Cerebrum - Applied Neuroscience Overview PDF

Summary

This document provides an overview of the cerebrum, including its functions, structure, and components. It describes the organization and functions of the central nervous system (CNS), peripheral nervous system (PNS), and the limbic system. The text also defines the major structures and functions of the cerebrum, focusing on areas like the cerebral cortex, white matter tracts, and the different lobes with their corresponding functions.

Full Transcript

CEREBRUM

APPLIED NEUROSCIENCE
OVERVIEW THE ORGANIZATION OF
NERVOUS SYSTEM (Part 1)
 Learning Outcome
Describe the organization/functions of
CNS
Describe the structure/function of PNS
Describe the organization/function of
lymbic system
Explain the brain protection
(meninges/CSF/BBB) and blood supply.
 Introduction
Classification
i. Central Nervous System
- Brain, Spinal Cord
ii. Peripheral Nervous System
- peripheral nerves (spinal & cranial),
ganglion, receptor
Develoment of Central
Nervous System
 BRAIN
Consist of 4 major parts:
– Brain stem
– Diencephalon
– Cerebrum
– Cerebellum
CEREBRUM:
Main functions:
Seat of intelligence
– It provides the ability to
read, write and speak;
Make calculations
Compose music
To remember the past
Plan for the future
Imagine things that have never existed before
Centre of sensory perception
Initiate and coordinate skeletal muscle
contraction
Cerebral cortex and it’s structures:
Consists of cerebral cortex (gray matter),
internal region of cerebral white matter and
gray matter nuclei deep within the white
matter.
Thick : 2 – 4 mm, contains billions of
neurons.
This gray matter is made of cell bodies of
neurons.
During embryonic development, when brain
size increases rapidly, the gray matter of the
cortex enlarges much faster than the deeper
white matter.
As a result, cerebral cortex rolls and folds
upon itself so that it could fit into the cranial
cavity.
 The folds called gyri / gyrus or
convolutions.
The deeper grooves between folds are
known as fissures.
The shallow grooves between folds are
termed as sulci / sulcus.
The most prominent fissure, is the
longitudinal fissure which separates
the cerebrum into right and left halves
called cerebral hemisphere.
 Within the longitudinal fissure between the
cerebral hemispheres is the falx cerebri.
The hemispheres are connected internally by
the corpus callosum. (broad band of white
matter containing axons that extend between
the hemispheres)
 Each hemisphere is further subdivided
into five lobes.
The lobes are named after the bones
that cover them:
– Frontal lobes.
– Parietal lobes.
– Temporal lobes.
– Occipital lobes.
– Insula
A fifth part of the cerebrum, the insula, cannot be seen at
the surface of the brain because it lies within the lateral
cerebral sulcus, deep to the parietal, frontal, and
temporal lobes.
Main boundaries in cerebrum:
Sulcus and fissures
Central sulcus
– Separates the frontal and parietal lobes.
Longitudinal fissure
– Separates the cerebrum into right and left
hemispheres.
Lateral cerebral sulcus
– Separates the frontal and temporal lobes.
Parieto-occipital sulcus
– Separates parietal and occipital lobes.
Major Gyrus of
cerebrum:
Precentral gyrus
– Located immediately
anterior to the
central sulcus.
– It contain primary
motor area.

Postcentral gyrus
– is located
immediately
posterior to the
central sulcus,
contains the primary
somatosensory area
of the cerebral
cortex.
 CEREBRAL WHITE MATTER
The cerebral white matter consists of
myelinated and unmyelinated axons that
transmit impulses.
There are 3 types of tracts:-
– Association tracts.
– Commissural tracts
– Projection tracts.
 association
tracts;
contain
axons that
conduct
nerve
impulses
between gyri
in the same
hemisphere.
 Commissural
tracts; contain axon
that conduct nerve
impulses from gyri in
one cerebral
hemisphere to
corresponding gyri in
the other cerebral
hemisphere. 3
important commissural
tracts are the:
Corpus callosum
(largest fiber bundle
in the brain – 300
million fibers)
Anterior commissure
Posterior
commissure
 Projection tracts;
contain axons that
conduct nerve impulses
from the cerebrum to
lower parts of the CNS
(thalamus, brainstem, or
spinal cord) or lower
parts of the cerebrum to
the cerebellum. An
example; is the internal
capsule, which is the
thick band of white
matter that contains
both ascending and
descending axons.
 Summary of Tracts
projection tracts
From brain to spinal cord & vice verca,
forms internal capsule
Commissural tracts
Cross to opposite hemisphere:
» Corpus callosum
» Anterior and posterior
commissures
Association tracts
Connect lobes and gyri within a
hemisphere.
 Cerebral lobes: Frontal
The frontal lobe forms the
anterior portion of each
cerebral hemisphere.
Extends from precentral
sulcus up to the end of brain
anteriorly.
 It is bordered posteriorly by a central sulcus
(fissure of Rolando), which passes out from the
longitudinal fissure at a right angle and inferioly
by a lateral sulcus (fissure of Sylvius) which exits
the undersurface of the brain along its sides.
 Cerebral lobes: Parietal
Extend from central sulcus to parietooccipital
sulcus posteriorly.
The parietal lobe is posterior to the frontal lobe and
is separated from it by the central sulcus.
 Cerebral
Cerebral lobes:
lobes: Temporal
Temporal
The temporal
lobe lies
inferior to the
frontal and
parietal lobes
and is
separated
from them by
the lateral
sulcus.
 Cerebral
Cerebral lobes:
lobes: Occipital
Occipital
The occipital lobe forms
the posterior portion of
each cerebral hemisphere
and is separated from the
cerebellum by a shelflike
extension of duramater
called tentorium cereblli.
Extends from
parietooccipital sulcus to
the inferior end of brain
posteriorly.
The occipital,parietal and
temporal lobes have no
distinct boundary.
 Cerebral lobes: Insula
A fifth part of the
cerebrum, the insula –
cannot be seen at the
surface of the brain
because it lies within the
lateral cerebral sulcus,
deep to the parietal,
frontal and temporal
lobes.
Is on the lateral surface
(medially) of the cerebrum
Cerebral lobes and it’s functions
 Cerebral lobes and it’s functions
Frontal
– Voluntary motor functions
– Voluntary scanning movements of the eyes.
– Planning, mood, smell and social judgement
– Intellect
– Personality
– Complex learning ability
– Recall of information
– Initiative
– Reasoning
– Articulation of speech
 Cerebral lobes and it’s functions
Parietal
– Receives and integrates sensory
information.
– Examples: touch, proprioception, pain,
itching, tickle, temperature.
– Interprets the meaning of a speech.

Temporal
– Areas for hearing (auditory perception) and
smell (olfactory perception).
 Cerebral lobes and it’s functions
Occipital
– Visual center of brain
– Involved in visual perception
– Relates present and past visual experiences
and is essential for recognizing and
evaluating what is seen.
Functional Area of
Cerebral Cortex
 Functional
Functional Organization
Organization of
of the
the
Cerebral
Cerebral Cortex
Cortex
Specific types of sensory, motor and
integrative signals are processed in certain
regions of the cerebral cortex.
Sensory areas receive sensory information and
are involved in perception, the conscious
awareness of a sensation.
Motor areas control the execution of voluntary
movements.
Association areas deal with more complex
integrative functions (memory, emotions,
reasoning, will, judgments, personality traits
and intelligence)
 Brodmann’s
Brodmann’s Area
Area
Functional area of cerebral cortex
Define by German Anatomist, Dr Korbinian
Brodmann
Base on cytoarchitecture of the neuron in
cerebral cortex.
Split the cortex into 52 areas
Consist of
i. Motor areas (primary & association)
ii. Sensory areas (primary & association)
 MOTOR AREAS
Motor output from the cerebral cortex flows
mainly from the anterior part of each
hemisphere.
MOTOR AREAS
 IMPORTANT MOTOR AREAS
Primary motor area
Broca`s speech area
 Primary
Primary motor
motor area
area (4)
(4)
Located in the precentral gyrus of the frontal lobe.
Each region in the primary motor area controls
voluntary contractions of specific muscles or groups of
muscles.

Electrical stimulation of any point in the primary motor
area causes contraction of specific skeletal muscle
fibers on the opposite side of the body.

More cortical area is devoted to those muscles involved
in skilled, complex or delicate movement.
For instance, the cortical region devoted to muscles
that move the fingers is much larger than the region for
muscles that move the toes.

Form corticospinal and corticobulbar/nuclear tracts
 Broca’s speech area
(44, 45)
Located in the frontal lobe close to the lateral cerebral
sulcus. (dominant hemisphere)
Is involved in the articulation of speech.
In most people, Broca’s speech area is localized in the
left cerebral hemisphere.
Neural circuits between Broca’s speech area, premotor
area and primary motor area activate muscles of the
larynx, pharynx, and mouth and breathing muscles.
The coordinated contractions of your speech and
breathing muscles enable you to speak your thoughts.
In stroke patient when this areas is affected they still
have clear thoughts, but are unable to form words.(...)
MOTOR ASSOCIATION AREAS
 Premotor area (6,8)
Is a motor association area that is immediately anterior
to the primary motor area.
Neurons in this area communicate with the primary
motor cortex, the sensory association areas in the
parietal lobe, the basal ganglia and the thalamus.
The premotor area deals with learned motor activities
of complex and sequential nature
It generates nerve impulses that cause specific groups
of muscles to contract in a specific sequence, as when
you write your name.
The premotor area also serves as a memory bank for
such movements.
 Frontal eye field area (8)
Is in the frontal cortex
It is sometime included in the premotor area.
It controls voluntary scanning movements of the eyes
– like those you just used in reading this sentence.
Eyes move to the opposite site simultaneously –
conjugate movements.
SENSORY
SENSORY
AREAS
AREAS
 Primary
Primary Sensory
Sensory Areas
Areas
Sensory information arrives mainly in the
posterior half of both cerebral hemisphere in
regions behind the central sulci
The cortex, primary sensory areas have most
direct connections with peripheral sensory
receptors.
Sensory areas are:-
– Primary somatosensory area- postcentral gyrus.
– Primary visual area- occipital lobe.
– Primary auditory area- temporal lobe.
– Primary gustatory area- base of the postcentral
gyrus.
– Primary olfactory area- temporal lobe
 Secondary
Secondary Sensory
Sensory Areas
Areas
Secondary sensory areas and sensory association
areas often are adjacent to the primary areas and
from other brain regions.
Secondary sensory areas and sensory association
areas integrate sensory experiences to generate
meaningful patterns of recognition and awareness.

A person with damage in the primary visual area
would be blind in at least part of his visual field, but
a person with damage to a visual association area
might see normally yet be unable to recognize her
best friend.
 IMPORTANT
IMPORTANT
SENSORY
SENSORY AREAS
AREAS
 1.
1. Primary
Primary somatosensory
somatosensory area
area
(1,2,3)
(1,2,3)
Located posterior to the
central sulcus of each
cerebral hemisphere in the
postcentral gyrus of each
parietal lobe.
It extends from the lateral
cerebral sulcus, along the
lateral surface of the parietal
lobe to the longitudinal
fissure and then along the
medial surface of the parietal
lobe within the longitudinal
fissure.
 Receives nerve impulse for touch,
pressure, vibration, itch, tickle,
temperature, pain, proprioception and is
involved in the perception of these
somatic sensations.
The side of cortical area receiving
impulses from a particular part of the
body depends on the number of
receptors present there rather than on
the size of the body part.
A larger region of the somatosensory
area receives impulses from the lips and
fingertips than from the thorax or hip.
(sensory homunculus)
 2.
2. Primary
Primary visual
visual area
area (17)
(17)
Located at the
posterior tip of
tip of the
occipital lobe
mainly on the
medial surface.
Receives visual
information
and is involved
in visual
perception.
 3.
3. Primary
Primary auditory
auditory area
area (41,42)
(41,42)
Located in the
superior part of
the temporal
lobe near the
lateral cerebral
sulcus
Receives
information for
sound and is
involved in
auditory
perception.
 4.
4. Primary
Primary gustatory
gustatory area
area (43)
(43)
Located at the
base of the
postcentral
gyrus superior
to the lateral
cerebral
sulcus in the
parietal cortex.
Receives
impulses for
taste and is
involved in
gustatory
perception.
 5.
5. Primary
Primary olfactory
olfactory area
area (34)
(34)
Located in
the temporal
lobe on the
medial
aspect (and
thus not
visible)
Receives
impulses for
smell and is
involved in
olfactory
perception.
ASSOCIATION
ASSOCIATION SENSORY
SENSORY AREAS
AREAS
Secondary sensory areas /sensory
association areas often are adjacent to the
primary areas and from other brain regions.
Secondary sensory areas / sensory
association areas integrate sensory
experiences to generate meaningful patterns
of recognition and awareness.
A person with damage in the primary visual
area would be blind in at least part of his
visual field, but a person with damage to a
visual association area might see normally
yet be unable to recognize her best friend.
 ASSOCIATION
ASSOCIATION AREAS
AREAS
Consist of larger
areas of the
occipital, parietal
and temporal
lobes and
anterior surface
frontal lobe.
Association
areas are
connected with
one another by
association
tracts.
1.
1. Somatosensory
Somatosensory association
association area
area
(5,7)
(5,7)
Is just posterior to and receives input from the
primary somatosensory area, as well as from
the thalamus and other parts of the brain.
 It allows to determine the expect shape and
texture of an object without looking at it, to
determine the orientation of one object with
respect to another as they are felt, and to sense
the relationship of one body part to another.

Another role of the somatosensory association
area is the storage of memories of past somatic
sensory experiences, enabling you to compare
current sensations with previous experiences.
For example, the somatosensory association
area allows you to recognize objects such as a
pencil and a paperclip simply by touching
them.
 2.
2. Visual
Visual association
association area area

(18,
(18, 19)
19)
Located in the occipital lobe, receives sensory impulses
from the primary visual area and the thalamus.
It relates present and past visual experiences and is
essential for recognizing and evaluating what is seen.
For example, the visual association area allows you to
recognize an object such as a spoon simply by looking at
it.
3.
3. Facial
Facial recognition
recognition area
area (20,21)
(20,21)
Corresponding roughly to areas 20, 21 and 37 in the
inferior temporal lobe, receives nerve impulses from
the visual associations area.
This area stores information about faces, and it allows
you to recognize people by their faces.
(prosopagnosia)
The facial recognition area in the right hemisphere is
usually more dominant than the corresponding region
in the left hemisphere.
4.
4. Auditory
Auditory association
association area
area (22)
(22)
Located inferior and posterior to the primary auditory
area in the temporal cortex
Allows you to recognize a particular sound as speech,
music or noise.
 5.Secondary
5.Secondary olfactory
olfactory area
area (11)
(11)
Corresponding roughly to area 11 along the lateral part
of the frontal lobe
Receives sensory impulses from the primary olfactory
area.
 This area allows you to identify odors and to discriminate
among different odors.
During olfactory processing, the orbital frontal cortex of
the right hemisphere exhibits greater activity than the
corresponding region in the left hemisphere.
 6.
6. Wernicke’s
Wernicke’s area
area (39,40)
(39,40)
A broad region in the left temporal and parietal
lobes (dominant hemisphere), interprets the
meaning of speech by recognizing spoken
words.
It is active as you translate words into thoughts.
 7.
7. Common
Common integrative
integrative area
area
Is bordered by somatosensory, visual and auditory
association areas.
It receives nerve impulses from these areas and from
the primary gustatory area, primary olfactory area, the
thalamus and parts of the brain stem.

This area integrates sensory interpretations from the
association areas and impulses from other areas,
allowing the formation of thoughts based on a variety of
sensory inputs.
It then transmits signals to other parts of the brain for
the appropriate response to the sensory signals it has
interpreted.
 8.
8. Prefrontal
Prefrontal cortex
cortex (frontal
(frontal
association
association area)
area) (9,10,11)
(9,10,11)
is an extensive area
in the anterior
portion of the frontal
lobe.
This area has
numerous
connections with
other areas of the
cerebral cortex,
thalamus,
hypothalamus,
limbic system and
cerebellum.
Prefrontal cortex (frontal association area)
The prefrontal cortex is concerned with make up of a
person`s:
Personality
Intellect
Complex learning abilities
Recall of information
Initiative
Judgement
Foresight
Reasoning
Conscience
Intuition
Mood
Planning for future
Development of abstract ideas.
Prefrontal cortex (cont…)
Damage to bilateral prefrontal cortices make a
person become:
– rude,
– inconsiderate
– Incapable of accepting advice
– Moody
– Inattentive
– Less creative
– Unable to plan for the future
 SUMMARY
SUMMARY FOR
FOR CEREBRAL
CEREBRAL LOBE
LOBE
FUNCTIONS
FUNCTIONS
Frontal
– Voluntary motor functions
– Planning, mood, smell and social judgement
Parietal
– Receives and integrates sensory information
Occipital
– Visual center of brain
Temporal
– Areas for hearing, smell, learning, memory,
emotional behaviour.
 SUMMARY:
SUMMARY: LANGUAGE
LANGUAGE
Includes reading, writing, speaking and
understanding words.
Wernicke`s area
– Permit recognition of spoken and written language
and creates plan of speech.
Broca`s area
– Generates motor signals for larynx, tongue, cheeks
and lips.
– Transmits to primary motor cortex for action
HEMISPHERIC
HEMISPHERIC LATERALIZATION
LATERALIZATION
Slight anatomical differences between the
right and left hemispheres exist.
2/3rd of the population, the Wernicke's area is
50% larger on the left side than on the right
side.
Physiological differences also exists.
This functional asymmetry is termed as
hemispheric lateralization.
Most obvious examples are:
Left hemisphere receives somatic sensory
signals from and controls muscles on the
right side of the body, whereas the right
hemisphere receives sensory signals from
and controls the left side of the body.

In most people the left hemisphere is more
important for reasoning, numerical and
scientific skills, spoken and written language,
and the ability to use and understand sign
language.
 The right hemisphere is more specialized for:
– musical and artistic awareness;
– spatial and pattern perception;
– recognition of faces and emotional content
of language;
– Discrimination of different smells
– Generating mental images of sight, sound,
touch, taste and smell to compare
relationships among them.
HEMISPHERIC
HEMISPHERIC LATERALIZATION
LATERALIZATION
Neuroanatomy & Physiology
Basal Ganglia and its Clinical
Correlation
By Hermizan Halihanafiah
 Anatomical Classification
Neurologic structure Basal nuclei

Corpus striatum Caudate nuclei and lentiform nuclei

Lentiform nuclei Putamen & globus pallidus

Neostriatum / striatum Caudate nuclei & putamen

Amygdaloid body Amygdaloid nuclei

Claustrum Claustrum
 Functional Classification
Nuclei Discription

Corpus striatum Caudate nuclei and lentiform
nuclei

Subthalamic nuclei Diencephalic origin

Subtantia nigra Masses of grey matter located at
midbrain
 Basal Ganglia Disorder
Hypokinesia
Hyperkinesia
 Hypokinesia
Parkinsonism
- bradykinesia / akinesia
- resting tremors / pill rolling
- lead pipe regidity/cogwheel rigidity
 Hyperkinesia
Chorea – Huntington
- Sydenham’s / St Vitus Dance
Hemiballism
Athetosis
Dystonia
Tardive dyskinesia
Wilson disease – tremor, dyskinesia,
rigidity
Internal Capsule
 Internal capsule
Projection tracts (ascending and
descending tracts)
V shaped of white matter
Located in between lenticular nuclei
(laterally) and thalamic / caudate nuclei
(medially)
 Internal capsule
It divide into:
1.anterior limb
2.Genu
3.Posterior limb
4.Retrolenticular portion
5.Sublenticular portion
 Genu
Refers to the flexure of internal capsule
Consist of corticobulbar/corticonuclear
tracts
Which originate from primary motor area
(head and facial areas)
Terminate at the cranial somatic motor
nuclei (III, IV, V, VI, VII, IX, X, XI, XII)
 ANTERIOR LIMB
 Located in between lenticular nuclei and
caudate nuclei
 Huge connection between thalamus and
frontal lobe
 Three major tracts formed ALIC
1.thalamocortical/thalamofrontal
2.Frontothalamic and frontopontine
 Posterior Limb
The largest fibers of IC
Consist most of the ascending and
descending tracts
Located inbetween lentiform nuclei and
thalamus
 Contains fibers of:
1.Corticospinal tracts
2.Somaticsensory tracts (PCML, ASTT,
LSTT and TTT)
3.Optic radiation from thalamus to visual
cortex (occipital lobe)
4.Acoustic fibers to temporal lobes
 Meninges
Ventricle System and CSF
Blood Brain Barrier
Lymbic System
1. MENINGES
Is a protective covering of the brain and
spinal cord.
The cranial bones and cranial meninges
surround and protect the brain.
The cranial meninges are continuous with
the spinal meninges.
Consists of 3 layers:
– Dura mater (outer most)
– Arachnoid mater (middle)
– Pia mater (inner most)
1.1. Dura mater
cranial dura mater has 2 layers and spinal
dura mater has only 1 layer.
2 dural layers; periosteal and meningeal
layers around the brain are fused together
except where they separate to enclose the
dural venous sinuses that drain venous blood
from the brain and deliver it into the internal
jugular veins.(p498)
There is no epidural space in the brain.
Blood vessels enter brain tissue pass along
the surface of the brain, and as they penetrate
inward, they are sheathed by a loose – fitting
sleeve of pia mater.
Extensions of the Dura Mater

Copyright 2009, John Wiley & Sons,
Inc.
Extensions of the dura mater
3 extensions of the dura mater (Dural Folds)
separate parts of the brain (p498):
Falx cerebri – the largest dural folds,
separates the 2 hemispheres of the
cerebrum, lies in the longitudinal fissure and
anchored anteriorly by crista galli.
Falx cerebelli – separates the 2 hemispheres
of the cerebellum.
Tentorium cerebelli – horizontally separates
the cerebrum and the cerebellum.
 Dura mater
Falx Cerebri

Falx Cerebri
Tentorium Cerebelli
1.1. Dura mater (cont…)
(cont…)
spinal dura mater forms a loose sheath round the
spinal cord, extending from the foramen magnum to
the second sacral vertebra.
It encloses the filum terminale and fuses with the
periosteum of the coccyx.
It is an extension of the inner layer of cerebral dura
mater and is separated from the periosteum of the
vertebrae and ligaments within the neural canal
(vertebral canal) by the epidural or extradural space,
containing blood vessels and areolar tissue.
Nerves enter and leave the spinal cord, pass through
the epidural space.
1.2. Arachnoid mater
Is a serous membrane lies between the dura and pia
mater.
Is separated from the dura mater by the subdural
space, and from pia mater by subarachnoid space
which contains cerebrospinal fluid.
It passes over the convolutions of the brain and
accompanies the inner layer of dura mater in the
formation of the falx cerebri, tentorium cerebelli and
falx cerebelli.
It continues downwards to envelop the spinal cord
and ends by merging with the dura mater at the level
of the 2nd
nd sacral vertebra.
1.3. Pia mater
Is a fine connective tissue containing many minute
blood vessels.
It adheres to the brain, completely covering the
convolutions and dipping into each fissure.
It continues downwards surrounding the spinal cord.
Beyond the end of the cord it continues as the filum
terminale, pierces the arachnoid tube and goes on,
with the dura mater, to fuse with the periosteum of
the coccyx.
Spinal Meninges
Cranial Meninges
2. VENTRICLES
Within the brain there are 4 irregular shaped
cavities or ventricles containing CSF (p499):
2 lateral ventricles (right and left)
3rd
rd ventricle

4thth ventricle
 2.1. Lateral ventricles
lie within the cerebral hemisphere, one on each side of
the median plane just below the corpus callosum
(p502).
Anteriorly the lateral ventricles are separated from
each other by a thin membrane called septum
pellucidum, and they are lined with ciliated epithelium
(p502)..
Leteral ventricles communicate with 3rdrd ventricle by

interventricular foramina (foramina of Monro).
Consists network of blood capillaries called choroid
plexus.
 2.2. Third ventricles
Is a cavity situated below the lateral ventricles
between the right and left halves of the thalamus.
Is a narrow cavity along the midline superior to the
hypothalamus.
Communicates with the 4thth ventricle by a canal, the
cerebral aqueduct or aqueduct of the midbrain
(Aqueduct of Sylvius).
Consists network of blood capillaries called choroid
plexus.
 2.3. Fourth ventricles
Is a diamond shaped cavity situated below and behind
the 3rdrd ventricle, between the cerebellum and pons.
Is continuous below with the central canal of the spinal
cord and communicates with the subarachnoid space by
two lateral aperture (Foramina of Luschka) and one
median aperture (foramina of Magendie).
CSF enters the subarachnoid space through these
openings and through the open distal end of the central
canal of the spinal cord.
Consists network of blood capillaries called choroid
plexus.
3. CEREBROSPINAL FLUID
Is a colorless liquid that protects the brain
and spinal cord from chemical and physical
injuries.
It carries oxygen, glucose and other needed
chemicals from the blood to neurons and
neuroglia (brain tissues).
CSF continuously circulates through cavities
in the brain and spinal cord and around the
brain and spinal cord in the subarachnoid
space (between arachnoid and pia mater)
3. CEREBROSPINAL FLUID
The total volume of CSF is 80 to 150 ml in an adult.
CSF contains glucose, proteins, lactic acid , urea,
cations (Natt, Ktt ,Catt , Mg2t2t) and anions (Cl-- and
HCO3--); it also contains some white blood cells.
The CSF contributes to homeostasis in 3 main
ways:-
– Mechanical protection
– Chemical protection
– Circulation
3. CEREBROSPINAL FLUID
CSF contributes to Homeostasis in three main
ways:
Mechanical protection
Serves as shock-absorbing medium that
protects the delicate tissues of the brain and
spinal cord from jolts that would otherwise
cause them to hit the bony walls of the
cranial and vertebral cavities.
The fluid also buoys the brain so that it
‘floats’ in the cranial cavity.
3. CEREBROSPINAL FLUID
Chemical protection
It provides an optimal chemical environment
for accurate neuronal signaling.
Even slight changes in the ionic composition
of CSF within the brain can seriously disrupt
production of action potential and
postsynaptic potentials.

Circulation
CSF allows exchange of nutrients and waste
products between the blood and nervous
tissue.
3. CEREBROSPINAL FLUID
3.1. Functions of CSF
provide support and protection for brain and
spinal cord.
Maintain a constant pressure around the
brain and spinal cord.
Acts as cushion of fluid that absorb shock.
(shock absorber)
Carries nutrient, oxygen and needed
chemicals from blood to neuron and
neuroglia.
Carries out waste product from neuron and
neuroglia to blood.
3. CEREBROSPINAL FLUID
3.2. Formation of CSF
Produced at the choroid plexus, network of
capillaries in the walls of the ventricles.
The capillaries are covered by ependymal
cells that form CSF from blood plasma by
filtration and secretion.
The blood-CSF fluid barrier permits certain
substances to enter the CSF but excludes
others, protecting the brain and spinal cord
from potentially harmful blood borne
substance.
Figure 8.37c
3. CEREBROSPINAL FLUID
3.3. Circulation of CSF
Formed in the choroid plexuses of each lateral
ventricles - flows into the 3rdrd ventricle through
2 narrow, oval openings, the interventricular
foramina (of Monro).
More CSF is added by the choroid plexus in
the roof of the 3rdrd ventricle.
The fluid then flows through the aqueduct of
the midbrain (cerebral aqueduct @ of Sylvius)
which passes through the midbrain, into the 4thth
ventricle.
3. CEREBROSPINAL FLUID
3.3. Circulation of CSF
The choroid plexus of the 4thth ventricle
contributes more fluid.
CSF enters the subarachnoid space through 3
openings in the roof of the 4thth ventricles; a
median aperture (of foramen of Magendie) and
the paired lateral apertures (foramen of
Luschka), one on each side.
CSF then circulates in the central canal of the
spinal cord and in the subarachnoid space
around the surface of the brain and spinal cord.
Figure 7.14 Arrows showing the flow of cerebrospinal fluid.
Copyright © Elsevier Ltd 2005. All rights reserved.
3. CEREBROSPINAL FLUID
3.4. Reabsorption of CSF
CSF is gradually reabsorbed into the blood through
arachnoid villi, fingerlike extensions of the
arachnoid that project into the dural venous sinuses,
especially the superior sagittal sinus (a cluster of
arachnoid villi is called an arachnoid granulation)
Normally CSF is reabsorbed as rapidly as it is
formed by the choroid plexuses, at a rate of about
20mL/hr (480mL/day).
Because the rates of formation and reabsorption are
the same, the pressure of CSF normally is constant.
Summary of the formation, circulation, and
reasorption of CSF
Lateral
Lateral ventricles
ventricles Lateral
Lateral ventricles
ventricles
choroid
choroid plexuses
plexuses CSF Through interventricular
foramina
3rd
3rd ventricles
ventricles 33rdrd ventricles
ventricles
choroid
choroid plexuses
plexuses
CSF Through cerebral
44thth ventricles
ventricles aqueduct
44thth ventricles
ventricles
choroid
choroid plexuses
plexuses
CSF Through lateral and
Median apertures

Subarachnoid
Subarachnoid space
space

Arachnoid
Arachnoid villi
villi of
of dural
dural
venous
venous sinuses
sinuses

Venous blood

Heart
Heart and
and lungs
lungs
 Blood Brain Barrier (BBB)
The existence of BBB protect the brain cells from harmful
substances and pathogens by preventing passage of many
substances from blood into brain cells.
Endothelial cells of the blood vessels in the choroid plexus
which are joined by tight junction form the BBB.
The processes of many astrocytes press up against the
capillaries and secrete chemical that maintain the
permeability characteristic of tight junction.
A few water soluble substances such as glucoses cross the
BBB by active transport.
Other substances such as creatinine, urea, and most ions,
cross the BBB very slowly.
 Blood Brain Barrier (BBB)
Other substances such as
protein and antibiotic drugs do
not pass at all through BBB.

However, lipid-soluble
substances, such as oxygen,
carbon dioxide, alcohol, and
most anesthetic agents easily
cross the BBB.
Trauma, certain toxins, and
inflammation can cause a
breakdown of the BBB.
 THE LIMBIC SYSTEM
Part of the cerebrum
and diencephalon are
grouped together as a
lymbic system.
Lymbic refers to deep
portion of the cerebrum
that form a ring around
the diencephalon.
Sometimes called “the
emotional brain”.
The Limbic System
THE LIMBIC SYSTEM
The Limbic
System
The Limbic System
 COMPONENTS OF THE
LIMBIC SYSTEM (p 517)
The limbic system includes many structures in
the cerebral cortex and sub-cortex of the brain.
Limbic lobe – a rim of cerebral cortex on the
medial surface of each hemisphere.
It includes the cingulate gyrus which lies
above the corpus callosum
Located in the frontal lobe of cerebrum.
Cingulate gyrus : Autonomic functions
regulating heart rate, blood pressure and
cognitive and attentional processing
The Limbic System
COMPONENTS OF THE LIMBIC SYSTEM

parahippocampal gyrus which is in the
temporal lobe below.
Parahippocampal gyrus : Plays a role in the
formation of spatial memory.
The hippocampus is a portion of the
parahippocampal gyrus that extends into the
floor of the lateral ventricle.
Hippocampus : Required for the formation of
long-term memories
COMPONENTS OF THE LIMBIC SYSTEM
Dendate gyrus lies between the hippocampus
and parahippocampal gyrus.
Dentate gyrus : thought to contribute to new
memories and to regulate happiness.
The amygdala is composed of several groups
of neurons located close to the tail of the
caudate nucleus (basal ganglia).
Amygdala : Involved in signaling the cortex of
motivationally significant stimuli such as those
fear
COMPONENTS OF THE LIMBIC SYSTEM
The septal nuclei are located within the septal area
formed by the regions under the corpus callosum and
the paraterminal gyrus (a cerebral gyrus).
The mammillary bodies of the hypothalamus are two
round masses close to the midline near the cerebral
peduncles.
Mammillary body : Important for the formation of
memory
Two nuclei of thalamus, the anterior nucleus and the
medial nucleus, participate in limbic circuits.
Thalamus: The "relay station" to the cerebral cortex
The Limbic System
COMPONENTS OF THE LIMBIC SYSTEM
The olfactory bulbs are flattened bodies of the
olfactory pathway that rest on the cribriform
plate.
Olfactory bulb: Olfactory sensory input
The fornix, stria terminals, stria medullaris,
medial forebrain bundle, and mammillothalamic
tract are linked by bundles of interconnectimg
myelinated axons.
The Limbic System
 Summary:components Of The Limbic
System
Limbic lobe; includes the cingulate gyrus and
parahippocampal gyrus and hippocampus gyrus.
Dentate gyrus
Amygdala
Septal nuclei
Mammillary bodies of the hypothalamus
Anterior and medial nucleus
Olfactory bulbs
Fornix, stria terminals, stria medullaris, medial
forebrain bundle, mammillothalamic tract.
The Limbic System
The Limbic System
The Limbic System
 FUNCTIONS OF THE LIMBIC SYSTEM
The limbic system is sometimes called the
emotional brain because it plays a primary
role in a range of emotions, including pain,
pleasure, docility, affection, and anger.
It also involved in olfaction (smell) and
memory.
The amygdala involves fear and aggression.
The hippocampus, together with other parts
of the cerebrum function in memory. People
with damage to limbic system structures
forget recent events and cannot commit
anything to memory.