272 Chapter 14
cochlea Coiled structure in
the inner ear that contains
the organ of hearing (organ
of Corti).
hair cells Mechanorecep-
tors that are the sensory
receptors for sound.
organ of Corti Organ in the
ear where sensory hair cells
are located.
tectorial membrane
Jellylike structure that bend-
ing hair cells press against
in response to pressure
waves in the cochlear fluid.
tympanic membrane
The eardrum.
Hearing: Detecting sound Waves
n The sense of hearing depends on structures in the ear that
trap and process sounds traveling through air.
Sounds are waves of compressed air. They are a form of
mechanical energy. If you clap your hands, you force out
air molecules, creating a low-pressure state in the area they
vacated. The pressure variations can be depicted as a wave
form, and the amplitude of its peaks corresponds to loud-
ness. The frequency of a sound is the number of wave cycles
per second. Each cycle extends from
the start of one wave to the start of
the next (Figure 14.8).
The sense of hearing starts with
vibration-sensitive mechanorecep-
tors deep in the ear. When sound
waves travel down the ear’s audi-
tory canal, they reach a membrane
and make it vibrate. The vibrations
cause a fluid inside the ear to move,
the way water in a waterbed sloshes.
In your ear, the moving fluid bends
the tips of hairs on mechanore-
ceptors. With enough bending, the
result will be action potentials sent
to the brain, where they are inter-
preted as sound.
The ear gathers “sound signals”
A human ear has three regions (Figure 14.9A), each with its
own role in hearing. The outer ear is a pathway for sound
waves to enter the ear, setting up vibrations. The vibrations
are amplified in the middle ear. The inner ear contains the
coiled cochlea (kahk-lee-uh; Figure 14.9B), where vibra-
tions of different sound frequencies are sorted out as they
stimulate different patches of receptors. The inner ear also
contains semicircular canals, which are involved in balance
(Section 14.6).
Sensory hair cells are the key to hearing
Hearing begins when the outer ear’s fleshy flaps collect and
channel sound waves through the auditory canal to the
tympanic membrane (the eardrum). Sound waves cause
the membrane to vibrate, which in turn causes vibrations in a
leverlike array of three tiny bones of the middle ear: the mal-
leus (“ham mer”), incus (“anvil”), and stirrup-shaped stapes.
The vibrating bones transmit their motion to the oval window,
an elastic membrane over the entrance to the cochlea. The
oval window is much smaller than the tympanic membrane.
So, as the middle-ear bones vibrate against its small surface
with the full energy that struck the tympanic membrane, the
force of the original vibrations is amplified.
Now the action shifts to the cochlea. If we could uncoil
the cochlea, we would see that a fluid-filled chamber folds
around an inner cochlear duct (Figure 14.9C). Each “arm” of
the outer chamber functions as a separate compartment (the
scala vestibuli and scala tympani, respectively; Figure 14.9D).
The amplified vibrations of the oval window create pres-
sure waves in the fluid within the chambers. These waves
are transmitted to the fluid in the cochlear duct. On the
floor of the cochlear duct is a basilar membrane, and resting
Figure 14.8 Sound travels in the form of a wave. (© Cengage Learning) on the basilar membrane is a specialized organ of Corti,
Low
note
High
note
Same loudness,
different pitch
Soft
Loud
Same frequency,
different amplitude
Amplitude
Frequency per
unit of time
one cycle
Middle ear bones:
stirrup
anvil
hammer
Eardrum
auditory
canal Cochlea
auditory nerve
round
window
oval window
(behind stirrup)
Middle ear
eardrum,
ear bones
vestibular
apparatus,
cochlea
Outer ear
pinna,
auditory
canal
A
B
Inner ear
Figure 14.9 Animated! The ear gathers sound waves and
converts them to nerve impulses. (© Cengage Learning)
Fabian Cevallos/Sygma/Corbis
14.5
Low
note
High
note
Same loudness,
different pitch
Soft
Loud
Same frequency,
different amplitude
Amplitude
Frequency per
unit of time
one cycle
Low
note
High
note
Same loudness,
different pitch
Soft
Loud
Same frequency,
different amplitude
Amplitude
Frequency per
unit of time
one cycle
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