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Bright Blood Cine Imaging

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Okay, next we're going to focus

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on bright blood cine imaging.

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And so here on the screen, what you see

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are two sets of bright blood cine images.

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The left-hand side is a short axis cine image

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at the mid cavity of the left ventricle.

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And the right-hand side is a four-chamber cine image.

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And as I mentioned in the protocol

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section, the bright blood cine imaging

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is really the workhorse for cardiac MRI.

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And for some indications,

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really, the only sequence that we need to use, let's

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say somebody is just getting an evaluation of their

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function, all you need is the bright blood cine images.

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They're the most important for looking at wall motion.

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So how do we use them?

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I find it most helpful to look at the

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wall itself, and if I'm evaluating wall

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motion, I want to see the wall thickening.

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I want to see that the thickening is nice and uniform

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all the way around the entire

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circumference of the heart.

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And then the same thing goes for the long axis cine

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images, in this case, the four-chamber cine image.

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You can see that, for instance, if you look at

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the septum here, the base and mid portion of the

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septum doesn't really thicken a whole lot during

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systole, right there, whereas the lateral wall may be

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a little bit more, with a little bit more motion.

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So here you see some hypokinesis,

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meaning some reduced contraction

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of that wall, whereas in this case, you can see

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the right ventricle, that wall is moving quite

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a lot better than the left ventricular wall.

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So these are the types of things that we

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evaluate on the bright blood cine imaging.

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We're looking for wall motion, and then, which

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I'll touch on later, we also use those cine images

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to evaluate function and actually

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quantify ejection fraction and volumes.

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So bright blood, what are some other names and

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terms that we hear referring to bright blood?

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Well, the most generic term for bright blood imaging

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is balanced steady-state free precession imaging.

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And that's the sort of generic physics-based

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terminology for this particular sequence.

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The trade names that you're going to

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hear are TruFISP for Siemens, FIESTA

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for GE, and Balanced FFE for Philips.

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And what it is at its heart is an ECG

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gated balanced gradient echo sequence.

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You can actually perform them without ECG

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gating, for instance, in abdominal applications.

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You may perform them without gating,

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but generally when we're doing cardiac

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MRI, we're always going to have gating.

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And the nice thing about the bright blood,

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and what makes it so useful, is it has the

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highest signal-to-noise ratio per imaging

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time of all currently available sequences.

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And how does it do that?

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Well, it uses these very, very short TRs and TEs.

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And because they're so short,

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you actually have residual signal left

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over at the end of each excitation.

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And that signal is basically recycled into the next TR,

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using balanced gradients to maximize the signal.

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So, basically, that's the balanced part of

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the balanced steady-state free precession.

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The steady-state part is that you get this

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residual signal that builds up over time

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and eventually reaches a steady state.

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So that's the explanation, sort of the very,

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very low-level explanation of the physics behind

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bright blood steady-state free precession.

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The thing you really have to know about

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these bright blood images is that you can't

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really use them for tissue characterization

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because you have both a mix of T2

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and T1 weighting in these sequences.

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So, you will see that fluid is bright.

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In this case, in the upper right

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hand corner, this is the stomach.

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And you can see that the fluid

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in the stomach is bright.

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There's also some pericardial fluid, a little

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bit of pericardial fluid right here, also bright.

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And then blood is bright,

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you know, obviously from the name.

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But then other T2 bright things such as,

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you know, edema in the myocardium might be bright.

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But the thing that's confusing is T1 is also bright.

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So this is actually a little fat pad

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in the pericardium anteriorly here.

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That's bright.

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If you gave contrast, that's bright.

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So you can't really use bright blood images for tissue

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characterization, which is their one shortcoming

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and something you really need to be aware of.

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What else do you need to know

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about bright blood imaging?

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Well, generally we use them as a cine

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image with about one slice per breath hold.

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If you have a really good breath holder, like a

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young patient, for instance, you can usually squeeze

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out maybe two or even three slices per breath hold.

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But generally, when you keep them high resolution,

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you're limited in the number of slices you can get.

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So it can take quite a while to

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get through the entire heart.

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Most times if we're imaging the heart, we're going to

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have about 12 slices to get through the entire heart.

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And so it'll be about, you know, 12 breath holds or so.

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So it can be quite a while to get through

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the entire set of images you need.

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The biggest limitation that we know about

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for bright blood imaging is that it's very,

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very sensitive to field inhomogeneity.

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Those balanced gradients, you can almost

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think of it like you have these balanced

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gradients that are recycling the signal and

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building up this steady state of signal.

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Well, if you add some sort of artifacts into that whole

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situation, then those artifacts also build up over

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time and also kind of increase into a steady state.

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So, compared to other sequences, you get a lot

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of artifacts related to field inhomogeneity,

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and the things that cause field inhomogeneity are metal.

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So, for instance, if a patient has a device

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or has a lot of iron in the liver, or maybe

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even has some clips around their GE junction

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because they had gastric bypass or something

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like that, you're gonna see a lot of artifacts.

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Another area that we see artifacts is you can

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see how close the stomach is to the heart.

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Well, if you happen to just, just happen to

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have a big stomach, a big bubble of air in the

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stomach right underneath the heart, that can

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actually cause quite a lot of artifacts too.

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So, in those situations where you see a

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lot of artifacts because of these bright

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blood images and their sensitivity to

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field inhomogeneity, what do you do?

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Well, we find that the spoiled gradient echo

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sequences, these are the, kind of the old standard for cine imaging.

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They work a lot better when it comes to artifacts.

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They have less susceptibility. So for instance, in this

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case, this patient actually does have a device.

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You can see this black kind of void

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in the upper left-hand corner of the

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image, that's where the cardiac

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device is on this patient's chest wall.

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And then you can see the lead in their right ventricle.

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But despite all of this, you can still get decent

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imaging of the myocardium and the blood pool.

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Something that really is not going to be

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possible with your standard SSFP images.

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One of the biggest reasons we use bright

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blood imaging is to do quantification

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of cardiac function and cardiac volumes.

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And how does that work?

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Well, this is

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a graphical representation of the Simpsons

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method, which is the method that we use to

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evaluate cardiac volume, and it's very simple.

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The idea here is that you use a summation of

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discs, so each slice is a disc, and when you add

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up all these discs, you get an entire volume.

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So what happens is, with your specialized

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software, you outline the disc using some sort

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of endocardial tracing method, and then the

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area is calculated by combining the circle that

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you measure on the image with the slice thickness.

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And then from that, you can get the

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area and the volume of each slice.

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And then those volumes are added up

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together to get the total volume for the

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left ventricle and the right ventricle.

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And then, basically, you repeat this process

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for both end systole and end diastole.

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That'll give you your end systolic and end

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diastolic volumes, and then from that, you can

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calculate an ejection fraction, and that's it.

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It's pretty simple, actually.

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All right, so let's next talk about different

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limitations that we encounter with cine imaging.

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So this is not specific just to SSFP imaging, but

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rather limitations of just Cine Imaging in general.

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And the way cine imaging works and the

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simplest kind of way to look at it is that

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you're acquiring multiple bits of information

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from separate heartbeats and combining them

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together to make a whole, an entire image.

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So for instance, if you get 30 frames in

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your cine image, then you get a little

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bit of frame 1 through, you know, 30.

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The very, you know, first, say, set of pixels on one

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heartbeat, and then a few more on the next heartbeat,

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and a few more on the next, and then when you

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combine it all at the end, you get a complete image.

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So, the limitations of cine, basically, are due to

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the fact that you're relying on this steady heart

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rate and consistency from heart rate to heart,

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from heartbeat to heartbeat to get good imaging.

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So if you're combining all this data from multiple

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heartbeats and your heartbeats are changing from

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one beat to the next, then you can get blurring.

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So if you take a look at this figure here in the

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upper right-hand corner of the slide, this is

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an example of what can happen with arrhythmia.

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So if you look at the PQRS complex

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here, there's a certain distance

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between this P wave and the next P wave.

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And then when the following P wave comes up,

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it's actually coming up a little bit early.

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And so this part of the image data, which is in

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late diastole for this particular heartbeat,

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is actually now in systole for the next heartbeat.

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So you end up combining image data from both

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diastole and systole together, and you get blurring.

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A similar situation can happen when a patient

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is having difficulty with breath holding.

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In this case, you can have a regular,

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nice, regularl spaced heartbeats with

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a consistent P wave after your QRS.

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But if the patient is inhaling and then exhaling,

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you're going to have different parts of the heart

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in the image from one acquisition to the next.

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So, for instance, on heartbeat A, maybe

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you're looking at the top of the heart.

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But then, if the patient takes in a deep

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breath on heartbeat B, you're going to be

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looking actually at the ascending aorta.

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And then, you know, vice versa, and so up and

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down, up and down as the patient breathes.

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Again, if you have pieces of information

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from different heartbeats that are being

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combined and they aren't exactly the same,

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then you're going to get some blurring.

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So how do we counteract this in cine imaging?

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Well, the most commonly used

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approach is to use real-time imaging.

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It can be used in difficult cases.

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The problem with real-time imaging is that you

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do take a hit on spatial and temporal resolution.

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So you can think of real-time imaging

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basically as like a video camera.

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So rather than combining different pieces of data from

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multiple heartbeats, you're actually just turning on

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the camera and watching what happens in the heart.

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In order to make that happen, you need to acquire

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the images really, really, really quickly.

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And so that's where the spatial and temporal

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resolution sacrifices have to occur.

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You need to basically reduce the spatial

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resolution, reduce the temporal resolution,

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so that you can cram in all the information you can

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in order to get the images as fast as possible.

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And so, I'm going to show you

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an example on this next slide.

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So on the left-hand image here, this is cine

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imaging of somebody with poor breath holding,

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and you can see all the blurring that's occurring,

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especially at the end of systole there.

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You can see diastole looks okay, but then as the

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contractions happen, there's a lot of blurring.

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It would be really hard if you were doing

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contouring and trying to define the wall in

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order to calculate ejection fraction or volumes.

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It would be very difficult in this case.

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So here's the solution.

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Real-time imaging.

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You can see that there's not

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quite the level of detail, right?

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It just looks a little blurry.

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The edges aren't quite as sharp.

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But the nice thing is you don't have that same

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blurring that you have with the other image.

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So you don't have the smearing effect.

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The actual resolution is lower, but you do see nice

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sharp endocardial borders here, and you could, in fact,

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use that software to calculate an ejection fraction.

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You can see this patient actually was in bigeminy.

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If you remember back from med school, that's

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when people have two abnormal heartbeats in a row

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that just keeps repeating over and over again.

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So you can see there's a one, there's a two systolic

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contractions, which can be a problem for the

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standard cine software to figure out, and that's

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why we have the blurring on the breath hold imaging.

Report

Faculty

Stefan Loy Zimmerman, MD

Associate Professor of Radiology and Radiological Science

Johns Hopkins Medicine Department of Radiology and Radiological Science

Tags

Vascular

Trauma

Pericardium

Non-infectious Inflammatory

Neoplastic

Myocardium

Metabolic

MRI

Infectious

Idiopathic

Iatrogenic

Congenital

Cardiac valves

Cardiac

Acquired/Developmental