Lecture 10 Physiology of Hearing PDF

Summary

This lecture provides an overview of the physiology of hearing and the vestibular apparatus. It details the ear's structure, the processes of hearing transduction, and the role of different anatomical components like the cochlea and semicircular canals in maintaining balance. This includes the role of the middle ear ossicles in amplifying sound and the mechanics of hair cell stimulation in transducing sound into electrical signals.

Full Transcript

Functions of the Ear
The ears have two functions:
1. Hearing: Detection of sound
by the cochlea.

2. Equilibrium: maintain body
balance by the vestibule &
semicircular canals
 Parts of the Ear
The ear is composed of three main regions:
External ear (Outer ear)
Middle ear: Both the outer and the middle ear transmit sound waves to inner ear,
amplifying sound energy
Inner ear
Consists of 2 sensory systems:
I. Cochlea
II. Vestibular apparatus
The External Ear
Plays a role in Sound localization
Amplifies sound (approx. by 5-6 dB)
Pinna: collects sound waves and channels them
down the ear canal
Ceruminous (wax) glands produce ear wax (traps
foreign particles, preventing them from entering
the ear)
Ends at the tympanic membrane (eardrum): It
vibrates when sound waves hit it and transmits the
sound waves to the middle ear.
The Middle Ear
It contains three Ossicles (smallest bones)
– Malleus (hammer)
– Incus (anvil)
– Stapes (stirrup) attached to the oval window

Bones are connected to each other and transmit sound
waves from the tympanic membrane to inner ear
Amplify sound waves to 22 times
The auditory tube (Eustachian tube) connecting the
middle ear with the throat (nasopharynx): helps equalize
air pressure on both sides of the tympanic membrane
during yawning or swallowing.
The auditory tube
 The Middle Ear Con..
Muscles of the Middle Ear
Two muscles in the middle ear:
I. Tensor tympani:
Contraction of this muscle is a reflex triggered by the loud sounds, pulling the
tympanic membrane inwards, restricting its freedom of movement
Protects ear from loud noise or trauma

II. Stapedius: Smallest muscle in the body
Its contractions are part of a reflex initiated by
loud sounds
Contraction pulls the stapes posteriorly,
tilting its footplate
Dampening the ossicular chain vibration and
limiting the potential damage caused by the
loud noise
 The Inner Ear
Most complex portion of the ear
A maze of bony chambers within the temporal bone
It is separated from the middle ear by a membrane called the oval window
Includes sense organs for hearing and balance
Consists of three parts.
1. Semicircular canals –for balance Anterior
2. Vestibule – for balance
3. Cochlea – for hearing Semicircular Posterior Facial
canals nerve
Lateral Vestibular
nerve Cochlear
nerve

Cochlea
Vestibule
 1. Hearing (Audition)
Hearing is the transduction of sound waves into a electrical
signals.

Spiral organ of Corti is housed within the cochlear duct
and contains hair cells (hearing receptors)

Hair cells convert sound waves into nerve impulses which
are transmitted via the auditory nerves to the brain for
perception and interpretation as sound.

The cochlea encodes auditory stimuli for frequencies
between 20 and 20,000 Hz, which is the range of sound
that human ears can detect.
 Mechanism of Hearing
Sound waves in the ear canal strike the tympanic membrane (eardrum) and become
vibrations.

The sound wave energy is transferred to the three bones of the middle ear (malleus,
incus & staples), which vibrate.

Vibrations of the staples against the oval window are converted into fluid waves
within the vestibular duct.

Fluid waves push on the membranes of the
cochlear duct, thereby activating the sensory
hair cell receptors.

Fluid waves energy transfers across the
cochlear duct and into the tympanic duct
(scala tympani) and dissipated at the round
window.
Activating the sensory hair cell receptors
The inner hair cells are the cells that “hear”

Hair cells are mechanoreceptors sandwiched between
the basilar membrane and the gel-like tectorial
membrane

Vibrations in the basilar membrane causes the
receptor cells to become stimulated as their hairs
(stereocilia) are bent by movement of the gel-like
tectorial membrane

Transform the mechanical forces of sound (cochlear
fluid vibration) into the electrical impulses of hearing
(action potentials)
 Mechanism of Hearing Con…

The stereocilia of each hair cell are organized into graded heights
The tips of stereocilia are linked to the adjacent stereocilia by Tip
links
Upward movement of basilar membrane bends the bundle of
stereocilia toward the tallest stereocilia, stretching the tip links
Stretched tip links open the cation channels to which they are
attached
Endolymph has a higher concentration of K+ therefore entry of
K+ inside the cell causes Depolarization (receptor potential)

This in turn opens voltage gated Ca2+ channels and causes
neurotransmitter release at the basal end of the hair cell,
eliciting an action potential in the Cochlear nerve
 Mechanism of Hearing Cont…

Movement of basilar membrane in opposite direction bends the
hair bundle away from the tallest stereocilium loosening the tip
links – closing all channels causing Hyperpolarization

Hair cells do not undergo action potentials

Action potential in the Cochlear nerve propagates to the auditory
cortex for sound perception through vestibulocochlear nerve
 Auditory pathway

Schematic diagram of auditory pathway
 Auditory pathway
The nerve impulse traveling along the vestibulocochlear nerve synapses with neurons in the
cochlear nuclei of the medulla. The cochlear nuclei receives information only from one side of the
body (ipsilateral)
From the cochlear nucleus, some fibres synapse at the ipsilateral superior olivary nuclei, however,
most fibers decussate to the contralateral superior olivary nuclei (information from both ears
travels bilaterally). Hence, supranuclear lesion in one side (i.e. above the level of the cochlear
nucleus) do not lead to major hearing impairment.
The superior olivary nucleus begins the process of interpreting and combing input from the
cochlear nucleus (for example sound localization through estimating time difference and intensity
between each ear)
Fibers from superior olivary nuclei projects upwards through the lateral lemniscus to reach the
inferior colliculus nucleus, where all fibres carrying auditory information converge.
Axons carrying the auditory information from the inferior colliculus project to the medial
geniculate nucleus of the thalamus which then projects that information to the auditory cortex in
the temporal lobe of the cerebral where they are interpreted as hearing.
2. Physiology of Balance: Vestibular Apparatus
The vestibular apparatus consists of two structures of the bony labyrinth of the inner
ear and the structures of the membranous labyrinth contained within them:

I. The vestibule which responsible for
monitoring static equilibrium (linear
acceleration)
II. The semicircular canals which responsible
for monitoring the dynamic equilibrium
(angular acceleration)
 Vestibule: Utricle and Saccule
Static equilibrium: changes in position of the head in space with respect to the pull of gravity
when the body is not moving (static) for example forward or backward tilting of the head or
riding elevator

Maculae (static equilibrium receptors) are located within the membranous sacs of the
Vestibule (utricle and saccule).

Each macula is a patch of hair cells with stereocilia embedded in the otolithic membrane (a
viscous gel contains calcium crystals called otoliths [otoconia]). Hence, utricle and saccule are
sometimes called the otolithic organs.

While tilting the head, otoliths roll in response to the pull of gravity creating a pull on the
otolithic membrane and bending of macula hair cells.

The hair cells become activated and send impulses along the vestibulocochlear nerve to the
brain stem and cerebellum informing it of the head position in space.
Static Equilibrium
 Semicircular ducts
Provide the sense of dynamic equilibrium in which there is angular or rotatory movements of
the head.
The semicircular ducts are three ring-like extensions of the vestibule. One is oriented in the
horizontal plane, whereas the other two are oriented in the vertical plane.
The base of each semicircular ducts connects to an swollen regions known as the ampulla. The
ampulla contain the crista ampullaris which are the receptors for dynamic equilibrium.
The crista ampullaris is a cone-shaped structure covered in hair cells that are impeded in a gel-
like structure called the cupula.
Upon head rotation, the fluid (endolymph) within the semicircular duct lags and deflects the
cupula against the hair cells of the crista ampullaris.
The hair cells thus respond by stimulating the vestibulocochlear nerve to report of the head
movements within three-dimensional space.
Dynamic Equilibrium and
Crista Ampullaris
Summary of the Structures of Internal Ear

Bony Labyrinth Membranous Labyrinth Function Receptor region
Semicircular Semicircular ducts Equilibrium: rotational Crista ampullaris
canals (angular) acceleration

Vestibule Utricle and saccule Equilibrium: head position Macula
relative to gravity, linear
acceleration

Cochlea Cochlear duct Hearing Spiral organ
(scala media) (organ of Corti)