, anything around the 60
12:56
or less is probably a good way, you know, good time
12:59
to do, do the acquisition.
13:01
That of course, is a rolling dynamic number.
13:03
It is dynamic as the patient may be sitting in a cold,
13:06
dark room, um,
13:07
and you do a, a, a heart rate optimization evaluation,
13:11
and all of a sudden they're 50, no problem.
13:13
But then as soon as you start walking 'em, getting onto
13:15
that scanner, laying 'em down, it's a brighter room,
13:18
the technician starts talking to them,
13:19
and all of a sudden in our 30 year olds, right,
13:22
that shoots up to about a hundred.
13:24
It's not because you didn't have good heart rate
13:27
optimization and control, it's just that's, you know,
13:30
that's a, a good working and dynamic nervous system.
13:33
So I tend to have a little bit of five milligram,
13:36
maybe 10 milligram of iv, um,
13:39
medication available metoprolol available so
13:42
that if the technician or the nurse is seeing that
13:45
after they gave, um, the, you know,
13:48
after they've taken their optimized heart rate
13:50
and they had it noted that if there still is some, um,
13:54
dynamicism to the heart rate
13:56
and they're able to calm 'em down through breath holds,
13:58
then um, then we can give the IV medication.
14:03
Um, little chat about averdine.
14:05
This is typically done in academic centers.
14:08
This is considered the, the hammer, the sledgehammer to, um,
14:12
help out for individuals who have very consistently
14:16
tachycardic, um, rates.
14:19
Uh, I would say it's probably about 60%.
14:22
Uh, if we do use it, that it, it is successful, um,
14:25
that probably has nothing to do with the medication,
14:29
but more to do that, just a very
14:32
anxious patient is still gonna be an anxious patient
14:35
regardless of the medications you do.
14:36
And that's just their survival instinct.
14:38
So if you find that, um, maybe there's other methodologies,
14:42
but after you've, uh, maxed dose about 300 milligram po
14:46
metoprolol, and then you start on the evine train
14:49
and you're still not getting any results,
14:51
they're still hovering around 70, 65, maybe once
14:54
or twice, then
14:55
that's probably not gonna be the right patient.
14:57
I would probably still elect
14:58
to get then a full retrospective, um, acquisition.
15:04
But, um, some of my colleagues say, Nope, we'll just send it
15:06
to something else to get, um, that, the coronary evaluation
15:09
or chest pain evaluation.
15:11
But I like to scan just so that I can see
15:13
what I can learn from that.
15:14
And typically what we're dealing with in terms
15:17
of a population sensitivity wise is low risk
15:20
or any immediate risk.
15:22
It's not the higher risk where we're dealing with 70,
15:24
you know, to 99% stenosis where we really need a good,
15:28
quiet, slow, you know, um, still study to evaluate.
15:32
Does that make sense so far? Okay, positioning.
15:36
Um, this is typically what we have where, um, IV access
15:40
and then, um, uh,
15:42
and then leads are typically from the right side
15:44
of the patient field of view, obviously
15:47
centered on the chest, um,
15:48
and then leads off to the side in the periphery
15:51
of the chest wall here.
15:52
Typically, um, there's lead one and two,
15:55
and then, um, you know, uh, frontal lead, so above the head,
16:00
IV arms straight, um, ECG lines outside cranial side
16:04
for contrast line, of course, um, their metal items.
16:08
Um, not usually a problem.
16:10
I mean, this is pretty standard for every place, um,
16:12
and for essentially any acquisition of the chest.
16:15
So, um, lots of patients like to have their, um, a bolster
16:19
underneath their legs if they're on the scanner
16:22
for more than five minutes, I would suggest
16:25
changing the routine of your medication optimization.
16:28
Um, typically we have them on the table less than two
16:32
minutes, and that is a, an an area of really great,
16:37
um, uh, performative improvement.
16:39
So quality assurance, uh, assurance
16:42
and quality, uh, sort of quips.
16:45
So where you, if you're spending more than five minutes,
16:47
that's where you take that chunk of that
16:49
of cardiac imaging workflow and, and management
16:51
and you start dialing and figuring out out how that,
16:54
and why that patient's staying on there five minutes.
16:56
Is it because you didn't have two confirmative heart rates
17:01
that are less than or wherever your window is for 60 to 70?
17:05
Is it because you are transporting from a nurse center, um,
17:09
down to the CT center that's too far,
17:12
and then all of a sudden then the IV medication starts to,
17:15
um, dwell off?
17:17
So there are a couple different things that you can work
17:18
with it, but I usually see how long and I ask them,
17:21
and in fact, in some of my outpatient centers,
17:24
I have a little number space there
17:26
where they then are supposed to put in
17:28
how much time they spent on the table.
17:30
Most of them do check in a certain number, you know,
17:33
just try to keep me off their back.
17:35
But, um, I have some that are videotaped so
17:38
that I can just see, you know, exactly how long it's taking.
17:42
Procedural, uh, for the acquisition,
17:45
we typically do a breathe in, breathe out,
17:48
breathe in, hold your breath.
17:50
Some people can do an expiratory, so breathe in,
17:52
breathe out, hold your breath.
17:55
And then others are just a simple tidal volume breath.
17:58
So all three of them are especially acceptable.
18:01
There is no, from what I've seen, one
18:04
that works better than other, I would suggest tailoring it
18:08
in your checklist to the type of patient.
18:11
So if you have a small patient,
18:14
you want more tidal vol, uh, more volume.
18:17
So an ary hold is probably a good thing
18:19
because you want to expand the seat, um, the field of view,
18:23
uh, to make sure
18:24
that your heart is centered right in the center
18:27
of the field of view.
18:29
ISO centered, right? If you have a larger patient maybe
18:32
taking breath in and ex
18:34
and then expiring it out so
18:37
that the heart then is concentrated there,
18:39
that's probably another good way
18:40
of going that Oh, about it too.
18:41
I've also seen small tidal volume, you know, five
18:44
to 10 milliliter tidal volume, and that can work out well.
18:48
You don't need to typically do a val Salva.
18:51
What that does is tends to rush in lower extremity,
18:56
non contrasted volume, um, at the same time
18:58
that your contrasted volume from your right, um,
19:01
upper extremity comes in
19:02
to the right chambers at the same time.
19:05
And most of the, um, uh, generation two,
19:09
2.5 CT scanners, they are fast enough now
19:13
that you actually will see the mixing
19:15
and sometimes the mixing can cause then, um,
19:18
some issues in terms of attenuation and reporting.
19:21
So I don't usually have anybody squeeze, squeeze their butt,
19:25
squeeze their legs to try to pull in all the blood.
19:28
It just never works out that way very well.
19:31
I think tidal volume is fantastic, um, for most places
19:34
that are, for us automatically run working really well.
19:39
In terms of the breath hold time, most of
19:43
scanning is acquired within six seconds, eight seconds.
19:49
Um, the newer ones, um, uh, do spin faster
19:53
or have, you know, a detector, a z detector length
19:55
that is whole heart.
19:57
So you definitely get like one to two seconds
20:00
of acquisition in there.
20:02
So what this means for your patient, really not much
20:06
because the whirl of the, the worrying of the motor, um,
20:09
is occurring at the time of the Topo Graham or the scout.
20:12
It's also occurring, um, at during the feeding.
20:16
So they're not really gonna know the difference on the
20:18
acquisition from the pre-procedural acquisition.
20:22
Um, but your technician only has three seconds
20:26
of acquisition, so it's really affects more
20:28
of your technician in terms of that this is so fast compared
20:32
to five, 10 years ago when we were all in 64 row.
20:36
Now, most of the scanners that I see these days,
20:38
we've gotten, have gotten about 10 years
20:40
of life out of those 64.
20:42
So everything is sort of moving on to the one 20 eights,
20:46
two forties and the omes, um,
20:48
or, um, photon countings, which are faster.
20:51
Um, so, um, I think around five seconds is still the goal
20:56
to tell your technician as well as your patient, that of, of
20:59
how long this is gonna take.
21:00
That's also reassured to them
21:02
that they can just relax a little bit more.
21:05
Contrast media, what is, uh,
21:06
the right amounts in the right time.
21:08
Um, there's a lot of discussions about
21:10
what is the best contrast media, um, while, uh,
21:14
probably three years ago, you and I would also agree the the
21:16
best one is the one that we can get, right?
21:18
Because we did have that contrast shortage.
21:20
Oh man, what a, what a crazy time that was
21:24
trying to find contrast.
21:25
Contrast on the black markets. I mean, all this craziness,
21:28
it was just nuts, right?
21:29
Um, and so what it really allowed us
21:32
to do was dynamically get down to what is important
21:36
and the importance is delivering that small bolus.
21:38
If you've actually looked at it, you can do, we tried this,
21:42
what is the, how low can we go, right?
21:44
Like, how low can we go? It was around 20 to 40.
21:47
If it delivered correctly, it was enough to cover the heart,
21:51
um, but also allow then for some of it,
21:54
which was still just right in the middle
21:55
of the, the IV line.
21:56
So 20 to 40 really is all you need.
21:58
And you guys see this too, right?
22:00
How much of your bolus, your 80
22:02
and uh, maybe 90 milliliter is still in the right, you know,
22:06
AC or traveling through the subc clave at the time
22:09
that acquisition's already occurred, probably half of it.
22:11
So start playing with that
22:12
and how do you deliver that at the time of acquisition,
22:15
but also at the same time have an interval padding,
22:18
you know, as we like to call it in terms of the acquisition,
22:22
but also the contrast in there.
22:24
Anyway, that being said, the concentration
22:27
of iodine should be somewhere, magic number,
22:29
somewhere around 300.
22:30
I think that's really optimal.
22:32
So we have a couple different products,
22:33
Omnipaque 300, we like to use that.
22:36
I think that's a pretty good one. And that's through ge.
22:39
They actually opened up two different facilities
22:41
in two different parts of the world.
22:43
One in their Norway plant.
22:44
They still have that one,
22:46
and that one is still kicking out a ton.
22:48
The problem was, is that the Norway plant had a contract
22:51
to send it to, um, it wasn't Shanghai
22:55
du it was a, a really well-known, you know, um,
23:00
great city in in in China that did very well.
23:03
But unfortunately they were under covid
23:04
restrictions, so they couldn't do any work.
23:06
They actually had to stop.
23:07
So it wasn't the oaring in the, in the, the pre material.
23:11
It was actually the finishing material in China
23:13
that was a problem for our, at least mine,
23:16
US related shortages.
23:17
So GE opened up another one in South America,
23:20
um, for processing.
23:22
Um, so that kind of helped alleviate potential one,
23:26
you know, pathway concerns.
23:28
So that sort of just in time model is now a just in case.
23:32
So I, I don't think we're gonna have iodine concentration
23:37
issues as I'm now like calling the gods to, uh,
23:41
reign contrast on me.
23:44
ICVU is also another one.
23:45
It's, it's a little bit more expensive, um, mainly
23:48
because it can pack in more iodine in there.
23:51
And to be honest, you don't want too much iodine, um,
23:55
in there if you haven't prior to in,
23:58
what I typically do is I get the image right, just like you,
24:01
you can potentially just do a bone window, right?
24:04
So you bone window down, that gives you an opportunity then
24:07
to, it's a little bit higher than bone window,
24:10
but essentially that's a good starting point,
24:11
and then you can go up maybe a little bit more.
24:13
Um, but basically you're getting rid of all the,
24:16
the contrasting that I assume you three 70 gives you.
24:19
So that's why I just, I don't wanna
24:21
pay the premium for that.
24:22
I have too many centers, and then a lot
24:25
of our other vascular work doesn't really do very well
24:28
with three 70.
24:29
Um, so I don't, I'm not a big fan of having
24:34
so many different types of contrasting for one,
24:37
for cardiac one then for neurovascular one, then
24:40
for, you know, body and stuff.
24:41
So, um, I'm gonna pick 300, not that I'm endorsing it
24:45
or I have any shares or anything,
24:46
but that seems to work out very well for our facilities.
24:48
And like I said, they figured out on the backend, uh, how
24:52
to ensure duplicative
24:53
and reiterative, um, safety controls in the
24:57
contrast supply chain.
24:58
So, fun times, right? But I do would wanna foot stomp this.
25:02
I think a a right AC is absolutely, it's the shortest,
25:07
it's the most, um, I would think the safest route to go.
25:11
You do have a little bit of anatomic, um, uh,
25:16
anomalies that can occur with a left SVC,
25:19
maybe the brachiocephalic not being all
25:21
that great it dumping into all these other places
25:23
if you do a left route.
25:24
But I mean, you have to do what you gotta do.
25:26
So, I mean, don't worry,
25:28
but starting out in one place saying like, okay,
25:30
baseline's always gonna be a right ac it's gonna be a 17
25:33
or 18 gauge, or I'm sorry, 18
25:35
or 16 gauge if you're really lucky.
25:37
16 is really great. Um, even that's fantastic on our young,
25:40
um, sorry, our older patients, we have to, you know, try,
25:44
uh, go to a, um, you know, a smaller needle.
25:48
And so unfortunately that gauge will pop up, right?
25:51
And then we're getting down further
25:52
into the lower extremity.
25:54
Um, that's a tough one
25:56
because you want to stay on a baseline in terms of quality,
26:00
in terms of interpretation,
26:02
and then at the start, if you start deviating from that
26:04
or allowing the tech, the nurses to deviate,
26:06
you're gonna get a lot of different acquisitions
26:09
with different attenuations within your coronary arteries.
26:12
So don't, don't try to get too far into, you know,
26:16
cutesy technique with butterflies in the hand, just
26:19
because it's 78-year-old female or anything like that.
26:22
Try to toe the line if you need to get the, uh,
26:26
ultrasound out so you can find the vein
26:27
or colon, you know, the, your, your pick team
26:32
or whatever like that to get it.
26:34
I, I think that's a good way to go.
26:35
Um, but don't try to, you know, just for whatever you need,
26:40
you don't, you know, to get a, a butterfly in there
26:42
and let's roll because the amount of pressures
26:45
that we're gonna be using, which will be in the next
26:46
slide, it's not fun.
26:48
They blow fairy more commonly when they're further down on
26:52
the lower on the upper extremity towards the hands.
26:55
So let's talk a little bit about that contrast volume.
26:58
We sort of hinted upon this a little bit earlier.
27:01
Essentially we're looking for around 60 to a hundred.
27:04
Um, I would say around 40, um, is where I try to be,
27:09
but um, a lot of my autonomous places, they like, um, quats
27:13
of 80, I don't know why I keep telling 'em,
27:15
let's bringing down a little bit smaller to 40.
27:17
We could get more patients with, uh, less contrast
27:21
with this, but 60 to 100, uh, 10 to 12 second duration,
27:25
where if you're doing, um, a different type,
27:27
couple different types of bolus techniques,
27:29
we'll get into that in the next slide.
27:31
Uh, but the rate, so the rate, there's a lot
27:34
of different rate practices out there based on BMI.
27:38
Why? Well, there's a linear sort of correlative
27:41
that the bigger your patient is, the more contrast you need.
27:46
I don't believe that I, I, I think what
27:48
that means is essentially is that we are not, um,
27:51
conning down to the heart.
27:53
Um, and more importantly, we are not timing it critically,
27:58
but essentially if you have a larger patient in the AP
28:02
diameter, if you have more contrast delivered, uh,
28:05
that could be timed correctly within the, the coronary tree,
28:08
then that will help out with the attenuation
28:11
that's gonna occur just because there are a larger portion
28:13
and a lot of the anterior
28:15
and the posterior aspects are going to attenuate.
28:18
And you're gonna get that, um, uh, that modeled look, um,
28:22
that's just sometimes unavoidable with a larger BMI patient.
28:27
So somewhere around the six is my personal, no,
28:30
don't go any lower than that.
28:32
So six to seven milliliters per second.
28:35
And that might seem fast in terms of, um, what is,
28:39
what do we use in other places?
28:40
So if you're gonna do, um, abdomen pelvis work,
28:43
if you're gonna do, um, neurovascular, it's usually
28:46
around four, right?
28:47
I mean, three to four, you know,
28:49
a nice kind of gentle sort of thing.
28:51
Mr. For instance, uh, cardiac MR usually is two to,
28:54
you know, two to three.
28:55
That's a different substance of course, right?
28:57
Um, but that's in terms of the rate,
28:59
it's the same gauge needle, but we're packing quickly.
29:03
And why, because we're trying to get this all in the fastest
29:08
velocity tube in the entire body, which I would suggest is,
29:13
well, it's probably the second.
29:14
I think your renal vascular bed is probably your first,
29:16
but you can just get the entire thing
29:18
'cause it's a smaller bed, but the corners is must deliver
29:22
very quickly, everything else to the thoracic aorta.
29:24
And so then you gotta hit it fast.
29:27
You can't allow a slow train to go there.
29:30
Or else the, the non pass, non pacified contract, uh,
29:33
blood will be mixed within there
29:35
and it's gonna be a really crappy exam.
29:37
So around six to seven at milliliters per second,
29:40
um, is about right.
29:42
I think you can try to make it faster if you have a bigger
29:46
patient only to try that maybe once or twice.
29:49
I'll be honest, it was never very successful for me.
29:52
Um, but I do like younger patients with that fast flow
29:56
and mainly because, uh, younger patients tend
30:00
to Val Salva a little bit more.
30:01
They take that, you know, breath thing there,
30:03
and then all of a sudden, um,
30:05
the lower extremity mixes in within there if
30:07
you have a longer train.
30:08
So if you have a lot of contrast, 80 milliliter
30:11
for instance, and a longer train,
30:14
five milliliter per second, God forbid,
30:16
four milliliter per second,
30:18
and a younger patient where they're valve saling,
30:20
all the lower extremity in there,
30:22
it's gonna be a suboptimal examination.
30:24
Your attenuation in your
30:26
thoracic aorta is gonna be like 200.
30:29
It's gonna be terrible. In fact,
30:30
you might get a better PE than, um, a good, uh,
30:33
coronary vascular, uh, evaluation if you do it that way.
30:40
So that's one of the things that, um,
30:42
I think is really important to kind of keep an eye on here.
30:45
So let's go through some of these other things here.
30:47
Um, start the scan after contrast diminishing.
30:50
When do you know it? There's two different methods
30:52
of course we've got, uh,
30:53
which is called the bolus tracking technique.
30:56
I don't think anybody's still doing that.
30:57
If you guys are still doing it.
30:58
It's a, there are some really great literature on why it
31:02
works so well because you've tested,
31:04
so known is known, right?
31:06
You've tested it and you've seen it,
31:07
and so then you can model against it.
31:09
Things we know with dynamically with the heart, the patient,
31:12
and then just the next go round.
31:14
That may not always be the case.
31:16
So it's actually not gonna be the same curve.
31:18
It's gonna be maybe shift a little bit more
31:20
earlier or a little bit later.
31:21
So, bolus tracking, we don't do in any
31:24
of my facility centers, academic centers anymore.
31:27
We actually just do test bolusing.
31:28
And so the test bolusing is where it's a small scout of the,
31:32
um, of the area of interest.
31:34
And then typically an ROI is placed, um, in, if you were
31:38
to take this image here and divide into quadrants,
31:41
it's usually into this upper right, uh, left quadrant here.
31:44
Uh, radiology left around here.
31:46
If you get it too close to this side here,
31:47
it could hit a lot of this low attenuating fat around here,
31:50
or, or maybe the AZA is vein.
31:52
Um, so somewhere around here,
31:54
and it should be about two thirds of the size, your circle
31:57
of your, um, descending thoracic aorta.
32:00
This will give you, um, an opportunity to test bolus, uh,
32:04
where your threshold is set at a hundred
32:06
to 120 household unit.
32:08
That's really the best space in the best time to kind of,
32:12
um, then, um, start the contrast.
32:14
The movement through there. Typically the, um, acquisition
32:18
of your test bolus to then the acquisition of the image is
32:21
around two to four seconds.
32:23
That's the hold your breath period of it.
32:25
And so then that's where, um, usually then the, uh,
32:29
the attenuation will increase
32:31
from whatever threshold you set.
32:33
100, in this case, one 50 was, um, was
32:36
where the acquisition began.
32:37
So somewhere around one 20 was where the testing said,
32:40
this is what I'm gonna tell you at.
32:41
And it's gonna continue to, um, increase in a density within
32:46
that descending thoracic aorta, which if you know,
32:49
the coronary arteries is reperfused diastolic, um,
32:53
from the descending thoracic aorta flow.
32:55
So if the descending thoracic aorta flow is at 200
33:00
to two 50 household unit,
33:01
your coronary arteries are gonna be, uh,
33:04
very well attenuated.
33:05
They're gonna be just fine in terms of the attenuation
33:08
as opposed to if you do the ascending thoracic aorta,
33:12
this has not had time to, um, potentially
33:16
meet the maximal amount of, uh, attenuation here.
33:21
So this could be a little too early.
33:23
So I don't, and nobody should be putting an ROI in the US
33:27
sending thoracic aorta.
33:29
I can't think of any good reason why you would
33:31
put it in the US sending thoracic aorta.
33:34
That's of course a good place for neurovascular, right?
33:37
If we want, um, you know, circo of Willis
33:38
and carotid, typically we place it on there.
33:41
If we're gonna do our CTA head neck runs, we put it on the,
33:44
on on right in that space there.
33:46
But really it's this, um, uh,
33:49
I gotta think about that one for a bit.
33:51
I don't think that there's anything,
33:52
or maybe a coarctation, uh, maybe, I don't know.
33:56
Probably not. Okay.
33:58
What is the right injection rate and the right delay matter?
34:02
Um, so optimal signal to noise ratio requires
34:05
that there's an opacification difference, right?
34:07
If we're gonna review this image
34:08
or the one on the, on this side here, we want to be able to
34:12
contrast look at what's inside the coronary vessel
34:16
as opposed to what's outside the coronary vessel.
34:19
And in this case here, we have at least 250 household unit
34:22
in the proximal RCA, uh, whereas this yes, is probably is
34:27
a pacified to around 200 maybe,
34:30
but as you can see here, it's just poor contrasting
34:34
to the remainder of the structures around here.
34:36
And so that's gonna be obviously a, a very difficult thing
34:39
to, to interpret.
34:41
Not that you couldn't, but of course, okay. Right.
34:43
Settings for the highest image quality,
34:45
lowest radiation dose, the elara, uh, methodology here.
34:49
So there are a couple different things.
34:50
This is, um, a, a slide meant
34:53
to show you all the complexities involved in it,
34:56
but we really don't need to involve ourselves
34:58
behind all a lot of this stuff.
35:01
A lot of the preset conditions
35:03
that you will find in your Siemens, uh, your GE
35:07
or your Canon, um,
35:09
equipment will have them designed specifically
35:13
to the optimized capabilities of that, um,
35:17
um, piece of equipment.
35:18
So you won't really need to change it too much.
35:20
What you will need to do is try to determine what do you do
35:24
for your, just in cases, about 60 to 70%
35:28
of your patients will fall in into the presets
35:31
that are available on your machine.
35:33
That's totally fine. You wanna do prospective?
35:35
Well, about 60 to 70% of them should fall neatly within
35:39
that prospective capability.
35:40
It's when, what do we do for the big patient?
35:43
What do we do for the really tiny patient?
35:45
What do we do with the patient that's in an academic center
35:47
and then has a ton of comorbid disease?
35:50
Well, that's where then we have
35:51
to get a little bit more creative.
35:52
We have to learn other techniques, other ways
35:54
of doing things such as, um, how do we play with the pitch?
35:58
How do we, uh, determine then, um,
36:01
the gating are we gonna do Then some type of, um,
36:04
combination like the force allows you to where you have, um,
36:08
or, um, um, you know, where there is that fast moat
36:13
where you can do then a little bit, uh, in,
36:16
in one methodology, but then switch to another.
36:18
And then how do we potentially cover our butt so
36:21
that we have a good data set to review?
36:23
And that's then of course the padding and so forth.
36:26
Image recon, um, we'll get into that just a little bit.
36:28
So here are some scanner, um, recommended
36:34
scan ranges and some protocols here.
36:37
Don't need to take pictures, don't worry about it.
36:39
I'm sure your, your presets already have this on here,
36:42
but one thing to kind of keep in mind here is
36:45
as you start looking along here, there really isn't that,
36:48
well, okay, so maybe the,
36:50
and these need to be updated a little bit more
36:52
because we're probably a little
36:53
bit higher than that right now.
36:55
But the Z axis coverage is essentially the big
36:57
one that we want to do.
36:58
And as you can tell, scan range to z axis coverage,
37:01
essentially one heart, right?
37:03
So those, um, do try to offer that there.
37:05
Um, there are some very nice machines that Siemens have
37:08
that are not, um, dual source.
37:11
They are, um, they're a little bit less than that
37:14
and they do very nice temporal resolution in ranges here,
37:17
but this is a little bit in terms of field of ra, field
37:19
of view, uh, Z axis coverage and scan range.
37:24
Alright, a little bit more into the physics portions of it.
37:26
Here you have a source that provides the radiation
37:30
to then the, um, typically 180, um, offset,
37:35
which is the detector array.
37:37
And that's a array, um, in a, in a way that will cover, um,
37:41
the fanning of the, um, heterogeneous spray of radiation
37:45
that comes through there in the center, uh,
37:47
between the source and detector is typically the patient.
37:50
And so this is rotating in the 360.
37:52
Uh, obviously if you have a dual source,
37:54
the 180 degree is then halved,
37:57
where you then have another source offset
37:59
90 degrees to this.
38:01
So it will then do, um,
38:03
or able to acquire the image data set in half the time
38:08
because it has to rotate only half 90 degree
38:11
instead of 180 degree.
38:14
As we look at this, um, tracing here, this EKG tracing here,
38:18
we have a QRS complex.
38:21
And if we were to take this, this portion here, this r
38:24
to then this next r this is considered the cardiac cycle.
38:28
You can divide this up into percentages, zero to 100%,
38:31
or you can divide it up in milliseconds, zero
38:35
to 1000 milliseconds.
38:36
Those nicely coincide with systole.
38:39
So anything 50% or 500 milliseconds and less,
38:43
and then diastole 501 to then,
38:46
or 51% to then 100%.
38:49
And so the acquisition will tend to occur in the area
38:52
that is best optimized for the coronary artery in terms
38:55
of opacification heart rate optimization,
38:59
where there's less movement due to the squeeze
39:03
or the systolic movement of not only just the valves,
39:06
but also the chambers as well.
39:07
So you get less valvular movement,
39:09
less chamber movement in when sary, diastole diastole.
39:14
So typically a lot of the presets
39:17
and protocols are in diastole, mainly
39:20
because that's where less of the move motion
39:22
and movement is
39:23
occurring in the dual source.
39:28
As I mentioned here, we have a 95 90 degree offset,
39:31
so they're able to acquire that in half the time.
39:37
Okay? Uh, rotation.
39:41
Rotation has to synonymously deal
39:44
with temporal resolution.
39:46
So we have spatial resolution, which is associated with
39:50
how many detectors are on the, on from source to detector,
39:55
how many detectors do you have in there,
39:57
and what kind of septation is in there
39:59
or not, depending if you have a photon
40:01
counter that's spatial.
40:03
So how much can you acquire in the radiation
40:07
that's being spt spat out there.
40:09
Temporal resolution is how quickly
40:13
is the source moving to acquire it?
40:17
So what is the highest temporal resolution imaging
40:20
modality that we have?
40:22
Is it nukes? Is it mr?
40:25
Is it x-ray, what do you guys think?
40:28
Ultrasound it's What do you think?
40:32
And this will be probably one
40:33
of the only questions I'll ask you guys.
40:38
Any thoughts? Do you think it's CT is
40:42
166 milliseconds the highest
40:45
and best temporal resolution in imaging?
40:48
No, ultrasound probably is considered, uh, one
40:52
of the highest diagnostics for cardiac imaging, mainly
40:56
because it's essentially a motion
40:58
or a view of what's occurring there.
41:01
Now, the spatial resolution is not what CT imaging is like,
41:06
hence why it's had, has a very limited degree
41:09
of use in cardiac imaging.
41:11
But the temporal resolution, how,
41:14
and you can see something move in time
41:16
as you're seeing my hand move, that is
41:19
where ultrasound shines
41:20
and why then we try to optimize that in CT in terms
41:24
of evaluating for temporal resolution.
41:27
So how do we get higher temporal resolution, reducing
41:31
the amount of spin necessary for the source to complete
41:35
that a hundred, that 180 degree or 360 rotation.
41:39
So if you have two sources instead of one source,
41:42
your temporal resolution's gonna go down.
41:45
If you have more detectors
41:47
or a longer paddle of detectors,
41:49
that could make your spatial resolution go down.
41:56
Okay? So the recommended pitch, this is
41:59
how quickly you move in the Z axis from, uh, for instance,
42:03
from the top to the bottom or my diaphragms up.
42:06
So, um, most coronaries have a very flashed
42:09
or high pitch, um, with if you're gonna do this dual source.
42:13
Um, but for the most part,
42:14
the recommended pitch is somewhere
42:16
around just a little under one in why that is, is
42:20
because we want to over sample an area, have more data
42:25
so that we can then ensure that there is, um, less motion
42:29
or gaps in the evaluation.
42:32
So if we're covering a large area such
42:35
as the abdominal aorta, thoracic aorta,
42:38
we have a high pitch, fast pitch, right?
42:40
That's where, um, those really shine
42:42
because there isn't a lot of variability in one centimeter
42:47
to the next centimeter in terms of the abdominal ATA aorta,
42:50
for instance, or the carotid arteries.
42:52
However, in coronary the real estate is smaller
42:57
and so there is much more variability in one centimeter.
43:00
And so therefore you want to unders sample
43:02
or to have a smaller degree of motion along the Z axis,
43:06
obviously you need the motion to move it there
43:09
or you aren't gonna get from point A to point B,
43:11
but it's extremely important.
43:13
So perspective gating,
43:14
what this means is if we were gonna take a look at the
43:17
sample volume here, we're going to evaluate six to 80% of,
43:21
um, that cardiac cycle, which I told you was a,
43:24
the diastole, the, um, table's going to x-ray on 40
43:29
for about 40 millimeters,
43:30
and then we're gonna then move the table X-ray on
43:33
for the next 40 millimeters and then move the table
43:36
and then x-ray on on so
43:38
that we could cover the stack from the bottom of the heart
43:41
to the top of the heart
43:42
or the top of the heart to the bottom.
43:45
This is called the step and shoot
43:48
or axial methodology as opposed to,
43:52
uh, CT chest.
43:54
Very interesting, right? So we have two organs
43:56
that are in the same cavity, uh, let's say the lungs
43:59
and the, and the heart, but the helical
44:02
or spiral acquisition is not useful at all for cardiac, not
44:06
because of of other reasons, but mainly
44:10
because we're just not getting that fine spatial resolution
44:14
that, uh, will be extremely useful.
44:16
Um, so it was very interesting
44:18
because for a lot of of time the cardiac ct, um,
44:23
coding was in the same basket
44:28
as the pulmonary or lung evaluation
44:31
because it was assumed that the technique was the same.
44:34
Now, of course, there was obviously a lot more in cardiac
44:37
imaging, coronary cardiac imaging than, uh,
44:40
a pulmonary angiogram of the chest, uh, for the lungs,
44:44
for instance, or for, um, the thoracic aorta.
44:47
So it actually is not the same, um, and should
44:50
and rightfully so, has been in, in my country, been moved
44:53
to a different separate coating, um,
44:55
because it does involve a separate different technique.
44:58
So that was actually a really good win, um, to kind
45:01
of help people understand that retrospective instead
45:04
of the stop shoot, we just have the, um,
45:07
source on all of the time.
45:09
And you can see that it's just acquiring
45:11
a 100% source on acquisition, a dataset, um,
45:15
from the, um, bottom of the heart to the top of the heart
45:18
or the top of the heart to the bottom high pitch.
45:21
Um, essentially it just has, um, you know, that pitch.
45:24
So there is less duplicative sampling
45:27
and more of motion, um, potentially prone.
45:31
Now we like to do this in, um, again, vascular imaging.
45:35
So if you're gonna do a thoracic aorta evaluation
45:37
for aneurysm or post tvar, um, plus your coronary arteries,
45:42
you want to do one that's the coronary artery technique
45:45
first retrospective, get the entire data set
45:47
and then do a flash technique while the contrast is still
45:50
there to acquire the, the thoracic ata.
45:52
Of course, you'll capture the thora, uh,
45:54
the coronary arteries one more time,
45:56
but it will then allow you then to capture that amount
45:59
of real estate at a smaller spatial resolution comparatively
46:03
to the coronary arteries.
46:05
So that's just a typical, uh, TAVR technique, right?
46:09
Padding. You might have heard this term,
46:11
and I'm only talking very quickly about it,
46:14
but we can get into a little bit more.
46:16
It's where there is just a little bit of fluff.
46:18
The tube is on 100%,
46:19
but there tube could be on a little bit more, uh, on,
46:23
but at a less so maybe 90%, 50%, 25% in terms
46:27
of the, of the, uh, amount of, of dosing,
46:32
but at different parts of it.
46:33
So a little bit before and a little bit
46:34
after your main acquisition.
46:36
Why is that useful? Well,
46:38
you can still iteratively reconstruct some of
46:40
that imaging into your, um,
46:43
what we call an idealized dataset
46:46
to get you a good looking coronary tree.
46:50
It's interesting because it's actually, um,
46:52
using the same coronary arteries,
46:54
but a picture is not the same picture as another picture
46:58
of the same thing, right?
47:00
So if I were to take a picture of, um, you know, this tree
47:03
behind me here and I take it one time
47:05
and then I take it another time,
47:06
those are two separate pictures,
47:08
but I'm gonna fuse 'em together of the tree.
47:11
And that's supposed to be a good representation
47:13
or a finalized representation of the tree,
47:15
but it actually is two separate pictures of the tree.
47:19
So you can get superimposed artifact, you can get modeling,
47:23
or you can get an over
47:25
aggressive re iterative reconstruction.
47:28
I only make that up because you may want to,
47:31
as you're deciding to create a program,
47:32
look at the raw imaging.
47:34
It's a big dirty data set, but it's a thin, you know, 0.25
47:39
and then see what you like,
47:41
how much iterative reconstruction, how much, um, you know,
47:44
filter back versus the iterative,
47:46
you know, do you want in there?
47:47
And you can play with that. How thin, thick,
47:50
how much padding, not so much padding do you want involved
47:53
to be sent to you for the acquisition.
47:55
Now, me, I try to use,
47:59
uh, the least amount of acquisition, the least amount
48:03
of images sent to me.
48:05
I believe that just hones my clinical skill as opposed
48:09
to having a ton of data sets, a ton
48:12
of imaging, and to go through it all.
48:14
Um, not only is there an efficiency standpoint,
48:16
but also it allows me then to say, look, I need
48:20
to change some things in my protocol to ensure
48:23
that this type of patient with this thing, I don't,
48:26
I I get the best thing next time.
48:29
So how do you become better?
48:31
I don't know if it is because you have more tools
48:34
or that you constrain your tool set
48:37
and try to hone to the areas of, um,
48:40
where you can optimize it.
48:42
So for me, I don't have a lot of padding.
48:44
I know that my cardiologist who work with me,
48:46
they love a lot of padding, um, but it's less work.
48:50
It is more efficient, um, sending it,
48:53
receiving it across different areas of the country.
48:56
In my country anyway, it's prone to less error.
48:59
And, um, I think it's a good way of, like I said,
49:02
honing my own personal technique.
49:03
I don't know what you guys think about that,
49:05
but this is one of the ways that we can use
49:09
to make more images that might be good
49:12
or not good depending on where you want to be in terms
49:14
of a cardiac imager.
49:19
Okay. Field of you. And, uh, we'll stop here
49:22
for a little bit just so I can ask, uh, uh,
49:25
get some questions from you guys.
49:26
Again, this PowerPoint extensive so much a lot in here,
49:32
um, and I'm hoping when we go to office hours that, uh,
49:36
you have some more questions about this based on, you know,
49:39
not only the interpretation,
49:40
but also then some of these things, protocols and factors,
49:44
but field of view, the matrix
49:46
and spatial resolution are correlative.
49:48
So, um, how big you make your matrix
49:52
will have an inverse relationship to the spatial resolution.
49:56
So you make a really large matrix
49:58
that then could potentially invert the,
50:00
your spatial resolution
50:01
because obviously you have to fill that data
50:04
with the limited amount
50:05
of photons we're going through there.
50:06
So if you constrain your matrix size, um,
50:09
five 12 is typically what we keep it at
50:12
and you constrain your field of view, that amount
50:16
of photons in will
50:17
and displayed in your matrix, your, your visual matrix
50:22
will then be at a better ratio as opposed to then, um,
50:26
doing, uh, the opposite.
50:28
So what I try to do is I try to tell my technicians,
50:30
make the smallest box possible, smallest box possible.
50:34
I need the coronary arteries, you know,
50:36
and that's there in the larger, the extra coronary.
50:40
What we have to do for atypical coronary CTA, that's
50:43
where you go from shoulder to shoulder,
50:45
but my coronary view should just be the coronaries.
50:48
It's not even the rest of the heart
50:51
and honestly it's just the coronaries
50:52
because I'm dealing with a limited amount of, of radiation
50:56
that I want to put into the coronary arteries as opposed
50:59
to the extra coronary, um, organs of the body.
51:03
So in this case here we have a very high spatial resolution
51:07
due to the constrained voxels, um,
51:10
and, uh, voxel, uh, uh, matrix here, the two 50
51:14
by 2 55 12,
51:16
and as you can see here, it can be difficult to always, um,
51:20
artistically change this on every patient.
51:23
So make sure that you have a sized box based upon typical
51:27
anatomy markers.
51:29
So the anatomy marker that we typically do is the anterior
51:32
aspect of the sternum, as you can see here,
51:34
and the first third of the vertebral body
51:37
that typically gets the, uh, thoracic aorta,
51:40
descending thoracic aorta
51:41
and the ascending thoracic aorta, which will always be
51:45
the coronary arteries, will always be bounded
51:47
by those two structures anterior
51:49
and the descending thoracic aorta.
51:50
Never knock on wood,
51:52
have I ever seen the coronary arteries extend
51:54
beyond the field of view of those two structures there.
51:56
Um, just wait until the next exam I guess. Okay.
52:01
Alright, so iterative reconstruction and quality.
52:04
This has always been a hot topic for many,
52:06
many years, decades, right?
52:08
You and I have always gone back FVP, uh,
52:11
how much acer admire do we want on these?
52:13
And we get to play with that and look at it.
52:15
Some guys love it, some gals don't, da da on
52:19
and on it, it's personal preference
52:21
because this is just the image interpretation standpoint.
52:24
It's not the image acquisition.
52:26
So you can always change it, change it within two weeks,
52:29
because sometimes you,
52:30
you get the data dump on your CT scanner, right?
52:32
But, um, but anyway, I'll, I'll leave that up
52:35
for another thing because there's some really fun things
52:37
that AI is doing
52:38
where you can actually reduce your dose down to, I've seen,
52:42
I work with some companies,
52:43
they're like down at like 25, 30 milli seaberg, you know,
52:47
really tiny amounts, like a third of current dose.
52:50
I'm about a hundred, 105 most in most
52:52
of my centers right now, but they're at 25 30
52:55
and they're AI based iterative reconstructions,
52:58
and they look just like the, the normal ones,
53:00
the diagnostic ones, they're fantastic.
53:03
And it's not just in your Joe Schmo
53:05
idealized patient, right?
53:06
I mean, it's like big old chunky dudes, you know, and, and,
53:10
and so forth and calcified, you know, coronary arteries,
53:13
like these are legit coronary disease patients.
53:16
So, um, it's kind of fun to see that stuff
53:18
that AI is constantly improving this area of it.
53:21
It's never gonna take away us yet,
53:24
but I think it's doing some really great stuff in terms of
53:26
that soft kernel, sharp kernels.
53:28
There are some importance of utilizing
53:30
or having the opportunity
53:32
or at least knowing when would I use a soft kernel?
53:34
That's when I want to have more gray
53:37
and open up than that spatial resolution a little bit more.
53:40
Um, sharp kernel is where there is a contrasting difference
53:45
between the edge of the coronary artery
53:47
and the next thing around it.
53:48
So the fat. So if you have calcium for instance,
53:50
or if you have stents, you're gonna use a sharp kernel.
53:53
What's another name for a sharp kernel long window?
53:56
What's another name for maybe a soft kernel?
53:58
Probably, you know, a body window or a bone window.
54:05
Okay, so I'm gonna stop right there just so that I can kind
54:08
of show you a few of the other do, do, do.
54:12
We're gonna share. Hmm,
54:17
where's the screen?
54:18
Okay, very quickly, I, I think you all had gotten a, a quick
54:23
tutorial on Terry recon,
54:25
maybe you've visited in the past or not.
54:27
Um, the way that I, I've known it
54:30
for a very long time, I think it's fantastic.
54:33
We, um, all the cases will have a week one and a case one.
54:37
There'll be five cases per week, um, like I said, try
54:40
to do one per day just so you get used to the program just
54:44
so there aren't any issues,
54:45
but essentially have it outlined here.
54:47
Um, you may have then, um, you know, a little window,
54:51
a visualization window that will then show down here
54:54
where you can scroll through as well.
54:56
But, um, these were typically acquired on a Siemens.
55:01
So this is Siemens, no nomen, uh, nomenclature here.
55:05
So, um, the 55 obviously means that, uh, heart rate,
55:10
cardiac cycle, it was considered the best diastole.
55:13
And you can see then that's probably somewhere right around,
55:15
although this image says 70, um, it's,
55:18
it's probably more true to 55.
55:20
Okay, so I'm going to click then on the load button here,
55:24
I'm gonna find this is anatomically.
55:26
So the top of this row is for neuro neck
55:29
and then we get into cardiac pulmonary, um,
55:32
abdominal, mss, K and so forth.
55:34
So we're gonna find a coronary, uh, cardiac one here.
55:37
You can do cardiac cardiac one, cardiac tech.
55:40
It's all it does is as we move from patient list
55:43
to then the viewer and back
55:45
and forth, all it did was rearrange these mini apps here.
55:48
So, uh, as you can see here, this uh, has your, um,
55:54
axial, coronal and sagittal view,
55:55
and then it also has then a 3D, uh, volume rendered.
55:59
The chest wallet is in there.
56:00
If it didn't automatically remove it,
56:02
you can click this button here to remove it.
56:05
And so then now you have your volume rendering.
56:07
The volume rendering is not usually designed
56:10
for a diagnostic or interpretation,
56:11
but it is a good idea to see then,
56:13
because this is based on contrast, how
56:17
well contrasted is the LAD
56:19
and all its, um, branches here to, uh, to the RCA, uh,
56:23
to the, I'm sorry, to the LCX and then to the RCA.
56:26
Uh, and so, um, I'm sorry, so that's LCX
56:29
and that's RCA down in that area right around there.
56:32
So how do they look? Are they isometric, iso attenuating?
56:35
Do they have, you know, a pretty good look view?
56:37
You can remove, um, you know, some of that tissue
56:40
by holding down your left and right mouse
56:42
and that essentially windows and levels it off.
56:45
Um, as we're kind of doing some work here, um,
56:48
I'll show you this row is the volume renderings Uh,
56:52
so it'll just move them accordingly.
56:54
Here. Let's go ahead and just take this right corner artery.
56:57
I'm gonna click the shift button.
57:00
And as you can see, that should,
57:02
uh, no.
57:06
Oops. Okay. Yeah. So once you're on this row here,
57:08
if you hold down the shift button, you've got a cross hair,
57:11
you can see the cross hair, then you can click on the
57:13
coronary artery and it'll just then do a full width half max
57:17
on the attenuation of there,
57:19
and then, um, be able to show you that, uh,
57:21
from the origin all the way down to the, the tail.
57:25
These are 90 degrees to each other.
57:26
So once you turn this one, this one will turn you,
57:29
you've got these handlebars here
57:30
that can then help you measure
57:32
then the length of the plaque.
57:33
There is of course, a, uh, an A to B ratio,
57:37
which can give you a, a percentage ratio.
57:40
Um, that's kind of important. Down here is the SMPR.
57:44
So straight, um, multiplanar reformat,
57:47
and so you can straighten it.
57:49
Now, what is the highest spatial resolution?
57:52
The highest spatial resolution is the one that is,
57:54
looks like, acts like the one that, um,
57:59
that is similar to what was acquired.
58:03
So if your patient's laying on their back
58:06
and we're actually acquiring,
58:07
the highest spatial resolution image is gonna be
58:10
that the done your axial acquisition.
58:13
So this will have always, always, always, always
58:17
the highest spatial resolution comparatively
58:21
to your volume rendering, comparatively to your
58:25
CPRS curved plan reforms or your straightened plan reforms.
58:28
So what I'm saying is the more that you have to take
58:32
this amount of data
58:33
and three dimensionally place it into this, and then this
58:37
and this, you corrupt the data.
58:39
That is, it becomes, as you can tell,
58:42
less spatial resolution compared to this.
58:45
So this should not be your go-to,
58:47
or your first wave interpreting.
58:48
This is your real estate view.
58:50
You are looking at this to see what are the areas
58:53
of concern, what are the areas of interest?
58:56
And so if we're evaluating from the origin its course
59:00
and its termination,
59:02
and then what is inside here, attenuation wise,
59:05
we are making sure that it has a normal origin,
59:08
a normal course for this particular artery,
59:10
for the atrial ventricular groove,
59:12
and the posterior inter ventricular groove
59:14
and terminates deeply in the, um, posterior aspect
59:18
of the chambers.
59:20
And then of course, attenuation is the same,
59:22
and there's no luminal blockage running along in there.
59:25
These will give you less information compared to this.
59:29
Now, what this gives you is real estate view.
59:31
You can see the entire thing,
59:32
whereas this is the higher spatial resolution.
59:35
So we will find more information if we follow this
59:38
guy all the way down.
59:40
It's actually faster to read it axial off your PACS than it
59:44
is to try to, you know, speed this thing up, turn it on,
59:48
forget your password, reenter a password, find a patient,
59:51
oh no, images are not there yet.
59:53
Upload the images again,
59:54
and then come in here and then do this.
59:57
Whereas if you were to learn how to read from your,
60:00
from your packs, it's better and easier.
60:02
So I personally read a axial.
60:05
I of course have access to the these
60:08
and have it for just, you know, di some
60:10
of the difficult cases where I really need
60:11
to make sure my 70 to 99% is correct,
60:15
and how much, um, iso attenuation is there, is there any
60:20
abnormal hypo enhancement of the myocardium?
60:22
Because obviously we're de delivering
60:24
iodine to the myocardium.
60:26
So if there's areas that are hyperintense
60:28
or hyperintense, I wanna make sure I see that and so forth,
60:30
and as well as some of the other structures there.
60:32
Okay. So that is a little bit about, um, this, I, um,
60:37
as you can tell, there's so much more I could go into
60:39
and I'd love to, but we're gonna stop right there, um,
60:43
and, uh, open up for any questions that you may have about,
60:48
um, again, acquisition and protocol design.
60:55
Hi, I have a question.
60:57
Uh, Dr. Lawrence, can you hear me?
61:02
I can hear you. Can You hear me? Yeah. Okay.
61:04
Um, so you said to, uh, look at the aal,
61:08
but we were told yesterday that
61:10
because coronary angiogram, you're supposed
61:12
to assess it in the longitudinal
61:14
because it's different from like carotid a**l.
61:18
Um, so you will still do your recon to a,
61:23
to, if you see a stenosis, you're still elongated
61:27
and measure, right?
61:29
Right. You have to because that's, that's the goal standard.
61:32
That's what he said yesterday.
61:34
No, there are many, many different ways
61:38
of evaluating this.
61:39
What is important is ensuring the accuracy of it.
61:43
And so we're gonna teach you probably three different ways
61:46
of evaluating it.
61:47
And so if you look on here,
61:48
the first row is your volume rendering, which gives you
61:50
that quick view.
61:52
The second row is the curve planar view,
61:56
which like you said, is gonna not gonna be a long axis,
61:59
or allow you then to evaluate the,
62:03
if you were looked down the barrel, the of the circle
62:05
and see then how much percentage stenosis.
62:08
But it does give you a quick view
62:09
because you can have your, uh, line right here,
62:12
and I'm just gonna, and if that's 50%,
62:14
then there's probably less than that.
62:16
That's probably less than 50%.
62:17
And then I'll give you a, a quick view.
62:19
When we go to something, for instance, on this view,
62:22
this is called a vessel track or short access view.
62:25
You can then very quickly see then by circle wise, if
62:28
that amount of luminal stenosis
62:30
or plaque is at 50%, so forth and so on.
62:35
What you forget, though,
62:36
or what my, some of my colleagues
62:37
who teach this forget though, is
62:39
that this double iterative acquisition takes the same amount
62:43
of information on the axial view,
62:45
and it has to duplicate it into this view.
62:48
So as you can tell, it's blurry, it's probably less
62:53
accurate because then, um, you are trying to take
62:56
that same amount of dosing
62:57
and then apply it into a three dimensional view.
63:00
Now, because this is now x, y,
63:02
and Z axis, as we can see here, if you do this on the, um,
63:07
on your packs, by having this view here, uh, this,
63:12
uh, let's skip back over here.
63:17
Your axial, your coronal and your sagittal,
63:20
and then you start playing, for instance,
63:22
with these handle bars here.
63:24
So then you're always looking at down the barrel,
63:27
as you can see here, I'm at, you know, that,
63:29
that's fine too, but what do we know as being radiologists
63:32
or individuals who've been practicing image
63:34
before the coronals and the sagittals
63:38
or the obliques are less information
63:41
because they're not acquired in the way
63:43
because it wasn't the axle, which is the acquisition.
63:46
So even if we are gonna do our short access and da da
63:48
and follow it down there, it's still less information
63:51
because it's not a three dimensional acquisition,
63:53
it's a two dimensional acquisition.
63:55
And so I think that's important.
63:58
It is gold standard,
63:59
but know then that what is considered the gold standard is
64:02
because it was based on inter invasive coronary angiography,
64:05
not CT acquisition,
64:07
which is a two dimensional acquisition as opposed to a three.
64:10
So that's how we, um, work with those,
64:13
those diametric things.
64:15
Coming back to what you said
64:16
and what, um, what I would said earlier,
64:19
we're gonna teach you how
64:20
to take a look at all these different ways
64:23
of interpreting it in, um, our office hour session.
64:27
So you can see the benefit of on pacs two dimensional axial,
64:32
um, on performative, uh, software, so that you can see two,
64:37
uh, two dimensional plus
64:39
and three dimensional plus, which is the short access view.
64:41
So hopefully that answers your question. Thank you.
64:46
Yeah, of course. But uh, as you can see, yeah,
64:49
this thing has all those easily to go to.
64:52
So if you had this already up, many
64:54
of my cardiology colleagues like to only read on here,
64:57
mainly because it doesn't show the rest of the chest.
65:00
But if it's a chest pain,
65:01
you gotta see the chest and everything else.
65:03
And much of our reporting
65:05
that you're gonna be doing in coronary
65:07
and for this course is gonna say, whoa,
65:08
what about all these other structures here?
65:10
Did you look at them? Because we got a lot
65:12
of Easter eggs, um, in there too.
65:14
So something to keep in mind.
65:19
What other questions do you guys have? Does it seem onerous?
65:23
A lot of work? It's, does it seem like
65:24
totally within your wheelhouse?
65:34
Hi, Dr. Lawrence. I had a question.
65:36
Um, I know that you mentioned, uh,
65:38
the glomerular filtration rate, uh,
65:41
but is there a creatinine level
65:44
that you would recommend in order to do the, the study?
65:50
Most of the academic facilities that I work at, um,
65:53
trying not to use a creatinine
65:55
because the, um,
65:59
blood volume plays a big role in creatinine levels
66:02
as opposed to filtration rate, which is, uh,
66:05
although it's, it's not an abs uh, an objective, it is, uh,
66:10
an inferred reference to glial function,
66:13
but I would say somewhere around 1.3
66:15
and less is totally fine if as long as it's full, you know,
66:20
uh, creatinine will increase, uh,
66:23
again based on that blood volume status.
66:25
So typically our older patients will have less blood volume
66:28
and so therefore the will creep up.
66:30
And so, um, I don't try to worry too much about that in some
66:35
of our standing facilities, our imaging centers that I stat,
66:39
um, GFR, uh, is, is pretty good and it works really well
66:43
and I've seen that used,
66:44
but I'd say 1.3 for creatinine, GFR somewhere around 35,
66:49
um, you know, definitely have a conversation.
66:52
Anything less than that should be a chronic GFR.
66:55
You know, somebody who has chronic renal disease
66:57
that you're gonna just scan anyway
66:59
'cause you're not gonna change the
67:01
functionality of their kidneys.
67:03
Um, or you know, if it's brand new GFR low, you know, 30,
67:08
then maybe that's a great time to have a conversation
67:10
with the, with the referral.
67:12
Thank you. Yeah, of course.
67:16
Good evening, sir. Hi.
67:19
Hi. Uh, so let's say like, I don't have, I'm not able
67:23
to get a peripheral line, an anti cubital vein in,
67:26
and I have a central vein.
67:29
Mm-Hmm. What will happen to the protocol?
67:31
Uh, if I have access one lead to a central line?
67:35
Shorter, shorter, shorter.
67:37
Now, if you are doing, uh, uh, IV access
67:41
through the jugular, you know, vena cva, you know,
67:45
and you have for instance, like a, a power line.
67:48
So they, for instance, they are an oncology chemo patient,
67:52
they have then a, a power safe injector.
67:55
You know, something that's gonna be, you know, tri luminal
67:58
in here or dual lumen,
68:00
you know, all those other things there.
68:01
They're typically rated
68:03
and the rating you may have to check,
68:06
but usually they're good for five milliliter per second.
68:10
Um, some of them are six, uh,
68:13
but five is, is really a good one there.
68:16
In terms of what that means from your
68:17
acquisition standpoint.
68:18
You obviously have to begin the acquisition sooner.
68:22
So that bolus technique
68:24
where you're watching the ROI down in the descending
68:27
thoracic aorta, that's gonna kick off much sooner.
68:30
What that means then is your breath hold should not then be
68:34
a breath hold, it should just be tidal volume.
68:37
'cause you will not have enough time to swing
68:40
or sling the, the source to for your temporal resolution.
68:44
And wait the three seconds there.
68:46
So I typically omit verbal instructions to hold breath.
68:49
I typically omit the breathe in,
68:52
breathe out, hold your breath.
68:53
If I have a central line, just
68:55
because it's an, an immediate access into
68:58
essentially, I mean, what is that?
69:00
That's maybe 30 centimeters. 40 centimeters.
69:03
So you gotta get rid of all that, um,
69:04
those automated instructions if that's the kind
69:07
of patient population you're dealing with.
69:10
Thank you. Yeah.
69:11
But like I said, the main thing is make sure
69:13
that whatever you're gonna push the contrast through at
69:16
that rate is rated for that low rate.
69:20
And, uh, five seems to be where most of them are.
69:24
Um, in, in my neck of the world in, in the woods here, six,
69:28
I've seen very few of them that are around six.
69:31
So five should still get you a pretty good exam.
69:34
Okay, thank you. Yeah, of course.
69:37
Hey, Dr. Loren, this is Courtney.
69:38
Um, I received a couple of questions about how
69:42
to locate the cases once, um, the users log into Tara recon.
69:47
Is there a specific, um, location or button in Tara Recon?
69:52
I, I thought that they would just pop up once, uh,
69:55
they logged into their account.
69:57
Yeah, they need to pop up.
69:58
We'll, uh, check with the Tara Recon rep
70:00
to make sure that they're loaded correctly. But yeah,
70:03
I've already reached out to Tara Recon,
70:05
but I thought since we have you here, I would, I would ask,
70:08
but yep, I'm in contact
70:10
with Terry Recon trying to figure this out.
70:12
Yeah. And you guys should see 'em exactly like this
70:15
where it's week ones, then week twos and so forth.
70:18
And, um, your data set is exactly like mine.
70:20
I don't have a cheat sheet data set.
70:21
So I love this course
70:23
'cause I always have to, I keep it real.
70:25
I'm like, oh crap, I missed this,
70:26
or I gotta think about this.
70:28
And, and it's fun because on some of them, not all of 'em,
70:31
but some of 'em, I'm like, dude,
70:33
I totally over called this one.
70:34
Why would I do that? And other times I under called it.
70:37
So that sort of drift, you know,
70:39
inter radiology drift, it's a thing, right?
70:42
And especially when you're dealing with a cad rad system
70:45
where it's percentage zero
70:46
to a hundred percent, it's common.
70:48
So of course we're not gonna be testing you on that.
70:52
It's not like you said, 0% and it's actually 2%. No, no, no.
70:57
It's, if you say 0%
70:58
and actually there's a hundred percent occlusive plaque,
71:01
that's when we'll, we'll go through it.
71:03
But happy hunting and learning here.
71:07
Please send any questions you have to Courtney
71:10
and, and or to us.
71:12
And, uh, I can't wait to see you guys again
71:14
so we can do more, uh, classes together.
71:17
Thanks. Uh, Dr. Yeah. Um, Dr.
71:19
Lorenz looks like we just have one last question from Dr.
71:22
Yeah, I just wanna quickly show you what my problem is.
71:26
I can't see, I don't know if I'm clicking. No.
71:28
Like this is the page I get, so if I take a
71:32
Dr. Sure. Dr.
71:33
Yap, we actually, um,
71:35
we can take this off of the Oh,
71:37
Okay, sure. Yeah.
71:38
The Tara representative will have to assist us.
71:42
Okay, perfect. Thanks. Mm-Hmm.
71:44
We'll get, we'll get you guys on there
71:45
and if not, we have other ways of, of getting it through you
71:49
to via obra
71:51
and we have, so we have a backup to the, to this in case.
71:54
Okay, perfect. Thanks.
71:56
I just don't wanna be the one
71:57
who is not clicking the right button. That's all.
71:59
Thanks. We understand. Hi, Dr. Lawrence.
72:03
Hi. Sorry. I just have a couple of questions.
72:07
Uh, I just wanted to find out if you, uh, sorry,
72:10
I just wanted to ask if you could tell us a bit more about
72:13
photon capturing CT N if it's in mainstream use.
72:17
Uh, I just heard about it, uh,
72:20
just one center that was using it.
72:22
Mm-Hmm. Uh, as to my knowledge,
72:24
but, uh, I wasn't too sure as to what the difference was.
72:27
I, I hear it's a much better, um, acquisition
72:32
mode ra uh, for the cardiac imaging.
72:36
What, gosh darn it.
72:37
Um, I, um, so what it is is, uh,
72:42
I, there was a slide that I showed you
72:44
where the source was sending the radiation down
72:47
and then the detectors were down there.
72:49
Yeah. To define the detector
72:51
or the square, you need the septation in between.
72:55
And the septation is a material
72:56
that is not absorbing of the radiation.
72:59
So it could, the radiation could potentially send,
73:02
go into the, the pixel.
73:05
The problem is, if you wanted to get to the
73:09
spatial resolution that is defined by this artery
73:13
and many other organs, we need to remove the septation
73:17
as the last block of restriction to, um,
73:22
evaluating the, the, the, the material.
73:27
And so the citation is removed
73:30
in what's called a photon counting system, where every,
73:35
uh, peak of radiation from let's say, um,
73:40
uh, four 50, you know, to anything else,
73:44
every peak is counted for by a new material.
73:49
Um, melin molybdenum as it's called, um,
73:52
it's acquired in there.
73:53
So every radiation peak is a picked up.
73:57
There is no noise, which is not counted information
74:01
or counted dose.
74:02
And you are able then to subtract then that if you know
74:06
what it is and where it is.
74:08
So now you have theoretically the highest spatial resolution
74:11
possible because every peak in everything
74:14
there is accounted for.
74:16
Now what you still have is some compton scattering,
74:19
which is a physics component that
74:23
because not all of the, all of the tissue
74:25
of interest is absorbing all of the radiation.
74:28
You know, for instance, the, the fat and the skin
74:30
and all that stuff can absorb it
74:32
and then scatter the electrons in that space there.
74:36
But most of the radiation that's going
74:39
through somebody is not compton scatter image.
74:42
It's that it's not counted for
74:44
or it's below the threshold of the K edge.
74:48
So we are now able then to acquire much more
74:52
beyond just the K edge
74:54
and then subtract that noise out,
74:57
creating then a cleaner image.
74:58
We've been working with this for about since, oh, for me,
75:01
I've been working with it since 2018 at some
75:03
of my centers in the us and it's a very good for, um,
75:09
for coronary, it's very good for interstitial lung disease.
75:12
I'm a cardiovascular radiologist,
75:14
so interstitial lung disease, it's not so good for, um,
75:18
some things that I was really surprised about thoracic, uh,
75:21
or vascular imaging.
75:23
I'm not very happy with it.
75:24
I don't think it does as great as it could do.
75:27
And, but there, those are some technical concerns.
75:30
But essentially what photon counting is,
75:32
it's remove the septation, which is the,
75:34
the was the last threshold in being able
75:36
to get the cleanest image
75:38
and allowing for the counting of the noise.
75:41
Non-competent scatter. That is oftentimes in our image.
75:46
Thank you. Uh, one more question with regards
75:50
to coronary ct.
75:52
Um, how much functional imaging are we
75:55
able to get off the heart?
75:57
Uh, are we able to extract from the volume rather?
76:01
I love this question because this is my thing is like,
76:05
how can I gather more from this system
76:08
if I'm already capturing the system, you know,
76:12
anatomy without using mm-hmm.
76:14
Contracts. So there is correlatives that is the more, um,
76:19
calcium density, um, there is in your si in your tree,
76:24
typically the worse your function is.
76:25
So it's inverse, um, for that thing.
76:28
And it also leads to, on a population basis, um,
76:32
higher increases
76:34
or associations with major adverse cardiac events.
76:36
So that is the higher your CAC score,
76:39
the worse you are probability wise in a population
76:43
setting by race.
76:44
Because we use the MESA criteria that's been studied there,
76:48
but also just density wise, it tends
76:50
to just correlate as well.
76:52
Functionally, same thing that is the, uh,
76:54
metabolic equivalent of work.
76:56
Um, the, the met,
76:58
which is typically used in functioning
77:00
cardiac functioning evaluation.
77:02
So how many mets of work you can do?
77:03
So you and I would probably get up downstairs, we can go
77:06
for a walk, we can do all that stuff without taking a,
77:08
a shortness of breath or dyspnea.
77:10
We've got probably 10 to 14 mets easy, no big deal, right?
77:14
Okay. So that same thing has been correlative.
77:17
That is the more CAC you have, um, coronary artery calcium,
77:21
the worse your mets are.
77:23
So there is an inverse relationship
77:24
to the functionality of that.
77:26
How then can you deploy that in a preventative setting?
77:30
We are still trying to figure out,
77:32
because the calculator based functional assessment
77:36
and then looking at that in terms of then
77:40
what failure is gonna look like
77:41
or even event is gonna look like, that's not accounted for
77:45
yet because of the compensatory mechanism of this body.
77:49
Your body will compensatory, mech, um, you know, mm-hmm.
77:51
Compensate so well that it's not a straight linear,
77:55
it's probably u-shaped
77:56
or it has some other components behind it too.
77:59
Great stuff. I love it
78:00
because then we could combine lung cancer screen, we can do
78:03
that, you know, there's a lot
78:04
of really fun things we could do.
78:05
You know, capture, you know, the heart,
78:07
the coronary arteries, uh,
78:09
and then determine out, like you were saying,
78:11
functional assessments, lot of really great things.
78:14
Opportunistic biomarkers as well have been looked into this.
78:17
So how much, um, sarcopenia, how bone density associated
78:21
with coronary disease, calcium, for instance.
78:24
Um, and plaque for instance, has also been studied.
78:27
Uh, eat, which is the epicardial attenuation of fat, um,
78:32
that has been studied and correlated
78:34
to opportunistic biomarkers, again, sarcopenia
78:37
and bone density and so forth.
78:39
Uh, visceral fat also.
78:40
So we are really getting down into this in terms
78:43
of being able to, from, uh, preventative standpoints,
78:47
look at a lot of different biomarkers
78:49
acquired on a typical ct, um,
78:52
and then be able to make really educated guesses
78:54
on where we're gonna go next.
78:56
So I'm in it from the innovation standpoint.
78:59
I try to fund companies, um,
79:01
and do things, um,
79:02
more than just the interpretation standpoint
79:04
because I want people to get into this.
79:06
I want the, the physicists, I want, the, the,
79:08
the coders I want, you know,
79:10
we can really do some really cool stuff.
79:12
So there's a lot of really good work that it is.
79:14
But, um, in terms of what's out there right now
79:15
and what's guideline based, um,
79:18
coronary artery calcium is associated
79:20
with major adverse cardiac events in a
79:22
linear or uh, fashion.
79:24
And that's about as far as we go.
79:26
But it's not great because
79:28
that does not take into account many other factors
79:31
that have obviously lead to, um, atherosclerotic
79:35
related coronary debt.
79:37
So we'll see.
79:39
Thank you for that. Thank you
79:41
everybody for your questions.
79:43
So we wanna be respectful of everybody's time.
79:45
We're already 22 minutes over.
79:47
So thank you all again for attending.
79:49
If you do have any follow-up questions, feel free
79:52
to forward them to me at cRose@modality.com
79:55
and I will reach out to Dr.
79:58
Loren and Fenni for an answer.
80:00
Um, and just a reminder, this, uh, is being recorded
80:03
and will be made available, um, in 10 business days or less.
80:07
So thank you again Dr.
80:08
Lorenz, for staying on a little, uh,
80:10
while longer to answer questions.
80:12
You guys have a good one. Take care.
80:13
Thank you all. Bye.