Title: Chapters 9,10 Auditory and Vestibular Systems
1Chapters 9,10 Auditory and Vestibular Systems
- Chris Rorden
- University of South Carolina
- Norman J. Arnold School of Public Health
- Department of Communication Sciences and
Disorders - University of South Carolina
2Audition
- The ear converts sound energy into patterns of
neural firing transduction - Outer ear collect and amplify sound, aid in
localization - Middle ear impedance matching
- Cochlea frequency and intensity analysis
- Auditory pathway complex signal processing
3Ear structures
- Peripheral
- Outer ear
- Middle ear
- Inner ear
- Auditory nerve
- Central
- Brainstem
- Midbrain
- Cerebral
4Anatomy and function
- Pinna the projecting part of the ear lying
outside of the head (also called auricle, or just
ear lobe) - Reflection of sound in pinna provides spectral
cues about elevation of a sound source
5Outer Ear Auditory Canal
- External auditory meatus
- Provides communication between middle and inner
ears by conducting sound to the ear drum - S-shaped tube _at_ 2.5cm long and _at_ 7mm wide
- Lining of the lateral 1/3rd of canal has cilia
and glands - Cerumen (ear wax) protects ear canal from drying
out and prevents intrusion of insects
6Outer Ear - Ear drum
- Tympanic membrane
- Separates outer and middle ear
- Compliant
- Thin, three-layered sheet
- Epithelium of EAM outer layer
- Middle layer fibrous (strong) tissue
- Inner layer of middle ear mucous membrane
7Outer Ear - Ear drum
- Slightly concave to EAM, cone-shaped
- Most depressed and thinnest point is called the
umbo cone of light (_at_ 2 mm) - End of the attachment of malleus
- Slightly oval, taller than wide
- Otoscope if you pull the pinna up and back the
tympanic membrane is visible
8Middle Ear Tympanic Membrane
9Role of outer ear
- To augment the sound shadow
- Ear canal protects delicate parts of middle and
inner ear from impact. - To heighten our sensitivity to sounds
- Ear canal boosts sounds 15 to 16 dB between 1.5
and 8 kHz (in the area of speech) - This is due to resonance of ear canal
- Just like vocal tract this tube amplifies and
dampens certain frequencies based on its length
and composition
10Localization and shadowing
- Intensity differences louder if nearer, less
shaded - Inter-aural timing differences
- Frequencies influenced by location relative to
pinna.
11Middle Ear Eustachian Tube
- Establishes communication between middle ear and
nasopharynx - 35 to 38 mm long, typically closed
- Biological functions
- To permit middle ear pressure to equalize with
external air pressure - On the air plane, change in atmospheric pressure
but not pressure in middle ear - Yawning or swallowing opens pharyngeal orifice of
tube to equalize pressures - To permit drainage of normal and diseased middle
ear secretions into the nasopharynx
12Middle Ear - Ossicles
- 3 of the smallest bones
- Malleus (hammer)
- Incus (anvil)
- Stapes (stirrup)
- Ossicular chain Transmits acoustic energy from
tympanic membrane to inner ear - Acts as lever large weak motion of TM causes
small forceful movement of stapes. - Takes force from gas (air) and matches impedance
to liquid (inner ear). - Muscles allow movement to be attenuated Prevents
the inner ear from being overwhelmed by
excessively strong vibrations
13Middle Ear Ossicles
14Middle Ear Ossicles - Malleus
Malleus (hammer) 9 mm long Manubrium (handle)
attaches to tympanic membrane pulls the drum
medially Caput (head) jointed (quite inflexibly)
to Incus
15Middle Ear Ossicles - Incus
- The ossicles give the eardrum mechanical
advantage via lever action and a reduction in the
area of force distribution - Pressure Force/Area so less area more
pressure - the resulting vibrations would be much smaller if
the sound waves were transmitted directly from
the outer ear to the oval window. - The movements of the ossicles is controlled
muscles attached to them (the tensor tympani and
the stapedius).These muscles can dampen the
vibration of the ossicles, in order to protect
the inner ear from excessively loud noise and
that they give better frequency resolution at
higher frequencies by reducing the transmission
of low frequencies
16Middle Ear Ossicles - Stapes
Head (caput) jointed to incus Anterior and
posterior crura (legs) Footplate joins oval
window of inner ear (opening in temporal bone)
via annular ligament
17Cochlea and neighbors
18Inner Ear - Cochlear
19Osseous cochlea
- Oval window
- Connects scala vestibuli and middle ear
- Round window
- Connects scala tympani and middle ear
20Cochlear Structures
- Cochleus from 5mo fetus
- Oval window (blue arrow)
- Round window (yellow arrow)
21Tonotopic
22Travelling wave
- Always starts at the base of the cochlea and
moves toward the apex - Its amplitude changes as it traverses thelength
of the cochlea - The position along the basilar membrane atwhich
its amplitude is highest depends on the frequency
of the stimulus
23Traveling wave
- High frequencies have peak influence near base
and stapes - Low frequencies travel further, have peak near
apex - A short movie
- www.neurophys.wisc.edu/ychen/auditory/animation/a
nimationmain.html
- Green line shows 'envelope' of travelling wave
at this frequency most oscillation occurs 28mm
from stapes.
24Cochlear structure
- Cross-section shows the coiling of the cochlear
duct The red arrow is from the oval window, the
blue arrow points to the round window. - Scala media filled w Endolymph
- scala vestibuli filled w Perilymph
- scala tympani filled w Perilymph
- spiral ganglion
- nerve fibres
- www.iurc.montp.inserm.fr/cric/audition/english/coc
hlea/fcochlea.htm
25Inner Ear - Labyrinth
Endolymph K 100 mV Perilymph Na 20mV
Reissners Membrane Basilar Membrane
26Inner Ear Organ of Corti
27Inner Ear OHC IHC
- Inner Hair Cells
- Non-motile
- Outer Hair Cells
- Vibrates when triggered acts as preamplifier.
28Neural connections
- Inner hair cells many nerve fibers for each cell
(many-to-one innervation) - Outer hair cells each nerve fiber connected to
many hair cells (one-to-many innervation).
29Function of the cochlea
- First stage of auditory processing
- 1. Spectral analysis
- Extracts frequency and amplitude information from
sound waves - 2. Temporal analysis
- Basic temporal characteristics of sounds
30- The ear codes frequency in two ways
- Position of neural responses along basilar
membrane changes with frequency - tonotopic
organization or the place coding - Timing of neural responses follows the time
waveform of sound phase-locking
31Place coding
- Place coding Auditory frequency coded by
location of stimulation.
32Phase locking
- The rate of neural firing matches the sound's
frequency. - Problem some auditory frequencies much faster
than neurons can fire - Each neuron can only fire around 200 times per
sec. - Solution volley principle large numbers of
neurons that are phased locked can code high
frequencies.
33Afferent and efferent innervation
- Afferent signals from sense organ to brain
- Auditory signals
- Efferent signals from brain to sense organ
- Inhibits auditory signals
- Both cochlear and ossicles
- Improves signal-to-noise ratio by suppressing
noise
34Primary auditory cortex
Medial geniculate Body (thalamus)
Inferior colliculus (in midbrain)
Auditory radiation
Cochlear and Superior olivary Complex in the
Medulla
35Central Auditory Mechanism
- Auditory input projects to the cortex
bilaterally, with stronger contralateral
connections. - The superior olive and the inferior colliculus
send efferent fibers back to attenuate motion of
the middle ear bones (dampen loud sounds)
36- Cochlear Nucleus
- At least 6 different neural responses
- Evidence of signal processing (monaural)
- Superior Olivary Complex (SOC)
- Binaural processing
- Localization of sound source
- Low frequency sounds arrival time compared
- High frequency sounds intensity level compared
37Auditory Pathway
- Lateral Lemniscus
- Fiber tract within CNS
- From SOC to IC
- Inferior Colliculus (IC)
- Bilateral innervation
- Frequency, intensity and temporal processing
- Medial Geniculate Body (MGB)
- Tonotopic mapping
- Complex responses to contralateral signals
38Cerebral cortex
- Signal comes primarily from contralateral ear via
ipsilateral MGB - Heschls gyrus
- Tonotopic mapping in columns
- Each column has one characteristic frequency
- Neurons in column responsive to different
stimulus parameters, like frequency and intensity
39Anatomy and function
- Many sound features are encoded before the signal
reaches the cortex -
- Cochlear nucleus segregates sound
information - Signals from each ear converge on
the superior olivary complex - important for
sound localization - Inferior colliculus is
sensitive to location, absolute intensity, rates
of intensity change, frequency - important for
pattern categorization - Descending cortical
influences modify the input from the medial
geniculate nucleus - important as an adaptive
filter
cortex
medial geniculate body
inferior colliculus
cochlear nucleus complex
cochlea
superior olivary complex
40Clinical Notes
- Conductive
- Cerumen in canal, Otitis Media of Middle Ear (ear
infection) - Sensorineural
- Menieres disease (abnormality in the fluids of
the inner ear vertigo), Presbycusis (age
related hearing loss) - Central
- Pathology in cortex
- Bilateral auditory cortex lesions result in
- Profound loss of auditory discriminative skills
- Impaired speech perception
- Hearing loss