[NEURO]LEC_208_BRAIN-PROTECTION.pdf

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(008) BRAIN PROTECTION
DR. A. VIADO | 01/27/2021

OUTLINE
I. BRAIN PROTECTION a. Dura Mater
A. MENINGES - 2 layers of fibrous connective tissue
1. 3 Layers of Meninges Periosteal layer (endosteal) - attached to bone
a. Dura mater Meningeal layer (dura mater proper) - proper brain covering
b. Arachnoid mater
c. Pia mater - dural partitions subdivide cranial cavity & limit movement of brain:
2. Potential Intermeningeal Spaces a. Falx cerebri (sickle-shaped fold)
3. Basic Differences of Intracranial Injuries - In longitudinal fissure; attaches to crista galli of ethmoid
B. CEREBROSPINAL FLUID bone
1. CSF Production - largest dural fold and separates the two cerebral
2. Ventricles hemispheres at midline.
3. CSF pathway b. Falx cerebelli (small, sickle-shaped fold)
a. Hydrocephalus - Runs vertically along vermis of cerebellum
C. BLOOD BRAIN BARRIER - separates the two cerebellar hemispheres.
II. INPUTS FROM THE MENINGES AND DURAL c. Tentorium cerebelli (crescent-shaped fold)
VENOUS SINUSES VIDEO - Sheet in transverse fissure between cerebrum &
A. PARTS OF MENINGES cerebellum
B. DURAL VENOUS SINUSES - is continuous with the falx cerebri and separates the
cerebrum from the cerebellum.
III. INPUTS FROM THE VENTRICULAR SYSTEM OF THE
BRAIN VIDEO
A. VENTRICLES
B. CEREBROSPINAL FLUID (CSF)
IV. INPUTS FROM THE BLOOD SUPPLY TO THE BRAIN
VIDEO
A. INTERNAL CAROTID ARTERY (ICA)
B. VERTEBROBASILAR ARTERY
C. CIRCLE OF WILLIS
V. TEST YOUR KNOWLEDGE
VI. REFERENCES

I. BRAIN PROTECTION
Figure 2. The dural partitions
1. Meninges: Covers the brain
2. Cerebrospinal fluid: Cushions the brain b. Arachnoid mater
3. Blood brain barrier: Prevents chemicals and toxins from entering delicate, impermeable membrane covering the brain and lying
the brain between the pia mater internally and the dura mater externally
It is separated from the dura by a potential space, the subdural
A. MENINGES space, filled by a film of fluid.
The brain in the skull is surrounded by three protective membranes or it is separated from the pia by the subarachnoid space, which
meninges: the dura mater, the arachnoid mater, and the pia mater. is filled with CSF.
Deep to arachnoid is subarachnoid space
1. 3 layers of Meninges: o Filled with CSF
a. Dura mater o blood vessels run through (susceptible to tearing)
b. Arachnoid mater Superiorly, forms arachnoid villi: CSF valves
c. Pia mater o Allow draining into dural blood sinuses
o Reabsorption of CSF

c. Pia mater
The pia mater is a vascular membrane that closely invests the
brain, covering the gyri and descending into the deepest sulci.
The cerebral arteries entering the substance of the brain carry a
sheath of pia with them.
The pia mater forms the tela choroidea of the roof of the third
and fourth ventricles of the brain, and it fuses with the ependyma
to form the choroid plexuses in the lateral, third, and fourth
ventricles of the brain.
Delicate, clings to brain following convolutions.
Figure 1. The three layers of meninges Compared with the Dura and arachnoid which only cover brain
loosely
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2. Potential Intermeningeal Spaces b. Subdural Hematoma

Figure 6. Sample subdural hematoma
Figure 3. The potential intermeningeal spaces

Epidural: Between Inner skull and Dura mater B. CEREBROSPINAL FUID
Subdural: Between Dura and Arachnoid Mater
Subarachnoid: Between Arachnoid and Pia mater Made in choroid plexuses (roofs of ventricles)
Intracerebral: within the brain Filtration of plasma from capillaries through
ependymal cells (electrolytes, glucose)
500 ml/d; total volume 100-160 ml at a time
3. Basic Differences of Intracranial Injuries Cushions and nourishes brain
CSF Pressure = intracranial pressure
Assayed in diagnosing meningitis, bleeds, MS
Hydrocephalus: excessive accumulation

Figure 7. The cerebrospinal fluid.

Figure 4. The location of epidural, subdural, and intracerebral
1. CSF Production
hematomas.
Choroid plexus (Main CSF Production)
a. Epidural Hematoma
Interstitial space
Ependymal lining
Dura of the nerve root sleeve (Spine)
Property Pediatric Adult
(Newborn)
Total volume 5 150 (50%) intracranial.
50% spinal
Formation rate 25 ml/day 0.3-0.35 ml/min (450-
750ml/day)
Table 1. CSF Production

Note: CSF turnover 3x/day
Figure 5. Sample epidural hematoma.

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2. Ventricles
Central cavities
Filled with CSF (cerebrospinal fluid)
Lined by ependymal cells (these cells lining
the choroid plexus)
Choroid Plexus: Production of CSF

(Cerebrospinal Fluid )
Continuous with each other and central
canal of spinal cord

Figure 10. The ventricles

CSF REABSORPTION: Subarachnoid space (Arachnoid granulation)

Figure 11. The CSF reabsorption

a. Hydrocephalus: Pathology in the CSF pathway

Figures 8-9. The ventricles and its components

3. Take note: CSF pathway
- Production in the Choroid plexus of the lateral
ventricles→ foramen of Monroe → third ventricle cerebral aquaduct →
4th ventricle foramina of luschka and magendie → subarachnoid space
→ arachnoid granulations that drain into the Dural Venous Sinuses to
be recirculated again Figure 12. An image showing a child with hydrocephalus.
The rest will be drained into the central canal of the spinal cord.
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Types of Hydrocephalus

Communicating: Non-obstructive HCP.
-Impaired CSF reabsorption in the subarachnoid space
(Arachnoid granulations)
Non-Communicating:
- Obstruction within the ventricular system.

Figure 14. An image showing a normal CT-scan.

Communicating Hydrocephalus
Enlargement of lateral, 3rd,
and 4th ventricles
Note sulcal effacement, temp horns,
rounded 3rd, and enlarged 4th

Figure 13. An image showing the causes of hydrocephalus.

Figure 13. An image showing the ventricles and components.

Figure 15. An image showing a CT-scan with hydrocephalus case.

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CSF circulation: through ventricles, median and lateral apertures, CSF:
subarachnoid space, arachnoid villi, and into the blood of the superior -Made in choroid plexus
sagittal sinus -Drained through arachnoid villus

Ventricle

Cannula (narrow
tube) inserted into
ventricle (cavity) of
the brain to drain CSF

Pressure valve (adjusts
fluid drainage to keep a
consistent level of fluid
pressure in the brain)

Drainage tube passes
under the skin and
continues into the
abdomen (belly)
Cannula (narrow tube)
inserted into a ventricle
(cavity) of the brain to Figures 16-18. Images showing the CSF circulation.
drain CSF

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C. BLOOD BRAIN BARRIER (BBB)
Tight junctions between endothelial cells of brain
capillaries, instead of the usual permeability.
Formed by astrocytes.
Highly selective transport mechanisms
Allows nutrients, O2, CO2
allows uncharged and lipid soluble molecules; allows
alcohol, nicotine, and some drugs including anesthetics.
Prevents lipophilic neurotoxins, bacteria

Figure 20. Image showing Blood Brain Barrier.

Figure 19. Actual photos from Dr. Viado.

Figure 21. Image showing the lobes of the brain.

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Figure 22. Image showing the respective functions of each lobe of
the brain. Figure 24. Brain, sagittal sec, medial view

1. Cerebral hemisphere
2. Corpus callosum
3. Thalamus
4. Midbrain
5. Pons
6. Cerebellum
7. Medulla oblongata

Figure 23. Pons & Cerebellum, sagittal section, medial view

1. Midbrain
2. Cerebellum
3. Pons
4. Medulla oblongata
5. Inferior colliculus
6. Superior medullary velum
7. Fourth ventricle

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SUPPLEMENTAL NOTES:

The brain is supplied by the two internal carotid and the two
vertebral arteries that lie within cerebrospinal fluid of the
subarachnoid space.
The internal carotid begins at the bifurcation of the common
carotid in the neck, where it possesses a local dilation called
the carotid sinus.
The internal carotid enters the cranial cavity through the
carotid canal of the temporal bone.
The internal carotid terminates as the anterior and middle
cerebral arteries after giving off ophthalmic and posterior
communicating arteries.
The two vertebral arteries enter the cranial cavity through the
foramen magnum after ascending through the transverse
foramina of the cervical vertebrae. A. PARTS OF MENINGES
The cranial portion of the vertebral artery gives off the
posterior spinal, anterior spinal, posterior inferior cerebellar,
medullary, and meningeal arteries. 1. Dura mater
The vertebral arteries merge to form the basilar artery on the
Periosteal layer and meningeal layer
anterior surface of the pons.
Dural septae
The basilar artery branches into pontine, labyrinthine,
anterior Inferior cerebellar, superior cerebellar, and posterior Dural venous sinuses
cerebral arteries. 2. Arachnoid mater
The circle of Willis is formed by the anastomosis between Subarachnoid space
the two internal carotid and vertebral blood supplies by Arachnoid granulations (villi)
communication of the anterior cerebral and anterior 3. Pia mater
communicating arteries, internal carotid arteries, posterior
communicating and posterior cerebral arteries, and the
basilar artery.
The corpus striatum and Internal capsule are supplied by the
medial and lateral striate branches of the middle cerebral
artery.
The thalamus Is supplied by branches of the posterior
communicating, basilar, and posterior cerebral arteries.
The midbrain is supplied by the posterior cerebral, superior
cerebellar, and basilar arteries.
The pons is supplied by the basilar, anterior inferior, and
superior cerebellar arteries.
The medulla oblongata ls supplied by the vertebral, anterior
and posterior spinal, posterior inferior cerebellar, and basilar
arteries.
The cerebellum is supplied by the superior cerebellar,
anterior inferior cerebellar, and posterior inferior cerebellar Parts of meninges:
arteries. 1. Dura mater

II. INPUTS FROM THE MENINGES AND DURAL
VENOUS SINUSES VIDEO

What:
…are the meninges
…. Are the dural venous sinuses
…Is the deal with the cerebral circulation

Anatomy:
1. Layers of the scalp
2. Skull bones
3. Meninges
4. Brain
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Periosteal layer and meningeal layer
Most superficial layer of the meninges
L. Dura “tough” L. mater “mother”
Consist of 2 layers:
o Periosteal layer: lines internal surface of skull;
ends at the foramen magnum
o Meningeal layer: continuous with the brain and
spinal cord

Vertical and separates cerebral hemispheres within
longitudinal cerebral fissure

Dural septae
2 dural layers are bound together and only separate when
forming dural septae and dural venous sinuses
o Periosteal layer
o Meningeal layer
Restrict displacement of the brain (much like a seat belt)
o Falx cerebri
o Falx= L. “Sickle”

Tentorium cerebelli
Horizontal and separates the occipital lobes and cerebellum

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Falx cerebelli Dural venous sinuses (DVS) are similar to veins in that it contains
venous blood and are lined with endothelium
Located between cerebellar lobes
But DVS are not similar to vein in that they lack valves and
they lack tunica media
Basically, Dura mater; dense connective tissue line with
endothelium that’s where DVS is.

B. DURAL VENOUS SINUSES
Venous channels located between the periosteal and
meningeal layers of dura mater

Dural venous sinuses (DVS)
a) Cavernous sinus
Located on each side of the sella turcica (pituitary
gland)
CNN III, IV, V-1 and V-2 course through lateral wall
CNN VI and ICA (Internal carotid artery) course through
the middle

Receive blood from cerebral, diploic and emissary veins

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2. Arachnoid mater
Middle layer of the meninges; drapes over brain and
spinal cord
Arachnoid= L. “spider-like” mater= L. “mother”

Communicates with the facial vein and pterygoid plexus
of veins in addition to draining into the sigmoid sinus

All DVS’s ultimately drain into the Internal Jugular Vein
(IJV)

Subarachnoid space – is filled with CSF, which surrounds
the brain and spinal cord
Arachnoid granulations (villi)- CSF drains from
subarachnoid space into the sup sagittal sinus

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III. INPUTS FROM THE VENTRICULAR SYSTEM OF
THE BRAIN VIDEO

What
…are the ventricles of the brain?
…is CSF, where is it produced and where does if flow?
A. VENTRICLES
1. Lateral ventricles
2. 3rd ventricle
3. 4th ventricle
3. Pia mater
Pia L. “soft” mater L. “mother”
They are called soft because they are composed of
Loose connective Tissue
Deepest layer of the meninges; intimately associated
with brain and spinal cord

Ventricles:
1. Lateral ventricles
Paired, C-shaped chambers in each cerebral
hemisphere
Largest of the ventricles
Below the corpus callosum

2. Interventricular foramen (of Monroe)
Communication between the lateral ventricles and 3rd
ventricle

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3. 3rd ventricle
Midline, narrow space between the L and R
diencephalon

B. CEREBROSPINAL FLUID (CSF)
4. Cerebral aqueduct
Aka: Mesencephalic aqueduct / Aqueduct of Sylvius Cerebrospinal fluid (CSF):
Located in the midbrain Chroroid plexus
Connects the 3rd and 4th ventricles o Produces CSF (enables CNS to float)
o Located in each ventricle

5. 4th ventricle
Located between the pons/ medulla and cerebellum

Ventricular System

Flow starts at CSF from the choroid plexus from the lateral ventricles

Flows into Inter-ventricular (IV) foramen

Joins with the CSF of the 3rd Ventricles choroid plexuses

flow down to the cerebral aqueduct

Join from the CSF produce from the 4th ventricles choroid plexus

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4th Ventricle
Median Aperture (median apeture of magendie) Note:
Lateral Aperture (lateral apeture of luschka) CSF come from Choroid plexus
Subarachnoid space flows also at SPINAL CORD
Note: this two apertures (opening) were to communicating with the CSF drain into the blood thru at superior sagital sinus thru
CSF from the 4th ventricles to the Subarachnoid space arachnoid granulation

Subarachnoid space - CSF from Subarachnoid space
flows around the outside of the brain until it reach the
arachnoid granulation.

Arachnoid granulation – filtering plasma from up, filtering
CSF from the subarachnoid space into the dura venous Volume of CSF in Adults = 150ml
sinus and enters in the superior sagittal sinus o CSF is replaced every 8 Hours
o About 500ml is formed each day
o CSF cushions and gives buoyancy to the brain
and spinal cord

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A. INTERNAL CAROTID ARTERY (ICA)

IV. INPUTS FROM THE BLOOD SUPPLY TO THE
BRAIN VIDEO
BRAIN is supplied by 2 Arteries:
1. Internal carotid artery (ICA)
2. Vertebrobasilar artery
Bifurcates into internal and external carotid artery on a
lateral view.
Internal carotid artery ascends up and goes up on the base
of the skull (carotid canal)

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Parts of Internal Carotid:
Cervical-carotid artery is on the neck, on the cervical region.

Cerebral-is the part where all branches of internal carotid comes of.

Petrous- carotid artery going from the base of the skull and carotid
artery in the middle cranial fossa between the the two is the internal
carotid artery of petrous part.

Cavernous
Branches of Internal Carotid:
is the part that is in the cavernous sinus a. Ophthalmic artery - goes to the eyes
the only artery that is inside of a vein.
*Central Artery-supplies the the retina of the eyes
If its occluded because of diabetes or clot, blindness will
occur.

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b. Posterior communicating artery d. Anterior communicating artery-connecting the two anterior
Connects the post cerebral artery and ICA cerebral artery (ACA)

e. Middle Cerebral Artery (MCA) - located at the middle of
cerebrum
Connects anterior and posterior circulation on one side

Distribution- Lateral aspect of cerebral hemispheres (except
superior front/parietal and inferior temporal lobes)

c. Anterior Cerebral Artery (ACA)-supplies the front of the
cerebrum
Distribution- Medial aspect of cerebral hemisphere back to B. VERTEBROBASILAR ARTERY
parietal lobe.

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b. Anterior spinal artery-supplies the front of the spinal cord.

c. Basilar artery-comes from two vertebral artery to become basal
artery that course vertically along the pons between the pons and
clivus of the scalp.
consist of the Vertebral arteries and Basilar artery
Vertebral arteries - arises from the subclavian artery and
ascend up to neck thru the transverse foramina of the
cervical vertebrae through the foramen magnun and into the
skull. Then, vertebral artery traverse with foramen magnum
and fuses with the other vertebral artery and becomes basal
artery.

C. CIRCLE OF WILLIS

Branches: Branches:
a. Posterior inferior cerebellar artery (PICA)-supplies the bottom a. Anterior inferior cerebellar artery (AICA)-supplies the front and
back of the cerebellum bottom of the cerebellum.

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b. Superior cerebellar artery - supplies the top of the cerebellum.
Collateral circulation between the 2 ICA’s and
Vertebrobasilar arteries
Name after the anatomist THOMAS WILLIS (1621-1675)
and numbered the Cranial nerves (CN). He is also the one
who termed Diabetes Mellitus.

c. Posterior cerebellar artery-supplies the back of the cerebrum

Provides redundancy and permits circulation should a part of
the circle be occluded.

*CN III - is in between the posterior cerebral artery and superior
cerebellar artery.
Forms around the optic chiasm and pituitary gland
if there are varying aneurysm to the both it can pulls off the
CN III and leads to eye deficit.
Distribution- Occipital Lobe (vissual cortex), temporal
Lobe(post-med/inf)

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V. TEST YOURSELF 10. Shunts CSF from ventricle to abdomen
A. Ventriculoatrial shunting
1. True or False
B. Ventriculoperitoneal Shunting
Blood Brain Barrier prevents the passage of the large hydrophobic
C. Ventriculopleural
neurotoxins and pathogens like bacteria.
D. Third ventriculostomy
2. What is the major contributor of CSF production?
11. It prevents chemicals and toxins from entering the brain
A. Dura of the nerve
A. Meninges
B. Ependymal lining
B. Cerebrospinal fluid
C. Interstitial space
C. Blood Brain Barrier
D. Choroid Plexus
D. Dural venous sinuses
3. This is due to increased CSF production but impaired
12.The following statements concern the ventricular system:
reabsorption.
A. The fourth ventricle has a rectangular-shaped floor.
A. Meningitis
B. The pineal body is suspended from the roof of the fourth
B. Aneurysm
ventricle.
C. Hydrocephalus
C. The nerve centers controlling the heart rate and blood pressure
lie beneath the floor of the third ventricle.
4. Runs vertically along vermis of cerebellum.
D. The choroid plexus of the lateral ventricle projects into the
A. Falx cerebri
cavity on its medial side through the choroidal fissure.
B. Falx cerebelli
C. Tentorium cerebelli
13. The following statements concern the blood—brain barrier
D. Tentorium cerebri
(BBB):
A. It protects the brain from toxic compounds of low molecular
5. This serves as roof of ventricles.
weight. (b) It is present in the pineal gland.
A. Corpus callosum
B. The endothelial cells of the blood capillaries are
B. Superior sagittal sinus
nonfenestrated.
C. Choroid plexus
C. The endothelial cells of the blood capillaries are held
D. Third ventricle
together by localized tight junctions.
D. L—Dopa has difficulty passing through it in the treatment of
6. The following nerves are sensory to the dura mater:
Parkinson disease.
A. Oculomotor nerve
B. Trochlear nerve
C. Sixth cervical spinal nerve A 58-year-old man, while eating his evening meal, suddenly
D. Trigeminal nerve complained of a severe headache. Moments later, he slumped
E. Hypoglossal nerve forward and lost consciousness.

7. The following structure limits rotatory movements of the brain
14. On being admitted to the hospital, the examining physician
within the skull:
could have found the following physical signs except:
A. Tentorium cerebelli A. He was in a deep coma, and his breathing was deep and
B. Diaphragma sellae slow.
C. Falx cerebri B. The patient’s head was turned to the left.
D. Dorsum sellae C. The muscle tone of the limbs was less on the right side than
on the left.
8. True or False D. The right abdominal reflexes were absent, and there was a
Midbrain surrounds the third ventricle. positive Babinski response on the left side.

9. It separates supratentorial from infratentorial compartment. 15. Three days later, the patient regained consciousness, and the
A. Falx cerebri following additional signs could have become apparent except:
B. Falx cerebelli A. The right arm and, to a lesser extent, the right leg were
C. Tentorium cerebelli paralyzed.
D. Tentorium cerebri B. Movements of the left arm and leg and the left side of the
face were normal.

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C. The upper and lower parts of the right side of his face were
paralyzed.
D. The patient had difficulty in swallowing.

ANSWERS:

1. False. It should be hydrophilic
2. D. Choroid Plexus
3. C. Hydrocephalus
4. B. Falx cerebelli
5. C. Choroid plexus
6. D is correct. The trigeminal nerve is an important sensory nerve to the dura
mater within the skull.
7. C is correct. The falx cerebri limits rotatory movements of the brain within the
skull.
8. False. Diencephalon
9. C. Tentorium Cerebelli
10. B. Ventriculoperitoneal Shunting
11. C. Blood Brain Barrier
12. D is correct. The choroid plexus of the lateral ventricle projects into the cavity
on its medial side through the choroidal fissure.
13. C is correct. The endothelial cells of the blood capillaries in the BBB are non
fenestrated.
14. D is the exception. A positive Babinski sign was present on the right side.
15. C is the exception. The muscles of the upper part of the face on the right side
are not affected by a lesion involving the upper motor neurons on the left side
of the brain. This is due to the fact that the part of the facial nucleus of the
seventh cranial nerve that controls the muscles of the upper part of the face
receives corticonuclear fibers from both cerebral hemispheres.

VI. REFERENCES

PDF – Dr. Allan Viado

Ph.D., S.R. (2018). Snell’s Clinical Neuroanatomy (8th ed.). LWW

Videos – Dr. Allan Viado

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