Interactive Transcript
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Okay. In this video we're gonna talk about, uh,
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specifically annular measurements that are used for optimal device sizing and
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selection. Uh,
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these form part of the more global aortic root assessment that's performed with
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cardiac ct. Um, and we've divided this up into a couple different videos. Um,
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so another important part of the aortic root assessment that we won't discuss in
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this video is identification of high risk anatomy. And those additional, uh,
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points are gonna be discussed in the, uh, measurements of the aortic root video.
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Um, and those include things like low coronaries, neuro sinuses, and, um,
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calcification as well. Um,
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so here in this video we're gonna focus on the annulus,
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which is the most important, um, measurement, uh,
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for deciding on what device can be used, uh, in the patient. So first,
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uh, before we get into how to measure the annulus,
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I just wanna take a quick step back and talk about why we measure the annulus
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with ct. Um, and that really has to do with, uh,
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the concept of paravalvular leak, um, also known as paravalvular regurgitation.
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And this is, uh, really simple. Conceptually,
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it's an incomplete seal between the transcatheter valve and the aortic annulus.
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So there's a gap between the edges of the device and the annulus.
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And that gap allows blood to flow retrograde from the aorta into the left
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ventricle. So, uh,
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we know from prior studies that this is associated with increased mortality and
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poor functional status. Um,
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and so we want to avoid paravalvular leak as much as possible.
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There's also some association with valve and annular calcifications that disrupt
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apposition of the stent to the annulus. Um,
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and we're gonna actually talk about that in a different video. Uh,
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the annular calcification video. So here's just some data, um,
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from the, uh, previous trial. This is the partner trial, um,
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two-year follow-up data. Uh, and the thing I just wanna point out here, uh,
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is that this is mortality death from any cause, uh,
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and patients with no paravalvular leak had significantly reduced
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mortality compared to any patients with either mild or severe, uh,
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paravalvular leak. Um, and this, uh, slide here shows that, um,
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even among patients with mild versus moderate disease, they both,
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those groups still tended to do fairly poorly, um,
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sort of hammering home this point that we really wanna avoid paravalvular leak
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as much as possible.
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The reason I'm talking about this is that paravalvular leak, like I mentioned,
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is really behind the whole push to perform CT for TAVR assessment.
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Originally in the early TAVR trials, echo was used to size the annulus, uh,
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and they found that the echo measurements, which you see up here, um,
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which use a single dimensional measurement and then extrapolate them into the
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area of a circle, um, were inadequate. Um,
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and that's because the echo measurements basically perform this type of
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diameter,
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and they extrapolate to a circle when the real aortic annulus is an oval shaped.
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And, um, these, uh,
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mathematical assumptions made by echo resulted in undersizing of the devices.
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And
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That undersizing led to increased paravalvular leak.
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This was tested in a randomized control trial,
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and that trial showed that the paravalvular leak was twice as frequent in the
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echo sized group versus the CT size group. And, you know,
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basically from that day forward, uh,
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CT has been the test of choice for sizing devices for tavr.
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So now in order to understand, uh, the aortic annulus and how to measure,
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we need to understand the aortic root anatomy. Um,
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and basically the aortic root is this part of the heart that connects up to the
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aortic itself. And we have this wide part called the sinuses.
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And then within the sinuses you have the aortic valve cusps. These cusps, um,
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insert on the aortic annulus and the,
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the annulus is considered the lowest point where these cusps insert. Um,
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and you sort of take a virtual ring from those, uh, lowest points.
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I'll show that in another image in a second.
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So here's sort of a, a short axis, um,
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reconstruction from, uh, a CT compared to a long axis reconstruction.
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To give you an idea of what we're talking about, um,
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if you take this short axis reconstruction here on the right,
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you can see the three different valve leaflets.
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And then as we march inferiorly to towards the annulus,
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you see these leaflets start to disappear. And then at the level of the annulus,
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that's when the leaflets transition to being completely outside of your field of
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view. Uh, and now you see just this rounded, um,
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actually oval shape structure here,
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and the leaflets are attached just above that point.
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And so this is our annulus and this is, uh,
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basically where the device is gonna sit.
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And this determines the boundaries of the device itself. Um,
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so here's one other image, and this is from the literature.
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I think this is a nice, uh, figure. It's a lot of colors,
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so it can be a little confusing. And anybody who's colorblind, I apologize. Uh,
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this is hard to evaluate. Um, I give the reference down here below,
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but these red lines, uh,
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are the actual edges of the attachment of the cusps of the aortic valve
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to the aortic root. And you can see that they have a,
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a high commissure up here between the two valves, and then they swing down low.
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Um, here this basal point and this green thing is the
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annulus, which is made by the,
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the ring form between all the three different basal attachment sites.
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And so when we go through the case, I'll show you how to do this, um,
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and attain this annular measurement with ct.
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So what are the measurements that we get? We tend to get the maximum diameter,
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uh, from, uh, along the long axis of this oval shaped annulus,
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and then the perpendicular, um, as well as the perimeter and the area.