0:00

Images acquired in cardiac CT

0:04

are synchronized with the ECG.

0:08

In many ways, it's obvious why we do this, but

0:10

I think it's probably worth asking why still.

0:13

The obvious answer is because the heart

0:16

signals its movement, that it has an

0:19

electrical signal, so there may be a compulsion

0:21

to synchronize requisition with that.

0:24

But the real reason is that it is done to

0:27

compensate for an inadequate temporal resolution.

0:31

Imagine if the temporal resolution was

0:33

five milliseconds and you could acquire

0:34

the whole heart in 10 milliseconds.

0:37

I mean, we're not there anywhere.

0:39

But let's say you could, then there would be no part

0:42

point of ECG synchronizing 'cause you'd be able to

0:44

get pretty much the entire heart with very little

0:48

difference between the top of the heart and the

0:50

bottom of the heart in terms of where they were in

0:52

the cardiac cycle in a, uh, flash of the second.

0:56

So we really have to do this because the temporal

1:01

resolution is historically and still is inadequate.

1:06

So what are the modes of ECG synchronization?

1:08

I use that as a generic term.

1:09

And to understand that we have to

1:12

understand the modes of scanning today.

1:16

Modes of scanning today really are two types.

1:18

One is where the table moves and the

1:20

second is where the table is stationary.

1:22

The table is stationary when the gantry also is

1:25

stationary and it just does one rotation.

1:29

And in that one rotation, it covers

1:32

the organ of interest, the heart.

1:34

And that happens with the area detectors that

1:37

have multiple detectors, such as 320 detectors.

1:39

And they're able to scan the whole

1:41

heart in one gantry rotation.

1:44

Mostly this table moves.

1:47

And the table can move in two manners.

1:48

One is sequential and the other one is helical.

1:52

And basically, although this is just a

1:54

very basic distinction, sequential uses

1:58

prospective and helical uses retrospective.

2:03

So what happens with prospective?

2:04

It's also called prospective triggered.

2:07

We say the R wave is very important.

2:09

If you recall your ECG, there's the PQRS

2:13

complex T wave and the R wave is the

2:15

biggest part of the ECG, the tallest part.

2:18

Sometimes that's not the case.

2:19

It may be the T wave.

2:21

So we take a predetermined point from

2:25

the R wave and we say that at that point

2:29

the images are going to be acquired.

2:31

So the gantry moves around the patient.

2:36

That's the shoot.

2:38

Next heartbeat.

2:40

The table advances so that we have a next volume

2:43

that hasn't been scanned, that gets scanned.

2:46

So that's step.

2:48

And then you shoot again.

2:50

This is how we still do the calcium scans.

2:53

We used to do the calcium scans,

2:54

of course, this way we still do it.

2:56

But with increasing number of detectors, we

3:00

can actually employ this method in coronary

3:03

arteriography as well, the angiographic part.

3:06

So this is step and shoot, and there

3:09

are various adaptations of this.

3:13

Which take some stepping, some moving non-

3:19

sequentially, and some moving sequentially.

3:22

So there's a combination of things you can

3:24

do, but the purest form, this is what it is.

3:28

Another is the helical, which

3:30

is the retrospective gating.

3:31

What's retrospective is that we acquire the

3:33

images throughout the cardiac cycle.

3:37

And then we decide later on to put the

3:41

images retrospectively in various bins.

3:44

That can be at 5 percent intervals of the cardiac

3:47

cycle, 10 percent intervals of the cardiac cycle,

3:49

or millisecond intervals, like 50

3:54

milliseconds, 100 milliseconds.

3:56

So the radiation is on continuously, but

3:59

it can be reduced during portions of the

4:02

cardiac cycle that we know the imaging will

4:04

not be that great, such as during systole.

4:07

So that's called tube current modulation

4:09

that saves 40 percent or so radiation dose.

4:13

It used to be the method of choice.

4:15

You know, because the scans were taking so long

4:19

that there was a chance of heart rate variability

4:23

and different arteries had their quiet period

4:26

at different times of the cardiac cycle.

4:27

So we would have to do reconstructions for the RCA

4:30

in a certain phase and the LAD in a certain phase.

4:34

These days we hardly employ retrospective

4:37

unless we want functional imaging either

4:40

of the aortic valve or the heart functional

4:43

imaging to see how the heart is contracting.

4:46

Or if we

4:48

encounter a patient with arrhythmia

4:51

so that we know that there may be

4:54

different phases of the cardiac cycle that will

4:56

work for different portions of the heart.

5:01

So this is a not-so-new now but certainly new

5:07

when this paper was published in 2009 method of

5:10

acquisition which is known as high-pitch imaging.

5:13

Pitch tells you it's like a kind of helical

5:17

spring, and a pitch of one means that the gantry

5:24

moves the same distance as the collimator width.

5:28

A pitch less than one is overlap, which is

5:30

what you need for retrospective gating.

5:32

And a pitch greater than one means that

5:36

there could be informational loss.

5:37

However, that makes the scan faster.

5:43

With two tubes at right angles to each

5:45

other, you can go up to a pitch of 3.2.

5:49

120 00:05:49,829 --> 00:05:53,650 And there are other fancy algorithms used to correct

5:53

for the possibility of informational loss.

5:59

So you can go up to a pitch of

6:01

3.2 without any informational loss.

6:05

So you can start at the top of the heart in

6:07

the beginning of the cardiac cycle as you

6:09

do over here, and by the time you're

6:14

through one or two rotations, pretty much done.

6:20

You've covered the entire volume within the heartbeat.

6:23

So I say one or two, I really mean one heartbeat.

6:27

So this is known as the high

6:28

pitch spiral scan, FLASH.

6:31

Scan time is the time that it takes for the

6:37

table to move from the top of the heart to the bottom

6:39

of the heart to acquire that particular volume.

6:42

Given a pitch of 3.2

6:44

and very fast table speeds, this can

6:48

be done within a single cardiac cycle.

6:50

And this is very different from the prospective

6:53

where you're kind of stepping, shooting,

6:57

moving, shooting, moving, so sequential.

7:00

So this is still helical; the trajectory is helical.

7:04

Very high physiological, except

7:07

it's done within one shot, one sweep.

7:14

Thank you.

ECG Synchronization

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Interactive Transcript

Pro Tip: Click on a word in the transcript to jump to that point in the video

0:00

Images acquired in cardiac CT

0:04

are synchronized with the ECG.

0:08

In many ways, it's obvious why we do this, but

0:10

I think it's probably worth asking why still.

0:13

The obvious answer is because the heart

0:16

signals its movement, that it has an

0:19

electrical signal, so there may be a compulsion

0:21

to synchronize requisition with that.

0:24

But the real reason is that it is done to

0:27

compensate for an inadequate temporal resolution.

0:31

Imagine if the temporal resolution was

0:33

five milliseconds and you could acquire

0:34

the whole heart in 10 milliseconds.

0:37

I mean, we're not there anywhere.

0:39

But let's say you could, then there would be no part

0:42

point of ECG synchronizing 'cause you'd be able to

0:44

get pretty much the entire heart with very little

0:48

difference between the top of the heart and the

0:50

bottom of the heart in terms of where they were in

0:52

the cardiac cycle in a, uh, flash of the second.

0:56

So we really have to do this because the temporal

1:01

resolution is historically and still is inadequate.

1:06

So what are the modes of ECG synchronization?

1:08

I use that as a generic term.

1:09

And to understand that we have to

1:12

understand the modes of scanning today.

1:16

Modes of scanning today really are two types.

1:18

One is where the table moves and the

1:20

second is where the table is stationary.

1:22

The table is stationary when the gantry also is

1:25

stationary and it just does one rotation.

1:29

And in that one rotation, it covers

1:32

the organ of interest, the heart.

1:34

And that happens with the area detectors that

1:37

have multiple detectors, such as 320 detectors.

1:39

And they're able to scan the whole

1:41

heart in one gantry rotation.

1:44

Mostly this table moves.

1:47

And the table can move in two manners.

1:48

One is sequential and the other one is helical.

1:52

And basically, although this is just a

1:54

very basic distinction, sequential uses

1:58

prospective and helical uses retrospective.

2:03

So what happens with prospective?

2:04

It's also called prospective triggered.

2:07

We say the R wave is very important.

2:09

If you recall your ECG, there's the PQRS

2:13

complex T wave and the R wave is the

2:15

biggest part of the ECG, the tallest part.

2:18

Sometimes that's not the case.

2:19

It may be the T wave.

2:21

So we take a predetermined point from

2:25

the R wave and we say that at that point

2:29

the images are going to be acquired.

2:31

So the gantry moves around the patient.

2:36

That's the shoot.

2:38

Next heartbeat.

2:40

The table advances so that we have a next volume

2:43

that hasn't been scanned, that gets scanned.

2:46

So that's step.

2:48

And then you shoot again.

2:50

This is how we still do the calcium scans.

2:53

We used to do the calcium scans,

2:54

of course, this way we still do it.

2:56

But with increasing number of detectors, we

3:00

can actually employ this method in coronary

3:03

arteriography as well, the angiographic part.

3:06

So this is step and shoot, and there

3:09

are various adaptations of this.

3:13

Which take some stepping, some moving non-

3:19

sequentially, and some moving sequentially.

3:22

So there's a combination of things you can

3:24

do, but the purest form, this is what it is.

3:28

Another is the helical, which

3:30

is the retrospective gating.

3:31

What's retrospective is that we acquire the

3:33

images throughout the cardiac cycle.

3:37

And then we decide later on to put the

3:41

images retrospectively in various bins.

3:44

That can be at 5 percent intervals of the cardiac

3:47

cycle, 10 percent intervals of the cardiac cycle,

3:49

or millisecond intervals, like 50

3:54

milliseconds, 100 milliseconds.

3:56

So the radiation is on continuously, but

3:59

it can be reduced during portions of the

4:02

cardiac cycle that we know the imaging will

4:04

not be that great, such as during systole.

4:07

So that's called tube current modulation

4:09

that saves 40 percent or so radiation dose.

4:13

It used to be the method of choice.

4:15

You know, because the scans were taking so long

4:19

that there was a chance of heart rate variability

4:23

and different arteries had their quiet period

4:26

at different times of the cardiac cycle.

4:27

So we would have to do reconstructions for the RCA

4:30

in a certain phase and the LAD in a certain phase.

4:34

These days we hardly employ retrospective

4:37

unless we want functional imaging either

4:40

of the aortic valve or the heart functional

4:43

imaging to see how the heart is contracting.

4:46

Or if we

4:48

encounter a patient with arrhythmia

4:51

so that we know that there may be

4:54

different phases of the cardiac cycle that will

4:56

work for different portions of the heart.

5:01

So this is a not-so-new now but certainly new

5:07

when this paper was published in 2009 method of

5:10

acquisition which is known as high-pitch imaging.

5:13

Pitch tells you it's like a kind of helical

5:17

spring, and a pitch of one means that the gantry

5:24

moves the same distance as the collimator width.

5:28

A pitch less than one is overlap, which is

5:30

what you need for retrospective gating.

5:32

And a pitch greater than one means that

5:36

there could be informational loss.

5:37

However, that makes the scan faster.

5:43

With two tubes at right angles to each

5:45

other, you can go up to a pitch of 3.2.

5:49

120 00:05:49,829 --> 00:05:53,650 And there are other fancy algorithms used to correct

5:53

for the possibility of informational loss.

5:59

So you can go up to a pitch of

6:01

3.2 without any informational loss.

6:05

So you can start at the top of the heart in

6:07

the beginning of the cardiac cycle as you

6:09

do over here, and by the time you're

6:14

through one or two rotations, pretty much done.

6:20

You've covered the entire volume within the heartbeat.

6:23

So I say one or two, I really mean one heartbeat.

6:27

So this is known as the high

6:28

pitch spiral scan, FLASH.

6:31

Scan time is the time that it takes for the

6:37

table to move from the top of the heart to the bottom

6:39

of the heart to acquire that particular volume.

6:42

Given a pitch of 3.2

6:44

and very fast table speeds, this can

6:48

be done within a single cardiac cycle.

6:50

And this is very different from the prospective

6:53

where you're kind of stepping, shooting,

6:57

moving, shooting, moving, so sequential.

7:00

So this is still helical; the trajectory is helical.

7:04

Very high physiological, except

7:07

it's done within one shot, one sweep.

7:14

Thank you.

Report

Faculty

Saurabh Jha, MD

Co-Program Director, Cardiothoracic Imaging Fellowship, Associate Professor of Radiology

University of Pennsylvania

Lesson

Introduction

Lesson

Acquisition

Lesson

Case Review

ECG Synchronization