hearing Flashcards
Properties of sound
- Pressure disturbance (alternating areas of high/low pressure) produced by vibrating object
- Sound wave –> moves outward in all directions in sine wave
Properties of sound waves
Frequeny = # of waves/time –> pure tones have repeating crests and troughs
wavelength = distance bt waves –> shorter wavelength = higher frequency
pitch = percieved frequency–> normal range = 20-20000 Hz –> higher frequency=higher pitch
quality = rechness and complexity of sounds (music)
amplitude = height of crests –> percieved as loudness –> normal range is 0-120 dB –> hearing loss with prolonged exposure above 90 dB –> rock concerts over 120 dB
Transmission of sound to internal ear
- sound wave vibrates tympanic membrane
- ossicles vibrate and amplify pressure at oval window
- cochlear fluid set into wave motion
- pressure waves move thru perilymph of scala vestibuli
- waves go thru cochlear duct, vibrating basilar membrane at specific location according to frequency
(waves with frequencies below threshold travel thru helicotrema and scali tympani to round window)
Resonance of basilar membrane
- fibers near oval window are short and stiff –> resonate with high frequency pressure waves
- fibers near cochlear apex are longer and floppier –> resonate with lower frequency pressure waves
- mechanically processes sound before signals reach receptors
cells of spiral organ
cells of spiral organ
- supporting cells
- cochlear hair cells (one row of inner hair cells; three rows of outer hair cells –> have many stereocilia and one kinocilum)
- afferent fibers of cochlear nerce coil around bases of hair cells
Function of hair cells is to convert mechanical stimulus (bending) into electrical signal (transduction)
Excitation of hair cells in spiral organ
When basilar membrane vibrates
-hair cells move
- bending of tereocilia against tectorial membrane –> towards longest stereocilia –> opens cation K channels –> influx (from endolymph)–> depolarization (elec gradient, not chem) –> voltage gated Ca channels open –> more depolarization –> increased release of glutamate
- bending of stereocilia away from longest stereocilia –> closes K channels –> hyperpolarization
Auditory Pathway
- NT release excites sensory neurons at base of hair cells
- axons of sensory neurons form cochlear branch of vestibulocochlear nerve
Nerve VIII goes to
- cochlear nuclei of medulla
- midbrain (inferior colliculi) –> auditory reflex
- cerebellum = motor response to sound
- back to cochlea to inhibit weaker signaling area
- back to mid ear muscles (sound attenuation reflex)
- medial geniculate nucleus of thalamus
Auditory cortex in each hemisphere recieves input from both ears, but not all sensory signals cross over to other side –> partial decussation
auditory processing
- pitch
- loudness
- location
- pitch percieved by impulses from special hair cess in dif positions along basilar membrane
- loudness detected by increased number of APs that result when hair cells experience larger deflections
- localization of sound depends on relative intensity and relative timing of sound waves reaching both ears
Homeostatic imbalances of hearing
Conduction deafness
- blocked sound conduction to fluids of internal ear
- impacted earwax, perforated eardrum, otis media, ostosclerosis of ossicles
Sensorineural deafness
- damage to neural structures at any point from cochlear hair cells to auditory cortical cells
- usually from gradual hair cell loss –> lose high frequency ones first