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T2 Mapping

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Okay, this next topic is T2 mapping cardiac MRI.

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T2 mapping cardiac MRI is another mapping

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technique, similar to T1 mapping as just described.

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It's used for direct quantitative

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measurement of the T2 time of tissue.

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It's useful for detection of edema.

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And in most situations, you're

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probably going to find it,

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it's more reliable than dark

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blood images, with less artifact.

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So, um, if you take a look at this image on the right

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hand side of the slide, uh, if you do a lot of dark

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blood T2 imaging, you often see something like this

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here in the upper left-hand corner, which is that you

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have signal dropout for the myocardium of interest,

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uh, which is not particularly useful.

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With a lot of expertise and trial and error,

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a lot of times you can get pretty good,

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reproducible dark blood T2-weighted images.

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However, I have to say, of all the various sequences

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that we do, that this one is the hardest to really

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get good quality imaging all the time. The T2 mapping

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sequences are a little more forgiving in general.

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It seems to, in my experience, work more consistently.

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And then the nice thing about that is,

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just like T1 mapping, you get a number.

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And so you're not left scratching your head with,

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as you are with the T2 dark blood, you know,

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is this a little bit of edema, or is it normal?

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You can use a number and use a cut

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point to decide whether or not

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you see edema in this particular patient.

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So, how do they work?

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They're bright blood or, um,

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Turbo Spin Echo-based sequences

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that, similar to T1 curve, use varied T2

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preparation times to sample the T2 weighted

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tissues after various T2 preparation times.

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They're helpful in myocarditis or

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acute infarction to identify edema.

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I also have to note that I think

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they're helpful in sarcoidosis as well.

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If you're looking for acute involvement of sarcoidosis.

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Not infrequently, I find that we'll have patients

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referred for sarcoid, and you'll see some scar.

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But then the question will be, well, is this

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active sarcoid or is this old sarcoid, and the

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presence of edema that matches the scar would

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suggest this is more of an active process.

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Here's an example of one of

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the T2 preparation techniques.

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This is an SSFP, or steady-state free precession,

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based technique pulled out of the literature.

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And in this technique, they basically use three

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different acquisitions with different T2 preparations.

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Um, the bottom line is each

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one is essentially a longer TE.

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So you have a T2 prep of zero and then elongating TEs

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of 24 and 55, uh, which allows more time for T2 decay.

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And that T2 decay curve is created.

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And from that curve can be created a

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pixel-by-pixel plot of the T2 time.

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Just like with T1, we have normal reference T2

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values available from this normal reference range

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paper, uh, which is extremely useful for any type of

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reference you're trying to find for a whole variety

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of different measurements that we do in cardiac MRI.

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In T2, um, there's a decent body of literature

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out there looking at the normal T2 times.

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Um, you can see here in the right side of this

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table, um, normal T2 times range around the kind of

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low to mid-fifties, um, depending on technique.

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Generally, if you're doing three Tesla, you're

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going to find that T2 times are a little longer.

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Although if you look here at this graph,

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the lowest T2 time is the one from

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this Philips 3T at 45 milliseconds.

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So it's not perfect.

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And for that reason, it's really important

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to establish site-specific reference ranges.

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That's accomplished by basically

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acquiring a whole bunch of cases.

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And if you have patients who you know are normal

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in terms of they get evaluated for rule-out

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HCM, rule-out sarcoidosis, and the case ends up

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being normal, then you can use those to establish

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local reference ranges to figure out what

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your local norms are, because there's always a

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little bit of difference between every scanner.

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And that's useful to identify the correct T2.

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So how do we use T2 clinically?

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I would say, like I said, sarcoid

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is a really important use.

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And then the biggest use, particularly now

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with all of the COVID-related issues that we're

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facing and COVID myocarditis, I think myocarditis

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is really a key application of T2 mapping.

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If you're having any familiarity with myocarditis,

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the Lake Louise criteria were the original way to

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diagnose myocarditis, and they included basically

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early gadolinium enhancement, late gadolinium

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enhancement, and then also the T2 ratio from

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dark blood T2 images compared to normal muscle.

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The problem with that whole thing was that nobody

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wants to acquire early gad enhancement images.

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It's kind of a pain and, you know, waste time.

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It's just more time in the scanner.

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And then the T2 dark blood images,

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as we've talked about, are often unreliable.

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So the new Lake Louise criteria includes both

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T2 and T1 mapping, which is really helpful.

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And the bottom line for this is if you have to

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support the diagnosis of myocarditis, you'd like

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to see a T1 abnormality, and that can be either

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abnormal native T1, increased ECV, or regional LGE.

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So that's all shown in this bottom row right here.

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So you want to have some sort of sequence that shows

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abnormal T1 and a sequence that shows abnormal T2.

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And so that can be either your dark blood images

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if they worked out well for you, or a T2 map.

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And so it's nice to be able to get

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all of these things in one protocol

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and then have a much more reliable

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way to evaluate for myocarditis.

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And then down below you can, you know,

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you can have these cases where, um,

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you know, it's kind of a borderline case.

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Maybe you have a T2 and not a T1, or T1 and not a T2.

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Um, and if you have some supportive criteria,

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um, like perhaps a systolic dysfunction

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or pericarditis, that might push you

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to say, this is probably myocarditis,

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although it doesn't meet all the criteria.

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What's an abnormal T2?

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Well, in a paper that was used to establish

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this Lake Louise criteria, they had a

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number of 57 milliseconds that they used.

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You know, I think for me clinically,

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probably about, you know, 60 milliseconds

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or so is a good number to keep in your head.

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You know, if you see something above 60, that's

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probably abnormal, but again, you really want

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to establish your local reference ranges to make

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sure that that's the correct number for you.

Report

Faculty

Stefan Loy Zimmerman, MD

Associate Professor of Radiology and Radiological Science

Johns Hopkins Medicine Department of Radiology and Radiological Science

Tags

Vascular

Pericardium

Non-infectious Inflammatory

Myocardium

Metabolic

MRI

Infectious

Idiopathic

Congenital

Cardiac

Acquired/Developmental