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A Beginner's Guide to CT for Coronary Artery Anomalies, Christy Pomeranz (3-14-24)

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0:02

Hello and welcome to noom Conference hosted by MRI Online.

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NOOM Conference connects the global radiology community

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through free live educational webinars that are accessible

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for all and is an opportunity

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to learn alongside top radiologists from around the world.

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and share ideas to help the community learn and grow.

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by creating a free MRI online account.

0:28

Today we're honored to welcome Dr.

0:29

Christy Pomerance for a lecture entitled A Beginner's Guide

0:33

to CT for Coronary Artery Anomalies in

0:35

the pediatric population.

0:37

Dr. Pomerance completed her residency at Weill Cornell

0:40

and her pediatric radiology fellowship at Children's

0:43

Hospital of Philadelphia before returning

0:45

to Weill Cornell in 2018, where she's currently on staff

0:50

as an assistant professor.

0:51

At the end of the lecture, please join her in a q

0:53

and a session where she will address questions you may

0:55

have on today's topic.

0:57

Please remember to use the q

0:58

and a feature to submit your questions so we can get to

1:01

as many as we can before our time is up.

1:03

And with that, we are ready to begin today's lecture. Dr.

1:06

Pomerance, please take it from here.

1:08

Hi, good afternoon everybody. My name's Kristi Pomerance.

1:11

Um, and as they mentioned,

1:12

I am a pediatric radiologist at Cornell.

1:15

Um, and today I'm going

1:16

to be talking about coronary artery anomalies in

1:20

children on ct.

1:21

Um, so we're gonna go, uh,

1:23

I am primarily a pediatric body radiologist,

1:26

but I do read, um, pediatric cardiac ct.

1:30

Um, so hopefully this will be a good introduction.

1:32

Um, I know it's something that a lot

1:33

of people are not comfortable reading,

1:35

don't have a lot of experience with.

1:37

So we're gonna do an overview.

1:39

We'll talk about the CT technique we use at our institution.

1:42

We'll review normal coronary artery anatomy.

1:45

We're gonna go over some

1:46

of the d big disease categories you're looking at,

1:48

and we're gonna show, um,

1:49

some interesting cases from our institution.

1:53

So the gold standard

1:54

for evaluating the coronary arteries in both adults

1:57

and children is cardiac CTA, and that is a CTA that is gated

2:01

or timed for the cardiac cycle.

2:03

And cardiac CTA has been found to be even superior

2:06

to invasive or congen conventional angiography

2:09

as well as MRI.

2:11

And I know pediatrics is a bit of a niche field,

2:13

and pediatric cardiac imaging is

2:15

even more of an niche field.

2:17

But, um, as our, uh, cts are getting better and better

2:21

and faster and faster, even regular cts that are not gated

2:25

and not for cardiac purposes, um, you can see some

2:28

of the cardiac anatomy on.

2:29

So for example, this is a teenager

2:31

who came into their RER, um, for trauma.

2:34

And this is a regular CT chest.

2:36

It is not gated, it is not a cardiac ct.

2:38

And you can see the coronaries on here.

2:40

Um, so these are things that are coming up more

2:43

and more even on regular ct

2:44

and additionally even coronary anomalies that we see.

2:47

These are coronary anomalies that we also see in adults

2:50

and might not present until adulthood.

2:52

And the same imaging features

2:54

and clinical considerations

2:55

that we apply in children also apply to adults as well.

2:59

Um, so hopefully even if you're not a pediatric radiologist

3:02

or you don't even read cardiac imaging, um,

3:04

you'll still find something useful in this talk,

3:07

um, for the future.

3:08

So anomalous coronary arteries are found in about one to 2%

3:12

of the population in the literature.

3:14

Um, but this is based on autopsy studies.

3:16

So this is actually thought to be a underestimation

3:19

because, um, it's only catching a portion, um, of the, um,

3:24

of the people with anomalous coronaries.

3:27

And so the real estimate they believe can almost be

3:29

as high as 5%.

3:31

And it's something that's very difficult

3:33

to diagnose clinically

3:34

because there's such a broad range of presentations.

3:37

So some people with anomalous coronaries are

3:39

completely asymptomatic.

3:40

They go their whole life without even knowing they have it.

3:42

Others present with more mild symptoms such

3:45

as chest pain or palpitations.

3:47

And then there are people who present with cardiac rest

3:49

and sudden cardiac death.

3:50

And sudden cardiac death in athletes is associated

3:53

with coronary anomalies up to 17% of the time.

3:57

And it's the second leading cause of cardiac arrest

4:00

and sudden cardiac death in athletes.

4:02

And it's specifically the anomalous aortic origin

4:05

of a coronary from the opposite sinus

4:07

with an intraarterial course.

4:08

That's the second leading cause

4:10

of sudden cardiac death in this population.

4:12

And an active US military who have sudden cardiac death

4:15

who have gone to autopsy autopsy studies show

4:18

anomalous coronaries are responsible in about 25

4:21

to 27% of those cases.

4:24

Um, so most of these events of sudden cardiac death

4:27

and cardiac arrest occur between the ages

4:29

of 10 and 30 years old.

4:31

It's more common in males

4:32

and it's most associated with basketball followed

4:35

by soccer track and field swimming and cross country.

4:38

So really high intensity endurance sports,

4:40

not strength training sports like weightlifting.

4:43

Um, and for those of you who are sports fans,

4:45

this is Sharif O'Neal.

4:46

This is Shaquille O'Neal's son.

4:48

He played UCLA, uh, he played BAS college basketball

4:51

for the UCLA Bruins

4:53

and he actually underwent surgical correction

4:55

for anomalous coronary in 2018 so he could continue playing.

4:59

Um, and that was publicly released by the family.

5:01

And this is Bronny James, who is LeBron James' son.

5:04

Um, last year he suffered a cardiac arrest in New Jersey

5:07

while playing basketball.

5:09

He subsequently underwent, um, surgery in LA, I believe

5:13

for a congenital issue.

5:14

And they haven't publicly said what he he has,

5:16

but a lot of cardiologists have publicly speculated

5:19

that it was also for repair of an anomalous coronary.

5:22

Um, so how do we scan, um,

5:24

how do we scan the coronaries in kids?

5:27

So the goal of, um, the CT is to decrease cardiac motion

5:31

as much as possible.

5:32

And how do we do this? Well,

5:34

we do this using a faster scanner.

5:36

Um, we can do this by decreasing the heart rate

5:38

with medications such as beta blockers.

5:40

And we can also do this with cardiac gating.

5:43

So cardiac gating triggers a scan

5:45

during very specific part of the cardiac cycle.

5:47

Usually the stillest,

5:49

well hopefully the stillest part of the cardiac cycle.

5:51

So the patient must be hooked up to the EKG leads.

5:54

So the CT can be done in conjunction

5:56

with the EKG and the heart rate.

5:58

So retrospective gating is when we scan throughout the

6:02

entire cardiac cycle.

6:03

And as you can imagine, this is a large amount of radiation.

6:05

It's equivalent to getting multiple cts at once.

6:08

So we really try to avoid that in children.

6:10

So we do prospective gating where the scan is timed

6:15

for a very specific part of the cardiac cycle.

6:17

We acquire all the images we can during that time.

6:20

If we don't acquire the whole scan, it waits

6:22

until the next heartbeat and require acquires the rest

6:24

during that next phase.

6:25

In the cardiac cycle, in patients less than 70,

6:28

or in patients who have a heart rate less than 70 beats per

6:31

minute, this is done during diastole.

6:33

This is usually most adult patients in, um, heart rates

6:37

that are over 70 beats per minute.

6:38

This is usually done in systole

6:40

and that's most of our pediatric patients.

6:42

We scan cranial coddle from head to toe

6:45

sedation is given on a case by case basis.

6:47

It really depends on the age and the mentation of the child,

6:50

but we usually do have to give sedation

6:51

for children younger than five years old so

6:54

that they can remain as still as possible

6:56

in unsedated patients who can follow instructions,

6:59

we do a breath hold and in sedated patients

7:01

where we're trying to evaluate the coronaries

7:03

or very small structures, we actually ask for intubation

7:06

and we do a breath hold by turning off the VE

7:08

for a few seconds while we scan.

7:11

So heart rate control.

7:12

So for cardiac cts in adults,

7:15

heart rate control is almost always given,

7:17

but we actually rarely give it in kids.

7:19

We actually rarely give beta blockers

7:21

and we almost never give nitrates.

7:22

We have given beta blockers a few times to older,

7:25

more adult sized teenagers.

7:27

Um, if the kid is in, uh, sedated

7:30

and pediatric anesthesias present,

7:32

occasionally we'll ask them to give rate

7:34

control as they deem safe.

7:35

But the point is is that most

7:37

of our scans are successfully done at much higher heart

7:40

rates than the adult cardiac studies are.

7:42

Um, and so another, um, important feature

7:45

of a cardiac CT done for coronaries is good timing

7:48

of the contrast in the coronary arteries

7:50

and things that can affect the contrast.

7:52

Timing include age and size, heart rate anatomy.

7:56

As you see here, this kid has a left-sided SVC.

7:58

That might time that

8:00

that might change the timing of the contrast.

8:02

Any cardiac shunts in any delay in scanning, we try

8:06

to use a right antecubital IV injection.

8:09

We bolus track

8:10

and we trigger the scan off

8:12

of the descending thoracic aorta at the level

8:14

of the Karina at a hundred hounds field units.

8:16

I know other places will do a test injection

8:18

and then time the scan based off that test, test,

8:21

test injection, we use Omnipaque three 50 followed

8:24

by saline flush and contrast dose is determined by scan time

8:28

and patient size for injection rate.

8:30

Um, a lot of times in children we're very limited by

8:33

what size IV we're able to get, but alienates

8:36

and infants, we try to go at one to two ccs per second.

8:39

And little kids, we try to go to three

8:40

to four to ccs per second.

8:41

And in adult sized teenagers we go five ccs, five

8:45

to six ccs per second, which is, you know, more similar

8:48

to an adult cardiac scan.

8:50

Okay, so let's review normal coronary artery anatomy.

8:53

So the coronary arteries arise from the aortic sinuses just

8:57

below the synott tubular junction.

8:58

There's usually two separate ostia.

9:01

There is a right coronary artery arising from the right

9:04

sinus of el salva or right cusp.

9:06

And there's a left coronary artery arising from the left

9:09

sinus of el Salva and cusp here.

9:11

And then there's also a posterior

9:14

or non coronary sinus,

9:15

which usually gives off no vessel whatsoever.

9:18

The left main coronary artery then divides into the LAD,

9:21

the left anterior descending and the left circumflex artery.

9:24

Occasionally it also gives off a third branch called the

9:26

ranis intermediates artery.

9:28

And in most people, usually there's a right dominant system.

9:31

What we mean by that is that the RCA curves around the back

9:35

of the heart to supply the posterior descending artery.

9:39

Coronary arteries are defined by the area of distribution

9:42

that they supply and not by their origin.

9:44

So the LAD is defined as courses

9:46

through the anterior intraventricular group.

9:49

It supplies the anterior intraventricular septum

9:52

and it gives off diagonal branches.

9:55

The left circumflex artery courses in the left AV groove

9:59

supplies the left ventricular free wall

10:01

and gives off obtuse marginal branches

10:03

and the right coronary artery courses in the right AV groove

10:06

supplies the right ventricular free wall

10:08

and gives off acute marginal branches.

10:11

And there are numerous normal variants that can occur

10:14

with the coronary arteries.

10:16

Many of them are listed here

10:17

and many of them that you see on imaging.

10:19

Frequently, we will discuss a high takeoff

10:21

of the coronary arteries, which is something

10:23

that we often see in children.

10:25

So the big disease categories you're looking

10:28

for in kids when it comes

10:29

to coronary artery anomalies are anomalies of origin,

10:32

meaning that the coronaries come

10:34

off from the wrong location.

10:35

Anomalies of course, meaning

10:37

that the coronaries have an abnormal course

10:39

and anomalies of termination, meaning

10:40

that the coronaries communicate

10:42

or terminate with adjacent structures

10:44

that they're not supposed to, such as cardiac tumors,

10:47

systemic vessels or pulmonary vasculature.

10:50

You can also think of these disease

10:51

categories in two other ways.

10:54

Um, there's one category which is benign

10:56

or non hema like significant.

10:58

These are things that we see on imaging,

11:00

but they might not clinically affect the patient

11:02

and they might not need any intervention

11:04

or surgery, whereas we have hemodynamically

11:07

and significant anomalies that are dangerous

11:10

for the patient can lead to serious outcomes

11:12

and may need intervention surgery.

11:14

And then finally I have a third category in my brain

11:17

that I think of is that things

11:18

that cause dilated coronaries in children.

11:20

And that includes, um, p uh,

11:23

coronaries coming from the pulmonary arteries,

11:25

congenital fistulas,

11:26

and then coronary artery aneurysms,

11:28

all of which we'll discuss.

11:30

So the main questions you wanna answer

11:32

with cardiac CT when you're doing a coronary artery

11:35

anomalies, do the coronaries have a normal origin?

11:38

If not, do they arise ECT topically from the aorta

11:42

or do they arise from a structure,

11:43

another structure other than the a, the aorta?

11:47

Does the coronary artery have a normal or abnormal course?

11:50

Does the coronary artery have any abnormal connections

11:53

to adjacent structures such as the cardiac chambers,

11:56

pulmonary arteries, or systemic circulations?

11:59

And are the coronary arteries dilated?

12:02

So we're gonna jump into cases now.

12:04

The first batch of cases we're gonna talk about, um,

12:07

involves anomalous aortic origin of the coronaries.

12:10

So this occurs, the left main coronary can arise from the

12:13

opposite sinus as it does here or from here

12:17

or the the left main

12:19

or the right, uh, coronary artery can arise from

12:21

the opposite sinuses.

12:22

The left main or the right coronary artery can also arise

12:25

from the posterior or non coronary sinus.

12:28

Or you can have a single coronary artery

12:30

arising from any sinus.

12:32

Um, and these also can have numerous, um, courses.

12:36

So you can have a pre pulmonic course of the coronary

12:38

where it runs anterior to the main pulmonary artery.

12:41

You can have a retro aorta course where it runs

12:44

behind the aorta.

12:45

You can have a transseptal course where it dives down

12:48

and runs in the intraventricular septum.

12:51

And these are all benign courses.

12:52

But the first one I wanna focus on is this interarterial

12:55

course where the coronary comes off from the opposite sinus

12:59

and travels between the aorta

13:00

and the main pulmonary artery as you see here.

13:03

Um, and this term, this course is actually the one

13:06

that is termed malignant.

13:07

Well, why is it termed malignant?

13:09

Because this is the course that's associated

13:12

with an increased risk of sudden cardiac death.

13:15

So an interarterial right coronary artery is more common

13:18

than an interarterial left main coronary artery.

13:21

But it seems and both are at risk for sudden cardiac death.

13:24

But an interarterial left main coronary artery is more

13:27

highly associated with sudden cardiac

13:28

death and cardiac arrest.

13:30

And there's two theories about why this is the case.

13:33

The first is that exercise causes expansion

13:36

of the aortic root

13:38

and the pulmonary artery,

13:39

which then can compress the artery.

13:41

But this theory is controversial and not well accepted.

13:45

The more prevalent theory is that most of these cases

13:48

of an intra arterial course actually have an intramural

13:51

segment where this coronary runs within the aortic wall.

13:55

And that portion, that intramural segment is hypoplastic

13:58

and easily compressed and, uh, compressed

14:00

and occluded by the aorta.

14:02

Intramural features include a slit light orifice like we see

14:06

here, an acute angle of takeoff between the coronary

14:10

and the aortic wall, and an elevated height to width ratio.

14:14

You can see that this coronary is being

14:15

squeezed in the vertical direction.

14:19

This is just a nice diagram from this paper showing normal

14:22

takeoff of coronary with a nice obtuse angle

14:25

with the aortic wall.

14:26

And you can see that as the coronary travels longer

14:29

and longer distances within the aortic wall,

14:32

there's a greater acute angle of the, um, coronary

14:35

with the aortic wall and the segment becomes more

14:38

and more narrowed, as does the o.

14:42

So this is our first case.

14:43

This is a 16-year-old who, uh, was completely healthy,

14:47

had no medical history

14:48

and experienced a cardiac arrest during basketball practice.

14:51

So all the cases I'm gonna show you start

14:53

with an axial CT of the chest.

14:55

So these are the great arteries.

14:56

This is the aorta that's well pacified,

14:58

and this is the pulmonary artery.

15:00

And as we scroll down, we can see there is normal takeoff

15:03

of a left main coronary artery from the left sinus,

15:06

but there is abnormal takeoff

15:08

of a right coronary from the left sinus coursing

15:11

between the aorta and the pulmonary artery.

15:13

And you can see that this has a very slit like osteum.

15:16

It has an acute angle of takeoff with the aor

15:19

with the aortic wall,

15:20

and it is very narrowed in that, um, interarterial segment

15:24

before it, um, runs into the AV groove

15:27

and has a more normal configuration.

15:31

And here are orthogonal.

15:33

This is a closeup orthogonal image of the RCA as it runs in

15:37

between the aorta and the pulmonary artery.

15:39

And you can see how narrowed

15:40

and slit, like it's, it has an increased height width ratio.

15:43

These are curved replan or reformats of the coronaries.

15:47

And you can see that the l the normal left main coronary

15:50

artery is nice and wide open at its osteum

15:53

and has no areas of narrowing versus

15:55

that anomalous right coronary artery,

15:57

which has a very slit like osteum

15:58

and has this long segment of narrowing,

16:00

which is highly suspicious for an intramural course.

16:05

This is a companion case.

16:07

This is a 7-year-old with chest pain.

16:09

Um, again, this is the aorta here

16:11

and the main pulmonary artery.

16:12

You can see there's a normal takeoff

16:14

of the left main coronary artery from the left sinus.

16:17

And there is an anomalous takeoff

16:19

of the right coronary artery from the left sinus,

16:21

again coursing between the aorta and the pulmonary artery.

16:25

This one is mildly narrowed at its osteum and proximally,

16:29

but not, probably not as greatly

16:31

as the last case I showed you.

16:32

And again, here are orthogonal images just showing

16:35

that it is very slightly probably, uh, squished

16:40

or narrowed in that, um, intraarterial in

16:43

that intraarterial region.

16:45

So this is more equivocal for an intramural course,

16:47

but this still has an intraarterial course.

16:50

And again, here's a nice picture of that.

16:52

Um, anomalous right coronary artery.

16:54

Again, it does have an acute angle of takeoff

16:56

with the aortic wall, um, and maybe slight mild narrowing.

17:00

And that's proximal portion.

17:01

And here's a curved replan or reformat of that artery.

17:07

This was a 14-year-old with syncope

17:11

and again, we have the aorta, the pulmonary artery.

17:14

This is an axial ct.

17:16

This time we have a normal takeoff

17:18

of the right coronary from the right sinus of El Salva here,

17:22

but we see

17:24

that we do not have a normal left main coronary artery

17:26

arising from the left sinus.

17:28

Instead, the left coronary artery,

17:30

left main coronary artery is arising from the right sinus

17:33

of salva just to the right of

17:35

that inter coronary commissure.

17:37

And again, having an interrater course between the aorta

17:40

and the pulmonary artery.

17:42

And here it's here. And again, we have an acute angle

17:45

of takeoff, we have mild narrowing,

17:47

we have a slip like osteum.

17:49

And then in that intra arterial segment we have a very

17:53

narrowed or ovoid configuration of the, um, coronary artery.

17:57

Again, suspicious for an intramural segment.

17:59

We can see that the left main coronary artery more distally

18:02

after it exits that intramural

18:04

and intra arterial region, um, demonstrates more rounded

18:07

and more normal configuration.

18:09

So this was an interarterial left main coronary artery

18:12

with an intramural segment.

18:14

So why is it important to detect these?

18:17

Um, because, um, we do surgery for these.

18:20

So the surgical technique

18:21

that's preferred is a coronary on roofing where they take

18:24

that intramural segment that's running in the aortic wall

18:27

and they actually make a slit in it to open up that segment

18:30

with the aorta and hopefully create a neo osteum

18:33

or a new opening in the more normal or orthotopic location.

18:37

Um, but there's two reasons

18:39

why you might not be able to do that.

18:40

The first is if the coronary runs to close

18:43

to the aortic valve commissures, if the, if the, if the um,

18:47

coronary artery crosses at that level.

18:50

So this is always something that we like

18:52

to report in our report in our dictations

18:54

and tell the surgeons about.

18:55

The other reason you might not be able to do

18:57

that is if the intramural segment is too short.

19:00

Um, and so this is another thing we do is we always measure

19:03

how long the intramural segment is

19:05

and report it in our dictations.

19:07

So if you can't do a coronary

19:08

and roofing, then they have to do a coronary reimplantation

19:10

where they actually take the coronary off

19:12

and they sew it back in,

19:14

in the orthotopic or normal location.

19:16

Um, but this comes with more long-term complications,

19:18

which is why coronary and roofing is referred.

19:22

Okay, so now let's talk about some

19:24

of the more benign variants

19:25

of an anomalous aortic origin of the coronary.

19:29

Um, so this is a case, this is a 23-year-old with chest pain

19:33

and here we have a normal right coronary coming from the

19:35

right sinus, but we see we have an anomalous left coronary

19:38

coming from the left sinus.

19:40

And at first it almost looks like it's interarterial

19:43

because it's traveling between the aorta

19:44

and maybe the pulmonary artery.

19:47

But if you look more closely, this um,

19:49

vessel is actually the left main coronary artery is diving

19:52

down, it's swooping down,

19:53

creating what's called a hammock sign.

19:55

And if you look on the sagittal image, you see that this,

19:58

um, left main pulmonary artery is actually traveling within

20:02

the intraventricular septum.

20:03

So instead of being up here

20:04

where an interarterial artery travel,

20:06

it's traveling down here.

20:08

So this was actually a transseptal course.

20:10

This is more common with the LAD in the

20:12

left main coronary artery.

20:13

Um, this hammock sign has been described to de to um,

20:17

describe, you know, when it dives down into the

20:19

intraventricular septum

20:21

and this is when the coronary, um, uh, travels

20:24

below the level of the pulmonary valve in the

20:26

intraventricular septum.

20:27

So how do you tell the difference between an interarterial

20:30

and a transseptal course?

20:31

In a transseptal course, the arteries surrounded

20:34

by septal myocardium, whereas in,

20:36

in an inter arterial course the artery surrounded

20:38

by aortic wall or epicardial fat in a transseptal course,

20:42

the artery course downward creating

20:44

that hammock sign we talked about.

20:46

And it travels below the level

20:48

of the pulmonic valve like we see here

20:50

on the sagittal image.

20:52

And an interarterial course, the artery travels

20:55

above the level of the pulmonic valve,

20:58

the artery In a transseptal course,

20:59

the artery does not have an oblong or slit like appearance.

21:02

And in an inter arterial course,

21:03

the artery may have an oblong

21:05

or slit like appearance if it has an intramural course.

21:09

Another benign variant that we see is a pre pulmonic course.

21:13

So this was a 23-year-old with tachycardia

21:16

and an anomalous left coronary seen on a PE study.

21:19

Again, hearkening back to the fact that we're starting

21:21

to see more and more coronaries on our non cardiac imaging.

21:26

Um, and this was a follow-up

21:28

cardiac CT done on this patient.

21:30

So again, we see a well pacified aorta in the

21:32

main pulmonary artery.

21:33

And this time we actually have a single coronary arising

21:36

from the right sinus of El Salva.

21:38

And you can see there's no left coronary coming off from

21:41

the left sinus.

21:43

And if we trace it out, we see

21:44

that there is a normal right coronary artery,

21:47

but we also have this additional vessel,

21:48

this left main coronary artery coming off from the single

21:51

osteum and coursing in a pre pulmonic fashion anterior

21:55

to the main pulmonary artery here.

21:57

And we can see it here on this 3D image.

22:00

And so this was a pre pulmonic left coronary artery.

22:04

This is more common with the left main

22:06

coronary artery than the right.

22:07

And we actually see this with tetrology of fallot.

22:10

It's associated with tetrology of fallot.

22:13

Um, so this was a five-year-old, um,

22:16

who was undergoing a presurgical workup for, um,

22:19

before a pectus excavatum surgery

22:22

and a coronary artery anomaly was incidentally found.

22:26

Um, so again, we see a well opacified aorta

22:30

and this is the main pulmonary artery.

22:32

We see normal takeoff of a right coronary

22:36

here arising from the right sinus.

22:38

But when we look at the left sinus,

22:40

we do not see a left main coronary artery coming off.

22:43

But what we do see is we see a left main coronary artery

22:46

coming off from the right sinus here

22:50

and coursing posteriorly, retro aortic behind the aorta

22:55

and then giving off the LAD in the circumflex.

22:58

And again, you can see that here and here.

23:00

So this was a retro aortic left main coronary artery.

23:04

Um, a retro aortic course is more common

23:06

with the left main coronary artery than the right.

23:09

And again, it's totally benign.

23:10

You don't have to do anything about it.

23:11

But it is important to know if this patient ever goes on

23:14

to get aortic valve surgery.

23:18

A single coronary artery is a very extremely,

23:21

extremely rare um, anomaly.

23:23

It is when you have a single aortic root osteum

23:26

with no additional ectopic

23:27

or atretic osteum, it can be associated with other types

23:31

of congenital heart disease.

23:32

And I just wanted to show you guys this very rare case we

23:35

had in a very young child.

23:37

They did an echo and they said we don't see a left main

23:40

coronary artery anywhere.

23:41

We don't even see it, you know, distally

23:44

and we're not sure sure where it's coming off of.

23:46

So we did a cardiac CT and again, here's the aorta

23:49

and we see a single coronary artery

23:51

and it's very large in size, especially

23:54

for this very young patient, um,

23:55

coming off from the right sinus.

23:57

And if you follow it around,

23:58

it's go traveling normally within the right AV groove,

24:02

but it's coming around the back of the heart

24:05

and it's actually giving off the left circumflex

24:10

And the left anterior descending artery as well.

24:13

So this was a very rare case

24:15

of a single coronary artery feeding the entire heart.

24:19

Osteo atresia is a companion case.

24:22

Um, some can be somewhat similar in appearance.

24:25

Um, but this occurs when coronaries become occluded in feal

24:28

or neonatal li uh, life.

24:31

It almost always involves the left mean coronary artery

24:34

and it's characterized by an atretic

24:36

or fibrous connection between the left coronary cusp

24:40

and the LAD and left circumflex.

24:42

There are usually prominent right to left collateral vessels

24:46

and there's usually a large conal branch coming from the

24:49

right coronary artery to supply the LAD,

24:52

which has a pre pulmonic course

24:54

and may mimic a pre pulmonic vessel.

24:56

And these patients usually will develop myocardial ischemia

24:59

later in life and eventually need some sort

25:01

of revascularization or bypass.

25:04

So this was a 2-year-old

25:06

who had an absent left main coronary artery on echo.

25:10

And we see as we scroll down, there is again takeoff

25:14

of a right coronary artery

25:15

and the right coronary artery is pretty big.

25:18

Could pretty good in size.

25:20

We can see that there is an LADA circumflex

25:23

and even a ramus intermediates artery,

25:26

but there is no left main coronary artery connecting it

25:29

back to the left sinus.

25:30

Um, you can imagine there's like a short segment here,

25:32

which you know, kind of should be there.

25:34

It looks like it almost made it there but not quite.

25:37

Um, and if we follow up that right coronary, we can see

25:40

that there is a large conal branch here coursing in front

25:43

of the main pulmonary artery connecting with a bunch

25:46

of collateral vessels here

25:47

and then feeding the left anterior descending artery here.

25:52

And again, here is that network of collaterals.

25:54

And here is that, um, conal branch feeding the left uh,

25:59

circulatory system.

26:00

So this was osteo atresia with a pre pulmonic vessel.

26:04

Okay, hi aortic takeoff.

26:06

Um, so this is one

26:07

of the normal variants I alluded to before.

26:09

This is actually one of the most common

26:10

thing we see in kids.

26:12

Um, it's much more common than the other, um,

26:14

anomalous aortic, um, uh, origins of the coronaries.

26:18

So the coronaries usually come off

26:19

below the OTT tubular junction,

26:22

but a hi aortic takeoff is defined as a coronary

26:24

that comes off five or even 10 millimeters

26:27

above the OTT tubular junction.

26:28

And it's benign, but it's important

26:30

to know about if the kid is ever getting cardiac

26:32

catheterization or cardiac surgery.

26:34

And it is much, much more common

26:36

with the right coronary than the left.

26:38

And a high takeoff of the right coronary is associated

26:41

with the bicuspid aortic valve.

26:44

So this was an 8-year-old with an anomalous coronary, uh,

26:47

right coronary on echo.

26:49

Um, they said, Hey, you know, we did this echo,

26:51

we really can't see where the right coronary is coming from.

26:53

We're worried that it might have a malignant course

26:55

or it might be coming off somewhere bad.

26:58

And so we did a cardiac CT

27:00

and you can see there is a normal left coronary arising from

27:04

the left sinus, um, of El Salva.

27:06

But we see this right coronary here, it has a normal course,

27:10

but as we trace it back, we see it goes up, up, up, up, up,

27:13

up, up and it is actually coming off from

27:15

the ascending aorta.

27:16

And here on this coronal image you can see that it's arising

27:19

above a level of the synott tubular junction.

27:21

So we said, hey, this is just a high aortic

27:24

takeoff of this coronary.

27:26

Um, this was a two week old, um,

27:29

with an echo done for murmur.

27:31

Um, they did the echo

27:32

and they couldn't see the right coronary artery very well

27:35

and in fact they were actually worried it was coming from

27:37

the pulmonary artery

27:38

because they could trace, almost trace it back

27:40

to the pulmonary artery, um, in which case

27:42

that would've required surgery.

27:44

And so they said, Hey, can you, we just wanna know

27:47

where the right coronary is coming off from.

27:48

That's our only goal from the ct.

27:50

And this is not a very pretty CT

27:52

'cause this is a very young child

27:53

with a very high heart rate

27:55

and we did it without any medication

27:57

but we ans we're able to answer their one question.

28:00

Um, so this is scanning from, um, cranial to coddle.

28:03

Okay, this is the aorta

28:05

and this is the main pulmonary artery here.

28:07

And as we scroll down we can see

28:09

that there's a very tiny right coronary artery here arising

28:12

from the aorta and not from the main pulmonary

28:15

artery as was suspected.

28:17

And then going down to the right AV groove

28:19

and having a normal course.

28:20

And here is a coronal image of that high takeoff

28:24

of the right coronary artery

28:25

above the synott tubular junction.

28:27

So again, we were able to say, hey,

28:28

this is just a high aortic takeoff

28:30

of the right coronary artery.

28:31

You guys don't need to do anything.

28:34

Okay, so now let's talk about dilated coronary arteries.

28:37

So speaking of coronaries

28:40

that come off from the pulmonary arteries, um,

28:42

there is something called the anomalous origin

28:45

of the left main coronary artery from the pulmonary artery.

28:48

It's also known, um, by the pneumonic Al Kappa.

28:51

Um, it's very rare, 90% of them present in infancy

28:55

with left ventricular heart failure

28:57

and only 10% of them are able

28:58

to reach adulthood without any surgery or intervention.

29:01

And interestingly enough, at birth,

29:03

the coronaries actually usually are not dilated.

29:07

Um, this is extremely rare.

29:08

So we don't see many cases of this.

29:10

But as in infancy, the as pulmonary resistance falls,

29:14

this causes shunting

29:15

or stealing from the coronaries to the pulmonary arteries.

29:18

And then you quickly develop very dilated coronaries

29:21

and collateral vessels in older children and adults.

29:24

There's also a companion to this called r kappa

29:28

anomalous origin of the right coronary

29:29

from the pulmonary artery.

29:31

And this is similar but much,

29:33

much rarer than the already very rare Al Kappa.

29:36

And these kids are actually usually asymptomatic

29:38

and at birth, again, the coronaries may not be dilated,

29:42

but um, as pulmonary resistance begins to fall in infancy,

29:46

this can again cause shunting or stealing

29:48

and cause markedly dilated coronaries

29:50

and collateral vessels.

29:52

So this was a fascinating case.

29:54

This was a 20-year-old presenting with fatigue

29:57

who somehow made it into adulthood

29:59

with Al Kappa not knowing that she had this.

30:03

Um, and I wanna draw your attention

30:04

to the main pulmonary artery here.

30:07

And if you look along the right side

30:08

of the main pulmonary artery, you see this blush

30:10

of un opacified blood coming from the right aspect

30:13

of main pulmonary artery.

30:14

And if you trace it back, you see a very, very large

30:17

and dilated left main coronary artery, um,

30:21

then giving off very large l uh, dilated LAD

30:24

and left circumflex arteries.

30:26

And this was a case of Al Kappa.

30:28

You can see that there is a normal origin

30:29

of the right coronary artery,

30:31

but this is also markedly dilated and tortuous.

30:34

You can see all of the coronaries are markedly dilated

30:37

and there are multiple collateral vessels.

30:39

So again, here's a 3D image showing that,

30:41

and here is an image showing that anomalous, um, origin

30:45

of the left main coronary artery from the pulmonary artery.

30:48

And this was a case of Al Kappa.

30:51

Um, this was a 7-year-old with palpitations.

30:55

Um, this kid underwent an echo

30:57

and was found to have dilated coronaries on echo.

31:00

Um, so the cardiologists were thinking, oh,

31:02

we wonder if this kid has coronary artery aneurysms from,

31:05

you know, Kawasaki or from Missy.

31:07

And so we did a cardiac CT

31:09

to further evaluate his coronaries.

31:11

And again, um, I'm gonna ask you to look at the,

31:13

the pulmonary artery here, the main pulmonary artery

31:16

and then along the right aspect of it, you see this blush

31:19

of contrast here

31:21

and then coming off, you can see this really massively

31:24

dilated right coronary artery, massively dilated,

31:27

tortuous right coronary artery.

31:28

And this kid had a normal origin

31:30

of the left main coronary artery here.

31:32

But you can also see that it's very, very dilated

31:35

and tortuous as well

31:36

and that there are multiple collateral vessels.

31:39

Um, and again, here is a reformat showing the takeoff

31:42

of the right coronary artery from the main pulmonary artery.

31:45

So this was a very rare case of r kappa

31:50

coronary artery fistula.

31:52

So, um, this is another entity

31:54

that can cause dilated coronaries in children.

31:57

So the normal coronary artery should terminate in the

31:59

capillary bed of the myocardium.

32:02

Um, but a coronary artery fistula occurs when the

32:04

termination of the coronary arteries

32:06

or its branches terminate in a cardiac chamber

32:08

or a low pressure vascular structure.

32:11

60% of these cases terminate in the right-sided heart

32:14

chambers and this can cause enlargement

32:17

and tortuosity of the coronary artery

32:19

or the branches due to shunting and steel phenomenon.

32:22

And a lot of these, and

32:23

although we do see it in kids,

32:24

they're often there asymptomatic.

32:27

So usually these present later in life in adults in the

32:30

fifth or sixth decade of life.

32:32

So this was a kid, um, a three-year-old with an echo done

32:35

for murmur and they incidentally said, Hey,

32:38

the left main corona artery looks really

32:39

dilated on this echo.

32:41

And again, they were worried.

32:42

They, they said, oh, is this a coronary artery aneurysm from

32:45

Kawasaki or from Missy that you know, we didn't know about?

32:48

So they asked us to do a CT to investigate further.

32:52

Um, and again, here's the main pulmonary artery.

32:54

Here is the aortic root.

32:56

And then as we scroll down,

32:58

we can see there is a very normal looking right coronary

33:01

artery arising from the right sinus of El Salva.

33:04

But we have a massively dilated left main coronary artery

33:08

coming off, um, normally from the left sinus,

33:12

but it is very, very dilated.

33:13

It's giving off what looks like a normal LAD

33:17

and a normal left circumflex artery,

33:20

but it is also giving off this additional vessel.

33:23

So it's very dilated. It's giving off this very dilated

33:25

additional vessel which is coursing retro aortic

33:29

behind the aorta.

33:30

And then finally terminating with the right atrium here

33:34

and you can see that there's contrast going from the vessel

33:37

into the right atrium.

33:38

And so this was actually a dilated sa nodal artery.

33:42

The sa nodal artery is a normal artery

33:44

that arises from the right coronary artery about 60%

33:48

of the time and arises from the left main coronary artery

33:51

about 40% of the time.

33:52

In this case, this anodal artery has had a coronary artery

33:57

fistula with the right atrium making it massively dilated

34:00

and making the left main coronary artery massively dilated.

34:04

So we were able to tell them, hey,

34:05

this isn't a coronary artery aneurysm,

34:07

this kid has a coronary artery fistula.

34:11

Um, so speaking of coronary artery aneurysms,

34:13

this is another, um, cause of dilation

34:16

of coronary arteries in children

34:18

and in pediatrics it's almost always caused

34:20

by Kawasaki syndrome

34:22

or by Missy, which is the multi-system inflammatory syndrome

34:26

in children after a COVID-19 infection.

34:29

Um, Kawasaki's disease is way more common than missi.

34:33

Um, and coronary artery aneurysms in both are actually going

34:36

down due to better recognition of Kawasaki's disease

34:39

and newer treatments, but also

34:41

with the newer co covid variants.

34:43

Um, it doesn't seem to be as associated as highly associated

34:47

with missi and Covid vaccination has also played a, uh,

34:51

has played a role in decreasing, um,

34:53

in decreasing the rates of Missy.

34:55

Um, so, uh, the coronary artery aneurysms in both tend

34:59

to be more proximal than distal

35:01

and the aneurysms may be ular or fusiform

35:04

and they may be multifocal

35:05

and they can be any size small, moderate, or giant.

35:09

And complications include thrombosis, stenosis,

35:13

occlusion rupture or later on calcification.

35:17

So this was a two-year-old who presented

35:19

with a fever and chest pain.

35:22

Um, and you can see that there are normal origins

35:25

of both coronary arteries.

35:26

There's normal origin of the right coronary

35:29

and there is normal origin of the left coronary.

35:32

But you can see that there are multifocal areas

35:34

of aneurysmal dilation, most notably involving the LAD here

35:38

where you can see on these replan reformats,

35:41

but also involving the left circumflex artery

35:43

and also multiple areas of, um,

35:46

aneurysmal dilation involving the right coronary artery.

35:49

So this was a case of Kawasaki's disease.

35:53

This was a 6-year-old who had a fever rash

35:57

and abdominal pain who presented in September of 2021

36:00

during the covid delta variant peak.

36:03

And we can see if we start the CT over from the beginning,

36:10

um, we can see

36:11

that there are normal origins of both coronaries.

36:14

The left comes off from the left sinus,

36:16

the right comes off from the right sinus.

36:19

You can see that there are multiple areas that

36:22

of massive aneurysmal dilation,

36:24

particularly involving the right coronary artery,

36:27

but also involving the LAD and the circumplex artery here.

36:30

Is that right? Corona with at least two

36:32

large aneurysms here.

36:34

And here's the left sided, um, coronaries.

36:37

So again, these were multifocal aneurysms in the setting

36:40

of Missy and you can see

36:42

that this patient was very, very sick at this time.

36:44

They were intubated and that they were in the ICU.

36:47

Um, so on imaging, um,

36:50

the coronary artery aneurysms between kasa in Kawasaki's

36:54

and Missy are pretty indistinguishable.

36:57

Um, to my knowledge there's really no features

36:59

that differentiate the two.

37:01

Um, so, uh, Kawasaki's

37:03

and Missy are often differentiated clinically.

37:05

So Kawasaki's disease is found in younger children,

37:08

usually less than five years old.

37:10

Um, left ventricular dysfunction is very uncommon.

37:13

It's really not associated with any GI symptoms.

37:15

Obesity is not a risk factor

37:17

and it seems to be more common in, um, people

37:20

of Asian ethnicity, whereas Missy tends to be, um,

37:23

found in older children.

37:24

Adolescents usually over six years old

37:26

and these kids are very, very sick.

37:29

They usually have, um, left vent,

37:31

left ventricular dysfunction from a myocarditis,

37:34

they can have really bad GI symptoms as well.

37:37

And um, it is associated with obesity

37:40

and it is found to be more common in people of Hispanic

37:42

and African American heritage.

37:45

So in summary, uh,

37:47

cardiac CTA can successfully be done in children

37:50

for coronary artery anomalies with prospective gating

37:53

and little to no medication or sedation.

37:56

Um, the most important coronary artery anomalies

37:59

to recognize because they require intervention

38:01

or surgery, um, include that anomalous aortic origin

38:04

of the coronary arising from the opposite cusp

38:07

with an intraarterial

38:08

and intramural segment as well as Al Kappa

38:11

and r Kappa, the left

38:13

and right coronary arteries arising from

38:15

the pulmonary arteries.

38:16

The other subtypes, um,

38:18

of anomalous coronaries are important to know about.

38:21

They're benign so they don't require intervention,

38:23

but they're important to know about if the patient is ever

38:26

getting any sort of chest or mediastinal surgery.

38:29

And other important causes

38:30

of coronary artery dilation in children include coronary

38:33

artery fistula, Kawasaki's disease, and Missy.

38:37

Um, so that is all I have. Thank you so much.

38:41

This is my email if anybody needs

38:43

to email me any questions or concerns.

38:46

Um, so I will open it up for questions now.

38:51

Thanks so much for sharing your lecture, Dr. Pomerance.

38:54

And yes, if you have a question, please place it in that q

38:57

and a feature so we can get through as many as we can

39:00

before we close our session.

39:04

So q and a at my

39:09

institution we use loron.

39:11

Okay, so the first question is my institution.

39:14

We use lomon 400 for, uh,

39:18

cardiac CTI in adults.

39:19

Is there a specific reason you don't use a more concentrated

39:23

contrast material or do you you

39:25

or do you just don't seem to need to?

39:28

Um, so we use omnipaque three 50 even in adults

39:33

at my institution.

39:34

Um, I don't know why we don't use LM on 400.

39:37

Honestly, I think we don't have it at my institution.

39:40

Um, I've never heard of anyone using it at

39:42

um, at, at Cornell.

39:44

I think we just have OMNIPAQUE 303 50

39:47

in the different dilution.

39:48

Um, so I started using omnipaque three 50 just

39:51

because that was what I was trained with

39:53

and that was what the adult people were using.

39:55

Um, I I'm not sure if there's any reason, uh, we've,

39:59

we've had, we've gotten good imaging

40:00

with OMNIPAQUE three 50, so, um, we haven't found

40:03

that we've needed a more concentrated contrast.

40:07

Um, excellent presentation. Thank you very much.

40:11

Um, yeah, we'll pause for a couple seconds.

40:13

Sometimes it takes a moment for questions

40:15

to come in, so Sure.

40:17

We might get a couple more.

40:25

One more question. Have you ever encountered a dominant

40:28

conal branch arising from the LAD

40:32

Dominic Conal branch rising from the led?

40:35

Um, no, I, I have not encountered that.

40:40

Um, I don't know if the adult,

40:42

I mean the adult people read a lot more cardiac cts than we

40:46

do, especially for coronaries.

40:47

Um, so, um,

40:49

I'm sure my adult colleagues probably have encountered that,

40:52

but I have not seen that in kids.

40:54

Please do use beta blockers in child cardiac CT frequently.

40:58

We do not. So, um, we, uh, I have talked

41:03

to the pediatric cardiologist about this

41:05

and most of our cardiac cts are done as an outpatient

41:09

on our outpatient scanners,

41:10

which are much better scanners than our inpatient scanners.

41:14

And for young children, we just weren't comfortable giving

41:16

beta blockers in an outpatient setting.

41:19

Um, so the only time I've given it to, um, outpatients

41:24

is in older kids who are really like almost adult patients,

41:27

like 17, 18 year olds, um, in, uh,

41:32

in younger children, in very young children

41:34

where we are sedating them, they're sedated,

41:36

they're intubated pediatric anesthesia's there.

41:38

And we are physically in the hospital

41:40

with the pediatric anesthesia team there.

41:42

I will ask them to give, be beta blockers as they,

41:46

as they deem safe because I mean, I have a whole team there.

41:49

Um, so I feel like it's safe to do that, um,

41:52

to lower the heart rate and usually those children

41:53

have very high heart rates.

41:55

Um, but that's the only time I give it.

41:56

Most of those scans that you saw were done as an outpatient

41:59

with no rate, um,

42:01

with no heart rate lowering, um, medications.

42:04

Um,

42:08

Awesome. I think you got

42:09

'em all. Okay.

42:10

Thank you guys so much and feel free

42:12

to email me if you guys have any other questions you don't

42:15

wanna put in the chat or you think of later.

42:16

Okay. Thank you for having me.

42:19

Of course, Dr. Pomerance

42:20

and thank you so much for your lecture today

42:22

and for everyone else for participating in this lecture.

42:25

We, we appreciate you being here.

42:28

You can access a recording of today's conference

42:30

and all our previous noon conferences

42:32

by creating a free MRI online account.

42:35

And be sure to join us next Thursday,

42:37

March 21st at 12:00 PM Eastern, where Dr.

42:40

Samir Rega will deliver a lectured entitled

42:44

Thora Columbar Spine Injury at ct,

42:46

A Systematic Search Pattern.

42:48

You can register for that@mrionline.com

42:51

and follow us on social media

42:53

for updates on future noom conferences.

42:55

Thanks again and have a great day.

Report

Faculty

Christy Pomeranz, MD

Assistant Professor of Radiology, Division of Pediatric Radiology

Weill Cornell Medical College

Tags

Vascular

Syndromes

Pediatrics

Metabolic

Idiopathic

Coronary arteries

Congenital

Cardiac Chambers

Cardiac

CTA

CT

Acquired/Developmental