Topography of the Brain

Question 1

Neurulation

Answer 1

The process by which the neural plate becomes the neural tube. The mesoderm and the ectoderm form the neural tube

• folding occurs in the middle then anteriorly than posteriorly
• during folding the mesoderm forms somites which develop into the 33 individual vertebrae of the spinal column and related skeletal muscles
  
  • nerves that innervate these skeletal muscles are called somatic nerves
• Folic acid is essential for this process

Question 2

What are the layers of the Neural tube?

Answer 2

• Neural Crest cells
• Mantle Layer
• Ependymal layer
• Lumen

Question 3

Anencephaly

Answer 3

• the failure of the anterior neural tube to close
• results in the degeneration of the forebrain, as it herniates out of the foetus​
  
  • always fatal

Question 4

Spina bifida

Answer 4

• • Failure of the posterior neural tube to close
    
    • leads to an open vertebral canal
• most severs is when posterior spinal cord fails to form from the neural plates (Spina Bifida Cystic)
  
  • the meninges projects out posterior from the spinal cord: can be filled the cerebrospinal fluid
• less severe cases present as defects in the meninges and vertebrae overlying the posterior spinal cord (Spina Bifida Occulta)

Question 5

Primary Brain Vesicles

Answer 5

These develop at the rostral end of the neural tube

• Prosencephalon (forebrain)
• Mesencephalon (midbrain)
• Rhimbencephalon (hindbrain)
  *

Question 6

Secondary brain Vesicles

Answer 6

From the Prosencephalon

• Telencephalon
  
  • Cerebrum
• Diencephalon
  
  • Eye Cup
  • Thalamus (hypo, epi)

From the Mesencephalon

• Mesencephalon
  
  • Midbrain

From the Rhomencephalon

• Metencephalon
  
  • Pons
  • Cerebellum
• Myecenphalon
  
  • Medulla oblongata

Question 7

the Adult Brain

Answer 7

• Frontal Lobe
• Parietal Lobe
• Temporal Lobe
• Occipital Lobe
• Cerebellum

Question 8

Grey Matter

Answer 8

• mainly neuronal cell bodies i.e cereberal cortex, brain nuclei

Question 9

White Matter

Answer 9

• myelinated neurons

Question 10

Telencephalon- Cerebral hemispheres

Answer 10

• Frontal Lobe
• Parietal Lobe
• Occipital Lobe
• Temporal Lobe
• folded to form gyri and sulci

Question 11

The Cerebral cortex

Answer 11

• Central Sulcus
• Lateral Sulcus
• Precentral gyrus
• Postcentral gyrus
  *

Question 12

Corpus callosum

Answer 12

• Seen as a large C-shaped tract of white matter when a midsagittal cut is made
• connects the two cerebral hemispheres of the brain
• the Coronal radiator is seen in a coronal view of the brain
  
  • all the wires connecting the brain together
• has a Genu, Body and Splenium
  
  • ​Genu- many motor axons, connecting the motor regions
  • Body- many sensory axons, connecting the sensory areas of the brain

Question 13

Limbic System

Answer 13

a deep brian structure which controls memory and emotion

• spans the telencephalon and diencephalon*
• Cingulate cortex
• Fornix
• Amygdala
• Hippocampus
• Thalamus*
• Hypothalamus*
• Mamillary bodies*

Question 14

Fornix

Answer 14

• a semicircular white matter tract that connects hippocampus and the mamillary bodies
  
  • from the hippocampus passes posteriorly in a curve then superiorly through the third ventricle, over the top of the third ventricle then drops down anteriorly to join with the mammillary bodies
• it is part of the limbic system (the telencephalon part)

Question 15

Basal Ganglia

Answer 15

sits in the base of the forebrain

a deep brain structure involved in the control of posture and voluntary movement

the Corpus striatum refers to the two main nuclei that forms the basal ganglia

• lentiform nucleus (lens shaped)
  
  • Putamen: the outer part
  • Globus pallidus: the inner part
• caudate nucleus (C-shaped)
  
  • follows the shape of the lateral ventricle wall
  • moves anteriorly to the inferior horn of the lateral ventricle

Question 16

The Capsules

Answer 16

• Internal Capsule
  
  • major white matter tracts in the brain that connects the cerebral cortex to the brainstem
  • internal to the lentiform nucleus
• External capsules
  
  • external to the lentiform nucleus
• The Extreme capsule is really small and is after the external capsule closer to the lateral sulcus

Question 17

Diencephalon

Answer 17

Sits in the middle of the brain

• Thalamus
• Hypothalamus

Question 18

Thalamus

Answer 18

a paired structure that is part of the diencephalon

• the paired structures are connected by an inter-thalamic adhesion through the third ventricle
• relays sensory info to the cortex
  
  • olfactory information doesn’t go through the thalamus
• involved in voluntary movement, personality and consciousness

Question 19

Hypothalamus

Answer 19

part of the diencephalon found inferior to the thalamus

• involved in homeostasis
  
  • coordinates ANS and endocrine response
    
    • connected directly to the pituitary gland (infundibulum connects them)
  • thermoregulation, feeding, drinking, circadian rhythms
    
    • near the pineal gland (melatonin released)
  • receives inputs from the limbic system
• Sits between he optic chiasm ad the mammillary bodies

Question 20

Mamillary bodies

Answer 20

• brainstem nuclei on the posteroinferior aspect of the hypothalamus
• attaches tot he fornix
• associated with recollective memory

Question 21

Mesencephalon and Rhombencephalon

Answer 21

together they form the brainstem and cerebellum

• Metencephalon
  
  • forms the Pons/ Cerebellum
    
    • A pontine flexure causes the cerebellum to be posterior to the brainstem around day 36 of embryonic development
• Myelencephalon
  
  • forms the Medula

are both part of the rhombencephalon

Question 22

Brainstem (Medulla)

Answer 22

Contains:

• cranial nerve nuclei within all three regions
• vital respiratory and cardiovascular centres
• vomiting centre
• nuclei involved with motor control, sleep
• white matter tracts

Question 23

Midbrain

mesencephalon

Answer 23

• Cerebral peduncles
  
  • the prosencephalon sits superior to these
  • white matter tracts connecting the pons (above) with the diencephalon (below)
• Superior colliculus: Vision
  
  • output to CNX 3,4,6, which are involved in eye movements
• Inferior colliculus: Auditory
  
  • receive information from CNX 8 and relay it to the auditory cortex
• Red nucleus
  
  • format motor relay complex between the cerebral cortex and the cerebellum
• Substantial Nigra ( appears black in an MRI, lots of melanin)
  
  • contain dopaminergic neurons, forms part of the basal ganglia (limbic system)
  • this part degenerates in patients with Parkinson’s

Question 24

Pons

Answer 24

• relays information to the cerebellum
• middle cerebellar peduncle
• contains reticular formation
  
  • nuclei concerned with sleep, motor control

Question 25

Medulla oblongata

Answer 25

• Pyramids
  
  • contain cortical spinal axons (white matter): the main voluntary motor pathway from the primary motor cortex to the spinal cord
  • pyramids of decussation (cross)
• Olive
  
  • Formed by olivary nuclei: motor relay to the cerebellum

These two nuclei form part of the ascending tract

• Cuneate tubercle
• Gracile tubercle

Question 26

Cerebellum

Answer 26

Sit posterior to the brainstem, mainly for motor control

• control of
  
  • postures
  • coordinating and planning limb movements
  • eye movements
• outer grey matter with underlying white matter
• two cerebellar hemispheres
• three lobes and contains nuclei deep in the cerebellar
• Cerebellar cortex
• Arborvitae (tree-like structure, ‘tree of life’)
• Vermis: connects the right and left cerebellar hemispheres
• Anterior lobe: posture
• Flocculondular lobe: eye movement and head position
• Posterior lobe: fine motor coordination

Connected to the brainstem via the cerebellar peduncles

Question 27

Neural Tube layers

Answer 27

• Ectoderm
  
  • covers the neural tube
• Mantle Layer
  
  • becomes brain parenchyma
• Ependymal Layer
  
  • lines the ventricles
• Lumen
  
  • become the ventricles + the central canal of the spinal cord

Question 28

The Prosencephalon

Answer 28

This is the most rostral part of the neural tube, it eventually forms the forebrain

• Secondary vesicles form from the early forebrain, the structure after the formation of these two vesicles is called the Diencephalon
  
  • Telencephalic vesicles
  • the Optic vesicles
    
    • folds to form the optic stalk and the optic cup: eventually, become the optic nerve and retinas

Question 29

The Telencephalic and the Diencephalon Differentiation

Answer 29

the telencephalon is the anterior part of the brain, which is also called the cerebrum, while the diencephalon is the part of the brain that is placed between the telencephalon and the midbrain

Question 30

Telencephalon Gyri and Sulci

Answer 30

• Central sulcus
  
  • divides the frontal and parietal lobe
• Postcentral gyrus (sensory)
• Lateral sulcus
  
  • divides the temporal lobe from the parietal lobe
• Pre central gyrus (motor)

Question 31

Functional areas of the cortex

Telencephalon

Answer 31

• Frontal Lobe
  
  • Primary motor cortex
    
    • in the precentral gyrus
  • Motor speech in the Brocas area
  • • Parietal Lobe
  • Somatosensory cortex (pain touch…)
    
    • in the postcentral gyrus
• Temperol
  
  • Auditory cortex
  • Olfactory cortex
• Occipital
  
  • Visual cortex
• the Gustatory cortex is found when the lateral sulcus is moved

Makes up 20% of the brain

Question 32

Hippocampus

Answer 32

Sits in the floor of the lateral ventricle

• involved in the emotions and memory in the limbic system

Question 33

Overview of the Ventricular system

Answer 33

• Four fluid-filled cavities
  
  • two Lateral Ventricles
  • the Third Ventricle
  • the Fourth Ventricle
• Lat.Vents communicate with the 3rdVent through the intraventricular foramina
• 3rdVent connected to the 4thVent through the narrow cerebral aqueduct (aqueduct of Sylvius)
• 4thVent continuous with the narrow central canal and the subarachnoid space
• Formed from the lumen of the rural tube, lined by the ependymal layer

Question 34

Which parts of the brain are the ventricles surrounded by?

Answer 34

• Lateral Vents: Telencephalon (Cerebral hemispheres)
• Third Vent: Diencephalon (Thalamus/ hypothalamus)
• Mesencephalon (Midbrain)
• Fourth Vent: Metencephalon (Pons/cerebellum)
• Myelencephalon (Medulla)
• Central canal

Question 35

The Lateral Ventricles

Answer 35

• there are two c-shaped ventricles, one for each ventricle
• Formed of
  
  • Body: occupies the parietal lobe
  • Anterior horn: frontal lobe
  • Posterior horn: occipital lobe
  • Inferior horn: temporal lobes
• The Septum pellucidum separates the lateral ventricles
• and the Corpus Callusom sits in the roof

Question 36

Borders of the lateral ventricles

Answer 36

• Caudate nucleus sits in the lateral wall
• the hippocampus sits in the floor of the inferior horn

Question 37

What is the Intraventricular foramen

Answer 37

• the communication centre between thew lateral ventricles and the third ventricle
• aka Foramen of Monro

Question 38

The Third Ventricle

(position)

Answer 38

The third ventricles appear as a slit-like cleft

• the Thalami sit in the lateral walls
• the Fornix forms the roof

Question 39

What is the Cerebral aqueduct

Answer 39

• The communication channel between the third and fourth ventricle
• aka Aqueduct of Sylvius
• this structure is surrounded by the midbrain

Question 40

Borders of the Fourth Ventricle

Answer 40

• surrounded by the hindbrain
  
  • The cerebellum is bordering it posteriorly
  • Pons and the Medulla border it anteriorly
  • Cerebellar peduncles border it laterally
• it is continuous with the central canal of the spinal cord and the subarachnoid space

Question 41

Communication in the Fourth ventricle

Answer 41

• three foramen exit into the subarachnoid space into the Cisterna Magna
  
  • two Foramen of Luschka (laterally, posterior to the cerebellar peduncles)
  • one Foramen of Magendie (in the middle)

Question 42

What is the Choroid plexus?

Answer 42

• the choroid plexus produces CSF
• the choroid plexus presents throughout the ventricles
  
  • it is a capillary network surrounded by cuboidal epithelium
• filters blood from branches of the internal carotid and basilar arteries
  
  • blood is filtered through fenestrated capillaries
  • components transported through the cuboidal epithelium into ventricles

Question 43

Structure of the choroid plexus

Answer 43

• Fenestrated capillaries: act as a filter
• Cuboidal epithelium: act as transport
• Tight junctions between epithelial cells
  
  • prevent macromolecules from entering the CSF
  • permeable to water and CO₂
• This forms part of the blood-CSF barrier

Question 44

What is the role of Cuboidal epithelium in the brain?

Answer 44

• They are specialized ependymal cells
• Villi increase the surface area for filtration
• they actively transport CSF
• the movement of components is bidirectional

Question 45

The composition of CSF and it’s difference from blood plasma

Answer 45

• the CSF has a significantly lower protein content
  
  • slightly lower pH, glucose content, Ca2+ and K+
  • slightly higher, Mg2+, Cl-
• these conditions are ideal for the functioning of neurons.

Question 46

Describe the direction of circulation in the CSF within the ventricles

Answer 46

• From the lateral ventricles, through the interventricular foramen to the
• Third ventricle, then through the Cerebral Aqueduct to the
• The fourth ventricle, then through the Luschka and Magendie foramina to the
• Cisterna manga (the Subarachnoid space)

Question 47

Describe the CSF circulation within the subarachnoid space

Answer 47

Question 48

What is the role of the Subarachnoid space

Answer 48

it lies between the pia mater and the arachnoid mater

allows the CSF to be in contact with the brain parenchyma

• transfer of micronutrients into the brain
• removal of metabolites

Question 49

The Arachnoid Granulations

Answer 49

• Herniations of arachnoid membrane (villi) through dura mater into venous sinuses
• Mainly within the superior sagittal and transverse venous sinuses

Question 50

Explain the pressure in the CSF

Answer 50

• CSF pressure in the subarachnoid spaces exceeds the pressure in the venous sinuses: prevents blood pooling in the subarachnoid space
  
  • Subarachnoid space: ~180mmH₂O
  • Venous Sinus: ~80mmH₂O

In Disease

• if venous pressure exceeds CSF pressure, the tips of arachnoid granulations close off acting as a one-way valve

Question 51

The CSF and its main functions

Answer 51

• 500ml CSF produced per day: total volume of this system 90-140ml
• any excess is absorbed by the arachnoid granulations
  Functions
• Hydraulic buffer to cushion brain against trauma
• Vehicle for removal of metabolites from CNS
• Stable ionic environment for neuronal function
• Transport of neurotransmitters and chemicals

Question 52

What different colours can the CSF present in a disease presentation?

Answer 52

usually clear sterile liquid

• Yellow/orange/pink
  
  • lysis of red blood cells, haemoglobin release
  • Subarachnoid haemorrhage
• Cloudy/Turbid
  
  • Leukocytes increased- infection
  • Bacterial meningitis

Question 53

How do you take a CSF sample

Answer 53

• taken via lumbar puncture
• at the lumbar cistern
  
  • L3/4 in adults
  • L4/5 in children

Question 54

What is Hydrocephalus

Answer 54

• Dilation of brain ventricles due to
  
  • blocked CSF circulation,
  • impaired absorption,
  • or over secretion
• Increased intracranial (CSF) pressure
• Pressure on surrounding tissues affects neurological function
  
  • Symptoms: headaches, vomiting, visual disturbance, papilledema, seizures, altered cognition, balance and coordination problems
• can be congenital or acquired

Question 55

What is non-communicating hydrocephalus?

Answer 55

• Blockage within the ventricular system
  
  • Due to tumour, cyst, stenosis (e.g. narrowing of the cerebral aqueduct)
• CSF does not circulate over the surface of the brain

Treatment:

• Surgery: insert a shunt to reduce intracranial pressure

Question 56

What is Dandy-Walker Syndrome?

Answer 56

• Congenital malformation of the cerebellum (1:30,000 births)
• Obstruction within foramina of the fourth ventricle:
  
  • Symmetrical dilation of lateral, third and fourth ventricles
• In infancy, head may become enlarged

Question 57

What is communicating hydrocephalus

Answer 57

• Obstruction in the arachnoid villi
• Movement of CSF into venous sinuses is impeded
  
  • E.g. Impaired absorption following subarachnoid haemorrhage, trauma or bacterial meningitis