0:01

This is a CT scan and some MR images in

0:04

a three-year-old child with a seizure,

0:07

and the patient happens to have a

0:10

birthmark on the right side of their face.

0:14

If we look up on the CT scan,

0:17

we're seeing this area of increased

0:19

density along the cortical margins.

0:24

And we're overlaying it, we're seeing slight

0:26

prominence of the CSF space as compared to the

0:31

contralateral side, suggestive of volume loss.

0:36

If we look at the MR, we see

0:39

confirmation of volume loss.

0:43

We're also seeing what looks like

0:46

asymmetric prominence of the diploic

0:48

space overlying this area of volume loss.

0:53

This is in the overlying areas

0:55

of the right frontal bone.

0:57

This prominence of the diploic space

1:00

is known as the Dyke Davidoff Masson

1:01

phenomenon, where chronic volume loss

1:04

results in focal prominence of the diploic

1:08

space overlying the region of volume loss.

1:11

Possibly could be thought of as a

1:14

compensatory way to fill in some of the space.

1:18

The underlying brain, we're

1:21

seeing cortical thinning.

1:23

and loss of subcortical white matter.

1:27

If we go to the T1 post-contrast image, we're

1:31

seeing here these linear areas of enhancement

1:38

representing transmantle veins, veins that

1:40

go from the cortex to the deep venous system.

1:45

We're also seeing Linear leptomeningeal

1:49

enhancement overlying some of the areas

1:51

of cortical thinning and volume loss.

1:55

Well, why is this?

1:57

If we look on the T2-weighted image again,

2:01

beyond the brain, where we see less

2:05

than we normally would in this region, and

2:07

beyond the overlying bone, where we talked

2:09

about the Dyke David Auf Messon phenomenon,

2:11

in between, we can see cortical veins.

2:15

predominantly drain the cortex.

2:17

They're a part of the superficial

2:18

venous drainage system.

2:21

Notice overlying this region of volume loss,

2:23

we're not seeing signs of cortical veins.

2:27

The brain cortex has a smaller

2:29

volume than the white matter, but it

2:31

is much more metabolically active.

2:34

So therefore it has significant

2:35

need for venous drainage.

2:40

In the absence of venous drainage, because of

2:43

the no cortical veins overlying this region,

2:46

what happens to the draining venous blood?

2:49

Well, you can have transmantle collaterals

2:54

going to the deep venous system, or you

2:57

can have leptomeningeal collaterals that

3:00

take it almost laterally to get the blood

3:03

to a region where there are cortical veins.

3:06

What does that do?

3:07

That allows there to be venous drainage.

3:09

But in the absence of the normal venous

3:13

drainage, you get chronic venous congestion.

3:17

What happens with chronic venous congestion?

3:20

It results in chronic venous ischemia, results

3:23

in volume loss, and dystrophic mineralization.

3:30

The dystrophic mineralization can also

3:31

be seen on susceptibility weighted

3:33

imaging, where we see this ribbon-like

3:36

susceptibility hypointensity along the cortex.

3:41

This actually allows us to see it with better

3:44

delineation than we do on this CT scan, even.

3:48

So this chronic venous ischemia results

3:51

in transmantle collaterals, chronic

3:55

venous ischemia, volume loss, and one

3:59

analogy I've heard that's relevant is

4:02

that calcium is the tombstone to an

4:07

if you think about it like that, these

4:08

areas with dystrophic mineralization,

4:10

there has been injury to the brain.

4:13

That's why there's been volume loss.

4:15

Injured brain has the propensity

4:18

of being epileptogenic.

4:19

So the patients get seizures.

4:22

This vascular abnormality with the resultant

4:25

volume loss and dystrophic mineralization

4:28

and abnormal venous collaterals ends up

4:32

being ipsilateral to the facial birthmark.

4:37

This is known as

4:38

encephalotrigeminal angiomatosis.

4:42

Encephalo for brain, trigeminal

4:44

because the birthmark is in the

4:45

trigeminal nerve distribution.

4:47

Angiomatosis because of the blood

4:49

vessel proliferation here and

4:52

abnormalities in the venous drainage.

4:54

So encephalo-trigeminal angiomatosis

4:56

is the more formal or medical

4:59

name for Sturge-Weber syndrome.

5:01

So this patient has Sturge-Weber syndrome.

Sturge Weber Syndrome

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

0:01

This is a CT scan and some MR images in

0:04

a three-year-old child with a seizure,

0:07

and the patient happens to have a

0:10

birthmark on the right side of their face.

0:14

If we look up on the CT scan,

0:17

we're seeing this area of increased

0:19

density along the cortical margins.

0:24

And we're overlaying it, we're seeing slight

0:26

prominence of the CSF space as compared to the

0:31

contralateral side, suggestive of volume loss.

0:36

If we look at the MR, we see

0:39

confirmation of volume loss.

0:43

We're also seeing what looks like

0:46

asymmetric prominence of the diploic

0:48

space overlying this area of volume loss.

0:53

This is in the overlying areas

0:55

of the right frontal bone.

0:57

This prominence of the diploic space

1:00

is known as the Dyke Davidoff Masson

1:01

phenomenon, where chronic volume loss

1:04

results in focal prominence of the diploic

1:08

space overlying the region of volume loss.

1:11

Possibly could be thought of as a

1:14

compensatory way to fill in some of the space.

1:18

The underlying brain, we're

1:21

seeing cortical thinning.

1:23

and loss of subcortical white matter.

1:27

If we go to the T1 post-contrast image, we're

1:31

seeing here these linear areas of enhancement

1:38

representing transmantle veins, veins that

1:40

go from the cortex to the deep venous system.

1:45

We're also seeing Linear leptomeningeal

1:49

enhancement overlying some of the areas

1:51

of cortical thinning and volume loss.

1:55

Well, why is this?

1:57

If we look on the T2-weighted image again,

2:01

beyond the brain, where we see less

2:05

than we normally would in this region, and

2:07

beyond the overlying bone, where we talked

2:09

about the Dyke David Auf Messon phenomenon,

2:11

in between, we can see cortical veins.

2:15

predominantly drain the cortex.

2:17

They're a part of the superficial

2:18

venous drainage system.

2:21

Notice overlying this region of volume loss,

2:23

we're not seeing signs of cortical veins.

2:27

The brain cortex has a smaller

2:29

volume than the white matter, but it

2:31

is much more metabolically active.

2:34

So therefore it has significant

2:35

need for venous drainage.

2:40

In the absence of venous drainage, because of

2:43

the no cortical veins overlying this region,

2:46

what happens to the draining venous blood?

2:49

Well, you can have transmantle collaterals

2:54

going to the deep venous system, or you

2:57

can have leptomeningeal collaterals that

3:00

take it almost laterally to get the blood

3:03

to a region where there are cortical veins.

3:06

What does that do?

3:07

That allows there to be venous drainage.

3:09

But in the absence of the normal venous

3:13

drainage, you get chronic venous congestion.

3:17

What happens with chronic venous congestion?

3:20

It results in chronic venous ischemia, results

3:23

in volume loss, and dystrophic mineralization.

3:30

The dystrophic mineralization can also

3:31

be seen on susceptibility weighted

3:33

imaging, where we see this ribbon-like

3:36

susceptibility hypointensity along the cortex.

3:41

This actually allows us to see it with better

3:44

delineation than we do on this CT scan, even.

3:48

So this chronic venous ischemia results

3:51

in transmantle collaterals, chronic

3:55

venous ischemia, volume loss, and one

3:59

analogy I've heard that's relevant is

4:02

that calcium is the tombstone to an

4:07

if you think about it like that, these

4:08

areas with dystrophic mineralization,

4:10

there has been injury to the brain.

4:13

That's why there's been volume loss.

4:15

Injured brain has the propensity

4:18

of being epileptogenic.

4:19

So the patients get seizures.

4:22

This vascular abnormality with the resultant

4:25

volume loss and dystrophic mineralization

4:28

and abnormal venous collaterals ends up

4:32

being ipsilateral to the facial birthmark.

4:37

This is known as

4:38

encephalotrigeminal angiomatosis.

4:42

Encephalo for brain, trigeminal

4:44

because the birthmark is in the

4:45

trigeminal nerve distribution.

4:47

Angiomatosis because of the blood

4:49

vessel proliferation here and

4:52

abnormalities in the venous drainage.

4:54

So encephalo-trigeminal angiomatosis

4:56

is the more formal or medical

4:59

name for Sturge-Weber syndrome.

5:01

So this patient has Sturge-Weber syndrome.

Report

Description

Faculty

Asim F Choudhri, MD

Chief, Pediatric Neuroradiology

Le Bonheur Children's Hospital

Lesson

Rare MSK Diagnoses

Lesson

Rare Neuro Diagnoses

Lesson

Rare Cardiac Diagnoses

Lesson

Rare Body Diagnoses

Sturge Weber Syndrome