LOM TBL 1 NEURO PDF

Summary

This document discusses the meninges and ventricular system, blood-brain barrier, and cerebral arterial supply. It covers topics like hydrocephalus and the different types of hydrocephalus and how the blood brain barrier affects the passage of substances into and out of the brain, and the details of the arterial supply of the CNS, details of the internal carotid arteries and the vertebral arteries.

Full Transcript

Meninges & Ventricular

Choroid plexus (network of capillaries) is the main source of CSF and actively regulates in
constituents

Hydrocephalus
Dilation of one or more parts of the ventricular system and/or subarachnoid space due to the
ABNORMAL COLLECTION OF CSF

Noncommunicating (Obstructive) hydrocephalus
- Obstruction of CSF flow within the ventricular system (interventricular foramen, cerebral
aqueduct) or from ventricular to subarachnoid space (medial and lateral apertures of 4th
v)
- This causes an enlargement of ventricles PROXIMAL to the obstruction
- The most common cause of the obstruction of the cerebral aqueduct (enlargement of the
3rd ventricle?)
- Can there be an obstruction between multiple sites of ventricular system

Communicating hydrocephalus
- Caused by impaired CSF reabsorption in arachnoid granulations (usually secondary to
subarachnoid hemorrhage) or rarely by excess CSF production
- (all?)Ventricles and subarachnoid space are dilated

Normal pressure hydrocephalus
- Seen in elderly
- Clinical triad: gait difficulties, urinary incontinence, mental decline (dementia)
***cant walk, cant pee, cant think
- CSF pressure is not elevated; unknown mechanism (thought to be communicating w
impaired CSF reabsorption)

Blood Brain Barrier and Blood-CSF Barrier
Large molecules cant pass from blood to extracellular fluid of CNS due to existence of blood
brain barrier
Components of the BBB
- Endothelial cells with tight junctions between then
- Astrocytes with perivascular end-feet
- Capillary basement membrane
**BBB prevents entry of blood-borne foreign substances into the brain tissue, BUT problem
when the goal is to deliver drugs into the CNS

Large molecules cant pass from blood to CSF either due to the: blood-CSF barrier
*pls explain more about the blood-CSF barrier
In the choroid plexus, tight junctions do not exist between endothelial cells lining the capillary
wall; the capillary endothelium is fenestrated (large molecules can pass from blood through this
cap endothelium of choroid plexus)

**the blood brain barrier protects most of the blood vessels in the brain but some areas lack
BBB (circumventricular organs) that are centered around the ventricles in the brain
- Their functions require access into the bloodstream

Arterial Supply of the CNS

Internal Carotid
Begins at bifurcation of common carotid
4 parts:
Cervical (origin to base of skull)
Petrous (petrous part of temporal bone, with the carotid
canal)
Cavernous (within cavernous sinus)
Cerebral (exit cavernous sinus - become anterior &
middle cerebral arteries)

Br. of CEREBRAL part of internal carotid artery
- Ophthalmic artery
- Anterior choroidal artery
- Posterior communicating artery
- Anterior cerebral artery
- Middle cerebral artery
Branches of internal carotid (cerebral part)

Ophthalmic artery
Enters orbit with optic nerve via the optic canal
Supplies: orbit, nasal cavity, paranasal sinuses, scalp

Anterior choroidal artery
Runs posteriorly, inferior to the optic tract
Supplies: choroid plexus in inferior horn of lateral
ventricle, structures along medial aspect of temporal
lobe (uncus, hippocampus, amygdala), tail of
caudate, globus pallidus, inferior part of internal
capsule, optic tract, lateral portions of thalamus

Posterior communicating artery
Extends from internal carotid to proximal part of posterior
cerebral artery
Connects the anterior (carotid) and posterior
(vertebro-basilar) circulations

Anterior cerebral artery (ACA)
Joined by anterior communicating artery
A1 segment:
Extends from origin of ACA to anterior communicating
artery - passes anteriorly and medially above the optic
nerve

**the cortical branches of ACA supply:
Medial surface of cerebral hemisphere (frontal to
parietooccipital)
**includes parts of primary motor cortex and primary
somatosensory cortex
**they control movement and receive general sensory
info from contralateral L.L
Most of corpus callosum
Medial part of inferior surface of frontal lobe (inc. olfactory
bulb and tract)
Distal br supply a strip of cortex on lateral side

Middle cerebral artery (MCA)
Larger terminal branch of the internal carotid artery
Runs laterally, goes into lateral sulcus towards insula
where it divides into superior and inferior trunks
M1 segment:
Extends from origin of MCA to its bifurcation into superior
and inferior trunks
Distal to bifurcation, MCA is divided into M2 and M4
segments

Cortical branches of MCA supply:
Lateral part of inferior surface of frontal lobe
Insula
Most of lateral surface of cerebral hemisphere, except its
peripheral rim (supplied by br of anterior and posterior
cerebral arteries)

Superior trunk of MCA supplies:
Most of primary motor cortex and primary
somatosensory cortex → control movements and
receive general sensory info from contralateral face and
upper limb, motor speech (Broca’s area), frontal eye field
(controls conjugate eye movements to opposite side)

Inferior trunk of MCA supplies:
Primary auditory cortex (transverse temporal gyri)
Sensory speech (Wernicke’s area)
Vertebral artery
O: 1st part of subclavian artery
Divided into 4 parts:
1st - Prevertebral : runs superiorly and posteiroly to
transverse foramen of C6
2nd - Cervical : ascends through transverse foramina of
C6 to C1
3rd - Atlantic : lies in groove of sup. surface of post arch
of atlas
4th - Intracranial : pierces atlanto-occipital membrane,
dura mater and arachnoid and ascends into cranial cavity
(within subarachnoid space) via foramen magnum

In posterior cranial fossa, runs superiorly and medially,
anterior to rootlets of hypoglossal nerve, and at the
medullopontine sulcus joins vertebral artery of opposite
side to form basilar artery
Br of the 4th part
- Posterior inferior cerebellar artery
- Posterior spinal artery
- Anterior spinal artery

Branches of 4th part

Posterior inferior cerebellar artery (PICA)
Largest br of vertebral artery - curves around medulla to
reach inferior cerebellar surface
Supplies posterolateral part of medulla, choroid plexus of
4th ventricle and posterior and medial parts of inferior
surface of cerebellum

Posterior spinal artery

Anterior spinal artery
Supplies anteromedial part of medulla and anterior ⅔ of
spinal cord
Arterial supply of Medulla Basilar Artery
Runs in basilar sulcus of pons from medullopontine
sulcus to pons-midbrain junction, where it terminates by
dividing into 2 posterior cerebral arteries
Branches
- Pontine arteries
- Anterior inferior cerebellar artery
- Labyrinthine (internal auditory) artery
- Superior cerebellar artery
- Posterior cerebral artery

Pontine arteries

Anterior inferior cerebellar artery
Supplies anterior and lateral parts of inferior surface of
cerebellum, lower part of middle cerebellar peduncle,
choroid plexus of 4th ventricle, and send slender twigs to
upper medulla and lower pons

Labyrinthine artery
Enters internal acoustic meatus with cranial nerves VII
and VIII to supply internal ear

Superior cerebellar artery
Passes laterally, just inferior to oculomotor nerve
Wraps around brainstem, under tentorium cerebelli to
supply superior surface of cerebellum, including most of
cerebellar nuclei
Its proximal part gives branches to upper pons, upper
part of middle cerebellar peduncle, superior cerebellar
peduncle, and inferior colliculus of midbrain

Arterial Supply of Pons
 Posterior cerebral artery (PCA)
Passes laterally, just above oculomotor nerve →
continues around midbrain and joins medial aspect of
temporal lobe

Cortical branches of PCA supply:
Inferior and medial surfaces of temporal and occipital
lobe → this includes primary visual cortex
Splenium of corpus callosum
Distal branches supply a strip of cortex on lateral surface

Cerebral Arterial Circle (of Willis)
Consists of larger cerebral vessels and their interconnections on the ventral surface of the brain
Components:
- Internal carotid artery
- Anterior communicating artery
- Posterior communicating
- Posterior cerebral artery
- Anterior cerebral artery
**may serve as potential vascular shunt, assisting in development of collateral circulation if one
of the proximal vessels is occluded
 Perforating (central) branches
- Small arteries that originate from the large arteries on the base of the brain to supply
deeply located structures of the cerebral hemispheres and diencephalon and pats of the
midbrain
Groups:
- Anteromedial
- Anterolateral
- Posteromedial
- Posterolateral

anteromedial O: A1 segment of ACA and anterior communicating artery

Supply: optic chiasm and anterior part of hypothalamus

anterolateral O: M1 segment of MCA (lenticulostriate arteries) and a
few may come from A1 segment of ACA

Supply: most of caudate, putamen, globus pallidus, and
interal capsule

**lenticulostriate arteries are the most common site of
intra-cerebral hemorrhage in HTN ppl
posteromedial O: posterior communicating artery and P1 segment of
posterior cerebral artery

Supply: middle and posterior regions of hypothalamus,
subthalamus, anterior part of thalamus and medial parts
of midbrain

posterolateral O: P2 segment of posterior cerebral artery

Supply: posterior part of thalamus, choroid plexus of
lateral and 3rd ventricles and posterior and lateral
midbrain

Arterial supply of spinal cord
Spinal cord is supplied by 1 anterior and 2 posterior
spinal arteries

Blood received by spinal arteries from vertebral arteries
is sufficient only to supply upper cervical segments of
spinal cord

Spinal arteries are reinforced at intervals by spinal
branches of segmental arteries
- Spinal br enter vertebral canal via intervertebral
foramina and give off anterior and posterior
radicular arteries and anterior and posterior
spinal medullary arteries

Anterior and posterior radicular arteries supply ventral
and dorsal roots of spinal nerves and are present at ALL
spinal cord levels

Anterior and posterior spinal medullary arteries reinforce
anterior and posterior spinal arteries and are NOT
present at all spinal cord levels

Largest spinal medullary artery (Adamkiewicz) joins
anterior spinal artery in upper lumbar region, most
frequently on left side → may provide entire arterial
supply to lumbosacral spinal cord

Branches of anterior spinal artery supply anteior ⅔ of
spinal cord → anterior horn, intermediate zone of gray
matter, basal part of posterior horn, anterior and
lateral funiculi

Branches of posterior spinal artery supply posterior ⅓ of
spinal cord → posterior horn and posterior funinculus
 Somatosensory System
1-17, 23-27

General senses
- Touch (discriminative & non-discriminative)***
- Vibration
- Proprioception (limb position & motion)
- Pain
- Temperature

Discriminative touch, vibration, and proprioception are
carried by: DORSAL COLUMN-MEDIAL LEMNISCUS
pathway

Non-discriminative touch, pain, and temperature are
carried by: ANTEROLATERAL system
(spinothalamic tract)

LARGE DIAMETER, MYELINATED FIBERS (Aα, A𝛽)
form the MEDIAL DIVISION OF DORSAL ROOT
- These transmit the discriminative touch,
proprioception and vibration
- This info carried by: dorsal colum-medial
lemniscus system

SMALL DIAMETER MYELINATED (Aδ)
UNMYELINATED FIBERS (C) form the LATERAL
DIVISION OF DORSAL ROOT
- These transmit non-discriminative touch, pain,
and temperature
- This info carried by: anterolateral system
(spinothalamic tract)
 General Arrangement of the Somatosensory Pathways to the Cerebral Cortex
AFFERENT → SENSORY (signals of touch to brain)
EFFERENT → MOTOR (signals from brain to react)

Consists of 3 neurons

1st order neuron (sensory, unipolar, pseudo-unipolar)
Location: sensory ganglion (dorsal root ganglia or
spinal nerves, trigeminal ganglion)

2nd order neuron
Location: nucleus of spinal cord or brainstem
*the axon crosses to opposite side and then ascends
to the thalamus

3rd order neuron
Location: thalamus (VPL or VPM nuclei)
*projects to cerebral cortex which is the primary
somatosensory cortex
Dorsal Column-Medial Lemniscus Pathway

Carries discriminative touch, vibration and
proprioception from trunk and limbs

*central branches of the 1st order neurons enter
the spinal cord via medial division of dorsal roots then
divide into short local branch and a long ascending
branch
- Short local branch: ends in gray matter of
spinal cord (reflex connections)
- Long ascending branch: ascends in ipsilateral
column
*Long ascending branches entering dorsal column
below midthoracic levels are more medially
located and form gracile fasciculus
*Long ascending branches entering dorsal column
above midthoracic levels are more laterally
located and form cuneate fasciculus

The ascending fibers of gracile and cuneate
fasciculi synapse with 2nd order neurons that are
located in gracile and cuneate nuclei (lower medulla)

Axons of the 2nd order neurons run anteriorly in lower
medulla as internal arcuate fibers, cross midline in
sensory decussation, and ascend to thalamus in
medial leminscus

Axons of 3rd order neurons pass through posterior
limb of internal capsule and terminate in primary
somatosesory cortex (postcentral gyrus &
posterior paracentral lobule - areas 3,1,2 of
Brodmann)

Whole pathway = somatotopically organzied (info from
diff parts of body is carried by diff parts of pathway)
Anterolateral System (spinothalamic tract)

Carries nondiscriminative touch, pain, and temperature
info from trunk and limbs
There are: direct & indirect pathways

Direct spinothalamic pathway:
- Aka: neospinothalamic pathway
- Carries FAST pain (SHARP,WELL-LOCALIZED)
1st order neurons - sensory neurons located in dorsal
root ganglia of spinal nerves; their central branches
(Aẟ fibers) enter spinal cord via lateral division of
dorsal roots of spinal nerves and synapse w 2nd order
neurons

2nd order neurons - located in dorsal horn of spinal
cord (mainly laminae I and V); their axons decussate in
anterior white commissure and ascend to thalamus in
contralateral anterolateral system

*takes 2-3 spinal cord segments for decussating fibers
to join anterolateral system
*spinal cord lesions involving anterolateral system
cause contralateral loss of pain and temp sensations
beginning 2 or 3 segments below the level of lesion

3rd order neurons - located in VPL nucleus of thalamus
Their axons ascend to cerebral cortex via posterior limb
of interal capsule and terminate in primary
somatosensory cortex (POSTCENTRAL GYRUS &
POSTERIOR PARACENTRAL LOBULE)

Indirect spinothalamic pathway:
- Aka: paleospinothalamic pathway
- Carries SLOW pain (DULL, BURNING, ACHE)
Info carried into spinal cord by C fibers
Info does not travel directly from spinal cord to
thalamus, but indirectly via brainstem reticular
formation consisting of spinoreticular and
reticulothalamic fibers

Other fibers in anterolateral:
Spinomesencephalic fibers → extend from spinal cord
to periaqueductal gray matter of midbrain and play a
role in intrinsic pain control mechanisms

Hypothalamus and limbic system structures receive
pain info directly or indirectly → important for emotional
and autonomic responses to nociceptive stimuli
Primary Somatosensory Cortex (SI)

Location: postcentral gyrus and posterior paracentral
lobule (Brodmann 3, 1, 2)

Contains somatotopic representation of contralateral
body in an upside down fashion (“little man”)

The size of cortical area associated w a particular
region of the body DEPENDS ON SENSITIVITY of
body region and NOT THE SIZE OF THE REGION

- Hands and lips have high density of receptors =
large cortical representation
- Back has small density of receptors = small
cortical representation

Lesions affecting the primary somatosensory cortex
cause impairment of fine aspects of somatic sensations
(they cant judge the exact location or the intensity of
the stimulus)
There is also a deficit in sense of position and
movement of the body parts, but DOES NOT
ABOLISH TACTILE SENSATION OR SENSATION OF
PAIN *they can still feel pain

Supplied by: MCA and ACA
Vacular lesions in MCA = sensory loss in contralateral
upper limb and face
Vascular lesions in ACA = sensory loss in contralateral
lower limb