Diagnostic Imaging of Stroke

Mohamed Zaitoun
Assistant Lecturer-Diagnostic Radiology
Department , Zagazig University Hospitals
Egypt
FINR (Fellowship of Interventional
Neuroradiology)-Switzerland
zaitoun82@gmail.com

Knowing as much as
possible about your enemy
precedes successful battle
and learning about the
disease process precedes
successful management

Vascular Territories
a) Vascular Anatomy
b) Cerebral Arterial Territory
c) Watershed Infarcts
d) Lacunar Infarcts
e) Posterior Reversible Encephalopathy
Syndrome (PRES)
f) Cerebral Venous Territory
g) Cerebral Venous Thrombosis

a) Vascular Anatomy :
1-Internal Carotid Artery
2-Circle of Willis
3-Middle Cerebral Artery
4-Anterior Cerebral Artery
5-Persistent Carotid-Basilar Connections

1-Internal Carotid Artery :
-Cervical (C1) : doesn’t branch within the neck
-Petrous (C2) : fixed to bone as the ICA enters the skull
base , so a cervical carotid dissection is unlikely to
extend intracranially
-Lacerum (C3) : no branches
-Cavernous (C4) :
*Meningohypophyseal trunk arises from the
cavernous carotid to supply the pituitary , tentorium
and dura of the clivus
*Inferolateral trunk also arises from C4 to supply the 3rd
, 4th
& 6th
cranial nerves as well as the trigeminal
ganglion

-Clinoid Segment (C5) : the carotid rings are two dural rings that
mark the proximal & distal portions of the clinoid segment of
the ICA , the carotid rings prevent an inferiorly located
aneurysm from causing intracranial SAH with rupture
-Supraclinoid (C6-C7) : gives off several key arteries :
1-Ophthalmic artery :
-Supplies the optic nerve , it takes off just distal to the distal
carotid ring in 90 % of cases and can be used as a landmark
for the distal ring
-Aneurysms located superior to this ring can result in
subarachnoid hemorrhage
2-PCOM :
-Is an anastomosis to the posterior circulation
-A fetal PCA is a variant supplied entirely by the ipsilateral ICA
via an enlarged PCOM
3-Anterior choroidal artery :
-Supplies several critical structures , despite its small size , it
supplies the optic chiasm , hippocampus and posterior limb of
the internal capsule

Lateral projection of a left common carotid artery injection that displays the
order of branching in the intracranial carotid including 1: ophthalmic , 2:
posterior communicating , 3: anterior choroidal and 4: anterior cerebral
arteries

*Critical small arteries arising from the Circle of Willis:
-The A1 segment of the ACA travels above the optic
nerves and give off the recurrent artery of Heubner
which supplies the caudate head & anterior limb of
the internal capsule , the A1 segment also gives rise
to the medial lenticulostriate perforator vessels
which supply the medial basal ganglia
-Just outside the circle of Willis , the MCA gives rise to
the lateral lenticulostriate perforator vessels to
supply the lateral basal ganglia including the lateral
putamen , external capsule and the posterior limb of
internal capsule

Recurrent artery of Heubner infarction

Medial lenticulostriate arteries infarction

Lateral lenticulostriate infarction , note the inverted comma-shaped
hypodense left lenticular nucleus (red dotted lines) , the anterior limb of
the left internal capsule (yellow arrow) is also involved by the ischemic
infarction while the head of the left caudate nucleus (blue dotted lines) is
spared

-The PCOM travels between the optic tract and the 3rd
cranial nerve giving off anterior thalamoperforator
vessels , PCOM aneurysm may cause cranial nerve III
palsy
-The PCA gives off thalamoperforators to supply the
thalamus
-Artery of Percheron is a variant where there is a
dominant thalamic perforator supplying the
ventromedial thalami bilaterally and the rostral
midbrain arising from a P1 PCA segment , an artery
of Percheron infarct will result in bilateral
ventromedial thalamic infarction with (pattern 1) or
without (pattern 2) midbrain infarction (the infarct
may be V-shaped if the midbrain is involved , deep
venous thrombosis may also result in bilateral
thalamic infarcts

DSA of the left vertebral injection , lateral (A) and anteroposterior (B) views
and a coronal CTA image (C) show a large unpaired thalamic perforating
artery (arrows) arising from the proximal P1 segment supplying the
bilateral thalami (i.e. Artery of Percheron)

FLAIR at the level the thalamus (A & C) and midbrain (B & D) show bilateral
paramedian thalamic and midbrain involvement (pattern 1), notice the
hyperintense signal intensity along the pial surface of the midbrain
interpeduncular fossa representing the V sign (B and D)

Axial FLAIR (A and B) and DWI (C and D) images at the level of the thalamus
(A & C) and midbrain (B & D) demonstrate infarction of the bilateral
paramedian thalami without midbrain involvement (pattern 2)

Axial FLAIR through the midbrain show a V-shaped hyperintense signal
intensity along the pial surface of the midbrain at the interpeduncular
fossa (the V sign)

-The anterior choroidal artery is the most distal
branch of the ICA , it supplies the optic chiasm
, hippocampus and posterior limb of the
internal capsule

Anterior choroidal artery infarction , acute infarct is noted involving the
posterior limb of right internal capsule as well as the head of the right
hippocampus

-2D frontal view following right ICA
injection , the appearance of the carotid
circulation is normal , Note the early
bifurcation of MCA (normal variant)
1 ICA – cervical segment
2 ICA – vertical petrous segment
3 ICA – horizontal petrous segment
4 presellar (Fischer C5) ICA
6 horizontal (Fischer C4) intracavernous
ICA
9 ophthalmic artery
10 & 11 proximal and distal supraclinoid
segment ICA
12 posterior communicating artery
13 anterior choroidal artery
14 internal carotid artery bifurcation
15 A1 segment of ACA
17 recurrent artery of Heubner
20 proximal A2 segment ACA
21 callosomarginal branch ACA
28 pericallosal branch of ACA
31 M1 segment of MCA
32 lateral lenticulostriate arteries
33 bifurcation/trifurcation of MCA
34 anterior temporal lobe branches of
MCA
35 orbitofrontal branch of MCA
43 sylvian point
44 opercular branches of MCA
45sylvian (insular) branches of MCA

5-Persistent Carotid-Basilar Connections :
-Overview of persistent fetal anterior-posterior
connections :
*A number of carotid to basilar connections are
formed during embryogenesis , these fetal
anterior-posterior circulation connections
normally regress before birth
*Occasionally , a fetal carotid-basilar connection
may persist after birth , each anomalous
connection is named for the structures
adjacent to its course in the head & neck

-Persistent Trigeminal Artery :
*The most common persistent carotid-basilar
connection and has an association with
aneurysms
*The persistent trigeminal artery courses
adjacent to the trigeminal nerve , angiography
shows a characteristic trident or tau sign
(resembling the Greek letter τ) on the lateral
view due to the artery’s branching system
*Saltzman type I connects to the basilar artery
while Saltzman type II connects to the
superior cerebellar artery

Lateral left common carotid angiogram obtained during the arterial phase
shows the persistent trigeminal artery coursing posteriorly to supply the
distal basilar artery , the tau configuration (dotted lines) is also apparent

MRA shows lateral persistent trigeminal artery Saltzman type 1
(arrows) , note the hypoplastic vertebral artery (arrowhead)

-Less common carotid to basilar connections :
*The hypoglossal , otic and proatlantal intersegmental arteries
are rare persistent carotid-basilar connections
-Persistent primitive hypoglossal artery (HA) :
*Artery named for its association with 12th nerve
*Second most common after PTA , persistent vessel arises from
ICA at C1 to C3 segments , enters the skull through anterior
condylar or hypoglossal canal (not through the foramen
magnum) and courses posteromedially to continue as
terminal segment of the VA and BA
*The contralateral VA, if present, generally terminates in the
posterior inferior cerebellar artery

b) Cerebral Arterial Territory :
1-Posterior Inferior Cerebellar Artery
2-Superior Cerebellar Artery
3-Branches from vertebral and basilar artery
4-Anterior Choroidal artery
5-Lenticulostriate arteries
6-Anterior cerebral artery
7-Middle cerebral artery
8-Posterior cerebral artery

1-Posterior Inferior Cerebellar Artery (PICA in blue)
-The PICA territory is on the inferior occipital
surface of the cerebellum and is in equilibrium
with the territory of the AICA in purple which
is on the lateral side
-The larger the PICA territory , the smaller the
AICA and vice versa

Left-sided PICA infarction , notice the posterior extension , the
infarction was the result of a dissection (blue arrow)

Left sided PICA infarction, in unilateral infarcts there is always a sharp delineation in the midline
because the superior vermian branches do not cross the midline but have a sagittal course, this
sharp delineation may not be evident until the late phase of infarction, in the early phase, edema
may cross the midline and create diagnostic difficulties, infarctions at pontine level are usually
paramedian and sharply defined because the branches of the basilar artery have a sagittal
course and do not cross the midline, bilateral infarcts are rarely observed because these
patients do not survive long enough to be studied but sometimes small bilateral infarcts can
be seen

2-Superior Cerebellar Artery (SCA in grey)
-The SCA territory is in the superior and tentorial
surface of the cerebellum

SCA , cerebellar infarction in the region of the superior cerebellar artery and
also in the brainstem in the territory of the PCA , notice the limitation to
the midline

3-Branches from Vertebral and Basilar artery
-These branches supply the medulla oblongata
(in blue) and the pons (in green)

4-Anterior Choroidal artery (AchA in blue)
-The AChA originates from the posterior wall of
the ICA between origin of PCOM which is 2-5 mm
proximally and the internal carotid termination,
which is 2-5 mm distal to the AChA
The territory of the AChA is part of the hippocampus ,
the posterior limb of the internal capsule , optic tract
, mid brain , lateral geniculate nucleus and choroid
plexus of the anterior part of the temporal horns of
the lateral ventricles
-It has 2 segments , cisternal and intraventricular
segments

Uncommon infarction in the hippocampal region , part of the
territory of the anterior choroidal artery and the PCA are
involved

5-Lenticulostriate Arteries
-The lateral LSA (in orange) are deep penetrating
arteries of the middle cerebral artery (MCA)
-Their territory includes most of the basal ganglia
-The medial LSA (indicated in dark red) arise from
the ACA (usually the A1 segment)
-Heubner's artery is the largest of the medial
lenticulostriate arteries and supplies the
anteromedial part of the head of the caudate and
anteroinferior internal capsule

-The territory of the lateral lenticulostriate
perforating arteries of the MCA is indicated
with a different color from the rest of the
territory of the MCA because it is a well-
defined area supplied by penetrating branches
which may be involved or spared in infarcts
separately from the main cortical territory of
the MCA

Vascular supply to the basal ganglia

CT and T2W-gradient echo image of a hemorrhagic infarction
limited to the territory of the lateral lenticulostriate arteries

6-Anterior Cerebral Artery (ACA in red)
-The ACA supplies the medial part of the frontal
and the parietal lobe and the anterior portion
of the corpus callosum , basal ganglia and
internal capsule

-A1 segment : from origin to ACOM and gives rise
to medial lenticulostriate arteries (inferior parts
of the head of the caudate and the anterior limb
of the internal capsule)
-A2 segment : from ACOM to bifurcation of
pericallosal and callosomarginal arteries
-A3 segment : major branches (medial portions of
frontal lobes , superior medial part of parietal
lobes , anterior part of the corpus callosum)

1-Straight sinus
2-Internal cerebral vein
3-ACA (A2)
4-ACA (A3)
5-Callosomarginal artery
6-Pericallosal artery
7-Corpus callosum

7-Middle cerebral artery (MCA in yellow)
-The cortical branches of the MCA supply the
lateral surface of the hemisphere except for
the medial part of the frontal and the parietal
lobe (anterior cerebral artery) and the inferior
part of the temporal lobe (PCA)
-The deep penetrating LSA branches are
discussed before

CT+C , infarction in the territory of the MCA , there is extensive gyral
enhancement (luxury perfusion) , sometimes this luxury perfusion
may lead to confusion with tumoral enhancement

8-Posterior cerebral artery (PCA in green)
-P1 extends from origin of the PCA to the posterior
communicating artery contributing to the circle
of Willis
-Posterior thalamoperforating arteries branch off
the P1 segment and supply blood to the midbrain
and thalamus
-Cortical branches of the PCA supply the
inferomedial part of the temporal lobe , occipital
pole , visual cortex and splenium of the corpus
callosum

-Deep or proximal PCA strokes cause ischemia in
the thalamus and / or midbrain as well as in
the cortex
-Superficial or distal PCA infarctions involve only
cortical structures
-Only about 5% of ischemic strokes involve the
PCA or its branches

Patient with acute vision loss in the right half of the visual field ,
CT shows an infarction in the contralateral visual cortex , i.e
left occipital lobe

PCA infarction , notice the loss of gray / white matter differentiation in
the region of the left occipital lobe

c) Watershed Infarcts :
-Watershed infarcts occur at the border zones
between major cerebral arterial territories as a
result of hypoperfusion
-There are two patterns of border zone infarcts:
1-Cortical border zone infarctions :
-Infarctions of the cortex and adjacent subcortical
white matter located at the border zone of ACA /
MCA and MCA / PCA

2-Internal border zone infarctions :
-Infarctions of the deep white matter of the
centrum semiovale and corona radiata at the
border zone between lenticulostriate
perforators and the deep penetrating cortical
branches of the MCA or at the border zone of
deep white matter branches of the MCA and
the ACA

A patient with an occlusion of the right internal carotid artery , the hypoperfusion in
the right hemisphere resulted in multiple internal border zone infarctions, this
pattern of deep watershed infarction is quite common and should urge you to
examine the carotids

Small infarctions in the right hemisphere in the deep border zone (blue arrowheads)
and also in the cortical border zone between the MCA & PCA territory (yellow
arrows) , there is abnormal signal in the right carotid (red arrow) as a result of
occlusion

Small infarctions in the deep border zone and in the cortical border zone
between the MCA & PCA territory in the left hemisphere

Infarctions in the deep borderzone and in the cortical borderzone between the ACA
and MCA territory , the abnormal signal intensity in the right carotid is the result of
an occlusion

d) Lacunar Infarcts :
-Lacunar infarcts are small infarcts in the deeper
parts of the brain (basal ganglia , thalamus ,
white matter) and in the brain stem
-Lacunar infarcts are caused by occlusion of a
single deep penetrating artery

-Lacunar infarcts account for 25% of all ischemic
strokes
-Atherosclerosis is the most common cause of
lacunar infarcts followed by emboli
-25% of patients with clinical and radiologically
defined lacunes had a potential cardiac cause
for their strokes

T2W- and FLAIR image of a Lacunar infarct in the left thalamus , on the
FLAIR image the infarct is hardly seen , there is only a small area of
subtle hyperintensity

e) Posterior Reversible Encephalopathy
Syndrome (PRES) :
-It is also known as reversible posterior
Leukoencephalopathy syndrome (RPLS)
-It classically consists of potentially reversible
vasogenic edema in the posterior circulation
territories but anterior circulation structures
can also be involved

-Many causes have been described including
hypertension , eclampsia and preeclampsia ,
immunosuppressive medications such as
cyclosporine
-The mechanism is not entirely understood but is
thought to be related to a hyperperfusion state ,
with blood brain barrier breakthrough ,
extravasation of fluid potentially containing
blood or macromolecules and resulting cortical or
subcortical edema

-The typical imaging findings of PRES are most
apparent as hyperintensity on FLAIR images in
the parieto-occipital and posterior frontal
cortical and subcortical white matter , less
commonly , the brainstem , basal ganglia and
cerebellum are involved

Patient with reversible neurological symptoms , the
abnormalities are seen both in the posterior circulation as
well as in the basal ganglia

Four days later most of the abnormalities have disappeared

f) Cerebral Venous Territory :
-There is great variation in the territories of
venous drainage

g) Cerebral Venous Thrombosis :
1-Etiology :
-Cerebral venous thrombosis results from occlusion
of a venous sinus and / or cortical vein and
usually is caused by a partial thrombus or an
extrinsic compression that subsequently
progresses to complete occlusion
-Dehydration, pregnancy, a hypercoagulable state
and adjacent infection (eg, mastoiditis) are
predisposing factors

2-Diagnosis :
-Cerebral venous thrombosis is an elusive
diagnosis because of its nonspecific
presentation
-It often presents with hemorrhagic infarction in
areas atypical for arterial vascular distribution

MRA with non-visualization of the left transverse sinus, since the venous anatomy is
variable, this can be due to absence of the transverse sinus or thrombosis, the T1
clearly demonstrates, that there is a transverse sinus on the left, so the MRA
findings are due to thrombosis

The same patient , CT shows the dense thrombosed transverse
sinus (yellow arrow) , the FLAIR shows the venous infarction
in the temporal lobe

Thrombosis of deep cerebral veins
-The clinical presentation of thrombosis of the
deep cerebral venous system are severe
dysfunction of the diencephalon reflected by
coma and disturbances of eye movements and
pupillary reflexes , usually this results in a
poor outcome

-However , partial syndromes without a decrease in
the level of consciousness or brainstem signs
exist which may lead to initial misdiagnoses
-Deep cerebral venous system thrombosis is an
underdiagnosed condition when symptoms are
mild and should be suspected if the patient is a
young woman , if the lesions are within the basal
ganglia or thalamus and especially if they are
bilateral

Patient with deep cerebral vein thrombosis , notice the bilateral infarctions in
the basal ganglia

The same patient , there is absence of flow void in the internal
cerebral veins, straight sinus and right transverse sinus (blue
arrows) , on the MRA the right transverse sinus is not visualized

Acute Arterial Infarct - CT appearance
1-Normal
2-Initial Signs
3-Later Signs
4-Contrast Enhancement
5-Arterial Occlusion
6-Perfusion Defect

1-Normal :
-Initial appearances often normal in first few
hours , larger infarcts more prominent

2-Initial Signs :
a) Low Density Region
b) Mass Effect
c) Hyperdense Artery

a) Low Density Region :
1-Loss of grey / white matter differentiation is a
feature of acute infarction and is the earliest
radiological abnormality (thought to be due to
decreased cerebral blood volume)

Normal GWM differentiation Loss of GWM differentiation

There is some hypodensity and swelling in the left frontal region with
effacement of sulci compared with the contralateral side

2-The typical appearance of a cortical infarct is a
bland wedge-shaped area of low attenuation
involving both grey and white matter

-MCA infarction : on CT
an area of
hypoattenuation
appearing within six
hours is highly specific for
irreversible ischemic
brain damage
-The reason we see
ischemia on CT is that in
ischemia cytotoxic edema
develops as a result of
failure of the ion-pumps ,
these fail due to an
inadequate supply of
ATP , an increase of brain
water content by 1% will
result in a CT attenuation
decrease of 2.5 HU

Left MCA infarction , CT shows hypoattenuating foci throughout the
left sided white matter (arrows) and sulcal effacement in the left
MCA territory consistent with infarction

3-The (insular ribbon sign) is a finding of early
MCA infarction describes the loss of gray-
white matter differentiation in the insula , the
normal striated appearance of this area is
replaced by a swollen homogeneous area of
low attenuation

Insular ribbon sign due to acute MCA infarction , CT without contrast shows
subtle loss of the gray-white differentiation in the right insular cortex
(yellow arrows) , gray-white differentiation is preserved on the normal left
side

-Insular ribbon sign ,
this refers to
hypodensity and
swelling of the insular
cortex , it is a very
indicative and subtle
early CT-sign of
infarction in the
territory of the MCA
-This region is very
sensitive to ischaemia
following MCA
occlusion than other
portions of the MCA
territory because it
has the least potential
for collateral supply
from the ACA & PCA

**This figure shows :
-The insular cortex is located along the Sylvian fissure
overlying the external capsule where a ribbon of
normal cortex should be appreciable (red arrows)
-In the setting of MCA infarction , cytotoxic edema leads
to hypoattenuation such that the normal insular
ribbon is no longer visible (blue arrows)
-The left image shows a very early infarct (within the first
few hours) while the right image shows a more
established infarct (greater than 4 hours old)

4-Alternatively , the basal ganglia may disappear
as the infarcted grey matter acquires the
same CT attenuation as the surrounding white
matter , obscuration of the lentiform nucleus
(putamen & globus pallidus) is caused by loss
of gray-white matter differentiation at the
border of the lentiform nucleus and the
posterior limb of the internal capsule

Factor 1st Day 1st Week 1st Month <1Month
Stage Acute Acute Subacute Chronic
CT density Subtle
decrease
Decrease Hypodense Hypodense
MRI T2W: edema T2W: edema Varied T1W dark, T2W
bright
Mass effect Mild Maximum Resolving Atrophy
Hemorrhage No Most likely
here
Variable MRI detectable
Enhancement No Yes; maximum
at 2-3 weeks
Decreasing No

b) Mass Effect :
-Local effacement of the cerebral sulci and
fissures may be followed by more diffuse
brain swelling
-Maximal swelling usually occurs after 3-5 days
-Infarcts that do not have a typical appearance
must be differentiated from other solitary
intracranial masses

*N.B. : D.D. of a Solitary Intracerebral Mass
1-Primary Brain Tumor
2-Metastases
3-Arterial Infarct
4-Venous Infarct
5-Abscess
6-Acute Demyelinating Plaque
7-Hematoma
8-Cerebritis / Encephalitis
9-Aneurysm

1-Primary Brain Tumor :
-High grade tumors tend to have most mass
effect (tumor & surrounding edema)
-Heterogenous with areas of necrosis
(Glioblastoma)
-May infiltrate and involve (cross) corpus
callosum
-Variable enhancement but tends to increase
with increased grade

2-Metastases :
-Appearance variable on scans depending on
primary
-Often considerable associated edema
(vasogenic , white matter)
-Multiple / Solitary
-Often located at the grey-white junction

3-Arterial Infarct :
-Developing low attenuation (CT) , High T2 signal
(MRI) wedge shaped lesion with variable mass
effect
-Various enhancement patterns if contrast given

4-Venous Infarct :
-Area of low attenuation (CT) , High signal (MRI)
not in arterial distribution
-Often associated mass
-Often hemorrhagic
5-Abscess :
-Homogenous thin enhancing rim
-Usually considerable vasogenic edema

6-Acute Demyelinating Plaque :
-May be very large with minimal clinical signs
-Low attenuation (CT) , High signal T2 (MRI)
-Variable enhancement
7-Hematoma :
-Subacute to chronic

8-Cerebritis / Encephalitis :
-Poorly defined area of low attenuation (CT)
-HSV predilection for limbic system
-Variable enhancement

9-Aneurysm :
-May give rise to mass effect by itself but also
often associated edema in surrounding brain
-Appearance varies according to whether patent
or associated intramural thrombus +/-
calcification

c) Hyperdense artery :
-Represents acute thrombus within the vessel
-Most commonly recognized with basilar and
proximal MCA thrombosis
-False positives can occur if a vessel is partially
calcified or if the haematocrit is raised (i.e.
polycythaemia)

-On the left a patient with a dense MCA sign
-On CTA : occlusion of the MCA is visible

Gradient Echo shows blooming artifact (red arrow) in the right proximal MCA
which represents intraluminal thrombus and in the MRI correlate to the
hyperdense artery sign that can be seen on CT

3-Later Signs :
a) More Low Density
b) Generalized Mass Effect
c) Hemorrhage

a) More Low Density :
-More extensive area of low attenuation or
progressive decreased attenuation
b) Generalized Mass Effect :
-Ventricular or basal cistern effacement +/-
midline shift (subfalcine herniation) or other
herniation syndromes : uncal , transtentorial

c) Hemorrhage :
-Frank hemorrhage into an arterial infarct
typically occurs a few days after the initial
stroke
-If there is hemorrhage within an infarct from
the outset , a venous stroke or arterial
embolus should be considered

-Hemorrhagic transformation with foci of hemorrhage
at the right post central gyrus

CT , Hemorrhagic evolution of initial ischemic infarction with
significant midline shift

4-Contrast Enhancement :
-Usually occurs by 4 days and reflects impairment
of the blood-brain barrier
-Typically gyriform (following the cerebral cortex)
but may appear ring-enhancing or confluent
-Subsides by 4-8 weeks
-Luxury perfusion refers to hyperemia of an
ischemic area , the increased blood flow is
thought to be due to compensatory
vasodilatation secondary to parenchymal lactic
acidosis

-Enhanced CT images of a
patient with an infarction
in the territory of the MCA
-There is extensive gyral
enhancement (luxury
perfusion)
-Sometimes this luxury
perfusion may lead to
confusion with tumoral
enhancement
-Luxury perfusion used to
describe the dilation of
numerous vascular
channels observed within
the relatively avascular
infarcted area of the brain
24-48 h after an ischemic
stroke , these are
predominantly venous
channels but arterial
channels open up as well

5-Arterial Occlusion :
-CT angiography may demonstrate stenosis or
complete arterial occlusion prior to
spontaneous recanalization

-Demonstrates absence
of contrast enhancement
at the left MCA
distribution and
decreased left cerebral
hemispheric arterial
collateralization
compared to the right
cerebral hemisphere
-The intensity of the
vessels on the left is
decreased as compared
with those on the right

6-Perfusion Defect :
-CT can demonstrate the extent and degree of
cerebral ischemia with the use of iodinated
contrast medium or xenon
-With CT and MR diffusion we can get a good
impression of the area that is infarcted but we
cannot preclude a large ischemic penumbra
(tissue at risk)

-Within the ischemic cerebrovascular bed , there are
two major zones of injury:
1-The core ischemic zone
2-Ischemic penumbra (the term generally used to define
ischemic but still viable cerebral tissue(
-In the core zone which is an area of severe ischemia
(blood flow below 10% to 25%) , the loss of oxygen and
glucose results in rapid depletion of energy stores ,
severe ischemia can result in necrosis of neurons and
also of supporting cellular elements (glial cells) within
the severely ischemic area

-Brain cells within the penumbra , a rim of mild to
moderately ischemic tissue lying between tissue
that is normally perfused and the area in which
infarction is evolving may remain viable for
several hours , that is because the penumbral
zone is supplied with blood by collateral arteries
anastomosing with branches of the occluded
vascular tree , however , even cells in this region
will die if reperfusion is not established during
the early hours since collateral circulation is
inadequate to maintain the neuronal demand for
oxygen and glucose indefinitely

Occlusion of the MCA with irreversibly affected or dead tissue in black and
tissue at risk or penumbra in red

-The penumbra does receive some perfusion but at a reduced
rate compared to normal brain , perfusion of the penumbra is
< 20 mL/100 g tissue per minute in physiologic studies ,
compared to 60 mL/100 g tissue for normal grey matter , such
a low rate of perfusion causes cellular dysfunction and
produces a neurological deficit
-With perfusion studies we monitor the first pass of an iodinated
contrast agent bolus through the cerebral vasculature
-Perfusion will tell us which area is at risk , approximately 26% of
patients will require a perfusion study to come to the proper
diagnosis , the limitation of CT-perfusion is the limited
coverage

-The key to interpretation is understanding a
number of perfusion parameters :
1-Cerebral blood volume (CBV)
2-Cerebral blood flow (CBF)
3-Mean transit time (MTT)

1-Cerebral blood volume (CBV) :
-Is measured in relative units and correlates to the
total volume of circulating blood in the voxel
-CBV is a parameter that changes late in the
ischemic cascade and usually reduced CBV is also
accompanied by restricted diffusion
-Reduced CBV (and restricted diffusion) correlates
well with tissue that goes on to infarction

2-Cerebral blood flow (CBF) :
-Is measured in relative units and correlates to the
flow of blood in the voxel
-CBF can be used to predict the likelihood of brain
tissue infarcting
-In current clinical practice , a CBF abnormality
exceeding the DWI abnormality (diffusion-
perfusion mismatch) implies that there is brain at
risk that has not infracted yet , this brain at risk is
the target of therapeutic interventions

3-Mean transit time (MTT) :
-Is measured in seconds and is a measure of
how long it takes blood to reach the particular
region of the brain

-Areas which demonstrate matched defects in
CBV and MTT represent the unsalvageable
infarct core , whereas areas which
have prolonged MTT but preserved CBV are
considered to be the ischaemic penumbra

A, NCCT shows some
microvascular
ischemic changes
posteriorly
B−D, CTP maps , CBF
(B), CBV (C) and MTT
(D), demonstrate a
large area of matched
deficit on CBV and
MTT maps indicative
of core infarct in the
right MCA territory

A, On admission , NCCT
and CTP were performed
NCCT shows no evidence
of acute infarction
B, CT perfusion CBF map
shows a region of
decreased perfusion within
the posterior segment of
the left MCA territory
(arrows)
D, MTT map shows a
corresponding
prolongation within this
same region (arrows)
C, CBV map demonstrates
no abnormality , therefore,
representing a CBV/MTT
mismatch or ischemic
penumbra

Left MCA infarct. (A) Regional
cerebral blood flow map from
computed tomography
perfusion shows a large
perfusion defect in the left
frontal and temporal lobes ,
evidenced by a lack of color
display , (B) Regional cerebral
blood volume map
demonstrates a penumbra of
decreased perfusion
(indicated with arrows around
blue areas) surrounding the
defect (purple) indicating
potentially reversible
ischemia about the perfusion
defect

Acute Arterial Infarct – MRI Appearance
1-Diffusion Abnormality
2-Absent Arterial Flow Void
3-Increased T2 Signal
4-Mass Effect
5-Intravascular Stasis of Contrast Medium
6-Reduced Perfusion
7-Arterial Occlusion
8-Meningeal Enhancement
9-Hemorrhage
10-Wallerian Degeneration

1-Diffusion Abnormality :
-Abnormalities may be seen within minutes of
arterial occlusion with diffusion-weighted MRI
-Standard diffusion protocol includes a DWI and an
apparent diffusion coefficient (ADC) image ,
these are usually interpreted side by side
-DWI : summation of diffusion and T2 effects ,
abnormalities appear as high signal
-ADC : diffusion effects only , abnormalities appear
as low signal

Sequence Hyperacute
(<6 hr(
Acute (>6 hr( Subacute
(Days to
Weeks(
chronic
DWI High High High (decrease
with time(
Isointense to
bright
ADC Low Low Low to
isointense
Isointense to
bright
T2 / FLAIR Isointense Slightly bright
to bright
Bright Bright
T1 Subtle
hypointensity
Hypointense Hypointense Hypointense

-In the acute phase T2WI will
be normal but in time the
infarcted area will become
hyperintense. The
hyperintensity on T2WI
reaches its maximum
between 7 and 30 days after
this it starts to fade
DWI is already positive in the
acute phase and then
becomes more bright with a
maximum at 7 days , DWI in
brain infarction will be
positive for approximately for
3 weeks after onset (in spinal
cord infarction DWI is only
positive for one week)
-ADC will be of low signal
intensity with a maximum at
24 hours and then will
increase in signal intensity
and finally becomes bright in
the chronic stage

1st
row is T2 , 2nd
row is DWI & 3rd
row is ADC at (a) 5 hours , (b) 3
days , (c) 7 days & (d) 30 days of stroke onset

a) Hyperacute Infarct (0-6 hours)
b) Acute Infarct (6-72 hours)
c) Early Subacute Infarct (1.5 days-5 days)
d) Late Subacute Infarct (5 days-2 weeks)
e) Chronic Infarct

a) Hyperacute Infarct (0-6 hours) :
-Within minutes of critical ischemia , the sodium-
potassium ATPase pump that maintains the normal
low intracellular sodium concentration fails , sodium
& water diffuse into cells leading to cell swelling and
cytotoxic edema
-Calcium also diffuses into cells which triggers cascades
that contribute to cell lysis
-Diffusion is the most sensitive modality , DWI
hyperintensity & ADC map hypointensity reflect
reduced diffusivity which can be seen within minutes
of the ictus

-Diffusion is reduced in acute infarct by 2 factors:
1-Shift from extracellular to intracellular water due to
Na/K ATPase pump failure
2-Increased viscosity of infarcted brain due to cell lysis
and increased extracellular protein
-FLAIR may be normal , subtle hyperintensity may be
seen on FLAIR
-Perfusion shows decreased cerebral blood volume of
the infarct core with or without a surrounding region
of decreased cerebral blood flow which represents
the penumbra

b) Acute Infarct (6-72 hours) :
-The acute infarct is characterized by increase in
vasogenic edema and mass effect
-Damaged vascular endothelial cells cause leakage of
extracellular fluid and increase the risk of
hemorrhage
-On imaging , there is increased sulcal effacement and
mass effect , the mass effect peaks at 3-4 days which
is an overlap between the acute & early subacute
phases

-MRI shows hyperintensity of the infarct core on T2 ,
best seen on FLAIR , the FLAIR abnormality is usually
confined to the grey matter , DWI continues to show
restricted diffusion
-There may be some arterial enhancement due to
increased collateral flow
-Perfusion images most commonly show increase in
size of the infarct core with resultant decrease in size
of penumbra

RT MCA infarction , (A and B) Restricted water diffusion in the region
of infarct results in an increased signal intensity on diffusion (A) and
decreased signal on apparent diffusion coefficient imaging (B)

Left: Diffusion in acute ischemic stroke performed 35 minutes after
symptom onset
Right: ADC map obtained from the same patient at the same time

c) Early Subacute Infarct (1.5 days-5 days) :
-In the early subacute phase , blood flow to the
affected brain is re-established by leptomeningeal
collaterals and ingrowth of new vessels into the
region of infarction
-The new vessels have an incomplete blood brain
barrier causing a continued increase in vasogenic
edema & mass effect which peaks at 3-4 days
-MRI shows marked hyperintensity on T2 involving both
grey & white matter (in contrast to the acute phase
which usually involves just the grey matter)

-The ADC map becomes less dark or even
resolves if there is extensive edema , however
, the DWI typically remain bright due to
underlying T2 shine through
-Perfusion imaging shows continued expansion
of the infarct core and further reduction in the
ischemic penumbra

ADC map shows an area of low signal intensity in the right parietooccipital
junction (arrow) , a finding that usually persists for about 1 week , this
area demonstrates high signal intensity at diffusion-weighted imaging (not
shown)

T1 shows an area of low signal intensity (arrow)

T2 shows an area of high signal intensity (arrow)

FLAIR shows an area of high signal intensity (arrow)

d) Late Subacute Infarct (5 days-2 weeks) :
-The subacute phase is characterized by resolution of
vasogenic edema and reduction in mass effect
-A key imaging finding is gyriform enhancement which
may occasionally be confused for a neoplasm , unlike
a tumor , subacute infarction will not typically show
both mass effect and enhancement simultaneously ,
enhancement be seen from approximately 6 days to
6 weeks after the initial infarct
-Diffusion may remain bright due to T2 shine through ,
although ADC map will either return to normal or
show increased diffusivity

Enhancing infarcts , T1+C shows gyriform enhancement at the left insula and
posterior parietal lobe from a subacute left MCA infarct

e) Chronic Infarct :
-In the chronic stage of infarction , cellular debris and
dead brain tissue are removed by macrophages and
replaced by cystic encephalomalacia and gliosis
-Infarct involvement of the corticospinal tract may
cause mass effect , mild hyperintensity on T2 and
eventual atrophy of the ipsilateral cerebral peduncle
& ventral pons due to Wallerian degeneration , these
changes can first be seen in the subacute phase with
atrophy being predominant feature in the chronic
stage (See later)

-DWI has usually returned to normal in the
chronic stages
-Occasionally , cortical laminar necrosis can
develop instead of encephalomalacia , cortical
laminar necrosis is a histologic finding
characterized by deposition of lipid-laden
macrophages after ischemia that manifests on
imaging as hyperintensity on both T1 & T2

DWI shows an area of low signal intensity in the right occipital lobe (arrow)
with a peripheral rim of high signal intensity , a finding that may be due to
T2 shine-through

ADC map shows a corresponding area of high signal intensity
(arrow)

T1 shows a corresponding area of low signal intensity (arrow)

T2 shows an area of high signal intensity in the right occipital
lobe (arrow)

T1+C shows a corresponding area of parenchymal enhancement
(arrow)

Laminar necrosis , T1 shows gyriform T1 high signal in a chronic left MCA
infarct , mild enlargement of the sulci is consistent with encephalomalacia

A : Diffusion with b = 1000 s/mm2
shows a high signal lesion , consistent with acute infarct in the
left corona radiata and a low signal area in the right periventricular white matter (arrow),
consistent with a chronic infarct, a second low signal lesion is seen anterior to the high-signal
area in the left subcortical white matter, B : Diffusion at b = 2500 s/mm2 shows increased
contrast of the high signal and two low-signal lesions, C : Diffusion at b = 3000 s/mm2 also
shows the high and low signal areas more conspicuously than at b = 1000, D : FLAIR image
demonstrating the encephalomalacia and reactive gliosis associated with the two chronic
strokes seen as low signal lesions on a diffusion-weighted image, and increased signal in the
lesion seen as high signal on a diffusion-weighted image

2-Absent Arterial Flow Void :
-An immediate sign of vessel occlusion best seen
on T2W and FLAIR imaging
-An occluded vessel returns high signal on these
sequences

Left MCA thrombus , the left MCA shows high signal from an intraluminal clot
on FLAIR (a) but low signal on gradient recalled echo (GRE) T2* (b) , this
corresponds to a filling defect (arrow) on CT angiogram (c) , asubtle FLAIR
high signal is present at the left insula

Right MCA occlusion , 3D TOF MRA MIP shows absent flow-related
enhancement in the right MCA from embolic occlusion

3-Increased T2 Signal :
-T2W signal change represents cytotoxic edema
and typically becomes visible by 3-6 hours
-The earliest changes are identified within the
grey matter structures , accompanied by a
reduction in T1W signal

Hypointense signal intensity alteration on T1 (a) and
hyperintense on T2 FLAIR (b) in left parietal region ,
suggestive of acute infarct , there is also perilesional edema

T2 of acute infarct with increased signal involving the right
putamen and body and superior head of the caudate sparing
the inferior caudate and globus pallidus

(Left) T2 and diffusion (Right) showing bilateral thalamic infarcts

Cortical edema in a subacute infarct , a The axial FLAIR shows high
signal , gyral swelling and sulcal effacement , b There is subtle low
signal and gyral swelling (arrow) seen on the T1

Axial FLAIR shows geographic T2 prolongation in the RT MCA territory (arrows)
involving the RT frontal & temporal lobes & RT basal ganglia , the size of the T2
signal abnormality is less extensive that the infarct size apparent on DWI

4-Mass Effect :
-Local effacement of the cerebral sulci and
fissures may be followed by more diffuse
brain swelling
-Maximal swelling usually occurs after 3-5 days
-Infarcts that do not have a typical appearance
must be differentiated from other solitary
intracranial masses (See Before)

RT MCA infarction , fast spin echo T2 fat suppression shows
increased signal intensity and effacement of the right
temporal lobe consistent with subacute infarct

5-Intravascular Stasis of Contrast Medium :
-Prolonged transit of contrast medium through
distal / collateral vessels causes high arterial
signal on post-gadolinium T1W images

Arterial enhancement from infarct , T1+C shows increased
enhancement of the left MCA vessels in this hyperacute
infarct

4 hrs after left MCA symptoms began , extensive Intravascular
enhancement seen (an immediate finding)

6-Reduced Perfusion :
-Contrast-based MRI techniques show a
qualitative fall in brain perfusion within the
relevant vascular territory
-Early the process of cerebral ischemia reveals
reductions in CBF and CBV and an increase in
MTT of blood through the brain

Left: Perfusion-weighted MRI of a patient who presented 1 hour after
onset of stroke symptoms
Right: MTT map of the same patient

-Matched diffusion and perfusion abnormalities
correlate with the region of infarction and are
indicative of permanent neuronal death

On the DWI there is a large area with restricted diffusion in the
territory of the right MCA , notice also the involvement of the basal
ganglia , there is a perfect match with the perfusion images so this
patient should not undergo any form of thrombolytic therapy

There is a match of DWI and Perfusion , so no therapy

-Mismatched diffusion and perfusion
abnormalities with the perfusion abnormality
larger than the diffusion abnormality may be
indicative of a region of reversible ischemic
penumbra , patients with mismatch may be
candidates for stroke treatment by
thrombolysis

Diffusion-perfusion mismatch in acute ischemic stroke , the perfusion
abnormality (right) is larger than the diffusion abnormality (left)
indicating the ischemic penumbra which is at risk of infarction

-On the left we first
have a diffusion image
indicating the area
with irreversible
changes (dead issue)
-In the middle there is
a large area with
hypoperfusion
-On the right the
diffusion-perfusion
mismatch is indicated
in blue , this is the
tissue at risk , this is
the brain tissue that
maybe can be saved
with therapy

There is a severe mismatch , almost the whole left cerebral
hemisphere is at risk due to hypoperfusion , this patient is an
ideal candidate for therapy

7-Arterial Occlusion :
-MR angiography may demonstrate vessel
stenosis or occlusion
-Spontaneous recanalization is a feature of
thromboembolic stroke but may not occur
until after a period of irreversible ischaemia

ACA occlusion and infarct , (a) MIP of 3D TOF MRA shows absent flow-related
enhancement of the distal A2 segment of the left ACA ,arrow , (b) This
corresponds to a focal filling defect on CTA ,arrow) , note that MRA cannot image
the slow collateral flow in the distal left ACA , (c) DWI shows the left ACA territory
infarct

8-Meningeal Enhancement :
-Observed at 24 hours in the meninges adjacent
to an infarct
-Parenchymal enhancement is maximal at 4-7
days and is usually gyriform or patchy in
appearance

Enhancing infarcts , T1+C shows gyriform enhancement at the
left insula and posterior parietal lobe from a subacute left
MCA infarct

8 hrs after onset 2nd
day 1 week

6.5 hrs after onset 2nd
day 1 week

day 1 week

9-Hemorrhage :
-Hemorrhagic transformation is a little variably
used and collectively refers to two different
processes which have different incidence ,
appearance and prognostic implications ,
these are :
a) Petechial hemorrhage
b) Intracerebral hematoma

a) Petechial hemorrhages :
-Usually appear as the name suggests , as tiny
punctate regions of hemorrhage often not able
to be individually resolved but rather resulting in
increased attenuation of the region on CT of
signal loss on MRI , although this petechial
change can result in cortex appearing near
normal it should not be confused with the
phenomenon of fogging seen on CT which occurs
2 to 3 weeks after infarction

-Petechial hemorrhage typically is more
pronounced in grey matter and results in
increased attenuation
-This sometimes mimics normal grey matter
density and contributes to the phenomenon
of fogging

Petechial hemorrhage , gyriform low signal in the right frontal lobe
(arrow) on this GRE T2* corresponds to susceptibility from
petechial hemorrhage in an acute infarct

Hemosiderin in chronic infarct , the low signal from the
gyriform on this GRE T2* at the right frontal lobe is
from hemosiderin in an old petechial bleed

N.B. :
Fogging Phenomenon
-Is seen on non contrast CT of the brain and
represents a transient phase of the evolution of
cerebral infarct where the region of cortical
infarction regains a near normal appearance
-During the first week following a cortical
infarct hypoattenuation and swelling become
more marked resulting in significant mass effect
and clear demarkation of the infarct with vivid
gyral enhancement usually seen at this time

-As time goes on the swelling starts to subside and
the cortex begins to increase in attenuation , this
is believed to occur as the result of migration into
the infarcted tissue of lipid-laden macrophages as
well as proliferation of capillaries and decrease in
the amount of edema
-After 2 to 3 weeks following an infarct the cortex
regains near-normal density and imaging at this
time can lead to confusion or missed diagnosis

-Fogging has been demonstrated in around 50% of
cases
-If in doubt the administration of IV contrast
will demarcate the region of infarction
-A similar phenomenon is also seen on T2 weighted
sequences on MRI of the brain and is believed to
be due to similar cellular processes, as the timing
is similar , it has been found to occur in
approximately 50% of patients between 6 and 36
days (median 10 days) after onset of infarction

2 Days post onset of
symptoms
9 days post onset of symptoms

b) In the case of secondary hematomas :
-The radiographic features on both CT and MRI are
merely a summation of the features of a ischemic
infarct with superimposed cerebral hemorrhage
-The amount of hemorrhage relative the size of the
infarct can vary widely but usually it is possible to
identify significant areas of the brain which are
infarcted but not hemorrhagic
-This may not be the case if the hemorrhage is large
and the underlying infarct small

-By the time secondary hematomas form , the
underlying infarct should be easily seen
and will appear as a region of low attenuation
involving both the white matter and the
overlying cortex
-Hemorrhage is often patchy , scattered
throughout the infarcted tissue and usually
represents only a small component of the
abnormal tissue

T1 , Hemorrhagic transformation is detected as areas of increased
signal intensity , the gyral pattern of increased signal intensity may
also represent cortical laminar necrosis

T1 , Hemorrhagic transformation is detected as areas of increased
signal intensity

10-Wallerian Degeneration :
a) Incidence
b) Radiographic Features

a) Incidence :
-Appears in the chronic phase of cerebral
infarction (> 30 days)
-Frequently observed in the corticospinal tract
following infarction of the motor cortex or
internal capsule
-After ischaemic stroke it usually takes two to
four weeks before WD can be detected by
conventional MRI

c) Radiographic Features :
-Hyperintensity on T2-weighted images along the affected tracts
-Conventional MRI depict WD when sufficiently large bundles of
fibers are involved along the corticospinal tract , the corpus
callosum , fibers of the optic radiations , fornices and
cerebellar peduncles
-The most common observations regard the corticospinal tract
-WD of cerebellar peduncles is rarely described , It usually
involves the middle ones because they are largest and the
main path for pontocerebellar tracts
-Shows diffusion restriction

Coronal T2 shows hyperintensity of left corticospinal tract due to
wallerian degeneration

Axial T2 shows Bilateral and symmetric hyperintensities of
pontocerebellar tract (arrows)

Coronal T2 shows Right temporal lobe encephalomalacia (black arrow) and
hyperintensity of right corticospinal tract (red arrow)

Coronal T2 shows encephalomalacia of the right frontal and temporal lobes
and T2 high signal extending into the right cerebral peduncle (arrow) from
Wallerian degeneration

Axial T2 shows hyperintense signal in pons due to chronic infarct and
bilateral- symmetrical hyperintense signal in pontocerebellar tracts due to
WD

T2 showing bilateral symmetrical high signal in both cerebellar
peduncles

Axial T2 (A) shows symmetrical hyperintense signal in both the MCPs
(arrow) , Few hyperintense foci are also seen in pons , Diffusion (B) shows
hyperintense signal in both MCPs and in right paramedian pons ,
Corresponding ADC map (C) reveals reduced signal suggestive of restricted
diffusion

DWI and ADC map showing evidence of restricted diffusion in the cerebellar
peduncles in keeping with Wallerian degeneration

DW shows increased signal intensity in the left cerebral peduncle (arrow) ,
ADC map demonstrates that the ADC value in the left cerebral peduncle
(arrow) is lower that that in the normal right cerebral peduncle

*N.B. :
Differentiation between Infarct & Tumor
1-Clinical History
2-Distribution
3-Shape
4-Tissue Involvement
5-Advanced Imaging Techniques

1-Clinical History :
-Abrupt versus gradual onset and development of
symptoms
2-Distribution :
-Tumors not confined to vascular territory
3-Shape :
-Infarcts usually wedge shaped with base at
periphery , tumors tend to be spherical / ovoid

4-Tissue Involvement :
-Infarcts involve grey and white matter
-Most metastases or higher grade gliomas
involve white matter primarily
-Lower grade primary tumors may involve grey
matter

5-Advanced Imaging Techniques :
-Such as DWI or MR spectroscopy may be useful
in cases that remain unclear on standard
sequences

Acute Venous Infarct
-It is important to distinguish between venous and
arterial infarcts since the conditions are managed
differently
-The following radiological features are suggestive of
venous infarction :
1-Venous Occlusion
2-Bilateral Infarcts
3-Unilateral Infarct
4-Hemorrhage
5-Mass Effect
6-Dural Thickening
7-Imaging In Suspected Thrombosis
8-Chronic Dural Sinus Thrombosis and Related
Syndromes

Venous Anatomy
a) Dural Sinuses
b) Deep Cerebral Veins
c) Superficial Cerebral Veins

a) Dural Sinuses :
-The superior sagittal sinus (SSS) & its tributaries
drains the motor & sensory strips
-The paired transverse sinuses are usually
asymmetric , with the left transverse sinus
often hypoplastic
-The sigmoid sinus connects to the jugular bulb
-Te torcular herophili is the confluence of the
SSS , the transverse sinus & the straight sinus

-2D frontal views of the venous phase
of circulation following vertebral
artery injection
1 superior sagittal sinus
3 torcular herophili
4 transverse sinus
5 sigmoid sinus
6 jugular bulb
7 internal jugular vein
26 cavernous sinus
27 intercavernous sinus
29 superior petrosal sinus
30 inferior petrosal sinus
35 anterior pontomesencephalic vein
37 posterior mesencephalic vein
39 petrosal vein
41 precentral cerebellar vein
43 inferior vermian vein
44 cerebellar hemispheric vein
45 brachial vein
46 suboccipital veins
49 parietal veins
50 occipital veins

2 inferior sagittal sinus
4 transverse sinus
5 sigmoid sinus
6 jugular bulb
8 superficial cortical vein
9 vein of Trolard
10 vein of Labbé
11 superficial middle cerebral vein
12 septal vein
13 thalamostriate vein
14 internal cerebral vein
15 great cerebral vein of Galen
16 basal vein of Rosenthal
17 inferior ventricular vein
18 medial atrial vein
20 anterior caudate vein
21 terminal vein
22 direct lateral vein
24 straight sinus
25 sphenoparietal sinus
26 cavernous sinus
28 clival venous plexus
46 suboccipital veins
47 pterygoid venous plexus
48 true venous angle
51 superior ophthalmic vein
53 sphenopetrosal vein
55 false venous angle

b) Deep Cerebral Veins :
-Consist of paired internal cerebral veins , the
basal vein of Rosenthal & the vein of Galen
-The venous angle is the intersection of the
septal vein & the thalamostriate veins , the
venous angle is the angiographic mark for the
foramen of Monro

-2D frontal views of the
venous phase of circulation following
carotid artery injection
4 transverse sinus
5 sigmoid sinus
6 jugular bulb
8 superficial cortical veins
9 vein of Trolard
10 vein of Labbé
11 superficial middle cerebral vein
12 septal vein
13 thalamostriate vein
14 internal cerebral vein
24 straight sinus
25 sphenoparietal sinus
26 cavernous sinus
27 intercavernous sinus
31 occipital sinus
56 insular vein
57 deep middle cerebral vein

c) Superficial Cerebral Veins :
-The vein of Trolard connects superficial cortical
veins to the SSS
-The vein of Labbe drains the temporal
convexity into the transverse or sigmoid sinus

-Lateral views of venous
phase circulation following
carotid artery injection
2 inferior sagittal sinus
4 transverse sinus
5 sigmoid sinus
6 jugular bulb
8 superficial cortical vein
10 vein of Labbé
11 superficial middle
cerebral vein
15 great cerebral vein of
Galen
24 straight sinus

1-Venous Occlusion :
a) Etiology
b) Radiological Findings
c) Diagnostic Difficulties
d) Characteristic Patterns of Venous Infarctions

a) Etiology :
-The vast majority of venous infarcts are caused
by venous thrombosis
-If an area of infarction is seen which isn’t in
arterial distribution , consider sinus
thrombosis

b) Radiological Findings :
*CT :
-Acute thrombus is hyperdense on precontrast CT
and expands the occluded sinus / vein (Dense
clot sign)
- Cord sign : is defined as a homogeneous ,
hyperattenuated appearance of thrombosed
venous sinuses , the hyperattenuated
appearance of the affected veins often being
named (the attenuated vein sign)

-Postcontrast :
1-Filling Defect : demonstration of contrast-filling defects
in the involved sinus or vein
2-Empty Delta sign :
*The sign consists of a triangular area of enhancement
with a relatively low-attenuating center which is the
thrombosed sinus
*In early thrombosis the empty delta sign may be absent
and you will have to rely on non-visualization of the
thrombosed vein on the CECT
*The sign may be absent after two months due to
recanalization within the thrombus

Direct visualization of a clot in the cerebral veins on a non enhanced
CT scan is known as the dense clot sign

Dense clot sign in a thrombosed cortical vein

CT without contrast : Cord Sign , in the SSS (dotted arrow)
and the RTS (arrows)

Attenuated vein sign in both ICVs (thin arrows), in the SS (crossed arrow)

Hemorrhagic infarction in the temporal lobe (red arrow) , notice the dense
transverse sinus due to thrombosis (blue arrows)

CT without contrast , cerebral venous thrombosis

CT without contrast , cerebral venous sinus thrombosis

CT without contrast , Hyperdense veins (attenuated vein sign)

CT without contrast , Hyperdense internal cerebral veins
(attenuated vein sign)

CT+C shows contrast-filling defects in the ICVs (thin arrow) and the SS
(crossed arrows)

CT+C : Empty delta sign due to thrombosis of the SSS

*N.B. :
-Filling defects should not be confused with
Pacchionian bodies (arachnoid granulations) which
can be seen in essentially all dural sinues and are
especially common in the superior sagittal sinus
and transverse sinus
-MRI signal of arachnoid granulations : generally
those of CSF
*T1 : Low signal intensity
*T2 : High signal intensity : iso to even slightly
hyperintense to CSF
*FLAIR : Should attenuate
*T1+C : No enhancement

*MRI :
-Absence of flow void , thrombus is visualized on
MRI as loss of the normal venous flow void on
T2
-The clot acutely is isointense on T1 and
hypointense on T2 (this can mimic a flow void)
, with subacute clot becoming hyperintense
on T1
-All the findings listed in the CT are also seen on
MRI

1 =superior sagittal sinus
2 = straight sinus
3 = torcular herophili
4 = vein of Galen
5 = lateral ( transverse )
sinus
6 = sigmoid sinus
7 = internal jugular vein
8 = internal cerebral vein
9 = basal vein of Rosenthal
The arrows point to
superficial cerebral veins

(a) & (b) SSS (straight arrow) , straight sinus (arrowhead), and vein of Galen
(curved arrow)
(c) & (d) The right vein of Labbe (C , arrow) , the right vein of Trolard (D,
arrow) , depicted as a large tributary to the superior sagittal sinus

Vein of Labbe (6) , Transverse sinus (3)

T2 with normal flow void in the right sigmoid sinus and jugular vein (blue arrow) , on
the left there is abnormal high signal as a result of thrombosis (red arrow)

T2 : Absent signal void in the anterior SSS (Black arrows) representing thrombus, with
normal flow void (White arrows) in the posterior part of the SSS

T1 : There is extensive thrombus in the SSS , the thrombus is giving variable signal with the older
thrombus in the anterior part giving a hyperintense signal (Black arrows) and fresh thrombus
in the posterior part giving isointense T1 signal (white arrows)

Cerebral venous thrombosis in a 44 year old woman, axial (a) and sagittal (b) T1
show high signal intensity in the deep cerebral veins (arrow) and venous
sinuses (arrowheads), (c) 3D MIP from MR venography demonstrates
collateral vessels (arrowhead) secondary to occlusion of the cortical veins and
venous sinuses (arrow)

Abnormal high signal on T1 due to thrombosis, the thrombosis extends from the deep
cerebral veins and straight sinus to the transverse and sigmoid sinus on the right,
notice the normal flow void in the left transverse sinus on the right lower image

T1+C : Extensive filling defect due to thrombus in the SSS (White
arrows) and the straight sinus (Black arrows)

c) Diagnostic Difficulties :
-Diagnostic difficulties arise with congenital
variations of the venous system (i.e. normal
hypoplasia of the transverse sinuses) ,
arachnoid granulations and normal slow
turbulent flow

Hypoplasia of the left transverse sinus , notice the size difference of
the jugular foramen

1-Jugular bulb
2-Carotid canal
(pars horizontal)
3-Sphenoid sinus
4-Foramen ovale
5-Foramen
spinosum
6-Jugular foramen

Transverse MIP of phase-contrast images, to differentiate whether there is a
hypoplastic transverse sinus or thrombosed sinus , you need to look at the
source images, on the source image on the right you can see that there is
no hypoplasia (blue arrow), in this case there thrombosis of the left
transverse sinus

The signal in the vein depends on the velocity of the flowing blood and the velocity
encoding by the technician, on the far left a patient with non visualization of the left
transverse sinus, this could be hypoplasia , venous thrombosis or slow flow, on T1+C, it
is obvious that the sinus fills with contrast and is patent

d) Characteristic Patterns of Venous Infarctions:
-There are 3 characteristic patterns of venous
infarctions dependant on the location of the
thrombosed vein :
1-SSS thrombosis : infarction of the parasagittal high
convexity cortex
2-Deep venous system thrombosis : infarction of the
bilateral thalami
3-Transverse sinus thrombosis : infarction of the
posterior temporal lobe

NECT showing the delta sign at the level of the torcula (dark arrows) and
hemorrhagic infarctions on the parasagittal frontal lobes (light arrows) in
a case of SSS thrombosis

NECT shows hyperdense internal veins and bilateral (R > L) thalami
hypodensities , compatible with dural vein thrombosis and venous
infarction

(a) FLAIR shows the venous infarction in the temporal lobe , (b) CT nicely
demonstrates the dense thrombosed transverse sinus (yellow arrow)

2-Bilateral Infarcts :
-Venous infarcts are often bilateral in the midline and
hemorrhagic
-Occlusion of the midline veins (deep cerebral veins “
Internal cerebral veins and basal veins of Rosenthal
“ , straight sinus & SSS) may result in bilateral areas of
low attenuation on CT and increased T2
-Thrombosis of the deep cerebral veins may involve the
basal ganglia , thalami , midbrain and mesial temporal
lobes in a relatively symmetrical fashion

-The most frequently thrombosed venous
structure is the SSS , infarction is seen in 75%
of cases , the abnormalities are parasagittal
and frequently bilateral , hemorrhage is seen
in 60% of the cases

Bilateral infarction in superior sagittal sinus thrombosis

Bilateral parasagittal hemorrhage due to thrombosis of the SSS ,
the red arrow on the contrast enhanced image indicates the
filling defect caused by the thrombus

Attenuated vein sign in both ICVs (thin arrows) , in the SS (crossed arrow) as
well as bilateral edema in the thalami and in the putamen (thick arrows)

T1 revealing swollen hypointense thalami , T2 depicting swollen hyperintense
thalami

FLAIR image demonstrating high signal in the left thalamus , there is also high
signal in the basal ganglia on the right, these bilateral findings should raise
the suspicion of deep cerebral venous thrombosis, a sagittal CT
reconstruction demonstrates a filling defect in the straight sinus and the
vein of Galen (arrows)

Bilateral abnormalities in the region of the basal ganglia, based on the imaging findings there is a broad
differential including small vessel disease, demyelination, intoxication and metabolic disorders, but there
are abnormal high signal in the internal cerebral veins and straight sinus on the T1, where there should be
a low signal due to flow void, this was unlike the low signal in other sinuses, diagnosis is bilateral
infarctions in the basal ganglia due to deep cerebral venous thrombosis

Edema in venous infarction, in some cases of venous thrombosis the imaging findings can
resolve completely, on the left a patient with a subcortical area of high signal intensity, the
first impression was that this could be a low grade glioma, on a follow up scan the
abnormalities had resolved completely, in retrospect a dense vessel sign was seen in one of
the cortical veins and the diagnosis of venous thrombosis was made, the high signal intensity
can be attributed to vasogenic edema due to the high venous pressure that resulted from the
thrombosis

3-Unilateral Infarct :
-Thrombosis of the transverse sinus and / or
vein of Labbe may result in an infarct involving
the grey and white matter of the temporal
lobe in a non-arterial distribution
-Midline venous occlusion may also present with
unilateral infarcts

Thrombosis of the vein of Labbe, hypodensity in the white matter and less
pronounced in the gray matter of the left temporal lobe, there is some linear
density within the infarcted area, this is due to hemorrhage, the subtle density
in the area of the left transverse sinus (arrow) is the key to the diagnosis

There is a combination of vasogenic edema (red arrow) , cytotoxic edema and
hemorrhage (blue arrow) , these findings and the location in the temporal lobe
should make you think of venous infarction due to thrombosis of the vein of Labbe
(Hemorrhagic venous infarct in Labbe territory)

4-Hemorrhage :
-Hemorrhage is common within an acute venous
infarct (but this isn’t a contraindication to
anticoagulation as aim of anticoagulation is to
stop propagation of thrombus)
-Seen as an area of high attenuation on CT
-MR signal intensity depends on the age of the
hemorrhage (See Acute Intracerebral
Hematoma)

5-Mass Effect :
-Current diagnosis of CVI relies on the detection
of parenchymal edema or hemorrhage in the
presence of acute cerebral venous thrombosis
-Marked brain swelling is often seen with
venous infarction , even on day 1
-Arterial infarcts usually show maximal swelling
at 3-5 days

A: T1 showing slightly swollen right frontal cortex and no signal change
B : T2 depicting a ring of signal hyperintensity in right frontal cortex
C : Diffusion revealing a more hyperintense right frontal cortex than B
D : ADC showing corresponding decrease suggesting cytotoxic edema

-Cytotoxic cerebral edema refers to a type
of cerebral edema in which the blood brain
barrier (BBB) is intact (c.f. vasogenic cerebral
edema where BBB is lost) , it is an intracellular
edema which mainly affects grey matter but
also involves the white matter , it is due to a
cellular swelling from lack of ATP , that is
typically seen in area of cerebral ischemia or
cerebral hypoxia

MRI : Hyperintense T2 and FLAIR signals which
characteristically shows restricted diffusion
CT : Loss of grey white matter differentiation (as
it mainly affects grey matter) , effacement of
sulcal spaces

-Vasogenic cerebral edema refers to a type
of cerebral edema in which the blood brain
barrier (BBB) is disrupted , it is an extracellular
edema which mainly affects the white matter ,
through leakage of fluid out of capillaries , it is
most frequently seen around brain tumors (both
primary and secondary) and cerebral abscesses ,
although some vasogenic edema may be seen
around maturing cerebral contusion and cerebral
hemorrhage

CT : Grey-white matter differentiation is
maintained and the edema involves mainly white
matter , extending in finger-like fashion ,
secondary effects of vasogenic edema are similar
to cytotoxic edema with effacement of cerebral
sulci with or without midline shift
MRI : Hyperintense T2 and FLAIR signals which do
not show restricted diffusion
(c.f. cytotoxic cerebral edema which shows
diffusion restriction)

6-Dural Thickening :
-The empty delta sign of peripheral
enhancement around a central core of acute
thrombus represents hypervascularity and
engorgement of the dura , not a patent
peripheral channel
-Persistent dural thickening is a feature of
subacute / chronic venous thrombosis

7-Imaging In Suspected Thrombosis :
a) CT venography
b) MR venography
c) DSA

a) CT Venography :
-CT venography is a simple and straight forward
technique to demonstrate venous thrombosis
-In the early stage there is non-enhancement of
the thrombosed vein and in a later stage there
is non-enhancement of the thrombus with
surrounding enhancement known as empty
delta sign

-Unlike MR , CT venography virtually has no
pitfalls , the only thing that you don't want to
do , is to scan too early , i.e. before the veins
enhance or too late , i.e. when the contrast is
gone , some advocate to do a scan like a CTA
and just add 5-10 seconds delay , to be on the
safe side better to advocate 45-50 seconds
delay after the start of contrast injection , use
at least 70 cc of contrast

Infarction in the area of the vein of Labbe, on the non-enhanced images you can appreciate the
dense thrombus within the transverse sinus and the hemorrhage in the infarcted area, on the
enhanced images a filling defect can be seen in the transverse sinus

b) MR Venography :
-The MRI techniques that are used for the
diagnosis of cerebral venous thrombosis are :
1-Time of Flight (TOF)
2-Phase Contrast Angiography (PCA)
3-Contrast Enhanced MRV

1-Time of Flight (TOF) :
-MRI technique to visualize flow within vessels ,
without the need to administer contrast
-It is based on the phenomenon of flow-related
enhancement of spins entering into an
imaging slice
-As a result of being unsaturated , these spins
give more signal that surrounding stationary
spins

-With 2-D TOF , multiple thin imaging slices are
acquired with a flow-compensated gradient-
echo sequence , these images can be
combined by using a technique of
reconstruction such as maximum intensity
projection (MIP) to obtain a 3D image of the
vessels analogous to conventional
angiography

-With 3D TOF , a volume of images is obtained
simultaneously by phase-encoding in the slice-
select direction , an angiographic appearance can
be generated using MIP as is done with 2-D TOF
-Several 3D TOF volumes can be combined to
visualize longer segments of vessels , 3D TOF
angiography will allow greater spatial resolution
in the slice-select direction than 2D TOF ,
however , with thick volumes and slow flowing
blood, loss of signal is seen with the 3-D TOF
method

1 =superior sagittal
sinus
2 = straight sinus
3 = torcular herophili
5 = lateral (transverse)
sinus
6 = sigmoid sinus
7 = internal jugular
vein
-The arrows point to
superficial cerebral
veins

2-Phase contrast angiography (PCA) :
-Uses the principle that spins in blood that is
moving in the same direction as a magnetic field
gradient develop a phase shift that is
proportional to the velocity of the spins
-This information can be used to determine the
velocity of the spins , this image can be
subtracted from the image that is acquired
without the velocity encoding gradients to obtain
an angiogram

Transverse MIP image of a Phase-Contrast angiography , the
right transverse sinus and jugular vein have no signal due to
thrombosis

3-Contrast enhanced MRV :
-Uses the T1-shortening of Gadolinium
-It is similar to contrast-enhanced CTV

Lateral and oblique MIP image from a normal contrast-enhanced
MR venography. , notice the prominent vein of Trolard (red
arrow) and vein of Labbe (blue arrow)

CE-MRV , sagittal (A) and axial (B) thin MIP images shows filling defects within the
SSS (A, large arrow) and transverse and sigmoid sinuses (B, small arrows)
consistent with thrombosis, note the high diagnostic quality of the vein of
Galen (A, arrowhead) , the basal vein of Rosenthal (A, small arrow), and the
internal cerebral veins (A, thin large arrow)

c) Digital Subtraction Angiography (DSA) :
Angiography is only performed in severe cases ,
when an intervention is planned

Thrombosis of the SSS (red arrow) , straight sinus (blue arrow) and
transverse and sigmoid sinus (yellow arrow)

8-Chronic Dural Sinus Thrombosis and Related
Syndromes :
-Chronic dural sinus thrombosis can lead to
dural arteriovenous fistula formation and to
increased CSF pressure

a) DAVF :
-Dural arteriovenous fistula is an abnormal
connection between dural arteries which are
branches of the external carotid with the
venous sinuses
-Sinus thrombosis is seen in many patients with
a dural arteriovenous fistula but the
pathogenesis is still unclear

-There are two possible mechanisms:
1-Thrombophlebitis of the dural sinus may
induce a dural fistula
2-In the course of a dural fistula flow reversal
may lead to thrombosis
-Current classifications of DAVF focus mainly on
the presence of leptomeningeal reflux related
to cerebral venous hypertension leading to
cerebral venous infarction or hemorrhage

DSA images of a patient with a DAVF , notice the direct
communication between the branches of the external carotid
artery and the transverse sinus (blue arrow)

b) Thrombosis and increased CSF pressure :
-In some patients dural sinus thrombosis may
even after recanalization lead to persisting
disturbances in venous circulation
-This may lead to raised intracranial CSF
pressure as assessed by lumbar puncture

-Clinically , these patients complain of
headaches and they may have vision
disturbances due to papiledema
-On MRI , one may see increased CSF around the
optic nerve and an empty sella
-Apparently in some patients a residual stenosis
persists

T2 shows papiledema and an empty sella
T1 shows empty sella (arrow)

Intracranial Hematoma
a) Classification
b) Staging
c) CT
d) MRI

a) Classification :
Can be classified into :
1-Intracerebral (Intra-axial) Type
2-Extracerebral (Extra-axial) Type

1-Intracerebral (Intra-axial) :
-These can occur in the cerebral hemispheres ,
the cerebellar hemispheres or brainstem
-More in males , steadily increases with age and
peaks in the eight decade

-The mechanisms responsible for ICH include :
1-Hypertension
2-Hemorrhagic infarction
3-Cerebral amyloid angiopathy
4-Vascular malformations
5-Bleeding into primary or metastatic brain tumors
6-Coagulopathies (due to the use of anticoagulants and
thrombolytic agents)
7-Sympathomimetic drugs effect (amphetamines ,
phenylpropanolamine and cocaine )
8-Vasculitis
9-Moyamoya

1-Intraparenchymal hemorrhage associated with
hypertension :
-This entity affects patients in the average age of 50-60
years
-Chronic hypertension is the most common cause of
spontaneous adult intraparenchymal hemorrhage
-Most commonly occurs in deep brain structures like
basal ganglia (especially putamen) , thalamus , pons
and cerebellum
-An additional MR specific findings suggesting
hypertensive hemorrhage is the presence of
microhemorrhages on T2* (GRE or SWI) in the basal
ganglia or brainstem

Hypertensive hemorrhage , NECT show a left thalamic hemorrhage (yellow
arrow) with extension into the left ventricle occipital horn (red arrow)

-Intraparenchymal hemorrhage associated with hypertension , sagittal T1 and axial T2
FLAIR show a hyperintense hematoma located in the left putamen , this location is
typical of hypertensive hemorrhage , SWI shows a halo of hemosiderin in the
periphery of the hematoma (arrow) , an hemorrhage of chronic evolution and of
the same etiology is seen in the contralateral basal ganglia

2-Hemorrhagic transformation secondary to
ischemic stroke :
-T2 FLAIR , GRE or SWI sequences , diffusion-
weighted and ADC can give information about
non-hemorrhagic areas and show the blood
within the infarct
-Venous thrombosis , thrombosis of cortical
veins or deep venous sinuses leads to venous
hypertension which may cause infarction &
parenchymal hemorrhage

-Hemorrhagic transformation of an ischemic stroke , acute phase , Diffusion shows
restriction to the movement of free water related to cytotoxic edema
(hyperintense in b1000 and hypointense in ADC) , this finding is compatible with
stroke of acute evolution in the territory of the left MCA , an heterogeneous lesion
located in left basal ganglia suggest an associated hemorrhage , SWI confirms a
hematoma located in the left basal ganglia

-Hemorrhagic transformation of an ischemic stroke , Chronic phase , T2
shows a hyperintense lesion located in the right occipital lobe with
hemosiderin deposits (arrow) on SWI sequence , related to a cerebral
parenchymal hemorrhagic infarct , there is no free water movement
restriction in ADC

3-Intraparenchymal hemorrhage associated with
Cerebral Amyloid Angiopathy :
-Commonly occurs in peripheral lobar regions and
affects the frontal , parietal & occipital lobes
-Usually associated with lobar microbleeds
-Affects particularly elderly patients , the main clinical
clue that a hemorrhage is secondary to CAA is that
the patient is a normotensive elderly adult
-GRE or SWI sequences are very useful for the
detection of small and diffuse hypointense regions
-In contrast to the microhemorrhages associated with
hypertension , CAA microhemorrhages are in the
cortex not in the basal ganglia

-Intraparenchymal hemorrhage associated with cerebral amyloid angiopathy , 70
years old male patient with lobar hemorrhagic collections in different stages ,
SWI identified multiples hypointense foci (arrow) in relation to microbleedings
, their distribution and multiplicity are typical of hemosiderin deposits in the
context of cerebral amyloid angiopathy

4-Vascular malformations :
-See (Vascular Malformations)
-Are found in lobe regions and presents a larger
hematomas associated
-Aneurysmal hemorrhage is by far the most common
cause of nontraumatic hemorrhage , if an
intraparenchymal hematoma is due to an aneurysm ,
the hematoma is usually adjacent to the ruptured
aneurysm dome , the pattern of SAH 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

-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
-Dural AVFs is 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) & posterior fossa dAVFs are the
most common types
-Cavernoma , although non-hemorrhagic cavernomas have a
characteristic MRI with popcorn-like lobular mixed/high signal
on T1 & T2 and a dark peripheral hemosiderin rim , once
bleeding occurs , the resultant hematomas has nonspecific
imaging features , the presence of a developmental venous
anomaly adjacent to a hematoma may suggest the diagnosis
of a recently hemorrhaged cavernoma

5-Hemorrhage Secondary to Tumors :
-There is more edema and mass effect compared to simple
bleeding and the vasogenic edema is persistent on time
-Most common primary tumor to cause hemorrhage is
glioblastoma
-There are relatively limited number of extracranial primary
tumors known to cause hemorrhagic metastases , including :
Choriocarcinoma , melanoma , thyroid carcinoma , renal cell
carcinoma
-In cases where the diagnosis is unclear , a follow-up MRI should
be performed once the initial hemorrhagic improves , it
tumor is present , the MRI may show a delay in the expected
evolution of blood products , persistent edema &
enhancement of the underlying tumor

-Intraparenchymal hemorrhage associated with tumor This patient suffered a stroke in the right
cerebral hemisphere few months ago , subsequently he was admitted to our hospital for
neurological deficit , T2 , T2 FLAIR and SWI show a hemorrhagic lesion in the left temporal
lobe , the initial diagnosis was of a hemorrhagic infarction , 7 months later , this lesion had
enlarged and presented pathological enhancement after the administration of contrast (
arrow ) , the final diagnosis was a tumoral lesion with bleeding

6-Coagulopathies (due to the use of anticoagulants and
thrombolytic agents)
7-Sympathomimetic drugs effect (amphetamines ,
phenylpropanolamine and cocaine)
8-Vasculitis :
-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 multiple foci of T2 prolongation in
the basal ganglia & subcortical white matter
-Angiography is the most sensitive test and shows multifocal
areas of stenosis & dilatation

9-Moyamoya :
-Moyamoya is a non-atherosclerotic vasculopathy
characterized by progressive stenosis of the
intracranial internal carotid arteries & their proximal
branches which leads to proliferation of fragile
lenticulostriate collateral vessels
-Angiography of the enlarged basal perforating arteries
gives a puff of smoke appearance
-The ivy sign on FLAIR represents tubular branching
hyperintense structures within the sulci representing
cortical arterial branches that appear hyperintense
due to slow collateral flow
-Perfusion studies show decreased flow in the affected
vascular regions

2-Extracerebral (Extra-axial) :
-The blood can be located in the ventricular
system , subarachnoid spaces , subdural space
and epidural space
-Extracerebral Hemorrhages compromise :
a) Epidural Hemorrhage (EDH)
b) Subdural Hemorrhage (SDH)
c) Subarachnoid Hemorrhage (SAH)
d) Intraventricular Hemorrhage (IVH)

a) Epidural Hemorrhage (EDH) :
-It is a blood collection extra-axial , results more
frequently from the laceration of the meningeal
arteries
-Location : blood between the skull and the dura mater
-Cause : It usually occurs after a severe head trauma and
the temporal lobe is affected more frequently
-Characteristics : It is a well defined biconvex collection ,
it does not exceed the skull sutures and it can cross the
midline

b) Subdural Hemorrhage (SDH) :
-It is a blood collection extra-axial and generally it
occurs by laceration of a cortical vein
-Location : They are located between the dura
mater and the arachnoid
-Cause : Trauma is the most common cause
-Characteristics : Crescentic extra-axial collection , it
can cross skull sutures , it never cross the midline
due to it is reflected along the brain falx

Subdural hematoma, axial and coronal CT , hyperdense hematoma of 14 hours of evolution
located in the left side , corresponding to a subdural hematoma, axial T2 and coronal T1
MRI , in another patient , show a large subdural hematoma located in the right side , the
hematoma is hyperintense in both sequences due to blood breakdown products , indicating a
late subacute hematoma , this hematoma is causing mass effect with compression of the
ipsilateral ventricular system and sulcal effacement

c) Subarachnoid Hemorrhage (SAH) :
-It is a blood collection extra-axial
-Can be traumatic (laceration of cortical veins or
arteries localized in the subarachnoid space or
cortical contusions with extravasation of
blood into the subarachnoid space) or non-
traumatic (ruptured aneurysms)

-Location : there is an accumulation of blood
within the subarachnoid space
-Cause : trauma is the most common cause
-Characteristics : Blood within subarachnoid
spaces between pia and arachnoid
membranes

-CT is very sensitive in detecting hyperdense blood
in the basal cistern and subarachnoid space
-On MRI , the blood is diluted with the
cerebrospinal fluid signal (CSF) , for this reason it
is difficult to detect on normal T2-weighted
sequences , on the other hand on T2-FLAIR
sequences subarachnoid hemorrhage is easily
detected as its signal is not suppressed like in
normal CSF

MR imaging shows subarachnoid hemorrhage, SAH appears hyperintense on
the T2 and FLAIR and isointense to hypointense on the T1, marked
blooming is observed on the gradient-echo (GRE), findings in the right
parietal region extend into cortical sulci and suggest hyperacute or acute
hemorrhage

MRI images show an extensive subarachnoid hemorrhage along the right cerebral convexity most
prominently in the frontal region, also depicted are edema in the underlying cerebral parenchyma ,
mass effect and compression of the right lateral ventricle, the hemorrhage appears hyperintense
on T1 , with low signal on T2 and blooming on gradient-echo (GRE), the vasogenic edema appears
hyperintense on T2 and GRE, TOF MRA shows a partially thrombotic aneurysm at the right
trifurcation of the MCA , these features suggest rupture of the aneurysm

d) Intraventricular Hemorrhage (IVH) :
-May be due to an extension of
intraparenchymal hemorrhage or from the
reflux of blood from the subarachnoid spaces

Intraventricular hemorrhage, CT shows an acute intraventricular hemorrhage in a
60 year-old man , the blood is located in both lateral ventricles due to an
extension of an intraparenchymal hematoma, located in the left frontal lobe,
T2 , T2 FLAIR and SWI show a hypointense hematoma and intraventricular
hemorrhage, sagittal T1 shows hyperintensity of the intraventricular
hemorrhage (early subacute stage)

Intraventricular hemorrhage, axial , sagittal and coronal CT show a hyperdense hematoma
located in the left caudate (arrow) with contamination of the ipsilateral lateral
ventricle and third ventricle system of acute stage, the hematoma and the
intraventricular hemorrhage are hyperintense on sagittal T1, the intraventricular
hemorrhage is hypointense on T2-weighted and SWI (arrow) , indicating an early
subacute stage

b) Staging of Hematoma :
-The evolution of an hematoma has been divided
into 5 stages:
1-Hyperacute hemorrhage: < 12 hrs of evolution
2-Acute hemorrhage: 12 hrs to 48 hrs of evolution
3-Early subacute hemorrhage: 2 days to 7 days of
evolution
4-Late subacute hemorrhage: 8 days to 1 month
5-Chronic hemorrhage: > 1 month

c) CT :
1-Hyperacute stage
2-Acute & Early subacute stages
3-Late subacute stage
4-Chronic stage

1-Hyperacute stage :
-The extravasated blood has a heterogeneous
pattern with a density between of 40-60
Hounsfield units (HU) , this density is equally
to the adjacent normal brain parenchyma
-It can be difficult to differentiate the density of
the parenchyma and extravasated blood

2-Acute and early subacute stage :
-In this phases there is going to be blood clot
retraction with increased density of the
hematoma
-The hematoma is going to be detected as
hyperdense in these phases (80 HU) with a
hypodense halo due to vasogenic edema

3-Late subacute stage :
-The hematoma is isodense to the adjacent
normal brain parenchyma
-This stage is characterized by the proteolysis of
the globin protein

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