Cortical Development

Question 1

Stages of Brain Development

Answer 1

• 0-4 weeks: Neurolation
• 4-8 weeks: Neuronal Proliferation
• 12-Birth: Neural Migration
• 16/18 weeks – late childhood: Apotosis
• 18 weeks – Late childhood: Synaptogenesis
• 30 weeks – Adulthood: Myelination

Question 2

Neuronal Proliferation

Answer 2

Neurons destined for the neocortex are produced in the proliferative zone near the cerebral ventricle (ventricular zone)

(proliferation means cells greatly increase in #)
organizer controls pattern of proliferation via chemical signals in neural tube

Question 3

Neurolation

Answer 3

Folding & fusion of the ectoderm to create the neural tube
Neural tube becomes the CNS

Happens week 0-4;

Week 5: ecotoderm differentiated into different brain structures

Question 4

Neural Migration

Answer 4

Neurons migrate along radial glial cells to the relevant layer of the cortex

phase 3 of prenatal development

cells need to migrate from ventricular zone and aggregate in this process

Question 5

Brain volume growth

Answer 5

Total: Peak = 10 (females) & 14 (Males)

Grey: Peak = 10 (males) & 8 (females)

WM: steep increase in first year; Then less rapid growth up to young adulthood

Question 6

Grey Matter in adolesence

Answer 6

So despite global changes in GM – we can see that it the thickness that is showing the most marked reduction

Change in grey matter volume refers to a change in:
Thickness
Surface area

Question 7

Sulcation

Answer 7

Process of brain growth in the 2nd – 3rd trimester

Abnormality = Lissencephaly (smooth brain)

Question 8

Abnormality of sulcation

Answer 8

Lissencephaly (smooth brain)

Question 9

Gyrification

Answer 9

development of the surface folds

Question 10

Sulcation development

Answer 10

13-17 gestational weeks - appearance of the first sulcus
18-19 gestational weeks - development of the periinsular sulci
20-22 gestational weeks - central sulci and opercularization of the insula
24-26 gestational weeks - covering of the posterior insula
27-28 gestational weeks - closure of the lateral sulcus (Sylvian fissure or lateral fissure)

Question 11

3 types of sulci

Answer 11

Primary
Consistently located
Easily recognisable
Central and Superior Frontal

2) Secondary
Branches of the Primary Sulci

3) Tertiary
Branches of the secondary Sulci
Individual differences
8/9month of pregnancy and into first year of life

Question 12

Theories of Gyrification

Answer 12

• Skull preventing the brain growing
• Axonal Tension Theory
• Differential Radial Growth – Richman 1975
• Differential Tangential Growth – Ronan 2014
• Constrained cortical expansion - Tallinen 2014, 2016

Question 13

Axonal Tension Theory

Answer 13

Axons connecting two areas are pulling on cortex and this causes them to fold. BUT: Axonal tension does exist but it quite weak; there are more gyri than sulci

Question 14

Constrained Cortical Expansion

Answer 14

Grey matter is expanding rapidly
White matter isn’t
Based on this theory:

Question 15

Polymicrogyria based on Constrained Cortical Expansion Theory

Answer 15

Poly microgryia = thin cortex but large surface area so it folds more

Question 16

Lissencephaly based on Constrained Cortical Expansion Theory

Answer 16

Lisencephaly = thick cortex but low surface area so it folds less

Question 17

2 ways neurons migrate along radial glial cells

Answer 17

2 ways cells move:
radial migration: move out in a straight line
tangential migration: cells travel in right angles

Question 18

Radial Unit Hypothesis process…

Answer 18

1. Ventricular zone = Generate Neurons
Intermediate Progenitor (IP) divide to forms pairs of neurons

2. Neurons Transverse Intermediate zone and Subplate Zones along RG cells
3. Pass through deep layers and settle between Cortical Plate and Marginal Zone

Question 19

Symmetrical Radial Division

Answer 19

Laterally – side way and therefore affects surface area

Question 20

Asymmetrical Radial Division

Answer 20

Linear increase in radial coloumns results in an increase in cortical thickness

Question 21

What determines position of neurons in neuronal migration?

Answer 21

Position of the neurons is determined by information in the VZ + a protomap in the SP and CP & is preserved by transient radial glial scaffolding

Question 22

What impacts cortical thickness?

Answer 22

The number of IP and RG cells = cortical thickness

Question 23

Human Vs. Rodent Brain

Answer 23

Outer sub-ventricular zone = larger

the division of the RG cells fromm sub-ventricular RG cells - which allows for ‘extra coloumns’ and a much larger cortex

Question 24

oRG

Answer 24

oRG = non-epithelial radial-glial like cells – able to self renew and produce neurons similar to classic RG cells
oRG and classic RG divide asymmetrically to produce IP cells
IP cells divide once or twice to produce immature neurons

oRG cells and IP cells are known as ‘transit amplifying neurons’ as they amplify the number on neurons being migrated
THEREFORE contribute to the larger cortex in humans

Question 25

Founder cells

Answer 25

during cortical development radial founder cells go through stages of symetrical cortical division to generate founder cells. Once the set number of founder cells is reached (different between species) the cells begin to divide assymetrically: forming one ventricular zone RG (vzRG) cell and one immature neuron – the immature neuron migrates up the RG fibre.

Question 26

Cortical layer formoation

Answer 26

After ascending the RG fibres the immature neurons form somewhere between the CP and Marginal Zone to form a cortical layer
IMP not only is the layer position important but also the coloumnar position
Despite being in different layers research found that neurons in the same COLOUMN respond to the same orientation of a bar of light

Question 27

Congenital Anopthalmia & Cortical development

Answer 27

Removing monkey’s eyes at 60 days old = reduced LG nucleus (1/2) + folds of occipital lobe are completely different
WHY? Hypotheses:
Thalamic input impact the surface area of V1: no eyes, reduced thalamic input, reduced V1 size
The neurons of this area (Area 17) formed a Hybrid Cortex
They have characteristics of area 17 but received input from Area 18

Question 28

Class 1 Brain Malformations

Answer 28

Class 1 – number of radial units reduced
Happens in first 6 weeks
Reduced surface area as there are reduced number of radial colomnar units for neurons to migrate along

e.g. Microcephaly

Question 29

Class 2 Brain Malformations

Answer 29

Class 2 – Number of neurons in each radial unit is reduced
After 6 weeks
Occurs due to interference with cell proliferation or migration
Reduced thickness as reduced neurons to migrate

Question 30

Class 3 Brain Malformations

Answer 30

Class 3 – Malformations of cortical organisation within the 6 layers

Question 31

Microcephaly

Answer 31

Class 1
Reduced surface area – reduction in number of radial unit coloumns
Non-genetic Causes
Genetic Causes

Zika Virus – potential link; however not solely microcephaly

Question 32

Nongenetic causes of Microcephaly

Answer 32

Causes:
Nongenetic
- congenital infection with toxoplasma, CMV
- Zika??
- maternal alcohol consumption during pregnancy Genetic
- Autosomal Recessive Primary Microcephaly
Rubenstein Taybi syndrome

Question 33

Lissencephaly

Answer 33

Smooth Brain

Class 2 BUT
Recent Research: affects a number of stages of Cortical Development
Therefore may also be contributed to by Class 1 malformations: an early occuring event that affects the number of coloumns - they don’t even get to the point of not being able to migrate

2 Types:
Isolated Lissencephaly Sequence (ILS)

Miller-Dieker Syndrome

Question 34

Isolated Lissencephaly Sequence (ILS)

Answer 34

Type of Lissencephaly

• Severe intellectual disability
• Microcephaly
• Developmental delay
• Recurrent seizures
• Genes: PAFAH1B1, DCX, or TUBA1A

Question 35

Miller-Dieker Syndrome

Answer 35

Type of Lissencephaly

• Severe intellectual disability
• Developmental delay
• Seizures
• Spasticity
• Hypotonia
• Feeding difficulties
• Distinctive facial features

Question 36

Polymicrogyria

Answer 36

Signs and symptoms depends on how many brain regions are affected

Its a disruption of the organisation rather than production or migration of the neurons

3 types:
Unilateral Focal Polymicrogyria
Bilateral Polymicrogyria
Bilateral Generalised Polymicrogyria

Question 37

Late maturation of Sylvian fissure

Answer 37

late maturation of Sylvian fissure is an indication of atypical brain development

Question 38

Schizophrenia

Disorder of neuronal development

Answer 38

Regions where there are functional differences show a different growth trajectory

Abnormal non-linear growth processes in prefrontal and temporal areas that have previously been implicated in schizophrenia, distinguishing fbetween cortical areas with age-constant deficits in cortical thickness and areas whose maturational trajectories are altered in schizophrenia