0:00

This is a wonderful illustrative example of

0:04

some pathology that I want to point out.

0:07

So, this was a patient who had a fall from a ladder and

0:13

had extensive soft tissue injury to the scalp.

0:17

That was demonstrated, as you can see, more posteriorly,

0:20

both on the right side and the left side.

0:22

You'll notice that the patient has

0:24

some surgical staples here,

0:26

which are from the correction of the lacerations that the

0:30

patient had and has active hemorrhage in the scalp.

0:34

However, as you scroll through here,

0:37

you'll notice that there doesn't seem to be all that much

0:40

with regard to the brain injury

0:44

despite the scalp abnormality.

0:47

This is a case where you have to be pretty

0:51

sharp to pick up the abnormality.

0:53

I'm going to go from the thick

0:54

sections to the thin sections,

0:58

and I'm happy to report that I detected the abnormality

1:05

at the time of the original CT scan.

1:09

And what one sees is just a small amount

1:13

of intraventricular hemorrhage,

1:16

and it seems to be just on the left side.

1:19

So, how is it that a patient who has had significant head

1:24

trauma is showing just a small amount

1:28

of intraventricular hemorrhage?

1:29

Well, this is a Yousem pearl.

1:33

If you see intraventricular hemorrhage and no other

1:38

area of hemorrhage in the brain to explain it,

1:42

the reason for the hemorrhage is a shearing injury

1:46

of the corpus callosum.

1:47

Now, I can't demonstrate for you that

1:50

shearing injury of the corpus callosum.

1:52

You may wonder,

1:53

is it a little bit low density here

1:56

in the corpus callosum at the top?

1:59

I cannot demonstrate it,

2:01

but I can assure you that on subsequent MRI scans,

2:05

you will find a shearing injury of the corpus callosum

2:08

if you have a patient with head trauma that

2:12

only has intraventricular hemorrhage.

2:15

Sometimes you'll see intraventricular hemorrhage in

2:17

association with a parenchymal hemorrhage that

2:20

perforates into the ventricular system.

2:23

Or sometimes you'll have blood in the ventricles

2:27

in a patient who has diffuse subarachnoid hemorrhage

2:30

and it gets resorbed into it.

2:31

In this case,

2:32

we don't see any subarachnoid hemorrhage.

2:33

We don't see a subdural hematoma.

2:35

We don't see a parenchymal hematoma.

2:37

All we have is a small amount of intraventricular

2:40

hemorrhage. When you see that,

2:42

order an MRI with susceptibility weighted

2:46

imaging on this patient.

2:48

Let's check the MRI.

2:50

On your MRI scan,

2:53

you want to look at the susceptibility weighted images.

2:58

Why is that?

2:59

Subtle hemorrhage may be missed on fast spin echo scanning

3:05

because of the refocusing 180 degree pulses with fast

3:10

spi echo imaging that actually leads to decreased

3:13

sensitivity to blood products.

3:15

This, although there is motion artifact,

3:17

this is our patient's susceptibility weighted scanned.

3:22

And what one sees is the hemorrhage that was

3:25

detected on the CT scan in the ventricle.

3:30

Not only that, but as we go further superiorly,

3:33

sure enough, as Dr. Yousem predicted,

3:37

there is this dark signal intensity at the top of the

3:40

corpus callosum and in the splenium

3:42

of the corpus callosum.

3:44

This is deoxyhemoglobin demonstrated on a susceptibility

3:49

weight scan within the top of the corpus callosum

3:52

and splenium of the corpus callosum,

3:54

identifying this patient as having had

3:56

a significant shearing injury that tore

4:00

the largest white matter tract in the brain,

4:02

the corpus callosum.

4:04

You'll also note on the susceptibility wade scan that there

4:07

are additional areas of dark signal intensity here at the

4:10

gray white matter junction in the right frontal lobe,

4:15

in the left parietal lobe, in the left occipital lobe

4:19

and more superiorly in the frontal lobe,

4:23

again, at the typical location for a shearing injury,

4:26

the gray white junction,

4:28

which we'll talk about shortly when we talk about

4:31

rotational injuries and diffuse axonal injury.

4:35

But my point really was to remember

4:38

intraventricular hemorrhage,

4:40

isolated intraventricular hemorrhage in the face of head

4:44

trauma is due to a tear in the splenium of the

4:48

corpus callosum.

4:49

Until proven otherwise, recommend MRI.

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

0:00

This is a wonderful illustrative example of

0:04

some pathology that I want to point out.

0:07

So, this was a patient who had a fall from a ladder and

0:13

had extensive soft tissue injury to the scalp.

0:17

That was demonstrated, as you can see, more posteriorly,

0:20

both on the right side and the left side.

0:22

You'll notice that the patient has

0:24

some surgical staples here,

0:26

which are from the correction of the lacerations that the

0:30

patient had and has active hemorrhage in the scalp.

0:34

However, as you scroll through here,

0:37

you'll notice that there doesn't seem to be all that much

0:40

with regard to the brain injury

0:44

despite the scalp abnormality.

0:47

This is a case where you have to be pretty

0:51

sharp to pick up the abnormality.

0:53

I'm going to go from the thick

0:54

sections to the thin sections,

0:58

and I'm happy to report that I detected the abnormality

1:05

at the time of the original CT scan.

1:09

And what one sees is just a small amount

1:13

of intraventricular hemorrhage,

1:16

and it seems to be just on the left side.

1:19

So, how is it that a patient who has had significant head

1:24

trauma is showing just a small amount

1:28

of intraventricular hemorrhage?

1:29

Well, this is a Yousem pearl.

1:33

If you see intraventricular hemorrhage and no other

1:38

area of hemorrhage in the brain to explain it,

1:42

the reason for the hemorrhage is a shearing injury

1:46

of the corpus callosum.

1:47

Now, I can't demonstrate for you that

1:50

shearing injury of the corpus callosum.

1:52

You may wonder,

1:53

is it a little bit low density here

1:56

in the corpus callosum at the top?

1:59

I cannot demonstrate it,

2:01

but I can assure you that on subsequent MRI scans,

2:05

you will find a shearing injury of the corpus callosum

2:08

if you have a patient with head trauma that

2:12

only has intraventricular hemorrhage.

2:15

Sometimes you'll see intraventricular hemorrhage in

2:17

association with a parenchymal hemorrhage that

2:20

perforates into the ventricular system.

2:23

Or sometimes you'll have blood in the ventricles

2:27

in a patient who has diffuse subarachnoid hemorrhage

2:30

and it gets resorbed into it.

2:31

In this case,

2:32

we don't see any subarachnoid hemorrhage.

2:33

We don't see a subdural hematoma.

2:35

We don't see a parenchymal hematoma.

2:37

All we have is a small amount of intraventricular

2:40

hemorrhage. When you see that,

2:42

order an MRI with susceptibility weighted

2:46

imaging on this patient.

2:48

Let's check the MRI.

2:50

On your MRI scan,

2:53

you want to look at the susceptibility weighted images.

2:58

Why is that?

2:59

Subtle hemorrhage may be missed on fast spin echo scanning

3:05

because of the refocusing 180 degree pulses with fast

3:10

spi echo imaging that actually leads to decreased

3:13

sensitivity to blood products.

3:15

This, although there is motion artifact,

3:17

this is our patient's susceptibility weighted scanned.

3:22

And what one sees is the hemorrhage that was

3:25

detected on the CT scan in the ventricle.

3:30

Not only that, but as we go further superiorly,

3:33

sure enough, as Dr. Yousem predicted,

3:37

there is this dark signal intensity at the top of the

3:40

corpus callosum and in the splenium

3:42

of the corpus callosum.

3:44

This is deoxyhemoglobin demonstrated on a susceptibility

3:49

weight scan within the top of the corpus callosum

3:52

and splenium of the corpus callosum,

3:54

identifying this patient as having had

3:56

a significant shearing injury that tore

4:00

the largest white matter tract in the brain,

4:02

the corpus callosum.

4:04

You'll also note on the susceptibility wade scan that there

4:07

are additional areas of dark signal intensity here at the

4:10

gray white matter junction in the right frontal lobe,

4:15

in the left parietal lobe, in the left occipital lobe

4:19

and more superiorly in the frontal lobe,

4:23

again, at the typical location for a shearing injury,

4:26

the gray white junction,

4:28

which we'll talk about shortly when we talk about

4:31

rotational injuries and diffuse axonal injury.

4:35

But my point really was to remember

4:38

intraventricular hemorrhage,

4:40

isolated intraventricular hemorrhage in the face of head

4:44

trauma is due to a tear in the splenium of the

4:48

corpus callosum.

4:49

Until proven otherwise, recommend MRI.

Report

Faculty

David M Yousem, MD, MBA

Professor of Radiology, Vice Chairman and Associate Dean

Johns Hopkins University

Lesson

Imaging Mastery Series: Brain Trauma Pre-Course Activities

Lesson

Imaging Trauma

Lesson

Hemorrhage and Hematoma

Lesson

Trauma - Surgical Indications

Lesson

Non-accidental Trauma

Lesson

Secondary Trauma Injuries

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