Blood supply of Human Brain
AmjadAli224
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May 27, 2016
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About This Presentation
Blood supply of Human Brain
Slide Content
Dr. Amjad PT
The consequences of stroke depend upon which areas
of the brain are affected by ischemia, hemorrhage,
hematoma or aneurysm. Therefore, it is important to
understand the organization of the cerebral blood
supply system.
Two arterial systems supply the brain with blood: the
internal carotid and vertebral. Theinternal
carotidsandvertebro-basilar arteriesare connected
via thecircle of Willis, which allows blood to pass
from one system to another in the event of blockage.
of the brain are affected by ischemia, hemorrhage,
hematoma or aneurysm. Therefore, it is important to
understand the organization of the cerebral blood
supply system.
Two arterial systems supply the brain with blood: the
internal carotid and vertebral. Theinternal
carotidsandvertebro-basilar arteriesare connected
via thecircle of Willis, which allows blood to pass
from one system to another in the event of blockage.
C1
C2
C3
C4
C5
C6
C7
ant. clinoid proc.
cavernous sinus
foramen lacerum
carotid canal
C2
C3
C4
C5
C6
C7
ant. clinoid proc.
cavernous sinus
foramen lacerum
carotid canal
The Internal Carotid Arteries
There are two internal carotid arteries. They ascend from
the aortic arch toward the brain along each side of the
neck. They pass behind the ear into thetemporal
lobeand enter the subarachnoid space. They then go to
the circle of Willis where each bifurcates to form two
main branches: theanterior cerebral arteryand
themiddle cerebral artery.The course of the internal
carotid arteries and their branches is tortuous.
Because of their many twists and turns these arteries
are all subject to blockages caused by cholesterol
build-up. For this reason, the internal carotids, and
the middle and anterior cerebral arteries are more
vulnerable to ischemic rather than hemorrhagic
stroke.
There are two internal carotid arteries. They ascend from
the aortic arch toward the brain along each side of the
neck. They pass behind the ear into thetemporal
lobeand enter the subarachnoid space. They then go to
the circle of Willis where each bifurcates to form two
main branches: theanterior cerebral arteryand
themiddle cerebral artery.The course of the internal
carotid arteries and their branches is tortuous.
Because of their many twists and turns these arteries
are all subject to blockages caused by cholesterol
build-up. For this reason, the internal carotids, and
the middle and anterior cerebral arteries are more
vulnerable to ischemic rather than hemorrhagic
stroke.
The contralateral internal carotid may use the circle of Willis/anterior
communicating artery to supply blood tobothpairs of anterior and
middle cerebral arteries. Complete interruption of blood flow in the
anterior cerebral artery is not very likely because the opposite anterior
cerebral can use the anterior communicating artery to make up for the
deficiency.
A patient who has suffered such a blockage might have a paralyzed leg
or be incontinent of bowel and/or bladder. Since the parts of the motor
and sensory strips connected to the arm receive some blood from the
anterior cerebral artery, the arm may also be somewhat affected by this
kind of blockage. Finally,apraxia of gait may also occur if an anterior
cerebral artery fails to supply an adequate amount of blood to the
medial part of the motor strip.
The anterior cerebral arteries also supply blood to the anterior aspects
of thefrontal lobes. As these areas are involved in higher level cognition
such as reasoning and judgment, a condition calledcerebral dementia
may result from anterior cerebral artery blockages.Confused
language..
communicating artery to supply blood tobothpairs of anterior and
middle cerebral arteries. Complete interruption of blood flow in the
anterior cerebral artery is not very likely because the opposite anterior
cerebral can use the anterior communicating artery to make up for the
deficiency.
A patient who has suffered such a blockage might have a paralyzed leg
or be incontinent of bowel and/or bladder. Since the parts of the motor
and sensory strips connected to the arm receive some blood from the
anterior cerebral artery, the arm may also be somewhat affected by this
kind of blockage. Finally,apraxia of gait may also occur if an anterior
cerebral artery fails to supply an adequate amount of blood to the
medial part of the motor strip.
The anterior cerebral arteries also supply blood to the anterior aspects
of thefrontal lobes. As these areas are involved in higher level cognition
such as reasoning and judgment, a condition calledcerebral dementia
may result from anterior cerebral artery blockages.Confused
language..
Anterior cerebral arteries
smaller terminal branch of the ICA
enters longitudinal fissure
connected to the opposite anterior cerebral artery by
anterior communicating artery (part of the CoW)
curves over corpus callosum
–central branch supply deep masses of gray matter in the
cerebral hemisphere
–Supply:
•cortical branches supply all medial surface of cerebral cortex
up to parieto-occipital sulcus
•corpus callosum
•approximately 1 inch of the frontal and parietal cortex on the
superior aspect of their lateral surface (this include the leg
area of the precentral gyrus)
•anterior portions of the basal ganglia and internal capsule
smaller terminal branch of the ICA
enters longitudinal fissure
connected to the opposite anterior cerebral artery by
anterior communicating artery (part of the CoW)
curves over corpus callosum
–central branch supply deep masses of gray matter in the
cerebral hemisphere
–Supply:
•cortical branches supply all medial surface of cerebral cortex
up to parieto-occipital sulcus
•corpus callosum
•approximately 1 inch of the frontal and parietal cortex on the
superior aspect of their lateral surface (this include the leg
area of the precentral gyrus)
•anterior portions of the basal ganglia and internal capsule
Middle Cerebral Arteries
These large arteries have tree-like branches that bring
blood to most of thelateral cortexof each cerebral
hemisphere. This means that the middle cerebral arteries
supply blood to the cortical areas involved in speech,
language and swallowing
runs laterally in the lateral sulcus
cortical branches supply entire lateral surface of the
hemisphere EXCEPT
area supplied by anterior cerebral artery
inferolateralsurface supplied by posterior cerebral artery
occipital pole
supply all motor area except “leg area”
supply parts of the internal capsule and basal ganglia
central branches supply deep masses of gray matter within
the cerebral hemisphere
These large arteries have tree-like branches that bring
blood to most of thelateral cortexof each cerebral
hemisphere. This means that the middle cerebral arteries
supply blood to the cortical areas involved in speech,
language and swallowing
runs laterally in the lateral sulcus
cortical branches supply entire lateral surface of the
hemisphere EXCEPT
area supplied by anterior cerebral artery
inferolateralsurface supplied by posterior cerebral artery
occipital pole
supply all motor area except “leg area”
supply parts of the internal capsule and basal ganglia
central branches supply deep masses of gray matter within
the cerebral hemisphere
If theleft middle cerebral arteryis
blocked,aphasia andapraxiamay
occur.
Blockages of the right middle cerebral
artery can causeleft side neglect,
which is an impairment in the ability to
recognize and respond to stimuli on the
left side of the body,prosopagnosiaor
the inability to recognize faces, and
variouscognitive problems,
includingagnosia. All of these are part
of the right hemisphere syndrome.
blocked,aphasia andapraxiamay
occur.
Blockages of the right middle cerebral
artery can causeleft side neglect,
which is an impairment in the ability to
recognize and respond to stimuli on the
left side of the body,prosopagnosiaor
the inability to recognize faces, and
variouscognitive problems,
includingagnosia. All of these are part
of the right hemisphere syndrome.
pituitary stalk
pituitary stalk
optic chiasm
oculomotor n.
mamillary bodies
abducens n.
pituitary stalk
optic chiasm
oculomotor n.
mamillary bodies
abducens n.
•Ophthalmic artery
–enters orbit through optic canal, below and lateral to
optic nerve
–supplies the eye, including retina and optic nerve
•Posterior communicating artery
–runs backward to join posterior cerebral artery at
interpeduncular fossa
•deep depression on inferior of midbrain between cerebral
peduncles
•part of the circle of willis
Choroidalartery
enter inferior horn of lateral ventricle to supply choroid
plexus
branches may help supply the optic tract, LGB, internal
capsule and crus cerebri
–enters orbit through optic canal, below and lateral to
optic nerve
–supplies the eye, including retina and optic nerve
•Posterior communicating artery
–runs backward to join posterior cerebral artery at
interpeduncular fossa
•deep depression on inferior of midbrain between cerebral
peduncles
•part of the circle of willis
Choroidalartery
enter inferior horn of lateral ventricle to supply choroid
plexus
branches may help supply the optic tract, LGB, internal
capsule and crus cerebri
branch of the 1
st
part of the subclavian artery
Both of thevertebral arteriesascend through the spinal
column and enter the brain through the magnum foramen.
Once in the brain, they continue to ascend, traveling beside
the brain stem. At the lower border of the pons the two
vertebral arteries join together to form thebasilar
arteryorvertebro-basilar artery.
Cranial branches
–meningeal arteries
–anterior and posterior spinal arteries
–posteroinferior cerebellar artery
•largest branch of the vertebral artery and supplies parts of the
cerebellum and the dorsolateral portion of the rostral medulla
–medullary arteries
•along with posteroinferior cerebellar artery, supply most of the
medulla
st
part of the subclavian artery
Both of thevertebral arteriesascend through the spinal
column and enter the brain through the magnum foramen.
Once in the brain, they continue to ascend, traveling beside
the brain stem. At the lower border of the pons the two
vertebral arteries join together to form thebasilar
arteryorvertebro-basilar artery.
Cranial branches
–meningeal arteries
–anterior and posterior spinal arteries
–posteroinferior cerebellar artery
•largest branch of the vertebral artery and supplies parts of the
cerebellum and the dorsolateral portion of the rostral medulla
–medullary arteries
•along with posteroinferior cerebellar artery, supply most of the
medulla
at lower border of pons, vertebral arteries unite to form the BASILAR
ARTERY
ascends along the ventral midline of the pons and terminates near the
rostral border of pons by dividing into 2 posterior cerebral arteries
Vertebrobasilararterial system
posterior circulation of brain
Branches:
branches to pons, cerebellum, internal ear
labyrinthine artery
follows the course of the CN VIII and supplies inner ear
anterior inferior cerebellar artery
supplies part of the pons and the anterior and inferior regions of
the cerebellum
superior cerebellar artery
supplies part of the rostral pons and superior region of the
cerebellum
pontinebranches
supply most of pons
ARTERY
ascends along the ventral midline of the pons and terminates near the
rostral border of pons by dividing into 2 posterior cerebral arteries
Vertebrobasilararterial system
posterior circulation of brain
Branches:
branches to pons, cerebellum, internal ear
labyrinthine artery
follows the course of the CN VIII and supplies inner ear
anterior inferior cerebellar artery
supplies part of the pons and the anterior and inferior regions of
the cerebellum
superior cerebellar artery
supplies part of the rostral pons and superior region of the
cerebellum
pontinebranches
supply most of pons
Posterior Cerebral Arteries
formed by the terminal bifurcation of the basilar artery
anastomoses with the posterior communicating artery in the CoW
Supply:
lateral surface of the hemisphere –occipital pole and inferior
temporal lobe
medial surface of the hemisphere –occipital lobe and posterior
2/3 of temporal lobe
At the superior border of the pons, the basilar artery divides to
form the twoposterior cerebral arteries. These arteries
supply blood to the part of the brain that lies in the posterior
fossa of the skull, including the medialaspects of theoccipital
lobes, the inferior portions of thetemporal lobes, the
brainstem, and thecerebellum. They also deliver blood to the
thalamus and some other subcortical structures. A vascular
lesion may result in Thalamic Aphasia or Thalamic Syndrome
The basilar and posterior cerebral arteries may hemorrhage
due to shearing injuries caused by accidents or pressure due to
edema of the brain.
formed by the terminal bifurcation of the basilar artery
anastomoses with the posterior communicating artery in the CoW
Supply:
lateral surface of the hemisphere –occipital pole and inferior
temporal lobe
medial surface of the hemisphere –occipital lobe and posterior
2/3 of temporal lobe
At the superior border of the pons, the basilar artery divides to
form the twoposterior cerebral arteries. These arteries
supply blood to the part of the brain that lies in the posterior
fossa of the skull, including the medialaspects of theoccipital
lobes, the inferior portions of thetemporal lobes, the
brainstem, and thecerebellum. They also deliver blood to the
thalamus and some other subcortical structures. A vascular
lesion may result in Thalamic Aphasia or Thalamic Syndrome
The basilar and posterior cerebral arteries may hemorrhage
due to shearing injuries caused by accidents or pressure due to
edema of the brain.
Since they provide blood to
the occipital lobes, damage
to these arteries can cause a
variety of visual problems,
includingcortical blindness,
which is an inability to read
andvisual agnosia, or the
inability to recognize stimuli
presented visually. Because
these arteries supply blood to
the cerebellum and to the
brain stem, blockages or
hemorrhaging there can
cause
eitherataxic(cerebellar)or
flaccid(lower motor neuron)
dysarthria..
the occipital lobes, damage
to these arteries can cause a
variety of visual problems,
includingcortical blindness,
which is an inability to read
andvisual agnosia, or the
inability to recognize stimuli
presented visually. Because
these arteries supply blood to
the cerebellum and to the
brain stem, blockages or
hemorrhaging there can
cause
eitherataxic(cerebellar)or
flaccid(lower motor neuron)
dysarthria..
•located at base of brain
•anterior partlies in front of optic chiasm
•posterior partsituated just below the mamillarybodies
•allows for excellent collateral circulation
–occlusion of an individual artery
•often completely compensated by collateral circulation through the
CoW
Formed by:
terminal part of the ICA
proximal parts of the anterior, middle and posterior cerebral
arteries
anterior and posterior communicating arteries
•anterior partlies in front of optic chiasm
•posterior partsituated just below the mamillarybodies
•allows for excellent collateral circulation
–occlusion of an individual artery
•often completely compensated by collateral circulation through the
CoW
Formed by:
terminal part of the ICA
proximal parts of the anterior, middle and posterior cerebral
arteries
anterior and posterior communicating arteries
1 –Vertebral artery
2 –AICA
3 –Basilar artery
4 –Superior cerebellar artery
5 –Posterior cerebral artery
6 –Posterior communicating artery
7 –Middle cerebral artery
8 –ICA
9 –Opthalmicartery
10 –Anterior cerebral artery
11 –Anterior communicating artery
12 –Hypothalamic artery
13 –Anterior choroidalartery
2 –AICA
3 –Basilar artery
4 –Superior cerebellar artery
5 –Posterior cerebral artery
6 –Posterior communicating artery
7 –Middle cerebral artery
8 –ICA
9 –Opthalmicartery
10 –Anterior cerebral artery
11 –Anterior communicating artery
12 –Hypothalamic artery
13 –Anterior choroidalartery
In the Circle of Willis the two internal carotids are joined together by
theanterior communicating arterywhile theposterior communicating
arterylinks the internal carotid system with the basilar artery. These
connections makecollateral circulation, which Love and Webb define as
"the flow of blood through an alternate route," possible. This is a safety
mechanism, allowing brain areas to continue receiving adequate blood
supply even when there is a blockage somewhere in an arterial system.
When all arteries are functioning normally, their blood supplies will not
mix where they meet in the Circle because the pressure of their streams
will be equal.
As long as the Circle of Willis can maintain blood pressure at fifty
percent of its normal level, noinfarctionor death of tissue will occur in
an area where a blockage exists. If collateral circulation is good,
sometimes a blockage will have no permanent effects. Sometimes, an
adjustment time is required before collateral circulation can reach a
level that supports normal functioning; the communicating arteries will
enlarge as blood flow through them increases. In such cases, atransient
ischemic attackmay occur, meaning that parts of the brain are
temporarily deprived of oxygen.
theanterior communicating arterywhile theposterior communicating
arterylinks the internal carotid system with the basilar artery. These
connections makecollateral circulation, which Love and Webb define as
"the flow of blood through an alternate route," possible. This is a safety
mechanism, allowing brain areas to continue receiving adequate blood
supply even when there is a blockage somewhere in an arterial system.
When all arteries are functioning normally, their blood supplies will not
mix where they meet in the Circle because the pressure of their streams
will be equal.
As long as the Circle of Willis can maintain blood pressure at fifty
percent of its normal level, noinfarctionor death of tissue will occur in
an area where a blockage exists. If collateral circulation is good,
sometimes a blockage will have no permanent effects. Sometimes, an
adjustment time is required before collateral circulation can reach a
level that supports normal functioning; the communicating arteries will
enlarge as blood flow through them increases. In such cases, atransient
ischemic attackmay occur, meaning that parts of the brain are
temporarily deprived of oxygen.
•veins of the brain have no muscular tissuein the wall
and no valves
•Veins –Located in the SAS
•Venous sinuses –located between 2 layers of the Dura
•superficial and deep veins of the brain drain into the
duralvenous sinuses (which in turn drain into the
internal jugular veins)
•Superficial veins
–drain the cortex and the more superficial hemispheric
white mater mainly into the superior sagittal and
cavernous sinuses
and no valves
•Veins –Located in the SAS
•Venous sinuses –located between 2 layers of the Dura
•superficial and deep veins of the brain drain into the
duralvenous sinuses (which in turn drain into the
internal jugular veins)
•Superficial veins
–drain the cortex and the more superficial hemispheric
white mater mainly into the superior sagittal and
cavernous sinuses
•Deep or internal veins
–drain the deep hemispheric white mater and basal
ganglia into the 2 internal cerebral veins which unite to
form the great cerebral vein
•Great cerebral vein
–formed by the union of 2 internal cerebral veins and
drains into the straight sinus
–drain the deep hemispheric white mater and basal
ganglia into the 2 internal cerebral veins which unite to
form the great cerebral vein
•Great cerebral vein
–formed by the union of 2 internal cerebral veins and
drains into the straight sinus
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