Ear Anatomy

What are hearing receptors?

cilia, hair-like structures on hair cells

Place Theory

"Different pitches stimulate different PLACES on basilar membrane" (due to difference in hair length between base and )

base = short/stiff hair cells = resonate with high frequencies
end = long/loose hair cells = resonate with low frequencies

What are hearing receptors?

cilia, hair-like structures on hair cells

Place Theory

"Different pitches stimulate different PLACES on basilar membrane" (due to difference in hair length between base and )

base = short/stiff hair cells = resonate with high frequencies
end = long/loose hair cells = resonate with low frequencies

Frequency Theory

"At low pitches, neurons fire at the same rate as the sound's frequency"
ex. 75 Hz sound triggers neurons to fire 75 times per second

"At intermediate pitches (like human voices), GROUPS of neurons fire at the same rate as sound's frequency"
ex. 5,000 Hz sound triggers groups of 5 neurons to fire in rapid succession

Ossicles

Group of 3 bones in middle ear that amplify sound waves

Pinna

ear lobe

• focuses sound waves down ear canal

Cilia

• hair-like receptor cell
• when hair cells triggered on the organ of corti, it opens up mechanically gated sodium channels (generating a graded potential that could lead to an action potential)

Timpone Membrane

eardrum

• membrane between outer and middle ear

Basilar Membrane

• forms the base of the organ of Corti.

• Movement of the in response to sound waves causes the depolarization of hair cells in the organ of Corti.

• The hair cells transduce auditory signals into electrical impulses

• diff. sections of the ____ respond to diff. frequencies of sound: high tones vibrate the region near the base, low tones vibrate the region near the apex

Oval Window

a membrane covering the entrance to the cochlea in the inner ear

is connected to stirrup

Cochlea

spiral cavity of the inner ear filled with fluid

Volley Principle

the principle that individual fibers in an auditory nerve respond to one or another stimulus in a rapid succession of rhythmic sound stimuli, whereas other fibers in the nerve respond to the second, third, or nth stimulus. The result is that successive volleys of impulses are fired to match the inputs of stimuli, yet no single fiber is required to respond to every stimulus. Thus, a nerve can reflect a more rapid frequency of stimulation (e.g., 1000 Hz) than any individual fiber could follow

• this fixes the rebuttle of frequency theory where it is impossible to explain perception of sounds above 500 Hz since neuron's refractory period renders neruon incapable of firing above 500 impulses per second

Organ of Corti

the receptor organ of the ear

• in the cochlea
• produces nerve impulses in response to sound vibrations
• contains receptor (hair) cells

Auditory Canal

passageway that leads from the outside of the head to the tympanic membrane, or eardrum membrane, of each ear

Auditory Nerve

intertwined axons of hair cells

• electrical impulses travel from organ of corti along (this nerve)__ .

Conduction Deafness

type of hearing loss that happens when sounds cannot get through the outer and middle ear (because they're damaged)

• hearing loss can be reduced with hearing aids that amplify sound waves

Perceptive Deafness

type of deafness that results from nerve damage in inner ear

• can be reduced by cochlear implants

Sound Localization

a listener's ability to identify the location or origin of a detected sound in direction and distance

Outer Ear

= collect sound waves

• ear lobe “pinna” funnels sound waves down the auditory canal

Middle Ear

= amplify sound waves

• defined by membranes on both sides
• ossicles: are all attached and get smaller, so the mechanical wave vibrations are amplified as they become more concentrated
• same frequency, but amplified amplitude (volume)

Inner Ear

= transduce sound waves

• cochlea
• basilar membrane
• cilia