Medical Sciences II Lecture Notes Chapter 1 PDF

Summary

These lecture notes cover the human nervous system, focusing on neuroanatomy and physiological control of biological functions. The material includes major divisions of the Central Nervous System (CNS) and Peripheral Nervous System (PNS), and microanatomy of neuronal cells. Recommended textbooks and online resources are listed.

Full Transcript

Medical Sciences II

Physiological control of biological function

(Human) Nervous System (9)
Muscular Skeletal System (3)
Endocrine System (3)
Renal System (1)
Gastrointestinal System (1)

Julien Vermot
[email protected]
office hour:Tuesday 1-2pm
Recommended textbooks
Medical Sciences II

9 lectures on:

Human Nervous System

„From simple reflexes to voluntary movements“
Example1: Brain Machine Interface for movement restoration

Pandarinath et al eLife 2017

Example2: Robots engineering

https://www.bostondynamics.com https://www.youtube.com/watch?v=WcbGRBPkrps
…But we have still lots to learn from humans

Simon Biles
https://www.youtube.com/watch?v=khz4sD1j0QU
Chapter1: Basic Neuroanatomy of the nervous
system
1. Major divisions of the Central Nervous System, CNS
2. Microanatomy of neuronal cells
3. The different non neuronal cell types
divisions of the Central Nervous System, CNS
ctions with the peripheral nervous system underlies function
Studying the Nervous System 15
Studying the Nervous System 15

nervous system
(A) Central Peripheral (B)

nervous system
(A) nervous system
Central nervous system
Peripheral (B) Cerebral hemispheres, diencephalon,

Central
nervous system nervous system Cerebral hemispheres,
cerebellum, diencephalon,
brainstem, and spinal cord

Central
cerebellum, brainstem,
(analysisand
andspinal cord of
integration
(analysis and integration
sensory and motor of information)
Brain Cranial nerves sensory and motor information)
Brain Cranial nerves
Spinal cord
Spinal cord Spinal
Spinal nerves
nerves

SensorySensory Motor Motor
components
components components
components

Visceral Visceral Somatic Somatic
motor system motor system

nervous system
motor system motor system

nervous system
SensorySensory
ganglia ganglia

Peripheral

Peripheral
and nerves (sympathetic,
(sympathetic,
and nervesparasympathetic,
parasympathetic,
and enteric
Motor nerves
divisions)and enteric Motor nerves
Sensory receptors divisions)
Sensory
(at surface and receptorsAutonomic
surface and ganglia Autonomic
(atbody)
within the
within the body)and nerves ganglia
and nerves

Effectors
Internal
and Effectors
Smooth muscles,
externalInternal cardiac muscles, Skeletal (striated)
environmentand muscles
Smooth muscles,
and glands
external Skeletal (striated)
cardiac muscles,
environment and glands muscles

FIGURE 1.12 The major anatomical components Figure
of 1.1 single glial covering that protects otherwise unmyelinated
the nervous system and their functional relationships. axons within peripheral nerves.
(A) The CNS (brain and spinal cord) and PNS (spinal and Two grossglial
single histological
covering terms
that distinguish
protects otherwiseregions richunmyelinated
FIGURE 1.12 The major anatomical components of
cranial nerves). (B) Diagram of the major components of the in neuronal cell bodies versus regions rich in axons. Gray
the nervous system and their functional relationships.
CNS and PNS and their functional relationships. Stimuli from
axons within peripheral nerves.
(A) matter refers
Two to any accumulation
histological of cell bodies and neu-
theThe CNS (brain
environment and information
convey spinal cord) to and PNS (spinal
processing circuitsand
in gross terms distinguish regions rich
cranial
the brain and spinal cord, which in turn interpret their signifi-of the
nerves). (B) Diagram of the major components ropil in the brain and spinal cord. White matter (named
in neuronal cell bodies versus regions rich in axons. Gray
CNS andand
cance PNSsend
andsignals
their functional
to peripheral relationships.
effectors thatStimuli
move the from for its relatively light appearance, the result of the lipid
matter refers to any accumulation of cell bodies and neu-
content of myelin) refers to axon tracts and commissures.
the environment
body and adjust convey information
the workings to processing
of its internal organs. circuits in
the brain and spinal cord, which in turn interpret their signifi- Within ropil
grayinmatter,
the brain
nerveandcellsspinal cord. White
are arranged in twomatter
dif- (named
cance and send signals to peripheral effectors that move the ferent ways. A local accumulation with neurons that haveof the lipid
for its relatively light appearance, the result
conventionally
body and adjustdivided the vertebrate
the workings nervous
of its internal system an-
organs. roughlycontent
similarofconnections
myelin) refers to axon tracts
and functions anda commissures.
is called nu-
atomically into central and peripheral components (Figure cleusWithin gray matter,
(plural: nuclei, not to benerve cellswith
confused are the
arranged
nucleusin two dif-
1.12). The central nervous system, typically referred to as of a cell); such
ferent collections
ways. A localare found throughout
accumulation withthe cere- that have
neurons
the CNS, comprises
conventionally the brain
divided (cerebral hemispheres,
the vertebrate nervous systemdien- an- brum,roughly
diencephalon,
similar connections and functionscon-
brainstem, and spinal cord. In is called a nu-
cephalon, cerebellum, and brainstem) and the
atomically into central and peripheral components (Figure spinal cord. trast, cortex (plural:
cleus (plural:cortices) describes
nuclei, not to besheetlike
confused arrays
withofthe nucleus
The peripheral nervous system (PNS) includes the sen- nerve cells. The cortices of the cerebral hemispheres and
1.12). The central nervous system, typically referred to as of a cell); such collections are found throughout the cere-
sory neurons that link sensory receptors on the body sur- of the cerebellum provide the clearest examples of this
the CNS, comprises the brain (cerebral hemispheres, dien-
face or deeper within it with relevant processing circuits in
brum, diencephalon, brainstem, and spinal cord. In con-
organizational principle. Within the white matter of the
cephalon,
the CNS. cerebellum, and brainstem)
The motor portion of the PNS in andturn spinalof
theconsists cord. axons cortex
CNS, trast, (plural:
are gathered intocortices)
tracts thatdescribes
are more sheetlike
or less arrays of
twoperipheral
The components.nervous
The motor system (PNS
axons that ) includes
connect the sen-
the brain nervetocells.
analogous nerves The cortices
in the of the
periphery. Eachcerebral hemispheres and
tract contains
sory
andneurons
spinal cord that
to link sensory
skeletal musclesreceptors
make upon thethe body sur-
somatic axonsofthatthetypically
cerebellum provide
originate in thethesame
clearest examples of this
gray matter
face or deeper
motor division within
of theitPNS,
withwhereas
relevantthe processing
cells and circuits
axons in organizational
structure, are organized principle.
in parallel, Within
and oftenthe terminate
white matter of the
that innervate smooth muscle, cardiac muscle,
the CNS. The motor portion of the PNS in turn consists of and glands in theCNS,
same division
axons are of gray matterinto
gathered at some
tractsdistance from
that are more or less
PURVES
make up: Neuroscience
the visceral6e or autonomic motor division. their analogous
origin. Tracts that cross the midline of the brain,
two components.
Figure: 0112 The motor axons that connect the brain to nerves in the periphery. Each tract contains
and Those nerve cell bodies that
spinal cord to skeletal
7.21.17 residemake
muscles in theup PNStheare lo-
somatic such as the corpus
axons callosum that
that typically interconnects
originate in the the same cere-
gray matter
cated in ganglia, which are simply local accumulations of bral hemispheres, are referred to as commissures. The
motor division of the PNS, whereas the cells and axons structure, are organized in parallel, and often terminate
nerve cell bodies and supporting cells. Peripheral axons sensory tracts of the dorsal spinal cord are referred to as
that
are innervate
gathered into smooth muscle,
bundles calledcardiac muscle, and glands
nerves, many of which
in the same division of gray matter at some distance from
columns.
PURVES
make up : Neuroscience
the visceral 6e or autonomic motor division.
are enveloped
Figure: 0112 by the glial cells of the PNS; as mentioned Thetheir origin.ofTracts
organization thatmotor
the visceral crossdivision
the midline
of the PNSof the brain,
Those
earlier,
7.21.17 nerve
these cell bodies
peripheral thatcalled
glia are reside in the cells
Schwann PNS(see
are lo- suchcells
(the nerve as thethatcorpus callosum
control the functions that interconnects
of the visceral or- the cere-
cated
above),in ganglia , which
and they either are simply
myelinate theselocal
axonsaccumulations
or provide a of gans, bral hemispheres,
including are referred
the heart, lungs, to as commissures
gastrointestinal tract, and. The
nerve cell bodies and supporting cells. Peripheral axons sensory tracts of the dorsal spinal cord are referred to as
are gathered into bundles called nerves, many of which columns.
are enveloped by the glial cells of the PNS; as mentioned The organization of the visceral motor division of the PNS
earlier, these peripheral glia are called Schwann cells (see (the nerve cells that control the functions of the visceral or-
 Medical Sciences II L1

1.2 Processes required to control motor action

Nervous
System

Biological systems operate under closed-loop conditions
Figure 1.2
 The nerve fibers to and from the spinal cord are distinct areas.
sory andbundled
a motor division. The sensory division (the
in 31 spinal nerves, each of which has a sen-
immediately rostral to the spinal cord—the medulla
The three divisions of the central nervous system
dorsal root) carries information
sory and a motor division. from
The muscles and skin
sensory division (the and
immediately rostral tocollectively
midbrain—are termedmedulla,
the spinal cord—the the brain ste
pons
dorsal root) carries information from muscles and skin and midbrain—are collectively termed the brain stem.

1. Major divisions of the Central Nervous System, CNS
1.3 Learning about function requires knowledge of CNS anatomy
Lateral view Medial view
Lateral view Medial view

Cerebral Cerebral
cortex Cerebral
Cerebral cortex
cortex
cortex

Diencephalon
Diencephalon
Cerebellum
Cerebellum
Brain Brain Midbrain
stem Midbrain
stem Brain
Pons
Spinal cord stem Brain
Pons
Spinal cord stem
Medulla
Medulla

Cerebellum
Cerebellum

Spinal cord

Spinal cord
CNS “in situ”

There are 7 major divisions.
Figure 15–3 The major divisions of the central nervous
Brain and spinal cord are protected by the skull and the backbone, respectively.
system. Drawings show a lateral view of the left side of the
brain and the medial surface of the right side of the brain.
Figure
Brain and spinal cord are bathed in cerebrospinal fluid, CSF. It provides 15–3
further
(Adapted, The
with major divisions
mechanical
permission, of the central
from protection
Nieuwenhuys, andnervous
Voogd, and
system. Drawings
van Huijzen 1988.) show a lateral view of the left side of the
is separated form the general vascular system by the blood-CSF barrier. brain and the medial surface of the right side of the brain.
Figure 1.3 (Adapted, with permission, from Nieuwenhuys, Voogd, and
van Huijzen 1988.)
 1
Ventral Dorsal
A Rostral-caudal and dorsal-ventral axes B Medial-lateral axis
1
(anterior) (posterior)
Dorsal

Rostral
Rostral
Rostral
Caudal
Caudal
Caudal
Caudal
Ventral Rostral
Rostral

C Section planes
2
Ventral Horizontal plane C
Ventral
(inferior)
(inferior)
Lateral Medial Lateral
Dorsal V
(superior) Dorsal
1

2 2
Rostral Caudal Ventral
Ventral Dorsal
Dorsal
Rostral (anterior)
(anterior) (posterior)
(posterior)
Chapter 15 / The Organization of the Central Nervous System 339
Ventral Caudal
Caudal V
(inferior)
rostral = towards the nose Ventral (
caudal = towards the tail Dorsal
2
Ventral C Section
C Section
Dorsal planes
planes dorsal = towards the back (posterior)
(anterior) (posterior) ventral plane
= towards the belly Coronal plane
Horizontal
Horizontal plane Figure 15–2 The
Coronal plane nervous system is Sagittal
central plane
described
Sagittal along
plane
superior = upper
Caudal
inferior = lower three major
Ventral
(anterior)
axes. (Adapted, with permission, from Martin
AC Rostral-caudal and dorsal-ventral axes medial = in theB middle
Medial-lateral2003.)
axis
Section planes
1
Horizontal plane
Dorsal lateral = at/towards the side
Coronal plane Sagittal A. Rostral means toward the nose and caudal toward the
plane

tail. Dorsal means toward the back of the animal and ventral
Rostral Caudal
toward the belly. In lower mammals the orientations of these
Ventral two axes are maintained through development into adult life.
In humans and other higher primates the longitudinal axis
flexes in the brain stem by approximately 110°. Because of
this flexure the same positional terms have different mean-
2
ings when referring to structures below and above the flexure.
Figure 15–2 The central nervous system is described along spinal column), ventral (anterior) means toward the belly, and
three major axes. (Adapted, with permission, from Martin dorsal (posterior) means toward the back. Below Abovethe flexure, in the spinal cord, rostral means toward the
the flexure,
2003.) Figure Figure 15–2 15–2 TheThe central
central nervous
nervous
rostral means systemsystem
toward the is described
nose,
Lateral iscaudal
described
Figure
head, along
1.4toward
means
Medial caudalalong
the back
means spinal
Lateral column),
spinal
toward column), ventral
the coccyx ventral(anterior)
(the lower endmeans
(anterior) meanstowa
of the to
Dorsal of the head, ventral means toward the jaw, and dorsal means
A. Rostral means towardthree the nosemajor
three and caudalaxes.
major (Adapted,
toward the
axes. (Adapted, with permission,
with permission, from fromMartinMartin dorsal
dorsal(posterior)
Dorsal (posterior)meansmeans toward the
toward back.
the Ab
back.
Figure 1.4:
toward the belly. In lower
Anatomical
tail. Dorsal means toward(superior)
2003.) 2003.)
mammals
terminology.
the back of the animal and ventral
the orientations of these
toward the top of the
synonymously with dorsal,
head. The term superior is
1 and inferior means the same as
often used
rostral means
rostral means toward
toward thethe
nose, caudal
nose, mean
caudal me
two axes are maintained through development into adult life. ventral.
Rostral
A. primates themeans toward the nose andtoward
caudal toward thethe of the
of head,
the ventral
head, ventralmeansmeans toward the
toward jaw,
the a
jaw
In humans and other higher A. Rostral means
longitudinal axis toward B. the
Medial nose
means and caudal
the middle toward
of the brain and lateral
Note
flexes in the brain stem by approximately
tail.tail.
Dorsal that
110°. in
Because humans
of the
toward orientation
the side. of the spinal cord toward
relative to
toward the
the top
the of
top the
of head.
the The
head. term
The superio
term sup
this flexure the same positional terms havemeans
Dorsal means
different toward
mean- toward the back
the
C. When
ofarethe
back
brains
animal
ofsectioned
the animal andand
for analysis,
ventral
slicesventral
are typically
ings when Rostral toward
referring to structures brain
theand
below is rotated
belly.
above by
In flexure.
the lower 90
Caudal degrees
mammals compared
in one ofthe orientations to the ofsituation
these synonymously
or in rodents. This withwith
synonymously dorsal, andand
dorsal, inferior mean
inferior m
toward the belly. In lower mademammals threethe orientations
cardinal planes: horizontal,ofcoronal,
these
Below the flexure, in the spinal cord, rostral means toward the
two axesRostral
is axes arelower
because maintained
humans sagittal.
through
arethrough
walkingdevelopmentupright,into which adult ventral.
ventral.
life.life. an adjustment
required
head, caudal means toward two
the coccyx (the are maintained
end of the development into adult
In humans of head
In humans andorientation.
other
and otherhigher primates
higher primates thethe longitudinal
longitudinal axisaxis B. Medial
B. Medial meansmeans toward
towardthethemiddle of the
middle br
of the
flexes flexesin thein brain
the stem
brain stem by approximately
by approximately 110°. 110°.Because
Because of of toward
toward thetheside.
side.
Ventral
this flexure
this
(inferior)flexure thethe same same positional
positional termsterms have havedifferent
different mean- mean- C. When brains are are
sectioned for for
analysis, sli
When
C.Ventral brains sectioned analysis,
ingsings when when referring
referring to structures
to structures belowbelow andand above above thethe flexure.
flexure. made in one of three cardinal planes: horizon
made in one of three cardinal planes: hori
Below Below thethe flexure,
flexure, in the spinal
in the spinalcord, cord,rostral
rostralmeans means towardtoward thethe sagittal. Dorsal
2 sagittal.
(posterior)
head, head,caudalcaudal meansmeans towardtowardthethe coccyx
coccyx (the(thelower lowerendend of the of the
Ventral Dorsal
(anterior) (posterior)

Caudal Ventral
(anterior)

C Section planes
Horizontal plane Coronal plane Sagittal plane

Figure 15–2 The central nervous system is described along spinal column), ventral (anterior) means toward the belly, and
three major axes. (Adapted, with permission, from Martin dorsal (posterior) means toward the back. Above the flexure,
2003.) rostral means toward the nose, caudal means toward the back
A. Rostral means toward the nose and caudal toward the of the head, ventral means toward the jaw, and dorsal means
tail. Dorsal means toward the back of the animal and ventral toward the top of the head. The term superior is often used
toward the belly. In lower mammals the orientations of these synonymously with dorsal, and inferior means the same as
two axes are maintained through development into adult life. ventral.
In humans and other higher primates the longitudinal axis B. Medial means toward the middle of the brain and lateral
flexes in the brain stem by approximately 110°. Because of toward the side.
this flexure the same positional terms have different mean- C. When brains are sectioned for analysis, slices are typically
ings when referring to structures below and above the flexure. made in one of three cardinal planes: horizontal, coronal, or
 2
seful anatomical definitions
Lateral Medial Lateral
Dorsal
-lateral axis 1
1

Caudal
stral

Ventral

Dorsal
2 (posterior)
2
ral Dorsal
erior) (posterior)

Medial
Caudal Lateral Ventral
Figure 1.5 (anterior)
Dorsal

tal plane Coronal plane Sagittal plane

s system is described along spinalVentral
column), ventral (anterior) means toward the belly, a
h permission, from Martin dorsal (posterior) means toward the back. Above the flexur
rostral means toward the nose, caudal means toward the b
Dorsal
e and caudal toward the of the(posterior)
head, ventral means toward the jaw, and dorsal mea
ck of the animal and ventral toward the top of the head. The term superior is often use
als the orientations of these synonymously with dorsal, and inferior means the same as
development into adult life. ventral.
ates the longitudinal axis B. Medial means toward the middle of the brain and lateral
ximately 110°. Because of toward the side.
Ventral
erms have different mean- C. When brains are sectioned for analysis, slices are typical
 the regulation of homeostasis. The overhanging por- pathways are not nearly as prominent but can be dem-
tion of the cerebral cortex that buries the insula within onstrated with neuroanatomical tracing techniques
the lateral sulcus is called the operculum. (see Box 4–2).

1.5 Anatomical structures of the CNS

Central sulcus Cingulate gyrus
Cingulate sulcus
Parietal Parietal
lobe lobe
Corpus Parietal
Frontal callosum occipital
lobe sulcus

Occipital
lobe Frontal Occipital
lobe lobe

Lateral
sulcus Calcarine
sulcus

Temporal
Temporal lobe
lobe
Medulla Cerebellum Pons Cerebellum

Spinal cord Medulla

Figure 15–4
Anatomical The major
structures: lobes
sulci and some
= grooves prominent
& gyri = elevated of the brain
sulci areas (singular: atgyrus)
sulcus, right. (Reproduced, with permission, from
of the human cerebral cortex. A lateral view of the left side Martin 2003.)
The most prominent
of the brain sulci
is shown define
at left and athe borders
medial view ofbetween the brain’s lobes
the right side
Figure 1.6

Figure 1.6: Major lobes of the cortex. The frontal lobe, separated by
the lateral sulcus from the temporal lobe, and the central sulcus from
the parietal lobe. The cingulate sulcus (visible in a sagittal section)
separates the frontal lobe from the parietal lobe internally.
 Medical Sciences II L1
Chapter 15 / The Organization of the Central Nervous System
1.6 Further structures invisible from the surface

Cingulate gyrus
Caudate nucleus Ventricle

Parietal lobe
Globus pallidus
Operculum
Putamen

Lateral sulcus Insular
cortex

Caudal

Rostral

Ventricle Amygdala

coronal section
Folding the cortex increases the brain surface Temporal lobe

area: more surface area means more computing
power!
Frontal lobe
Guess which “animal” has got an enormous
cortical surface area?
Figure 15–5 Structures in the middle of the cerebral hemi- called ventricles are filled with cerebrospinal fluid. (Adapt
spheres. These include theFigure 1.7 (caudate nucleus and
basal ganglia with permission, from England and Wakely 1991.)
globus pallidus) and insular cortex. Large cavities in the brain
Cross section to illustrate folded structure of the cortex and showing CSF-
filled ventricles in the brain.
The Major Functional Systems the arousal level of the animal. A single neuron
Are Similarly Organized cally receives signals from thousands of presyn
neurons, and the summation of all of these i
The central nervous system consists of several func- determines the output of the neuron. The inform
tional systems that are relatively autonomous. There encoded by each successive neuron in a func
are, for example, discrete systems for each of the five pathway is typically more complex than the outp
special senses (touch, vision, hearing, taste, smell), for the preceding neuron.
different classes of movement (eye movements, arm
movements, hand movements), and for language. Neurons at Each Synaptic Relay Are Organized
Each functional system comprises numerous intercon- a Neural Map of the Body
nected anatomical sites throughout the brain.
These several functional systems of the brain must One of the most striking features of the orga
act together cooperatively. In sensory systems, for tion of most sensory systems is that the inputs
example, sensory neurons in the periphery project, peripheral receptive surfaces—the retina o
directly or indirectly, to one or more regions in the eye, the cochlea of the inner ear, and the su
spinal cord, brain stem, and thalamus. The thalamus of the skin—are arranged topographically thro
projects to the primary sensory areas of cerebral cortex, out successive stages of processing. Neighb
which in turn project to other regions of cortex. groups of cells in the retina, for example, proj
neighboring groups of cells in nuclei of the t
mus, which, in turn, project to neighboring re
Information Is Transformed at Each Synaptic Relay
of the visual cortex. In this way the neurons at
The output of each synaptic relay in a functional path- successive relay of a sensory pathway for
way is rarely the same as its input. For example, infor- orderly neural map of information from the r
mation may be amplified or attenuated depending on tive surface.
 nized in the cortex to the white matter (Figure 15–6).
Layer I, the molecular layer, is occupied by the den-
drites of cells located in deeper layers and axons that
cortex near- travel through this layer to make connections in other
d into layers areas of the cortex.

Pial surface Golgi stain Nissl stain Weigert stain

I
Molecular
1.7 Cellular organization of the cortex
layer

External
II granule
cell layer

External
III pyramidal
cell layer

Internal
IV granule
cell layer
The cortex is organized
Internal
V pyramidal in distinct layers.
cell layer

Note that depending on
the staining technique
VI
Multiform you get different things to
layer
see

White matter

Figure 1.8

Figure 1.8: Golgi stains mark only a few cells more or less completely. It
is unknown “why” the many other cells are not stained. Note the pyramidal
cell the soma of which is located in layer V – its apical (single long process
above the soma) and basal dendrites (shorter processes arranged around the
soma) are nicely stained. The process right below the soma might be the
axon carrying information to other cells. Nissel, and Weigert stains mark
mostly only cell bodies and processes but no cell bodies, respectively.
 Chapter 15 / The Organization of the Central Nervous
IV
System 347
V
IV IV

V
Chapter 15 / The Organization of theV Central NervousV System 347 VI

Prefrontal Primary Parietal Primary
association motor association visual
cortex cortex cortex VI cortex

1.8 Cortical layers and Brodmann‘s areas
VI
I I VI
I I

II II
Prefrontal Primary II Parietal II Primary
association motor association visual III
cortex cortex cortex cortex
III 6 4
31
III III 8 2
I I I I IV 5

9
IV
II II V
7 9
II II IV
IV 19
III V
46
V V VI
40 10
10
III 39
18
VI 45 44
III III 43 41
IV VI 42 11
VI 47 22
11 17
IV 21
18
V 38 37 19
IV IV Lateral
view
20
V 6 4
31
Figure 15–8 The extent 6 of each cell
4 3 1 of the neocortex
layer layer
V V 8 VI 2 2
5 varies throughout the cortex. Sensory areas of5 cortex, such work
8
9 as the primary visual cortex, tend to have a very prominent
7 vario
7 internal
9 granular cell layer (layer IV), the site of sensory input. sion
Motor areas of cortex, such 31
24 as the primary motor cortex, have hum
VI 19 a very meager32layer IV but prominent output23 layers, such as19 2003
VI 46
VI