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Ankle MRI: Additive Gradient Echo Sequence

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Now we're going to illustrate the value,

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the power, the integrity of the 3D gradient echo,

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but not just any gradient echo, not field

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echo, not simple gradient echo, not GRASS, not

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FLASH, not FISP, but additive gradient echo

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imaging known as ADDIGE, MERGE, MEDIC, MFFE.

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Very powerful signal-to-noise sequences

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that allow for very thin slices.

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In this case, we've done

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1.7-millimeter cuts, contiguous,

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no separation, to allow for reconstruction.

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Although, typically, I like to

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have about 50% overlap.

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How thin can you go with these pulsing sequences?

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You can go down to about 0.5 millimeters.

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So, these are

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1.7s contiguous, acquired in the sagittal

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projection using gradient echo, which,

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which you know is powerful for cartilage,

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for the detection of bodies, and for tendons.

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It's also a very good supplementary sequence

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because of its high spatial detail for ligaments.

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So we're scrolling along and we see,

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look at that short plantar ligament.

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Oh, that is beautiful.

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We see the plantar fascia.

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Oh, that's beautiful.

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We're also besot with magic angle

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effect on gradient echo imaging.

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But there's a method to my madness here.

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So if I click this upper button,

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which I've already done, I can

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take this and reproduce a coronal.

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It's a straight coronal, but I

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don't want a straight coronal.

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I would like a paracoronal.

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I want a coronal that shows me

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the critical ligament in the foot.

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Now granted, there are critical ligaments in

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the ankle, and we're going to talk about those

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later on, especially when we get to the ankle.

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But in the foot, the critical

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ligament is the Lisfranc ligament.

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So I'm going to angle absolutely parallel to

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the long axis of the foot and plantar flexion.

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Now, let's scroll.

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There's our navicular for orientation.

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Let's find our medial cuneiform.

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That's easy, right there.

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We find our medial cuneiform.

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We find the connection of

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C1, medial cuneiform, to M2.

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And we are looking at the Lisfranc ligament

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complex, of which there are plantar components.

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There they are.

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Out of which there are middle components.

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There they are.

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And they will be discussed in detail

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when we have Lisfranc ligament injuries.

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So you can do that with just about any ligament.

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For instance, here are some

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intercuneiform ligaments.

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Wow.

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Now let's go over to the axial projection.

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This is straight axial.

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But you know what?

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I don't really want a straight axial.

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I want a curved axial.

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Because my peroneus brevis,

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and longus are curving.

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So let's curve, shall we?

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Let's make them perpendicular

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to the peroneus longus.

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There's the peroneus longus.

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Let's scroll it.

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We're perpendicular to it.

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It's beautiful, and then it turns gray.

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Is that gray magic angle effect, or is it real?

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It's real.

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But that will be another subject.

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Which, by the way, we've already

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covered in the magic angle effect,

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so go back and look at that vignette.

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Now let's go back up to the peroneus

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brevis, and let's angle absolutely

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perpendicular to the brevis.

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And we've got it.

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Now, when the foot is plantar flexed,

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one caveat, the tendons, especially the peroneus

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brevis, is going to be pushed or slammed up

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against the back of the malleolus and flattened.

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And this sometimes will obscure tears.

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But if you have a tear, you will see a very

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well-defined, bright split that separates the tendon

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in two, and it will look something like this.

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You'll see one limb of the tendon, the other limb

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of the tendon, and right in the very center of

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it will be some high signal intensity that is

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well-defined, separating those two components.

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We don't have that here.

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We have an intact, compressed tendon.

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This illustrates the strength of gradient echo

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imaging with proper reconstruction and proper

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creativity on the part of the imager to come

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up with correct and proper diagnoses on some

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very small structures, such as ligaments.

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The axial projection would also be a projection

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to look at the anterior tib-fib ligament.

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It'll be the projection to look at

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the anterior talofibular ligament.

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But usually we like it to be

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a little more perpendicular.

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So let's see if we can get it a

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little more perpendicular this way.

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And let's see if we can find and define

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the anterior talofibular ligament.

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Not so much.

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And the reason is too much swelling.

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So we would go back to our T2.

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Define a ligament, and believe me, it's there.

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It's on a prior vignette.

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It's perfect.

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It's thin.

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It's smooth.

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So a little too much hyperintensity

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present here to actually see the ligament

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with this particular pulsing sequence,

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even though it is a thin section.

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So, also illustrating that you have to

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go back and forth between the proper

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sequences to get the right answer.

Report

Description

Faculty

Stephen J Pomeranz, MD

Chief Medical Officer, ProScan Imaging. Founder, MRI Online

ProScan Imaging

Tags

Musculoskeletal (MSK)

MSK

MRI

Foot & Ankle

Acquired/Developmental

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