Lecture 8 - CNS PDF

Summary

This lecture covers the Central Nervous System, including its development, layout, and component cells. It also discusses brain regions, the spinal cord, and the cerebrospinal fluid. The figures and diagrams illustrate the concepts.

Full Transcript

Mon, Oct 21

Nervous System, Part 1:
The Central Nervous System
Development of the nervous system
Layout of the nervous system
Cells of the central nervous system
(brain and spinal cord)
Brain regions
A bit about the spinal cord

Reading:
Ch. 13, Sec 1 and 2
 Development of the Nervous System

The layout of the nervous system (like everything in the body)
is dictated by what happens when we’re an embryo

By Week 6:
All animals
(including humans) The neural crest starts forming
develop from the body’s sensory neurons
3 embryonic layers: The neural tube starts forming
the brain, spinal cord,
and motor neurons

In the 4th week of development,
part of the top layer
pulls into the middle layer
to form the nervous system

Figures from
Human Anatomy, 9th Ed.
by Elaine Marieb (2022)
 Development of the Nervous System

The layout of the nervous system (like everything in the body)
is dictated by what happens during embryonic development

The neural tube divides into segments over the coming weeks
to form the fetal brain and spinal cord
Development of the Nervous System
The head-end of the neural tube
wraps and twists around itself as it grows
to form a newborn brain

From
Human Anatomy, 9th Ed.
by Elaine Marieb
Fig. 13.2
Layout of the Mature Nervous System
 Layout of the Mature Nervous System
m e
S o if ic
p e c
(brain and spinal cord)
S l u s
i m u
t
S curs
Oc
Usually opens
some sort of
gated Na+ channels
(they open only in
urons

response to that
nse
te

specific stimulus
integra
a respo
Interne
Cells of the Central Nervous System
Space containing
Ventricles cerebrospinal fluid

mal
Ependy
Cells
line the
Neurons ventricle
s
form action
potentials
and
synapses!

Oligodendrocytes
make myelin

Br
intersain Microglia
tit
fluid ial brain defense
and
housekeeping

Fig. 5-3, p. 110
Cerebrospinal Fluid:
Produced in the ventricles deep in the brain
Percolates around the brain and spinal cord
Absorbed in the spinal column

From:
”Human Physiology, 7th Edition” by
Lauralee Sherwood (2012)
Cells of the Central Nervous System
Space containing
Ventricles cerebrospinal fluid

mal
Ependy
Cells
line the
Neurons ventricle
s
form action
potentials
and
synapses!

Astrocytes
form the
blood- brain
barrier

Oligodendrocytes Capillary
make myelin

Br
intersain Microglia
tit
fluid ial brain defense
and
housekeeping

Fig. 5-3, p. 110
 The Blood-Brain Barrier
Endothelial In the brain and spinal cord,
cells astrocytes send projections
to capillaries

Cause tight junctions to form
between the cells that make up
the capillary walls

Tight junctions close the capillary
pores, prevent paracellular flow
(i.e., substances can’t move around cells)

Now the only exchange between
the blood and the brain fluid can
Pores occur via transcellular flow
(substances have to move through the
A typical capillary of the body capillary cells using membrane transport
mechanisms we already learned about
is very leaky by design — highly specific!!)
Protective Layers of the CNS

Skin and sensory nerves

Skull and Vertebrae

Meninges
3 protective membranes:
- Dura Mater — “tough mother”
- Pia Mater — “gentle mother”
- Arachnoid Mater — “spidery mother”

Cerebrospinal Fluid (CSF)
- Provides a cushion for brain and spinal cord
- Provides nutrients, removes waste products
from the brain tissue
 Regions of the Central Nervous System
Cerebral Cortex
Cerebral cortex Thought, Consciousness,
Movement, Integration
“gray matter” is on surface
“white matter” underneath
Basal nuclei
(lateral to thalamus)
Basal Nuclei
Fine-tune muscle activity,
inhibit inappropriate actions

Thalamus Thalamus
(medial) Relay of all sensory information,
except the sense of smell

Hypothalamus
Hypothalamus Seat of homeostatic control,
master gland of the endocrine system
Cerebellum
Pituitary Cerebellum
Many regulatory hormones! Coordination of movements,
“muscle memory”

Midbrain Brain Stem
Many basic processes
Brain stem Pons essential for animal life
(digestive centers,
respiratory centers,
cardiovascular centers)
Medulla

Spinal Cord
Nerve pathways, many reflexes
The Cerebral Cortex is Divided Into Lobes
 The Cerebral Cortex is Divided Into Lobes
Primary motor cortex
Supplementary motor area (voluntary movement) Somatosensory cortex
(on inner surface—not visible; (somesthetic sensation
programming of complex movements) Central and proprioception)
sulcus
Posterior parietal cortex
Premotor cortex (coordination (integration of somatosensory
of complex movements) and visual input;
important for complex
Prefrontal association cortex movements)
(planning for voluntary
activity; decision making;
Wernicke’s area
personality traits) (speech understanding)
Parietal lobe
Frontal lobe

Broca’s area
(speech formation)
Primary auditory cortex
surrounded by higher-order
auditory cortex (hearing) Occipital lobe
Primary visual cortex
Limbic association cortex surrounded by higher-
(mostly on inner and bottom order visual cortex (sight)
surface of temporal lobe;
motivation and emotion; memory)
Temporal lobe
Cerebellum
Spinal cord
Brain stem
(a) Regions of the cerebral cortex responsible for various functions

Fig. 5-8a
 The Spinal Cord
White Matter: Gray matter:
Tracts of Axons Many, many
Interneurons

Dorsal Root

s
r ve
Sensory
t ne
n s
Information
ere r ve
Action Af
f
t ne
Potentials ren Ventral root
fe
Coming Ef
From The
Sensory
Receptors

Motor
Information
Action
Potentials
Going Spinal nerves (30 pairs)
To The part of the peripheral
Effectors nervous system