Autonomic Nervous System PDF

Summary

This document provides an overview of the autonomic nervous system, highlighting its functional roles in maintaining homeostasis and regulating various body systems. It details the anatomical and functional differences between the autonomic and somatic nervous systems, including the two main subdivisions (sympathetic and parasympathetic) and their respective influences on bodily functions. The text also discusses the organization of the spinal grey matter and the innervation of various organs.

Full Transcript

The Autonomic Nervous System
Images from Human Anatomy 6th ed., © 2009, by Martini,
Timmins and Talitsch, denoted by “Ma”.
Images from Human Anatomy, 2nd ed., © 2008 by McKinley
& O’Loughlin, denoted by “Mc”.

1

Fxns of the Autonomic Nervous System (ANS)
Functionally maintains homeostasis
• regulates body temperature via control of sweat glands and vascular
smooth muscle
• regulates the activity of body systems:
– cardiovascular
– respiratory
– digestive
– excretory
– reproductive systems

• monitors and adjusts body fluids, fine-tuning concentrations of
– electrolytes
– nutrients
– dissolved gases
2

The ANS differs from the Somatic NS
Anatomically:
• in the somatic NS, neurons in the CNS synapse directly onto effectors:
Brain stem
or spinal cord
(CNS)

Somatic motor neuron

Skeletal
muscle

Peripheral nerve

• in the ANS, the CNS controls effectors via a two neuron chain:

Brain stem
or spinal cord
(CNS)

Preganglionic
neuron

Autonomic
ganglion Postganglionic
neuron
Peripheral nerve

Smooth
or cardiac
muscle or
glands

• The somatic NS and the ANS may share a given peripheral nerve
• there are two subdivisions of the ANS, the sympathetic nervous system
(SyNS) and the parasympathetic nervous system (PsyNS)

3

The SyNS & PsyNS Differ Functionally
• the PSyNS predominates during resting conditions: “rest & digest”
• the SyNS predominates during exertion or emergencies: “fight or flight”
• within a given system, the two divisions usually oppose each other
– e.g. SyNS  HR, PSyNS  HR
– e.g. PSyNS  digestion, SyNS  digestion
• occasionally they work independently
– SyNS alone controls most vascular smooth muscle and all smooth
muscle in the limbs & body wall (BVs, erector pili muscle, glands)
4

The SyNS & PSyNS Differ Anatomically
The two divisions differ in the locations of their:

A

Preganglionic
neuron

Autonomic
ganglion Postganglionic
neuron
B
Peripheral nerve

Smooth
or cardiac
muscle or
glands

A. preganglionic neuronal cell bodies in the CNS
• SyNS (“thoracolumbar division”): spinal cord, T1-L2 levels
• PSyNS (“craniosacral division”): brainstem cranial nerve nuclei
& spinal cord, S2-S4 levels
B. postganglionic neuronal cell bodies in the PNS
• sympathetic ganglia located near the spinal cord in either the
paired sympathetic chain ganglia or unpaired preaortic ganglia
• parasympathetic ganglia located in or near effector organs

5

Organization of the
Spinal Grey Matter

• deep, forms a continuous column
extending the length of the cord

Gray matter
White matter
Ventral root

• at all levels, grey matter forms a
butterfly in XS, divided into:

Spinal nerve
Dorsal root
ganglion
Dorsal root

– dorsal horns: sensory, receives
input via spinal nerves and
dorsal roots
– ventral horns: somatic motor,
conducts output via ventral
roots, spinal Ns

Ma14.2

• at certain levels, (T1-L2 & S2-S4)
intermediolateral cell column (IML),
contains autonomic preganglionic
motor neurons, conducts output via
ventral roots, ensuing nerves
8

The Sympathetic Division

targets:

A. smooth muscle of limbs & body wall
B. viscera of head & thorax
C. viscera of abdomen & pelvis

preganglionic neurons (for ALL targets)
• cell bodies located in lateral gray horns, T1-L2;
• axons travel via ventral roots, spinal nerves, synapse onto:

postganglionic neurons
• cell bodies located in sympathetic ganglia near the vertebral column, either:
– in bilaterally paired sympathetic chain ganglia (targets A&B) or
– in unpaired prevertebral (preaortic) ganglia (targets C)
• postganglionic axons innervate the target organ

9

Somatic Innervation of the Body Wall & Limbs
• somatic motor neurons innervate skeletal muscle
– cell bodies in the ventral grey horn of the spinal cord
• sensory Ns monitor skin, joints, skeletal muscle
– cell bodies in dorsal root ganglia (DRG), axons
convey info to dorsal grey horn of spinal cord
• their axons form peripheral nerves

A. Dorsal horn
B. Lateral horn

H

E
G

I

C. Ventral horn
D

F

A
D. Dorsal root
B

E. DRG

C

F. Ventral root
G. Spinal nerve
H. Dorsal ramus

XS through spinal cord
between T1 and L2

I. Ventral ramus

10

A. Sympathetic Innervation of the Body Wall & Limbs
• the body wall & limbs are innervated by postganglionic sympathetic
neurons located in the paravertebral or sympathetic chain ganglia
• target organs are smooth muscle of erector pili, BVs, glands in ALL
dermatomes of body

Rami
communicantes
Paravertebral
ganglion

XS through spinal cord
between T1 and L2

11

Preganglionic sympathetic fibres can ascend
or descend within the sympathetic chain
before synapsing.
In this way, sympathetics are distributed to
dermatomes* ABOVE T1 and BELOW L2
*dermatome: the area of skin innervated by
a specific spinal segment and nerve

12

Summary: The Sympathetic Nervous System
PONS

Dermatomes

C2–C3
NV
C2–C3

Cervical Superior
sympathetic
Middle
ganglia Inferior

C2
C3

Gray rami to
spinal nerves
T2

C6

L1
L2

C8

Postganglionic fibers to
spinal Ns (innervating BVs,
sweat glands, erector pili
muscles, adipose tissue)

C7

T1

L3
L4

L5

Sympathetic
chain ganglia

C3
C4
C5 T2
3
T1 T
T4
T2 T
T3 T5
T4 T67
T5 T8
T6 T9
T7 T10
T8 T11
T9 T
L12
T10 L21
T11 L4L3
T12 L5
S2

C4
C5
T2
C6
C7

T1

SS
4
3

L1

S5

S1L5

C8

L2S2

L3

S1

Ma17.4

Preganglionic Ns
Ganglionic Ns

Coccygeal
ganglia (Co1)
fused together
(ganglion impar)

L4
ANTERIOR

POSTERIOR

13

B. Sympathetic Innervation of Thoracic Viscera & Face
Thoracic viscera & targets
in the face are innervated
by postganglionic
sympathetic Ns located in
the paravertebral or
sympathetic chain ganglia.
For targets in the thorax:
Axons of postganglionic
Ns form splanchnic Ns
(cardiac, pulmonary, esophageal splanchnic
Ns) which contribute to autonomic plexuses
(cardiac, pulmonary, esophageal plexuses)
that innervate targets in the thorax.
For targets in the face:
Axons of postganglionic Ns form autonomic
plexuses, which “hitch a ride” with arteries
to reach their targets. Named for artery, eg.
carotid plexus.

14

Summary: The Sympathetic Nervous System
Eye
PONS

Salivary glands

Cervical Superior
sympathetic
Middle
ganglia Inferior
Gray rami to
spinal nerves

Heart
Cardiac and
pulmonary
plexuses

Lung

Postganglionic fibers to
spinal Ns (innervating BVs,
sweat glands, erector pili
muscles, adipose tissue)
Sympathetic
chain ganglia

Ma17.4

Preganglionic Ns
Ganglionic Ns

15

C. Sympathetic Innervation of Abdominopelvic Viscera
Abdominopelvic viscera are
innervated by postganglionic
sympathetic neurons located in
the prevertebral ganglia, eg. the
celiac, superior mesenteric and
inferior mesenteric ganglia.
Axons of postganglionic neurons
contribute to autonomic plexuses,
which “hitch a ride” with arteries
to reach their target organs.
The plexuses are named by the
BV, ie. celiac, superior and
inferior mesenteric plexuses.

16

The Adrenal Medulla
• is a modified sympathetic ganglion
• is innervated by preganglionic sympathetic neurons of the lateral gray horns
• postganglionic “neurons” of the adrenal medulla release epinephrine &
norepinephrine which is picked up by blood vessels for systemic distribution
• consequences?

17

Summary: The Sympathetic Nervous System
Eye
PONS

Salivary glands

Cervical Superior
sympathetic
Middle
ganglia Inferior
Gray rami to
spinal nerves

Heart
Celiac
ganglion

Cardiac and
pulmonary
plexuses

Lung

Superior
mesenteric
ganglion

Liver and
gallbladder
Stomach
Spleen
Pancreas
Large intestine
Small intestine

Inferior
mesenteric
ganglion

Postganglionic fibers to
spinal Ns (innervating BVs,
sweat glands, erector pili
muscles, adipose tissue)

Adrenal medulla
Kidney

Sympathetic
chain ganglia

Ma17.4

Preganglionic Ns
Ganglionic Ns

Coccygeal
ganglia (Co1)
fused together
(ganglion impar)

Urinary bladder
Ovary
Uterus

Testicle

18

Mc18.7

19

The Parasympathetic Division

preganglionic neuronal cell bodies located either in:

1. brainstem cranial nerve nuclei; axons travel via cranial nerves (III, VII, IX,
and X (the vagus nerve)), OR
2. IML cell column, S2-S4
• preganglionic fibres synapse onto
postganglionic PS neurons within:

S2 – S4

parasympathetic ganglia
• located in or near the effector organ (intramural or terminal ganglia)
• short postganglionic fibres innervate the cells of the effector organ
CN III, VII & IX innervate viscera of the face
CN X (the vagus nerve) innervates viscera of the thorax & most of abdomen
pelvic splanchnic nerves innervate the viscera of the distal abdomen & pelvis

note: no parasympathetic innervation of smooth muscle targets in
limbs or body wall, nor most vascular smooth muscle elsewhere 20

Lacrimal gland
Eye
PONS

Salivary glands

N X (Vagus)

Heart

Lungs
Liver and
gallbladder

Autonomic
plexuses

Stomach
Spleen
Pancreas
Pelvic
splanchnic
nerves

Large intestine
Small intestine
Rectum

Spinal
cord

Kidney
Urinary bladder

Ma17.8

Preganglionic neurons
Ganglionic neurons

Uterus Ovary

Penis

Testicle

21

• visceral organs have dual
innervation

Autonomic Plexuses

• two divisions generally
antagonistic

Trachea
Left vagus nerve
Right vagus nerve
Aortic arch
Thoracic
Spinal
nerves
Esophagus
Splanchnic
nerves
Diaphragm
Celiac trunk
Superior
mesenteric
artery
Inferior
mesenteric
artery

• overlap of SyNS & PSyNS
Autonomic Plexuses
in autonomic plexuses:
and Ganglia
Cardiac plexus
Pulmonary plexus
Thoracic sympathetic
chain ganglia
Esophageal plexus
Celiac plexus and
ganglion
Superior mesenteric
ganglion
Inferior mesenteric
plexus and ganglion

Hypogastric plexus
Pelvic sympathetic
chain

– cardiac plexus
– pulmonary plexus
– esophageal plexus
– celiac plexus
– superior mesenteric plexus
– inferior mesenteric plexus
– hypogastric plexus
– pelvic plexus

Ma17.9

22

Autonomic Afferents: Homeostatic Input
• afferents from an organ retrace the path taken by the efferents to the organ
 if you know the motor output pathway, you know the sensory input pathway!
• afferents carrying homeostatic sensory information (eg. BP from
baroreceptors, blood gas from chemoreceptors) generally travel with
parasympathetic efferents
• other than the distal digestive tract and pelvis, this is via the vagus nerve!

23

Autonomic Afferents: Visceral Pain
• viscera are insensitive to cutting, burning, freezing
• visceral pain is caused by ischemia, distension, inflammation, blood etc.
• visceral pain usually travels with the sympathetic efferents
eg., the Sy efferents to the heart originate from spinal cord levels T1 – T5
 pain afferents from the heart travel with sympathetic efferents back to spinal
cord levels T1 – T5
Sensory neuron
from body wall

Both project to the
same dorsal horn cell

• in the spinal cord, overlap with
afferents from the T1 – T5 dermatomes
gives rise to the referral of cardiac
pain to these dermatomes, ie. chest,
armpit, medial arm
• this is the anatomical basis of “referred
pain”

Sensory neuron
from viscus

24

The Ear
Images from Human Anatomy 6th ed., © 2009, by
Martini, Timmins and Talitsch, denoted by “Ma”.
Images from Human Anatomy, 2nd ed., © 2008 by
McKinley & O’Loughlin, denoted by “Mc”.
Images from Neuroscience: Exploring the Brain
by Bear, et al., 3rd Edition, © 2006.

Sound Waves
• when an object moves towards a patch of air, molecules in the air are
compressed, i.e. made more dense
• when an object moves away from a patch of air, molecules in the air are rarefied,
i.e. made less dense
• vibrating objects alternately rarefy and compress the air around it, creating
alternating patches of compressed / rarefied molecules travelling through space
• these sound waves and move away from the source at the speed of sound
• when this mechanical energy meets the auditory apparatus, we “perceive sound”
Rarefied air

Air pressure

Compressed air

Distance

One cycle

Pitch of Sound
• the frequency of sound waves is the number of compressed or rarefies patches of
air that pass by our ears each second, expressed in cycles per second or Hz
• pitch is proportional to the frequency of the changes in air pressure per unit time
• our auditory system responds to sound waves over the range of 20 Hz – 20 kHz
• range decreases with age and with damage to the inner ear due to loud noise
• infrasound: sound waves below 20 Hz
• ultrasound: sound waves above 20 kHz

Lower frequency / pitch

i.e. not detectable by
our hearing apparatus
From Neuroscience: Exploring the Brain, 3e, by Bear, et al., © 2006.

Air pressure

Higher frequency / pitch

Distance

One cycle

Distance

One cycle

Intensity of Sound
• intensity is the difference in pressure between the compressed and rarefied
patches of air and determines the loudness
• intensity is measured in decibels or db, a logarithmic scale that requires a ten-fold
increase in intensity for a perceived doubling of “loudness”
• this graphic illustrates two sounds at the same pitch, but differing in their intensity,
and therefore perceived loudness

From Neuroscience: Exploring the Brain, 3e, by Bear, et al., © 2006.

Higher intensity / loudness

Air pressure

Lower intensity / loudness

Distance

One
cycle

From Neuroscence: Exploring the Brain by Bear, et al., 3e, © 2006.

Distance

One
cycle

The Ear: An Overview
EXTERNAL EAR

MIDDLE EAR
AIR-FILLED SPACES
GATHER, AMPLIFY, TRANSFER SOUND WAVES TO:

Ma18.9

INNER EAR
FLUID-FILLED SPACE
CONTAINS SENSE
ORGANS OF:
1. BALANCE
2. HEARING

5

A. pinna (auricle) gathers sound waves

The External Ear
EXTERNAL EAR

– contributes to sound localization

MIDDLE EAR

Elastic
cartilages

– supported by elastic cartilage
– the lobule (lobe) lacks cartilage
– directs sound waves into the:
B. external auditory canal
– wall of lateral 1/3 cartilagenous,
medial 2/3 bony

A
B

C

– lining skin contains ceruminous &
sebaceous glands which produce
cerumen (earwax)
C. tympanic membrane (ear drum)
– separates external, middle ear

Petrous part of
temporal bone

Ma18.9

– vibration of air (sound waves)
causes vibration of the “ear drum”
– thin skin externally, mucous
membrane internally
why mucous membrane internally?

6

The Middle Ear
MIDDLE EAR

INNER EAR

A. consists of the tympanic cavity, an airfilled space within the petrous temporal
bone containing auditory ossicles
B. tympanic cavity opens to the mastoid
air cells by many variable channels;

AUDITORY
OSSICLES

middle ear infections can lead to mastoiditis

C. opens to the nasopharynx by the
auditory (pharyngotympanic,
Eustachian) tube
∴lined by mucus membrane

EXTERNAL
AUDITORY
CANAL

– walls 1/3 bone, 2/3 cartilagenous

A

– latter closed at rest, opens with
muscular contraction during
swallowing, yawning…

B
C
TO NASOPHARYNX
Ma18.9

– equalizes P in middle ear with
atmosphere
– ∴ prevents distortion of tympanic
membrane with changes in
atmospheric pressure
– route for spread of infection from
pharynx to middle ear “otitis media” 7

The Auditory Ossicles
FOOTPLATE
OF STAPES

• span tympanic cavity from the tympanic
membrane to the oval window
• oval window separates the air-filled
middle ear and the fluid-filled inner ear
• footplate of stapes fits in oval window,
sealed and secured by annular ligament

Malleus
Incus

TYMPANIC
MEMBRANE

Ma18.10

• vibration of tympanic membrane moves
the auditory ossicles
• mvt of ossicles ↑ force of sound waves,
transfers them to the oval window

Stapes
TYMPANIC
CAVITY

• stapes moves like a piston in the oval
window, initiating pressure waves in the
fluid of the inner ear

8

MIDDLE EAR

INNER EAR

VIII VESTIBULAR
DIVISION
VIII COCHLEAR
DIVISION
CN VIII
VESTIBULAR
APPARATUS
COCHLEA

The Inner Ear I
• contains 2 special sense organs
innervated by the vestibulocochlear N.
(CN VIII):
A. the vestibular apparatus which senses
“equilibrium”, or the position &
acceleration of the head in space
• served by the vestibular division of
the vestibulocochlear N. (CN VIII)
B. the cochlea which senses sound
• served by the cochlear division of
the vestibulocochlear N. (CN VIII)

Ma 18.9

9

The Bony Labyrinth

Cast of right labyrinth (lateral aspect)

Frontal section through left temporal bone (posterior aspect)

Rohen, J. W. Anatomy: A Photographic Atlas, 8e, © 2015, Wolters Kluwer Health.

Cast of right labyrinth (posteromedial aspect)

10

Bony
labyrinth
Cochlea

Membranous
labyrinth
Cochlear
duct
Vestibule
Utricle &
saccule
Semicircular Semicircular
canals
ducts

Senses:

The Inner Ear II

Hearing

• bony labyrinth: interconnected,
fluid-filled spaces within the
petrous temporal bone

Position, linear
acceleration of head
Angular acceleration
of head

Vestibular
apparatus
SEMICIRCULAR
CANALS

VESTIBULE:
UTRICLE
SACCULE

COCHLEA

SEMICIRCULAR
DUCTS

Ma18.12

– 3 subdivisions: the cochlea,
vestibule & semicircular canals
• membranous labyrinth:
suspended within the bony
labyrinth, also fluid-filled
– consists of the cochlear duct,
utricle & saccule and
semicircular ducts
– the sense organs of hearing
and balance are epithelial
specializations of the
membranous labyrinth, and
are illustrated in purple
KEY

COCHLEAR
DUCT

Membranous
labyrinth
Bony labyrinth

11

The Cochlea
• a subdivision of the bony labyrinth
• a coiled, tubular space; walls made of
compact bone
• spirals around a peg of bone, the modiolus
which contains Ns & BVs
VIII

B
C

B
B

A
C
A
C

Ma18.17

• the membranous cochlear duct is suspended
within the cochlea; its contained space is the
scala media (B)

A

• the cochlear duct spans the cochlea from the
bony spiral lamina (SL) to the opposite wall;

B

A

• cochlear duct subdivides the cochlear space
into the scala vestibuli (A) and the scala
B tympani (C)

C
A
C

• cochlear duct ends at the apex of the cochlea
• scalae vestibuli and tympani continuous at
SL
the apex of the cochlea via the helicotrema

Ns, BVs

12

The Spiral Organ

Ma18.17

• basilar membrane (BM) separates the
scala media from the scala tympani

SCALA
MEDIA

• sense organ of hearing, the spiral organ
is located on the basilar membrane

SCALA
VESTIBULI

• spiral organ contains hair cells and
support cells
BM

SPIRAL
GANGLION

SCALA
TYMPANI

• afferent nerve fibres monitor hair cells
• cell bodies of sensory afferents in the
spiral ganglion

SPIRAL
ORGAN

• axons join cochlear branch of CN VIII
within modiolus

HAIR
CELLS

AFFERENT
NERVE FIBRES

SUPPORT
CELLS
BASILAR MEMBRANE

13

+
+

Hair Cells

+
+

• sensory cells of inner ear
• transduce sound energy into
APs in the afferent nerves

Reticular
lamina

Depolarization

• “hairs” are stereocilia on the
apices of the hair cells

Voltage-gated
calcium channel

Hair cell

• membrane potential of hair cells
determines rate of NT release
from basal surface of hair cells
• bending of hairs in one direction
opens channels, depolarizes
hair cell, ↑ NT release

• bending of hairs in the other
Vesicle filled
direction closes channels,
with excitatory
hyperpolarizes hair cell, ↓ NT
neurotransmitter
release
Spiral ganglion
neurite

B11.15

• pulsatile release of NT causes
bursts of APs in afferent Ns
14

The Cochlea Uncoiled
• the oval window / footplate of
stapes are at the base of the
scala vestibuli
• the membrane-enclosed
round window is at the base
of the scala tympani
• with vibration of the tympanic
membrane, the stapes moves
in and out of the oval window
like a piston
• pressure waves initiated in
the fluid of the scala
vestibule are relieved at the
round window
• the membranous labyrinth /
basilar membrane vibrates in
response to these pressure
waves
• hairs on the hair cells vibrate
→ pulsatile release of NT

A

Helicotrema
Malleus

Incus
Stapes

Oval window

Scala
vestibuli
Scala
media

Tympanic
membrane

Scala
tympani
Round window
with membrane

B

C

33 mm
Tympanic
membrane Round
window

Oval window

Compression
Rarefaction
From Principles of Neural Science, 5e, by Kandel, et al., © 2014 by McGraw-Hill.

Basilar
membrane

The Perception
of Pitch

LOW-FREQUENCY SOUNDS
SCALA MEDIA

SCALA VESTIBULI
HELIOCOTREMA

BASILAR MEMBRANE

SCALA TYMPANI

MEDIUM-FREQUENCY
SOUNDS

• BM is narrow and stiff at it’s base,
wide and floppy at its apex
• this is because the size of the spiral
lamina decreases from base to apex

HIGH-FREQUENCY
SOUNDS

Base

Apex

BASILAR
MEMBRANE
HIGH
FREQ

Mc19.29

MED
FREQ

Hz
Hz
20,000
1500
(high notes)

LOW
FREQ

Hz
500

• the BM is optimally displaced at a
certain point along its length by a
specific frequency; this activates the
population of neurons monitoring the
spiral organ at that point
• thus, the spiral organ is organized
“tonotopically”

Hz
•
20
(low notes)

pitch coded by the pop’n of neurons
firing in response to a given sound
16

Auditory Pathways
Auditory pathways project bilaterally
to primary auditory cortex.

Auditory cortex
(temporal lobe)

Low-frequency
sounds

What is the clinical implication of
this wrt a unilateral lesion?
Low-frequency
sounds

Thalamus

High-frequency
sounds
Medial geniculate
nucleus (thalamus)
Inferior
colliculus

High-frequency
sounds

Cochlear
nuclei

Ma18.18

Cochlear N.

17

Deafness
Conduction Deafness
• involves the external or middle ear
• e.g. “swimmer’s ear”, otosclerosis
• inner ear is intact, so hearing aids are effective

Sensorineural Deafness
• involves the inner ear or cochlear nerve
• e.g. destruction of hair cells by exposure to loud sounds, ototoxic drugs,
lesion of CN VIII

18

Bony
labyrinth
Cochlea

Membranous
labyrinth
Cochlear
duct
Vestibule
Utricle &
saccule
Semicircular Semicircular
canals
ducts

Senses:

The Inner Ear II

Hearing

• bony labyrinth: interconnected
spaces within the petrous
temporal bone

Position, linear
acceleration of head
Angular acceleration
of head

Vestibular
apparatus
SEMICIRCULAR
CANALS

VESTIBULE:
UTRICLE
SACCULE

COCHLEA

SEMICIRCULAR
DUCTS

Ma18.12

– 3 subdivisions: the cochlea,
vestibule & semicircular canals
• membranous labyrinth:
suspended within the bony
labyrinth
– consists of the cochlear duct,
utricle & saccule and
semicircular ducts
– the sense organs of hearing
and balance are epithelial
specializations of the
membranous labyrinth, and
are illustrated in purple
KEY

COCHLEAR
DUCT

Membranous
labyrinth
Bony labyrinth

19

The Vestibular Apparatus I: the Otolith Organs
• are the utricle and the saccule
• each contains a macula, an area of
epithelium with hair cells and support cells
• tips of stereocilia embedded in a gelatinous
matrix, the otolith membrane
• otolith membrane contains calcium carbonate
crystals called otoconia (statoconia)
• therefore, the otolith membrane has a higher
density than the surrounding fluid
Otolith membrane

Gelatinous material
otoconia

Hair cells

Nerve fibers

Ma18.15

20

The Otolith Organs: The Utricle & Saccule
• fxn: detect the static position and linear acceleration of the head
• macula of utricle oriented horizontally; macula of saccule oriented vertically
• tilting of head (see below) causes otolith membrane to shift due to gravitational
pull; this distorts stereocilia, alters NT release
• linear acceleration of head in plane of macula (not shown) causes otolith
membrane to shift due to inertia; this also distorts stereocilia, alters NT release
• popn of hair cells activated, 1° sensory neurons firing APs codes for head
position, linear acceleration
Head in Neutral Position

Ma18.15

Gravity

Head Tilted Posteriorly

Receptor
output
increases

Gravity

Otolith moves
“downhill,”
distorting hair
cell processes

21

The Vestibular Apparatus II: The Semicircular Ducts
Semicircular
ducts

Ampulla

• three arranged at right angles to each other
• each has an ampulla containing the crista
ampullaris with hair cells

Utricle
Saccule

• tips of hair cells embedded in the gelatinous
cupola
• no otoconia, so density of cupola is the same
as the surrounding fluid
• ∴ cupola moves with fluid

Ampulla
filled with
endolymph
Cupula

Anterior semicircular
duct

Hair cells

Lateral
semicircular
duct
Crista

Supporting
cells

Ma18.13

Sensory nerve

Ma18.14

Posterior semicircular
duct
22

The Semicircular Ducts Detect Rotation
• fxn: detect rotation of the head
• with rotation of the head in the plane of a given duct, endolymph and cupola
lag behind due to inertia, bending the hairs
• this alters AP traffic along vestibular division of CN VIII
• since at right angles to each other, each optimized to detect mvt around a
different axis
Direction of relative
endolymph movement

Direction of
duct rotation

Direction of
duct rotation

Semicircular duct
Ampulla

Ma18.13

Cupola
At rest
23

Pathways for Equilibrium Sensations
Information used to coordinate head mvt with eye, neck, trunk and limb mvt.
To thalamus and
cerebral cortex for
conscious sensation
Vestibular
ganglion

Semicircular
canals

N III
Vestibulo
-ocular
reflex
Vestibular
branch

N IV

Vestibular
nuclei

N VI

To
cerebellum
Vestibule
Cochlear
branch

Rotate your owl
Ma18.16

N XI
Vestibulocolic
reflex

Vestibulocochlear
nerve (N VIII)
Vestibulospinal
tract

24

The End

Rohen, J. W. Anatomy: A Photographic Atlas, 8e, © 2015, Wolters Kluwer Health.

25

The Eye
Images from Human Anatomy 8th ed., © 2015, by Martini,
Timmins and Talitsch, denoted by “Ma”.
Images from Human Anatomy, 2nd ed., © 2008 by
McKinley & O’Loughlin, denoted by “Mc”.

1

The Orbit
• a pyramidal space
• base located anteriorly
• apex located posteromedially at
the optic foramen
• contains eyeballs, muscles, Ns, BVs,
lacrimal apparatus and orbital fat
Orbits, superolateral view

The medial walls are parallel.
Orbits, superior view

2

The Orbit: Bones

Roof
A. frontal bone
B. sphenoid bone
C. fossa for lacrimal gland

A

J

C

Medial wall
I

D. ethmoid bone
E. lacrimal bone
F. fossa for lacrimal sac

B

Lateral wall

D E

G. zygoma

F

G

B. sphenoid bone

Floor
H. maxilla

K

H

G. zygoma

Orbital openings
I. optic canal
J. superior orbital fissure

Ma6.15

K. inferior orbital fissure
3

Surface Anatomy
of the Eye

A. palpebral fissure
C

B. medial and lateral angles

H

C. palpebrae superioris and
inferioris
G

D. pupil

B

E. iris

F

F. sclera covered by
conjunctiva; conjunctivitis

E

G. eyelashes with sebaceous
and apocrine glands

D
C’
Ma18.19

covered by cornea

A

B’

H. in medial angle, the
lacrimal lake
4

The Eye & Eyelids

A. orbicularis oculi
B. sup., inf. tarsal plates

F

D

C’

E

C

G
A
B

–

tarsal glands are large
sebaceous glands

–

often implicated in styes

C. medial, lateral palpebral
ligaments
D. levator palpebrae superioris
C. orbital fat
D. lacrimal gland

Ma18.19

E. lacrimal sac

5

The Eye in Sagittal Section
Ma18.21

D

C

B. palpebral conjunctiva

B
A

C. conjunctival sac
D. conjunctival fornix

E
K
J

G
F
I

A. orbital conjunctiva

H

E. sclera
F. cornea
G. iris
H. pupil
I. lens
J. suspensory ligaments
K. ciliary body
6

The Lacrimal Apparatus
A

B

E
C

F
D

G
H

Ma18.19

• fossa for lacrimal gland (A) in
superolateral orbit
• gland secretes lacrimal fluid into
conjunctival sac via ~12 lacrimal
ducts (B) that open into the
superior conjunctival fornix
• lacrimal fluid collects in lacrimal
lake (C)
• drains via lacrimal puncta (D),
lacrimal canaliculi (E) to the
lacrimal sac (F)
• drains via nasolacrimal duct (G)
into nasal cavity (H)

7

The Globe Consists of Three Layers
Fibrous Vascular Neural
tunic
tunic
tunic
(sclera) (choroid) (retina)

The three layers, or
tunics, of the eye
Ma18.21

The Fibrous Layer: The Sclera & Cornea
Visual
axis

A. opaque sclera covers post. 5/6
of eyeball
D

B

C

C

B. ant. portion visible through
orbital conjunctiva
C. insertion of the six extraocular
eye muscles, which position the
eye in the orbit

A
D. transparent cornea covers ant.
1/6 of eyeball, bends light to
focus it on the fovea (E)

Ma18.21

E

9

G

The
Extraocular
Eye Muscles

Trochlea

A
D

II
B

E
C

• insert into the sclera
• position the eye in
the orbit

F

A.

Superior rectus

B.

Inferior rectus

C.

Medial rectus

D.

Lateral rectus

E.

Superior oblique

F.

Inferior oblique

G. LPS
Why two muscles elevate,
and two muscles depress?
Balance out unwanted mvts

ELEVATION

A

Trochlea

E

Frontal bone

LPS

E

Trochlea

Optic nerve

A

C

D
ABDUCTION

D

ADDUCTION

B

F
Ma10.5

B
DEPRESSION

F

Maxilla

Lateral view

10

Movements of the Eye are Balanced
In the neutral position the eye is adducted relative to the orbital axis:
Depression:
•

superior oblique: depression (and intorsion & abduction)

•

inferior rectus: depression (and extortion & adduction

Elevation:
•

inferior oblique: elevation (and extorsion & abduction)

•

superior rectus: elevation (and intorsion & adduction)

ELEVATION

A

Trochlea

E
C

D
ABDUCTION

F

Orbits, superior view

ADDUCTION

B
DEPRESSION

Ma10.5
From Moore’s Essential Clinical Anatomy, 7e, © 2023 by Wolters Kluwer

11

Clinical Testing of
Extraocular Muscles
• abduction aligns angle of gaze
with pull of sup., inf. rectus
• adduction aligns angle of gaze
with pull of sup., inf. oblique

From Moore’s Essential Clinical Anatomy, 7e, © 2023 by Wolters Kluwer

12

Innervation: LR6, SO4, AO3
IV
III
G

A
D

II

B
F
VI

E
C
A.

Superior rectus

B.

Inferior rectus

C.

Medial rectus

D.

Lateral rectus

E.

Superior oblique

F.

Inferior oblique

G. Levator palpebrae superioris
Ma10.5

13

Nerve Palsies
Oculomotor nerve palsy
• only lateral rectus, inferior oblique spared
• inc. paralysis of levator palpebrae superioris
• inc. paralysis of sphincter pupillae
• Presentation:
– eye “down and out”
– ptosis (droopy eyelid)
– mydriasis (large pupil)
Abducens nerve palsy
• paralysis of lateral rectus
• eye adducted at rest due to unopposed medial rectus
• when asked to look toward lesioned side, only contralateral (unaffected)
eye moves
14

The Pigmented (Vascular) Layer
Fornix

Levator palpebrae
superioris Upper eyelid
muscle

Posterior cavity
Retina
Ethmoidal labyrinth
Sclera
Lacrimal gland
Medial rectus
muscle
Optic nerve (N II)
Trochlear nerve
(N IV)
Lateral rectus
muscle

Ma18.21

Horizontal section, superior view

A

The Pigmented (Vascular) Layer
Ma18.22

A
H
F

B

Ma18.21

G
A. choroid ends anteriorly as the: ciliary body (B)
& iris (C)

C

C. iris a contractile diaphragm extending anterior
to lens with a central aperture, the pupil
• size of pupil controlled by constrictor (D) &
dilator (E) pupillae muscles within the iris…

D

F. ciliary processes secrete aqueous humor,
provide attachment for suspensory ligaments
of lens (G)
H. ciliary muscle, within ciliary body, adjusts
thickness of lens to further refract light
• controlled by the accommodation reflex...

E
B
16

Control of Pupillary Size

Constrictor pupillae
(circular)

Pupil

Constrictors
contract with
PSy input

Dilator pupillae
(radial)

Ma18.22

Ma18.21

Dilators contract
with Sy input

17

The Accommodation Reflex: Far and Near Vision
• lens transparent, biconvex
• enclosed in a highly
elastic capsule
– isolated lens spherical

• held in place by
suspensory ligaments

• ciliary muscle
relaxed
• suspensory
ligaments taut
• lens flattened
• less refraction
of light

• tension in suspensory
ligaments adjusts shape,
convexity of lens

The eye
accommodates
for close vision
by tightening the
ciliary muscles,
allowing the
pliable crystalline
lens to become
more rounded.

• ciliary muscle
contracted
• suspensory
ligaments
slack
• lens rounded
• more
refraction of
light

– controlled by ciliary
muscle

• convexity of lens varies
continuously to fine-tune
focus of objects on retina

Light rays from
distant objects are
nearly parallel and
don’t need as much
refraction to bring
them into focus.

Light rays from
close objects
diverge and
require more
refraction to bring
them into focus.

18

The Lens and Chambers of the Eye
Ma18.22

Vascular tunic
Choroid
Ciliary body
Iris
Posterior
cavity

Neural tunic
(retina)
Neural layer
Pigmented layer

Anterior cavity
Fibrous tunic
Cornea
Sclera

The lens is suspended between the posterior cavity and the anterior cavity.

The Circulation of Aqueous Humour
Ciliary process

• anterior cavity divided into anterior
and posterior chambers, separated by
the iris

Suspensory ligaments

• epithelial cells covering the ciliary
body secrete aqueous humor into the
Anterior cavity:
Posterior chamber posterior chamber
Anterior chamber

Posterior
cavity
(vitreous
chamber)

Pupil
Cornea

Lens

Body of iris
Ciliary body
Canal of Schlemm
Conjunctiva
Sclera
Choroid
Retina

Ma18.22

• aqueous humor flows from the
posterior chamber through the pupil,
into the anterior chamber
• nourishes the avascular cornea
• at the iridocorneal angle aqueous
humor drains through the trabecular
meshwork into the scleral venous
sinus (canal of Schlemm) and is thus
returned to venous blood
• glaucoma occurs with increased
intraocular pressure
• usually caused by decreased

20

Glaucoma
• aqueous humor produced / removed at same rate to maintain intraocular
pressure, IOP
• in glaucoma, IOP rises due to accumulation of aqueous humor
• increased pressure on retina, optic nerve inhibits blood flow
• causes ischemic damage of retina
Open-angle glaucoma most common
• slowly developing
• age-related changes in the trabecular meshwork
increases resistance to aqueous humor outflow
• initially peripheral vision loss, eventually blindness
• screening for glaucoma part of eye exam
• tx medication, laser trabeculoplasty
21

The Inner (Neural) Layer

A. the retina
B. the ora serrata separates the
visual and nonvisual parts of
the retina

B

C. macula lutea
A

D. fovea centralis
E. optic disc: the “blind spot”

E

F. optic nerve

C

G. central A & V
Ma18.21

F

G

D

22

Macula Fovea
lutea

Ma18.23

Optic disc Central retinal artery
(blind spot) and vein emerging
from center of optic disc

A photograph taken through the pupil showing
the retinal blood vessels, the origin of the optic
nerve, and the optic disc

The Retina Has Four Cell Layers
1. ganglion cells: axons form optic N

2. horizontal, bipolar & amacrine cells process visual signal
3. photoreceptors (rods & cones) transduce light energy into a change in
membrane potential
4. pigmented layer absorbs XS light
Horizontal cell Cone Rod
Choroid
Pigmented
layer of retina
Rods and
cones
Amacrine cell
Bipolar cells
Ganglion cells
Nuclei of Nuclei of rods Nuclei of
ganglion cells and cones bipolar cells
LM x 75

Ma18.23

LIGHT

The retina

24

Why is Resolution Highest in the Fovea?
1. types of photoreceptors
• there are two kinds of photoreceptors: rods and cones
• cones are specialized for:
– high temporal resolution due to fast response time
– low sensitivity ∴ only saturate in intense light
– colour vision due to the presence of three types of cones with
different pigments
• rods are specialized for:
– low temporal resolution due to slow response time
– high sensitivity saturates in daylight
– achromatic as there is only one kind of rod pigment
• cones are concentrated at the fovea, rods in the periphery of the retina

25

Why is Resolution Highest in the Fovea? cont.
2. ratio of photoreceptors to ganglion cells
• average for entire retina 137:1
• in periphery 1000:1 ∴pixel size large
• at the fovea 1:1 ∴pixel size small

3. anatomically adapted for light sensitivity
• light passes through fewer cell layers to reach photoreceptor cells

Rods and cones

Fovea

Bipolar cells
Ganglion cells

26

The End

Ma18.23

Blood Supply of the CNS

Images from Human Anatomy 6th ed., © 2009, by Martini,
Timmins and Talitsch, denoted by “Ma”.
Images from Human Anatomy, 2nd ed., © 2008 by McKinley &
O’Loughlin, denoted by “Mc”.
Images from Grant’s Atlas, 11th ed., by A. Agur, © 2009 denoted
by “GA”

1

Intracranial Blood Supply •
Ma22.13

intracranial structures receive blood
from two sources: the paired internal
carotid As and the paired vertebral As

1. the internal carotid As are branches
of the common carotid As

• they enter the cranium through the
carotid canal
Internal
carotid A

External
carotid A

Vertebral A

2. the vertebral As are branches of the
subclavian As

Common
carotid A

Subclavian A

• they ascend in the neck through the
foramina transversaria and enter the
cranium through the foramen
Brachiocephalic
trunk
magnum alongside the spinal cord 2

These Four Major Arteries Anastomose* at the
* flow together: capillary beds may
Base of the Brain
receive arterial blood from > 1 source
FRONTAL
LOBE

ANTERIOR
CEREBRAL A.

PITUITARY
GLAND

INTERNAL
CAROTID A. (CUT)
MIDDLE
CEREBRAL A.

TEMPORAL
LOBE

POSTERIOR
CEREBRAL A.

POSTERIOR
CEREBRAL A.

BASILAR A.

CEREBELLUM

VERTEBRAL A.

OCCIPITAL
LOBE

Mc23.11

ARTERIES OF THE BRAIN
INFERIOR VIEW

3

The Circle of Willis
ANTERIOR
COMMUNICATING A.
ANTERIOR
CEREBRAL A.

• at a branch point, blood flow
into each artery is determined
by their relative resistance

• vascular caliber can change
over time in response to
changes in vascular resistance

INTERNAL
CAROTID A.

POSTERIOR
CEREBRAL A.

Mc23.11

• blood does not “circle” in the
Circle of Willis

POSTERIOR
COMMUNICATING A.

• this may lead to clinically
significant changes in the flow
pattern of the Circle
4

Cerebral Vascular Territories

Medial surface

PCA
branches

If the cerebral hemispheres are considered
to have three surfaces (inferior, medial, &
superolateral) and three poles (occipital,
frontal and temporal), then their vascular
supply can be summarized as follows:

ACA and
branches
Basilar A
ACA branches

Vertebral A

Lateral surface

MCA
branches
Basilar A

Artery Surface

Pole

ACA

medial

frontal

MCA

superolateral

temporal

PCA

inferior

occipital

Think about the functional localization within
these vascular territories. Stroke in which
vascular territory would lead to:
PCA
branches
Vertebral A

• aphasia?
• paralysis of the contralateral leg?
• paralysis of the contralateral face and arm?

5

Vascular Supply of the Brainstem and Cerebellum
• the midbrain is supplied by the PCAs
• the pons is supplied by the BA
PCA

• the cerebellum is supplied by branches
of the vertebral and basilar As
• the medulla is supplied by the VAs and
their branches
• a stroke in which vascular territory
might lead to:

BASILAR A.
VERTEBRAL As

Mc23.11

–

strabismus, diplopia, enlarged pupil and
ptosis?

–

difficulty with speech and swallowing?

• the vertebral arteries give rise to the
unpaired anterior spinal artery and the
CEREBELLAR As
paired posterior spinal arteries…..
6

Blood Supply of
the Spinal Cord
POST. SPINAL As

Branches of the vertebral arteries form:
1. the single midline anterior spinal artery
located in the ventral median fissure
•

it supplies the ventral and lateral columns of
white matter and the ventral grey horns

•

What pathways would be affected by a stroke
in the anterior spinal artery territory?

2. the bilaterally paired posterior spinal arteries
located in the dorsolateral sulcus

ANT. SPINAL A

Mc16.T1

•

they supply the dorsal white columns and the
dorsal grey horns

•

What pathways would be affected by a stroke
in a posterior spinal artery?
7

Spinal Cord Blood Supply is Reinforced
• at cervical levels by branches of the vertebral As
• at thoracic levels by branches of the intercostal As
• at lumbar levels by branches of the lumbar As

B

These form:
A. radicular As which supply
the spinal nerve roots
B. anterior and posterior
segmental medullary As,
which feed into the
anterior and posterior
spinal As

A
GA4.47

8

Meninges & Intracranial Bleeds

A. Extradural hematoma
•

torn meningeal A. usually with
head trauma

•

blood btw periosteum & bone

GA7.13

B. Subdural hematoma
•

torn cerebral vein as it crosses
from subarachnoid space to
dural venous sinus

•

blood btw dura & arachnoid

C. Subarachnoid hemorrhage

A

B

•

ruptured cerebral A.

•

blood in subarachnoid space

C

9

Meninges & Intracranial Bleeds: CT
extradural hematoma
• lens-shaped
• respects suture lines

Case courtesy of Dr Sandeep Bhuta

subdural hematoma
subarachnoid hemorrhage
• crescent-shaped
• gyral enhancement
• does not respect suture lines

Case courtesy of Dr Andrew Dixon

Case courtesy of Prof Peter Mitchell

10

Aneurysm and Embolism
Aneurysm: dilation of vessel wall
•

cerebral aneurysms within skull

•

may compress adjacent structures (such as a cranial
nerve), causing mass effects

•

ruptured aneurysm 2nd most common cause of
subarachnoid hemorrhage

•

frequently located at branch points

Embolism: occlusion of A by material flowing in blood

Case courtesy of Dr Bruno Di Muzio

(clot, tumor cells, clump of bacteria, air, plaque fragments)
•

cerebral embolism within the skull

•

leads to infarction, ischemia, necrosis

•

deficits reflect location of infarct

•

thrombus: embolism composed exclusively of blood products

•

transient ischemic attack (TIA) result in no lasting deficit

•

ischemic stroke vs. hemorrhagic stroke
11

The Brainstem and Cranial Nerves

Images from Human Anatomy 6th ed., © 2009, by Martini,
Timmins and Talitsch, denoted by “Ma”.
Images from Human Anatomy, 2nd ed., © 2008 by McKinley &
O’Loughlin, denoted by “Mc”.

1

BRAINSTEM
CERVICAL
CORD

SENSORY
NUCLEI

MOTOR
NUCLEI

The Brainstem vs. the Spinal Cord
• in both, the grey matter is deep and the white matter is
superficial
• in both, the white matter consists of axons carrying
sensory information rostrally, and motor information
caudally
• while grey matter in the spinal cord is a continuous
column, grey matter in the brainstem is broken up into
a discontinuous series of functionally specialized nuclei
• both subserve somatic and autonomic functions
• unlike the spinal cord, the brainstem:

LUMBAR
CORD

– subserves “special senses”: hearing and balance
– contains a “reticular formation” responsible for the
maintenance of vital functions and one’s level of arousal

2

Brainstem: White Matter Tracts
Descending fibre tracts
• UMNs carrying voluntary output from the cerebral cortex to the spinal cord,
controlling the body; “corticospinal tract”
• UMNs carrying voluntary output from the cerebral cortex to the brainstem,
controlling the face; “corticobulbar tract”
• involuntary descending fibre tracts that modulate & coordinate:
– posture, muscle tone, balance (e.g. vestibulospinal tract)
– autonomic functions (e.g. from the hypothalamus)

Ascending fibre tracts
• from the spinal cord to the thalamus
– e.g. SS input destined for conscious appreciation in the cerebral cortex

• from the spinal cord to the cerebellum
– e.g. subconscious proprioceptive input from muscles and joints

Peduncles: white matter bundles
• paired cerebral peduncles join the midbrain & cerebral hemispheres
• 3 paired cerebellar peduncles join the brainstem & cerebellar hemispheres
3

The Brainstem in Context
Diencephalon

Midbrain

Pons
Brainstem
Medulla

Ma15.1

4

The Brainstem:
Ventral View

A
B
D

C

E
F
H
I
J
K
M
N
O

G

P
L
Q
Ma15.20

A. diencephalon (thalami and hypothalami)
B. optic nerves

C. Midbrain
D. cerebral peduncles
E. occulomotor nerves (CN III)
F. trochlear nerves (CN IV)

G. Pons
H.
I.
J.
K.

trigeminal nerves (CN V)
abducens nerves (CN VI)
facial nerves (CN VII)
vestibulocochlear nerves (CN VIII)

L. Medulla
M.
N.
O.
P.
Q.
R.

glossopharyngeal nerves (CN IX)
vagus nerves (CN X)
accessory nerves (CN XI)
pyramids
hypoglossal nerves (CN XII)
olives

5

The Cerebellum must
be Removed to view
the Dorsal Brainstem
FOURTH
VENTRICLE

A

C. The inferior cerebellar peduncles
connect the medulla and cerebellum

B
C

The cerebellum overlies the fourth
ventricle.

MEDULLA

CEREBELLUM
MIDSAGITTAL SECTION thru the CBLM,
cutting left cblr peduncles, brainstem intact

Ma15.19

A. The superior cerebellar peduncles
connect the midbrain and cerebellum
B. The middle cerebellar peduncles
connect the pons and cerebellum

MIDBRAIN

PONS

Three paired masses of white matter
connect the cerebellum and brainstem:

Once the peduncles are cut, one sees
the floor of the fourth ventricle on the
dorsal aspect of the brainstem.
6

The Brainstem:

A. thalami

Dorsal View

B. pineal gland
A
B

C. Midbrain
D. superior colliculus (vision)
E. inferior colliculus (hearing)

D
E

C

F. trochlear nerve (CN IV)
F

H. Pons

G
H

I

I.

middle cerebellar peduncle

L

J.

floor of IVth ventricle

J
O
K

K. Medulla
L. inferior cerebellar peduncles
M. posterior median sulcus

N
M

Ma15.16

G. superior cerebellar peduncle

N. gracile tubercle
O. cuneate tubercle

7

The Cerebellum

D

• connected to the brainstem by the
(A, B, C) superior, middle & inferior
cerebellar peduncles

E

MIDBRAIN

D. cortical grey matter

PONS

B

• two bilaterally paired cerebellar
hemispheres

E. subcortical white matter

A
C

F. cerebellar nuclei

Functions of the Cerebellum

MEDULLA

F
Sagittal section

Ma15.19

• control of posture, balance
• coordination of motor function

8

Inputs to the Cerebellum

Frontal lobe

Include:

• spinocerebellar proprioceptive info. re.
ipsilateral body position, muscle tone

Thalamus
Cerebellum

• vestibulo-cerebellar input re. position
and acceleration of the head in space

Midbrain
Pons
Medulla
CN VIII

Cervical
cord

Vestibular
apparatus

• contralateral corticopontocerebellar
afferents re. movement planning

9

Outputs from the Cerebellum

Frontal lobe

• motor, premotor ctx via
VA, VL thalamus
• motor cortex controls mvt
of contralateral body….

Thalamus
Cerebellum

• what an elegant system
for control of body
movement!

Midbrain
Pons
Medulla
CN VIII

Cervical
cord

Vestibular
apparatus

10

BRAINSTEM
CERVICAL
CORD

SENSORY
NUCLEI

MOTOR
NUCLEI

The Cranial Nerves & their Nuclei

• like the body, the head has both:
• sensory & motor components

• voluntary & involuntary (autonomic) components
SOMATIC (VOLUNTARY) MOTOR
VISCERAL (AUTONOMIC) MOTOR
SOMATIC SENSORY
VISCERAL SENSORY

• unlike the spinal cord, functional columns disperse
into a series of longitudinally arranged, distinct nuclei
• unlike spinal nerves, CNs may carry a single modality
• unlike the spinal cord, the brainstem and cranial
nerves subserve the “special” visceral sensation,
taste and the “special senses” of hearing and balance

LUMBAR
CORD

VISCERAL SENSORY INCLUDING TASTE
HEARING AND BALANCE

Note: for clarity, motor columns are shown on one side
and sensory columns are shown on the other.
11
Both, however, are bilateral.

Functional Approach to Learning Cranial Nerves
1. Cranial nerves that convey special senses
–
–
–

I (the olfactory N.)
II (the optic N.)
VIII (the vestibulocochlear N.)

2. Cranial nerves that control skeletal muscle
–
–
–
–
–

III (the oculomotor N.)*
IV (the trochlear N.)
VI (the abducens N.)
XI (the accessory N.)
XII (the hypoglossal N.)

3. Mixed cranial nerves
–
–
–
–

V (the trigeminal N.)
VII (the facial N.)
IX (the glossopharyngeal N.)
X (the vagus N.)
12

Cranial Nerves that Convey Special Senses
I the olfactory nerve (covered with the nose / respiratory system)
• conveys smell from the olfactory epithelium in the roof of the nasal cavity
• nerves enter cranium by passing through the cribriform plate of the ethmoid

II the optic nerve (covered with the eye)
• conveys visual input from the retina
• nerve enters cranium through optic foramen

VIII the vestibulocochlear nerve (covered with the ear)
• conveys auditory sensations from the cochlea via its cochlear division
• conveys balance information from the vestibular apparatus via its vestibular
division
• nerve enters cranium through the internal auditory (acoustic) foramen
13

Cranial Nerves that Control Skeletal Muscle I
III the oculomotor nerve*
IV the trochlear nerve

• exit cranium through superior orbital
fissure to enter orbit
• control extraocular eye muscles that
position the eye in the orbit
• nerve damage causes

VI the abducens nerve

• strabismus (misaligned eye) and
• diplopia (double vision)

* also controls the levator palpebrae superioris muscle
– paralysis causes ptosis (a droopy eyelid)

* also conveys parasympathetic preganglionic fibres destined for the eye
– nerve damage causes mydriasis (enlarged pupil)
14

Cranial Ns that Control
Skeletal Muscle II
Jugular
foramen
Foramen
magnum
Cervical
spinal cord
Accessory N.
(CN XI)
SCM

XI the accessory nerve
• emerges as a series of rootlets from the
lateral aspect of upper cervical segments
• coalesce to form the accessory N. which
enters the cranium through the foramen
magnum
• exits via jugular foramen with CN IX & X
• controls the sternocleidomastoid (SCM)
and trapezius muscles
• SCM turns the head to the opposite side
• trapezius elevates the shoulder
• nerve damage causes…….

XII the hypoglossal nerve
• exits the cranium via hypoglossal canal
Trapezius

• controls the shape and position of tongue
via its intrinsic and extrinsic muscles

McT15.8

• nerve damage causes…..

15

A

C

Mixed Cranial Nerves 1:
The Trigeminal Nerve

B

D

A. the trigeminal nerve
• conveys somatic sensation from the face

E

• consists of three divisions:
B. ophthalmic division via superior orbital
fissure (with which other three CNs?)
C. maxillary division via foramen rotundum

B

C
McT15.7

D

D. mandibular division via foramen ovale
E. the trigeminal ganglion contains the cell
bodies of these pseudounipolar 1°
somatic sensory neurons (like a DRG)
• mandibular division also voluntary motor
to the four muscles of mastication
16

Mixed Cranial Nerves 2:
The Facial N (CN VII)
pterygopalatine G.
greater petrosal N.
geniculate G.

•

exits cranium via internal auditory
(acoustic) foramen

1. voluntary motor fibres exit skull via
stylomastoid foramen to innervate
muscles of facial expression
2. special visceral sensory (taste) from
anterior 2/3 of tongue
– 1° sensory axons in chorda tympani,
cell bodies in geniculate ganglion

3. parasympathetic preganglionic via:

stylomastoid
foramen
chorda tympani
submandibular G.

– the chorda tympani to submandibular
ganglion: postganglionic fibres
distributed to the submandibular and
sublingual glands, oral mucosa below
oral fissure
– the greater petrosal nerve to the
pterygopalatine ganglion:
postganglionic fibres distributed to the
lacrimal gland, nasal mucosa, oral
mucosa above oral fissure

– Nerve damage causes Bell Palsy
17

Mixed Cranial Nerves 3:
The Glossopharnygeal N
Pons
(CN IX) Otic ganglion
Pharyngeal
branches

CN IX

Lingual branch
Medulla

Parotid
gland

•

exits the cranium via the jugular
foramen (other nerves?)

1. somatic sensory from post 1/3
of tongue, oropharynx
2. special visceral sensory (taste)
from post 1/3 of tongue
3. visceral sensory from carotid
body (chemoreceptors) and
carotid sinus (baroreceptors)
4. parasympathetic preganglionic
fibres to otic ganglion;
postganglionic fibres innervate
the parotid gland

Carotid
body

Ma15.28

Common
carotid A.

Carotid
sinus

5. voluntary motor to a single
pharyngeal muscle
18

Pharyngeal
branch

Mixed Cranial Nerves 4:
The Vagus N (CN X)
CN X

Laryngeal
nerves

Cardiac
branches
Cardiac
plexus

Right
lung

Left
lung

Liver

Celiac
Stomach plexus

Pancreas

Spleen

Colon
Small intestine

Ma15.29

• exits the cranium via the jugular foramen
1. voluntary motor to the pharynx and larynx
2. general sensory from laryngopharynx, larynx
3. visceral sensory from chemoreceptors in the
aortic body, baroreceptors in the aortic arch,
thoracic and abdominal viscera
4. parasympathetic preganglionic fibres to
intramural ganglia of thoracic and abdominal
viscera
19