Trauma, Vasc Malfrms, SAH/Aneurysms, Vein Dz, Intraparenchymal Bleeds Flashcards

1
Q

Cavernous Malformation (aka cavernoma)

What is it? What can it cause?

Associated with what? What increased risk does this conjure?

What if there are multiple?

What can induce them?

CT appearance? MR appearance? CTA appearance?

A
  • A cavernous malformation (also called a cavernoma) is a vascular hamartoma with a very small but definite bleeding risk. The clinical course of a cavernous malformation is variable and the lesion may cause seizures even in the absence of significant hemorrhage.
  • Cavernous malformation is often associated with an adjacent developmental venous anomaly (DVA). There is an increased risk of bleeding if a DVA is present. However, the DVA itself does not have any bleeding risk.
  • When multiple, cavernous malformations represent an inherited disorder called familial cavernomatosis.
  • Cavernous malformations can be induced by radiation treatment to the brain.
  • Noncontrast CT shows a well-circumscribed rounded hyperattenuating lesion. The hyperattenuation is due to microcalcification within the cavernoma__.
  • MRI shows characteristic “popcorn-like” appearance of a lobular mixed signal on T1- and T2-weighted images from blood products of various ages. There is a peripheral rim of hemosiderin which is dark on GRE and T2-weighted image. There is typically no enhancement, but intense enhancement may be seen with a long delay after contrast administration. Cavernous malformations may range in size from tiny (a single focus of susceptibility artifact) to giant.
  • Cavernous malformations are usually occult by vascular imaging (CTA or angiography).
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2
Q

Developmental Venous Anomaly

What is it?

Characteristic appearance?

Clinical management?

A
  • A developmental venous anomaly (DVA) is an abnormal vein that provides functional venous drainage to the normal brain.
  • DVA can usually only be seen on contrast-enhanced images, where it appears as a radially oriented vein with a characteristic caput medusa appearance.
  • A DVA is a Do Not Touch lesion. If resected, the patient will suffer a debilitating venous infarct. The DVA must be preserved if an adjacent cavernous malformation is resected.
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3
Q

Capillary Telangiectasia

What is it?

Medical management?

Imaging appearance? Angiographical appearance?

A
  • A capillary telangiectasia is an asymptomatic vascular lesion composed of dilated capillaries with interspersed normal brain.
  • A capillary telangiectasia is another Do Not Touch lesion.
  • Post-contrast MRI shows a faint, brush-stroke-like enhancing lesion in the brainstem or pons, without mass effect or surrounding edema. GRE may show blooming due to susceptibility.
  • Similar to cavernous malformation, capillary telangiectasia is angiographically occult.
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4
Q

Name the high-flow and low-flow vascular malformations

A
  • High-flow vascular malformations (i.e. with shunting):
    • Arteriovenous Malformation
    • Dural AV Fistula
  • Low-flow vascular malformations (i.e. without shunting):
    • Cavernous Malformation
    • Developmental Venous Anomaly
    • Capillary Telangiectasia
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5
Q

Arteriovenous Malformation

What is it? Where is it normally? Presentation? What kind of hemorrhage doe it usually result it?

What is the Spetzler-Martin scale?

Imaging appearance?

Does it replace or displace brain?

A bleeding AVM may be angiographically occult in what situation?

Factors that increase bleeding risk?

Treatment?

A
  • An arteriovenous malformation (AVM) is a congenital high-flow vascular malformation consisting of directly connecting arteries and veins without an intervening capillary bed.
  • AVM occurs intra-axially and 85% are supratentorial. AVM usually presents with seizures or bleeding (usually parenchymal hemorrhage, rarely subarachnoid). Aneurysms of the feeding arteries or intra-nidal arteries are often seen, which predispose to bleeding.
  • The Spetzler-Martin scale helps to evaluate surgical risk for AVM resection. A large AVM draining to a deep vein in eloquent cortex is high risk, while a small AVM draining to a superficial vein in non-eloquent cortex is low risk.
  • On imaging, AVM is characterized by a vascular nidus (“nest”) containing numerous serpentine vessels that appear as black flow-voids on MRI. There are usually adjacent changes to the adjacent brain including gliosis (T2 prolongation), dystrophic calcification, and blood products (blooming on T2* gradient imaging). The gliosis/encephalomalacia or mineralization seen in the adjacent brain is due to alteration in vascular flow from the AVM.
  • AVM replaces rather than displaces brain. It causes minimal mass effect.
  • Uncommonly, a bleeding AVM may be angiographically occult if the malformed vessels are compressed by the acute hematoma.
  • Factors that increase bleeding risk that are detectable by imaging include intra-nidal aneurysm, venous ectasia, venous stenosis, deep venous drainage, and posterior fossa location.
  • Treatment can be with embolization, stereotactic radiation, or surgical resection.
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6
Q

What is a Vein of Galen malformation?

Between what two structures?

What is the enlarged vein?

Childhood presentation?

Adult presentation?

A
  • Vein of Galen malformation is a type of vascular malformation characterized by arteriovenous fistulae from thalamoperforator branches into the deep venous system.
  • The enlarged vein is actually an enlarged median prosencephalic vein.
  • In childhood, a Vein of Galen malformation is the most common extracardiac cause of high output cardiac failure. Vein of Galen malformation may also be seen in adults, but clinically would be either asymptomatic or may be the cause of Parinaud syndrome due to mass effect in the pineal region.
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7
Q

Dural arteriovenous fistulas

What are they?

What is the primary prognostic feature?

What is the Conard Classification?

A
  • Dural arteriovenous fistulas are a complex group of high-flow lesions characterized by arteriovenous shunts between the meningeal arterioles and dural venules.
  • The primary prognostic feature is the presence and degree of cortical venous drainage.
  • The Conard classification I through IV describes lesions with progressively increased risk of bleeding. Type V is reserved for spinal dAVFs.
    • Type I : No cortical venous drainage. Lowest risk of bleeding.
    • Type IIA : Reflux into dural sinus but not cortical veins.
    • Type IIB : Reflux into cortical veins: 10-20% hemorrhage rate.
    • Type III : Direct cortical venous drainage: 40% hemorrhage rate.
    • Type IV : Direct cortical venous drainage with venous ectasia: 66% hemorrhage rate.
    • Type V : Spinal venous drainage. may
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8
Q

What spaces are can you detect acute extra-axial hemorrhage?

Is it hyperdense, isodense, or hypodense on CT?

Blood must do what before it becomes apparent on CT?

Hyperacute blood or blood in a patient with severe anemia may appear as what density on CT?

A
  • Acute extra-axial hemorrhage (subarachnoid, epidural, or subdural in location) is usually hyperattenuating when imaged by CT; however, blood must clot in order to be hyperattenuating.
  • Hyperacute unclotted blood (and clotted blood in a patient with severe anemia) may be close to water attenuation on CT.
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9
Q

What is the most common cause of subarachnoid hemorrhage?

Where does this SAH tend to occur?

What is the second most common cause?

A
  • Trauma is the most common cause of subarachnoid hemorrhage (SAH), while aneurysm rupture is the most common cause of non-traumatic SAH.
  • Traumatic SAH tends to occur contralateral to the side of direct impact, most often in the superficial cerebral sulci.
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10
Q

Epidural Hematomas

What is an arterial epidural hematoma? Classic cause?

What shape do these form? Does it cross cranial sutures?

What is the swirl sign? What density is low attenuation blood?

What would make these a surgical emergency? What can you do if they are small?

Prevalence of venous epidural hematomas? What would these be due to and where and whom do they occur in?

A
  • An arterial epidural hematoma is an extra-axial collection of blood external to the dura, classically caused by fracture of the squamous portion of the temporal bone and resultant tearing of the middle meningeal artery.
  • An arterial epidural hematoma has a lentiform shape and does not cross the cranial sutures, where the dura is tightly adherent to the cranium.
  • The swirl sign describes mixed high and low attenuation blood within the hematoma and suggests active bleeding. The low attenuation blood is hyperacute unclotted blood while the high attenuation blood is already clotted.
  • A large epidural hematoma is a surgical emergency due to mass effect and risk of herniation, although small epidural hematomas can be conservatively managed with serial imaging.
  • Venous epidural hematomas are far less common than arterial epidurals and are due to laceration of the dural sinuses, usually occurring in the posterior fossa in children.
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11
Q

Intraventricular Hemorrhage

How can these occur?

Patients with IVH are at an increased risk of what and why?

A
  • Intraventricular hemorrhage can occur due to tearing of subependymal veins or from direct extension of subarachnoid or intraparenchymal hematoma.
  • Patients with intraventricular hemorrhage are at increased risk of developing noncommunicating hydrocephalus due to ependymal scarring, which may obstruct the cerebral aqueduct.
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12
Q

What does the coup/countrecoup mechanism describe?

A
  • The coup/contrecoup mechanism of brain trauma describes the propensity for brain to be injured both at the initial site of impact and 180 degrees opposite the impact site, due to secondary impaction against the cranial vault.
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13
Q

What are cortical contusions?

What part of brain do they affect?

A subacute cortical contusion may demonstrate what imaging finding?

How does a chronic contusion appear on CT? How about on MRI?

A
  • A cortical contusion is caused by traumatic contact of the cortical surface of the brain against the rough inner table of the skull.
  • Contusions affect the gyral crests and can occur in a coup or a contrecoup location.
  • A subacute cortical contusion may demonstrate ring enhancement and should be considered in the differential of a ring-enhancing lesion if there is a history of trauma. Enhancement may continue into the chronic stage.
  • A chronic contusion appears as encephalomalacia on CT. MRI is more specific, showing peripheral hemosiderin deposition as hypointense on T2-weighted images and blooming artifact on gradient echo sequences.
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14
Q

Traumatic intraparenchymal hematomas can occur where?

If they occur deeper in the brain, what is the cause?

Similar to cortical contusions, a subacute intraparenchymal hematoma may show what imaging finding?

A
  • Traumatic intraparenchymal hematoma can occur in various locations, ranging from cortical contusion to basal ganglia hemorrhage (due to shearing of lenticulostriate vessels).
  • Similar to a cortical contusion, a subacute intraparenchymal hematoma may show ring enhancement.
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15
Q

Diffuse/Traumatic Axonal Injury

What does it result from and what is it caused by?

Most common locations of DAI?

Grading of DIA? Prognosis?

CT appearance?

MR appearance?

A
  • Diffuse/Traumatic axonal injury - DIA is the result of a shear-strain deformation of the brain.
  • DAI is caused by rotational deceleration and subsequent reacceleration force that exceeds the limited elastic capacity of the axons.
  • The most common locations of DAI include the gray-whiteematter junction, the corpus callosum, and the dorsolateral midbrain. The higher the grade, the worse the prognosis.
    • Grade I DAI involves only the gray-white matter junctions.
    • Grade II DAI involves the corpus callosum.
    • Grade III (most severe) DAI involves the dorsolateral midbrain.
  • CT is relatively insensitive for detection of DAI, although hemorrhagic DAI may show tiny foci of high attenuation in the affected regions.
  • MRI is much more sensitive to detect DAI, although detection relies on multiple sequences, including FLAIR, GRE, and DWI.
    • GRE is extremely sensitive for hemorrhagic axonal injury; however, not all DAI is hemorrhagic.
    • FLAIR is most sensitive for nonhemorrhagic DAI.
    • Diffusion sequences show restricted diffusion in acute DAI due to cytotoxic edema and cell swelling.
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16
Q

Zygomaticomaxillary Complex Fractures

What is the common name for this fracture? What does this fracture cause?

What does the zygoma normally articulate with via what articulations?

ZMC fxs cause disruption of these articulations by fractures through which structures?

A
  • Commonly but, incorrectly known as the tripod fracture, a zygomaticomaxillary complex (ZMC) fracture causes a floating zygoma by disrupting all four of the zygomatic articulations.
  • The zygoma normally articulates with the frontal, maxillary, temporal, and sphenoid bones via the zygomaticofrontal, zygomaticomaxillary, zygomaticotemporal, and zygomaticosphenoid articulations.
  • A ZMC fracture causes disruption of the zygomatic articulations by fractures through the following structures:
    • Lateral orbital rim fracture: Zygomaticofrontal disruption.
    • Inferior orbital rim fracture: Zygomaticomaxillary disruption.
    • Zygomatic arch fracture: Zygomaticotemporal disruption.
    • Lateral orbital wall: Zygomaticosphenoid disruption.
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17
Q

Le Fort Fractures

What does the Le Fort classification describe? All disrupt what buttress and cause detachment of what bone from skull base?

All Le Fort fractures are defined by fractures through what?

Describe each type of Le Fort fractures (fracture lines through what and resulting free movement of which structures?).

A
  • The Le Fort classification describes a predictable pattern of midface fractures, all of which disrupt the pterygomaxillary buttress and cause detachment of the maxilla from the skull base. All Le Fort fractures are defined by fractures through the pterygoid plates.
  • Le Fort I (floating palate) detaches the maxillary alveolus from the skull base.
  • Le Fort II dissociates the central midface from the skull, causing the nose and hard palate to be moved as a single unit.
  • Le Fort III represents a complete midface dissociation.
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18
Q

Subarachnoid Hemorrhage

Most common causes? In what percent of cases is no cause identified?

How does SAH clinically present?

Initial imaging modality? Appearance?

What other things may also have this imaging appearance?

How sensitive is this initial imaging modality? What should you do if its negative in a suspected case of SAH?

What’s the gold standard for evaluating the presence of an aneurysm?

MR appearance?

A
  • Overall, the most common cause of subarachnoid hemorrhage - SAH is trauma. Aneurysm rupture is by far the most common cause of non-traumatic subarachnoid hemorrhage. No cause of the subarachnoid hemorrhage is identified in up to 22% of cases.
  • Clinically, non-traumatic subarachnoid hemorrhage presents with a thunderclap headache and meningismus.
  • Noncontrast CT is the initial imaging modality in suspected subarachnoid hemorrhage. On CT, subarachnoid blood appears as high attenuation within the subarachnoid space.
  • High attenuation material in the subarachnoid space may be due to SAH (by far the most common cause), meningitis, leptomeningeal carcinomatosis, or prior intrathecal contrast administration.
  • Noncontrast CT is >95% sensitive for detecting subarachnoid hemorrhage within the first six hours, with sensitivity slowly decreasing to 50% by day 5. If clinical suspicion for subarachnoid hemorrhage is high with a negative CT scan, the standard of care is to perform a lumbar puncture to look for xanthochromia.
  • If SAH is present on imaging or lumbar puncture shows xanthochromia, catheter angiography is the gold standard to evaluate for the presence of an aneurysm. Several recent studies have shown, however, that CT angiography is equivalent to catheter angiography in the search for a culprit aneurysm in cases of SAH.
  • On MRI, acute subarachnoid hemorrhage appears hyperintense on FLAIR and demonstrates susceptibility artifact on gradient sequences.
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19
Q

DDx for increased FLAIR signal in the subarachnoid space

This is similar to the DDx for what other imaging?

A
  • The differential diagnosis for increased FLAIR signal in the subarachnoid space is similar to the differential for high attenuation subarachnoid material seen on CT, including:
    • SAH
    • Meningitis
    • Leptomeningeal carcinomatosis
    • Residual contrast material.
      • Note that meningitis and carcinomatosis will typically show leptomeningeal enhancement in addition to the abnormal FLAIR signal.
    • Recent oxygen or propofol administration will also cause increased subarachnoid FLAIR signal.
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20
Q

Distribution of SAH

Multiple aneurysms are seen in up to what percent of patients with SAH?

Subarachnoid blood may redistribute if patients present in what way?

Provide what percent of intracranial aneurysms and in what cystern SAH is found in each below:

  • ACOM aneurysm
  • PCOM aneurysm
    • What else can result from a PCOM aneurysm?
  • MCA aneurysm
  • Basilar tip aneurysm
    • What else may appear like a basilar type aneurysm?
A
  • The pattern of subarachnoid hemorrhage may provide a clue to the location of the ruptured aneurysm. However, multiple aneurysms are seen in up to 20% of patients with SAH, and subarachnoid blood may redistribute if the patient was found down.
  • Hemorrhage in the anterior interhemispheric fissure suggests an anterior communicating artery aneurysm (33% of intracranial aneurysms).
  • Hemorrhage in the suprasellar cistern suggests a posterior communicating artery aneurysm (also 33% of intracranial aneurysms). Rarely, P-comm aneurysm rupture can result in isolated subdural hemorrhage.
  • Hemorrhage in the Sylvian fissure suggests a middle cerebral artery aneurysm (20% of intracranial aneurysms).
  • Hemorrhage in the perimesencephalic cistern suggests either a basilar tip aneurysm (5% of intracranial aneurysms), which has a high morbidity, or the relatively benign nonaneurysmal perimesencephalic _subarachnoid hemorrhag_e
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21
Q

Grading of SAH

What are the grading scores?

What are they based on?

Describe the grading criteria.

A
  • The Hunt and Hess score is the clinical grading scale for aneurysmal subarachnoid hemorrhage and is based solely on symptoms, without imaging. Grade I is the lowest grade, with only a mild headache. Grade V is the most severe, with coma or extensor posturing.
  • The Fisher grade classifies the CT appearance of SAH. Grade 1 is negative on CT; grades 2 and 3 are <1 mm thick and >1 mm thick, respectively, and grade 4 is diffuse SAH or intraventricular or parenchymal extension.
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22
Q

What is the most common cause of morbidity and mortality in patients who survive the initial episode of SAH?

The peak incidence of this complication?

What can this complication lead to?

Medical treatment? Endovascular treatment?

What other complication can develop in 20-30% of patients, which is due to what? Treatment?

A
  • Vasospasm is the most common cause of morbidity and mortality in patients who survive the initial episode of subarachnoid hemorrhage. The peak incidence of vasospasm occurs approximately 7 days after the initial ictus.
  • Vasospasm may lead to stroke or hemorrhage.
  • The medical treatment of vasospasm is triple-H therapy of hypertension, hypervolemia, and hemodilution.
  • Endovascular treatment of vasospasm involves intra-arterial infusion of vasodilators.
  • Approximately 20-30% of patients with subarachnoid hemorrhage will develop acute hydrocephalus, due to obstruction of arachnoid granulations. Treatment is ventriculostomy.
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23
Q

Superficial Siderosis

What is it and what is it due to?

Clinical picture?

Imaging appearance?

Imaging workup?

A
  • Superficial siderosis is a condition caused by iron overload of pial membranes due to chronic or repeated subarachnoid bleeding.
  • Clinically, patients with superficial siderosis present with sensorineural deafness and ataxia.
  • On imaging, the iron causes hypointensity on T2-weighted images outlining the affected sulci.
  • Imaging workup includes cranial and spinal imaging to evaluate for a source of bleeding.
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24
Q

Perimesencephalic SAH

What is this? Prognosis?

The hemorrhage must be limited to where and what is the standard of care?

What is this thought to be a cause of?

Clinical presentation? Prognosis?

A
  • Perimesencephalic subarachnoid hemorrhage is a type of nonaneurysmal subarachnoid hemorrhage that is a diagnosis of exclusion with a much better prognosis than hemorrhage due to a ruptured aneurysm.
  • The hemorrhage must be limited to the cisterns directly anterior to the midbrain. The standard of care is to perform catheter angiography twice, one week apart. Both angiograms must be negative. Although the cause of the hemorrhage is unknown, it is thought to represent angiographically occult venous bleeding.
  • Although the clinical presentation of perimesencephalic subarachnoid hemorrhage is similar to aneurysmal SAH (__thunderclap headache), patients generally do well without residual neurological deficits. Some patients may experience mild to moderate vasospasm.
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25
Q

What are the complications of SAH?

A
  • Vasospasm
  • Acute hydrocephalus (due to obstruction of arachnoid granulations)
  • Superficial siderosis (chronic)
26
Q

What is reversible cerebral vasoconstriction syndrome (RCVS)?

Presentation?

What is it characterized by?

A
  • Reversible cerebral vasoconstriction syndrome (RCVS) is a cause of nontraumatic, nonaneurysmal subarachnoid hemorrhage and ischemia.
  • RCVS presents with thunderclap headache and is characterized by prolonged (but reversible) vasoconstriction.
27
Q

What are the morphologically distinct aneurysms?

A
  • Saccular
  • Fusiform
  • Mycotic (infectious)
  • Oncotic (neoplastic)
  • Traumatic (pseudoaneurysm)
28
Q

Saccular Aneurysms

What are these? Most common location? The aneurysm points in what direction?

Seen in what population?

Caused by what?

Non-inherited risk factors?

Inherited risk factors?

What is the aneurysm neck? What is the significance of the neck:body ratio?

Size classification of berry aneurysms? Clinical significance?

Giant aneurysms often present how?

A
  • A saccular (also called berry) aneurysm is a focal outpouching of the arterial wall, most commonly arising at a branch point in the circle of Willis. The aneurysm points in the direction of blood flow leading into the branch point.
  • Saccular aneurysms are seen almost exclusively in adults, with a slight female predominance.
  • Saccular aneurysms are caused by a combination of hemodynamic stress and acquired degeneration of the vessel wall.
  • Non-inherited risk factors for the development of saccular aneurysm include hypertension and inflammatory vascular disease such as Takayasu or giant cell arteritis.
  • Inherited diseases that predispose to aneurysm formation include connective tissue diseases such as Marfan and Ehlers-Danlos, polycystic kidney disease, and neurofibromatosis type I.
  • The aneurysm neck is the opening that connects the aneurysm to the parent vessel and the aneurysm body is the aneurysm sac. The neck__:body ratio affects treatment options.
    • Aneurysms with relatively small necks are generally easier to treat endovascularly with coils.
  • Saccular aneurysms can be classified as small (<1 cm), medium (>1 cm and <2.5 cm), and giant (>2.5 cm). The larger the size, the greater the risk for rupture.
  • Giant aneurysms often present with mass effect, causing cranial nerve palsy.
29
Q

Fusiform Aneurysms

What are these?

These are usually due to what?

Anterior or posterior circulation is affected more?

Contrast to saccular aneurysms

Fusiform aneurysms of which system pose a particularly challenging treatment and why?

A
  • A fusiform aneurysm is segmental arterial dilation without a defined neck. Fusiform aneurysms are usually due to atherosclerosis, but may arise from chronic dissection.
  • The vertebrobasilar system is affected more commonly than the anterior circulation.
  • In contrast to saccular aneurysms, fusiform aneurysms do not occur at branch points. Fusiform aneurysms are much less common than saccular aneurysms.
  • Since there is no aneurysm neck to exclude from the systemic circulation, fusiform aneurysms are more difficult to treat.
  • Fusiform aneurysms of the vertebrobasilar system pose particular challenges, as critical perforating vessels may arise directly from the diseased artery.
30
Q

Mycotic Aneurysms

Account for what percent of all intracranial aneurysms?

What are they due to?

Most common source?

Contrast to saccular aneurysms

High or low risk of rupture?

A
  • Mycotic aneurysms account for only 2-4% of all intracranial aneurysms and are due to septic emboli.
  • Bacterial endocarditis is the most common embolic source.
  • In contrast to saccular aneurysms, mycotic aneurysms form in the distal arterial circulation, beyond the circle of Willis.
  • Mycotic aneurysms are fragile and have a high risk of rupture.
31
Q

What is an oncotic aneurysm?

Give one example that would cause this kind of an aneurysm?

A
  • An oncotic aneurysm is an aneurysm caused by neoplasm.
  • A benign left atrial myxoma may peripherally embolize and cause a distal oncotic aneurysm.
32
Q

Aneurysms due to trauma are most commonly what kind of an aneurysm?

The vessel will exhibit what proximal to the aneurysm?

Where do these tend to occur, which is similar to what other type of aneurysm?

Arteries close to what are prone to dissecting aneurysm? Give to examples.

A
  • Aneurysms due to trauma are most commonly pseudoaneurysms, which don’t contain the typical three histologic layers of the vessel wall.
  • Usually, the vessel will exhibit abnormal luminal narrowing proximal to the aneurysm.
  • Similar to mycotic aneurysms, traumatic pseudoaneurysms tend to occur distally.
  • Arteries close to bony structures (such as the basilar and vertebral artery) are prone to dissecting aneurysms.
33
Q

Cerebral Venous Anatomy

Name and describe the significance of everything!

What are the dural sinuses?

What are the deep cerebral veins?

What is the venous angle?

What are the superficial cerebral veins?

A
  • Dural sinuses:
    • The superior sagittal sinus (and its tributaries) drains the motor and sensory strips.
    • The paired transverse sinuses are usually asymmetric, with the left transverse sinus often hypoplastic.
    • The sigmoid sinus connects to the jugular bulb.
    • The torcular Herophili is the confluence of the superior sagittal sinus, the transverse sinus, and the straight sinus.
  • Deep cerebral veins
    • The deep cerebral veins consist of the paired internal cerebral veins, the basal vein of Rosenthal, and the vein of Galen.
    • The venous angle (red dot in the diagram) is the intersection of the septal vein and the thalamostriate veins. The venous angle is the angiographic landmark for the foramen of Monro.
  • Superficial cerebral veins
    • The vein of Trolard connects superficial cortical veins to the superior sagittal sinus.
    • The vein of Labbé drains the temporal convexity into the transverse or sigmoid sinus.
      • Retraction injury to the vein of Labbé during surgery may lead to venous infarction and aphasia.
34
Q

Venous Thrombosis

What can this lead to in younger patients?

Risk factors?

What is a clue to the diagnosis of venous thrombosis on NCCT? What is the empty delta sign?

MR venogram appearance?

What does venous thrombosis lead to?

A
  • Thrombosis of a cortical vein or a deep venous sinus is one of the more common causes of stroke in younger patients.
  • Risk factors for venous thrombosis include pregnancy, oral contraceptives, thrombophilia, malignancy, and infection.
  • A clue to the diagnosis of venous thrombosis on NCCT is increased density within the thrombosed sinus or cortical vein (the cord sign). On contrast-enhanced CT, the empty delta sign signifies a filling defect in the superior sagittal sinus.
  • MR venogram will show a lack of flow in the thrombosed vein or dural venous sinus.
  • Venous thrombosis leads to venous hypertension, which may cause infarction and parenchymal hemorrhage. There are three characteristic patterns of venous infarction, dependent on the location of the thrombosed vein:
    • Superior sagittal sinus thrombosis -> infarction of the parasagittal high convexity cortex.
    • Deep venous system thrombosis -> infarction of the bilateral thalami.
    • Transverse sinus thrombosis -> infarction of the posterior temporal lobe.
35
Q

Three characteristic patterns of venous infarction, dependent on the location of the thrombosed vein:

  • Superior sagittal sinus thrombosis -> _______?.
  • Deep venous system thrombosis -> ________?.
  • Transverse sinus thrombosis -> _________?.
A
  • There are three characteristic patterns of venous infarction, dependent on the location of the thrombosed vein:
    • Superior sagittal sinus thrombosis -> infarction of the parasagittal high convexity cortex.
    • Deep venous system thrombosis -> infarction of the bilateral thalami.
    • Transverse sinus thrombosis -> infarction of the posterior temporal lobe.
36
Q

What is the first imaging study performed in the emergency setting for a patient with a sudden neurologic deficit, HA, seizure, or altered level of consciousness?

Hyperacute/acute intracranial hemorrhage has what CT appearance relative to brain parenchyma?

What might make acute hemorrhage isoattenuating to water?

A
  • Noncontrast CT is usually the first imaging study performed in the emergency setting for a patient with a sudden neurologic deficit, headache, seizure, or altered level of consciousness.
  • CT is highly sensitive for detection of hyperacute/acute intracranial hemorrhage, which appears hyperattenuating relative to brain parenchyma and CSF.
  • Acute hemorrhage may be nearly isoattenuating to water in severe anemia (hemoglobin <8 mg/dL).
37
Q

What are the physiologic stages of iron in hemoglobin that affect the characteristics MR appearance?

A

Intracellular oxyhemoglobin -> deoxygenation ->

Intracellular deoxyhemoglobin -> oxidation ->

Intracellular methemoglobin -> cell lysis ->

Extracellular methemoglobin -> chelation ->

Hemosiderin and ferritin

38
Q

In general, all stages of hemorrhage are _________ or slightly _____ on T1-weighted

images, except for the methemoglobin stages, which are ______.

A
  • In general, all stages of hemorrhage are isointense or slightly dark on T1-weighted images, except for the methemoglobin stages, which are bright.
39
Q
  • Methemoglobin is _______ on both T1- and T2-weighted images, except for _______ methemoglobin, which is dark on T?-weighted images.
A
  • Methemoglobin is bright on both T1- and T2-weighted images, except for intracellular methemoglobin, which is dark on T2-weighted images.
40
Q

In general, non-hyperacute hemorrhage is ______ on T2-weighted images, with the exception of ________, which is ___________ on T2-weighted images. A hyperacute hematoma, containing primarily oxyhemoglobin, is slightly ________ on T2-weighted images but features a characteristic ________ rim representing deoxygenation at the periphery of the clot.

A
  • In general, non-hyperacute hemorrhage is dark on T2-weighted images, with the exception of extracellular methemoglobin, which is hyperintense on T2-weighted images. A hyperacute hematoma, containing primarily oxyhemoglobin, is slightly hyperintense on T2-weighted images but features a characteristic dark rim representing deoxygenation at the periphery of the clot.
41
Q

The expected evolution of blood products is highly dependent on what?

What is the significance of this?

A
  • The expected evolution of blood products is highly dependent on macrophage elimination of blood breakdown products.
  • This makes the rules of thumb are not applicable to extra-axial blood

and timing is generally not given for extra-axial blood, such as a subdural hematoma.

42
Q

Treatment of Intraparenchymal Hemorrhages

Imaging is performed to evaluate what?

What is the mainstay of treatment?

What can be done for larger hematomas? Why?

What is a particular location of a bleed to treat?

A
  • In most cases, imaging is performed to evaluate for a treatable cause of hemorrhage, such as AVM or aneurysm. The mainstay of treatment of intraparenchymal hemorrhage is supportive, including blood pressure control and normalization of any coagulopathy.
  • Larger hemorrhages can be evacuated surgically if there is significant mass effect or risk of herniation. In particular, a hemorrhage >3 cm in the posterior fossa would generally be treated surgically as there is increased risk of brainstem compression or hydrocephalus from fourth ventricular obstruction.
43
Q

What are the specific stages of parenchymal hematoma on MR?

Describe the physiologic stages and timing of iron in Hb and the resultant T1w and T2w appearances!

A
  • Hyperacute hematoma (<6 hours): Intracellular oxyhemoglobin
  • Acute hematoma (6–72 hours): Intracellular deoxyhemoglobin
  • Early subacute hematoma (3 days to 1 week): Intracellular methemoglobin
  • Late subacute hematoma (1 week to months): Extracellular methemoglobin (after RBC lysis)
  • Chronic sequela of hemorrhage: Hemosiderin and ferritin
    • Remember the bolds and fill in the gaps
44
Q

Hyperacute Intraparenchymal Hematoma

Timeline? Iron state?

This hematoma is composed of what? The hemoglobin is in what magnetic state?

Imaging appearance? Key imaging finding, which is due to what?

This imaging finding is most conspicuous on what sequence?

A
  • (<6 hours): Intracellular oxyhemoglobin
  • A few hours after red cell extravasation, a hyperacute hematoma is primarily composed of intact red cells containing oxygenated hemoglobin, which is diamagnetic.
  • The center of the hematoma will be isointense on T1-weighted images and iso- to slightly hyperintense on T2-weighted images.
  • The key imaging finding of a hyperacute hematoma is a peripheral rim of hypointensity on T2-weighted images due to deoxygenation of the most peripheral red cells. This peripheral dark rim is most conspicuous on GRE sequences.
45
Q

Acute Intraparenchymal Hematoma

Timeline? Iron state?

Imaging appearance?

A
  • (6–72 hours): Intracellular deoxyhemoglobin
  • After the red cells desaturate (lose oxygen), the entire hematoma becomes hypointense on T2-weighted images and iso- to mildly hypointense on T1-weighted images.
46
Q

Early Subacute Intraparenchymal Hematoma

Timeline? Iron state?

This phase is characterized by what molecule? What kind of magnetization does this molecule have?

What interaction does this molecule have with water?

This interaction _____ T1 to cause ________ on T1w images.

Imaging appearance of T2w images?

A
  • (3 days to 1 week): Intracellular methemoglobin
  • The subacute phase is characterized by methemoglobin, which is paramagnetic and undergoes proton-electron dipole-dipole interactions (PEDDI) with water. PEDDI shortens T1 to cause hyperintensity on T1-weighted images. Intracellular and extracellular methemoglobin are both hyperintense on T1-weighted images.
  • In the early subacute phase, blood remains hypointense on T2-weighted images due to the paramagnetic effects of methemoglobin, which remains trapped in the red cells.
47
Q

Late Subacute Intraparenchymal Hematoma

Timeline? Iron state?

T1w and T2w appearance? These are due to what?

Possible enhancement pattern?

A
  • 1 week to months. Extracellular methemoglobin (after RBC lysis).
  • The methemoglobin PEDDI effect persists after cell lysis, causing continued hyperintensity on T1-weighted images.
  • Paramagnetic effects of methemoglobin decrease. Signal intensity on T2-weighted images increases to that of CSF, due to RBC lysis and decrease in protein concentration.
  • There may be peripheral enhancement of a subacute to chronic hematoma.
48
Q

Chronic Sequela of Intraparenchymal Hemorrhage

Timeline? Iron stage?

What happens to the salvaged iron atoms?

Imaging appearance?

A
  • Months. Hemosiderin and ferritin.
  • Salvaged iron atoms are deposited into hemosiderin and ferritin, which become permanently trapped in the brain parenchyma after the blood-brain barrier is restored.
  • Susceptibility effects of the stored iron produce characteristic hypointensity on T2-weighted and GRE images.
  • Chronic hemorrhage may have peripheral enhancement.
49
Q

Name all the intraparenchymal hemorrhage etiologies and specific clues for each!

A
  • Hypertensive
  • Amyloid angiopathy
  • Aneurysmal hemorrhage
  • AVM
  • dAVF
  • Cavernous malformation
  • Venous thrombosis
  • Hemorrhagic neoplasm
  • Hemorrhagic infarct
  • CNS vasculitis
  • Moyamoya
50
Q

Hypertensive Intraparenchymal Hemorrhage

Prevalence of this type of hemorrhage for spontaneous adult intraparenchymal hemorrhage?

This is due to what?

Etiology?

Characteristic locations?

In addition to location, what other imaging findings suggest this type of bleed?

What other additional findings on GRE or SWI can one detect?

A
  • Chronic hypertension is the most common cause of spontaneous adult intraparenchymal hemorrhage and is due to the secondary microangiopathic effects of chronic hypertension.
  • Chronic hypertension causes arteriolar smooth muscle hyperplasia, which eventually leads to smooth muscle death and replacement with collagen. The resultant vascular ectasia predisposes to hemorrhage.
  • Hypertensive hemorrhage occurs in characteristic locations in the basal ganglia, thalamus, and cerebellum.
  • In addition to location, imaging (MRI or CT) findings suggestive of a hypertensive bleed include additional stigmata of hypertensive microangiopathy, such as periventricular white matter disease and prior lacunar infarcts.
  • An additional MR-specific finding suggesting hypertensive hemorrhage is the presence of microhemorrhages on T2* (GRE or SWI) in the basal ganglia or brainstem.
51
Q

Cerebral Amyloid Angiopathy

What is it

The spontaneous form of CAA occurs almost exclusively in what population? What if you see it in a younger population?

In addition to being a risk factor for hemorrhage, what else is CAA a risk factor for?

What is the main clinical clue for CAA?

What is the primary imaging feature to clue you in to CAA?

Important secondary MRI findings?

Contrast to hypertensive microhemorrhages

A
  • Cerebral amyloid angiopathy (CAA) is amyloid accumulated within the walls of small and medium arteries, ultimately causing vessel weakness and increased risk of hemorrhage.
  • While the spontaneous form of CAA occurs almost exclusively in elderly adults (in which population it is the second most common cause of nontraumatic hemorrhage), a hereditary variant has an earlier age of onset.
  • In addition to being a risk factor for hemorrhage, CAA can also occlude the lumens of small vessels and contribute to microangiopathy.
  • The main clinical clue that a hemorrhage is secondary to CAA is that the patient is a normotensive elderly adult.
  • The primary imaging feature to suggest CAA is the location of hematoma, which is almost always lobar or cortical, usually in the parietal or occipital lobes.
  • An important secondary MRI finding is multiple microhemorrhages seen on T2* (GRE or SWI) within the brain parenchyma. In contrast to the microhemorrhages associated with hypertension, CAA microhemorrhages are in the cortex, not in the basal ganglia.
52
Q

Aneurysmal Intraparenchymal Hemorrhage

Aneuysmal hemorrhage is the most common cause of what kind of hemorrhage?

An intraparenchymal hematoma is adjacent to what part of an aneurysmal hemorrhage?

What can help you figure out the localization of an aneurysm?

Study of choice for nontraumatic SAH?

A
  • Aneurysmal hemorrhage is by far the most common cause of nontraumatic subarachnoid hemorrhage. If an intraparenchymal hematoma is due to an aneurysm, the hematoma is usually adjacent to the ruptured aneurysm dome.
  • The pattern of subarachnoid blood may help localize the aneurysm; however, if the patient was found down, then the blood will settle in the dependent portion of the brain, confounding localization.
    • anterior interhemispheric fissure suggests an anterior

communicating artery aneurysm (33% of intracranial aneurysms

* **suprasellar cistern** suggests a posterior communicating artery aneurysm (also 33% of intracranial aneurysms).
* **sylvian fissure** suggests a middle cerebral artery aneurysm (20% of intracranial aneurysms).​
* **perimesencephalic** **cistern** suggests either a basilar tip aneurysm (5% of intracranial aneurysms) * **CT angiography** is the study of choice for further evaluation of nontraumatic subarachnoid hemorrhage.
53
Q

Intraparenchymal Hemorrhage Secondary to AVM

What is an AVM?

In case of AVM rupture, the resultant hematoma is usually located where?

Contrast to CAA?

A
  • An arteriovenous malformation is a congenital lesion consisting of abnormal high-flow arteriovenous connections without intervening normal brain.
  • In case of AVM rupture, the resultant hematoma is usually parenchymal. In contrast to amyloid angiopathy, a hematoma from a bleeding AVM tends to affect younger patients.
54
Q

Intraparenchymal Hemorrhage Secondary to dAVF

What is a dAVF?

Two most common types?

Imaging appearance?

A
  • Dural AV fistulas are a group of high-flow vascular malformations characterized by a fistulous connection between a meningeal artery and a venous sinus or cortical vein.
  • Cavernous sinus (cavernous-carotid fistula) and posterior fossa dAVFs are the most common types.
  • Imaging may show enlarged feeding arteries and enlarged or occluded dural sinuses, or enlarged cortical veins.
55
Q

Intraparenchymal Hemorrhage Secondary to Venous Thrombosis

What does venous thrombosis cause to increase the risk of infarction and parenchymal hemorrhage?

A
  • Thrombosis of cortical veins or deep venous sinuses leads to venous hypertension, which may cause infarction and parenchymal hemorrhage.
56
Q

Intraparenchymal Hemorrhage Secondary to Hemorrhagic Neoplasm

Can this be the initial presentation of a brain tumor?

Most common primary brain tumor to hemorrhage?

What are the extracranial primary tumors known to cause hemorrhagic mets? What about lung and breast CA?

What drug may cause an increased risk of hemorrhagic mets?

Clues to the dx to suggest underlying tumor causing hemorrhage?

Presence of what finding strongly suggest metastatic disease?

What do you do in cases where the diagnosis is unclear?

A
  • Occasionally, the initial presentation of a brain tumor may be acute hemorrhage.
  • The most common primary brain tumor to cause hemorrhage is glioblastoma.
  • There are a relatively limited number of extracranial primary tumors known to cause hemorrhagic metastases, including:
    • Choriocarcinoma.
    • Melanoma.
    • Thyroid carcinoma.
    • Renal cell carcinoma.
      • MNEMONIC: MRCT
    • Although breast and lung cancer rarely cause hemorrhage on a per-case basis, they are such common cancers overall that they can always be considered when a hemorrhagic neoplasm is suspected.
  • Patients treated with bevacizumab (trade name Avastin) may be at increased risk for hemorrhagic metastasis.
  • Clues to the diagnosis of an underlying tumor causing hemorrhage include more-than-expected edema surrounding a hyperacute hematoma and heterogeneous blood product signal, suggesting varying breakdown stages of hemoglobin.
  • The presence of multiple enhancing masses strongly suggests metastatic disease.
  • In cases where the diagnosis is unclear, a follow-up MRI should be performed once the initial hemorrhage improves. If a tumor is present, the MRI may show a delay in the expected evolution of blood products, persistent edema, and enhancement of the underlying tumor.
57
Q

Intraparenchymal Hemorrhage Secondary to Cavernous Malformation

What is a cavernous malformation?

Classic imaging appearance of a non-hemorrhagic cavernous malformation?

What imaging finding clues you into a cavernous malformation as a cause for an intraparenchymal hematoma?

Role of angiographic imaging?

A
  • A cavernous malformation is a vascular hamartoma that consists of low-flow endothelial-lined blood vessels without intervening normal brain.
  • Although non-hemorrhagic cavernomas have a characteristic MRI appearance (with “popcorn-like” lobular mixed/high signal on T1- and T2-weighted images and a dark peripheral hemosiderin rim), once bleeding occurs, the resultant hematoma has nonspecific imaging features. The presence of a developmental venous anomaly adjacent to a hematoma may suggest the diagnosis of a recently hemorrhaged cavernoma__.
  • Angiography plays no role in the diagnosis. Cavernous malformations are angiographically occult.
58
Q

Intraparenchymal Hemorrhage Secondary to Hemorrhagic Transformation of Infarct

Presentation?

What percent of patients receiving thrombolytic therapy experience hemorrhagic conversion?

What are the risk factors for hemorrhagic conversion after thrombolytic therapy?

Is this included in the AHA exclusion criteria?

A
  • In most cases, the clinical or imaging diagnosis of stroke is made before hemorrhagic transformation occurs; however, hemorrhage may occasionally be the presenting feature of an infarct.
  • More commonly, symptomatic hemorrhage occurs post-infarct in approximately 6-12% of patients receiving thrombolytic therapy.
  • Noncontrast CT can identify risk factors for hemorrhagic transformation after thrombolytic therapy, including a relatively large region of hypoattenuation and a dense artery sign. Note that per AHA guidelines, neither of these findings is an exclusion criterion for the administration of IV tPA.
59
Q

Intraparenchymal Hemorrhage Secondary to Vasculitis

Vasculitis affecting CNS are primary or secondary to CNS?

Most common presenation of vasculitis in CNS?

Standard MRI appearance?

Noninvassive vascular imaging? Sensitivity?

Most sensitive test? Appearance?

A
  • Vasculitis affecting the CNS may be primary or secondary to systemic vasculitides.
  • The most common presentation of vasculitis is cerebral ischemia. Less commonly, vasculitis may present with frank hemorrhage.
  • Standard MRI imaging shows of vasculitis show multiple foci of T2 prolongation in the basal ganglia and subcortical white matter.
  • Noninvasive vascular imaging (CTA or MRA) is relatively insensitive to small vessel involvement but may show irregularity of involved large or medium vessels.
  • Angiography is the most sensitive test and shows multifocal areas of stenosis and dilation.
60
Q

Intraparenchymal Hemorrhage Secondary to Moyamoya

What is Moyamoya? What does it lead to?

What is the puff of smoke appearance?

What is the ivy sign?

Patients with moyamoya are susceptible to forming what and in what location?

Perfusion study results?

A
  • Moyamoya is a non-atherosclerotic vasculopathy characterized by progressive stenosis of the intracranial internal carotid arteries and their proximal branches, which leads to the proliferation of fragile lenticulostriate collateral vessels.
  • Angiography of the enlarged basal perforating arteries gives a puff of smoke appearance.
  • The ivy sign on FLAIR MRI represents tubular branching hyperintense structures within the sulci, representing cortical arterial branches that appear hyperintense due to slow collateral flow.
  • Patients with moyamoya disease are susceptible to aneurysm formation, especially in the posterior circulation.
  • Perfusion studies show decreased flow in the affected vascular regions.