Frequency selectivity Sensorineural hearing loss
figure 4: neural tuning curve normal hearing.
the traveling wave along basilar membrane peaks @ different places along it, depending on whether sound low or high frequency. due mass , stiffness of basilar membrane, low frequency waves peak in apex, while high frequency sounds peak in basal end of cochlea. therefore, each position along basilar membrane finely tuned particular frequency. these tuned frequencies referred characteristic frequencies (cf).
if sound entering ear displaced characteristic frequency, strength of response basilar membrane progressively lessen. fine tuning of basilar membrane created input of 2 separate mechanisms. first mechanism being linear passive mechanism, dependent on mechanical structure of basilar membrane , surrounding structures. second mechanism non-linear active mechanism, dependent on functioning of ohcs, , general physiological condition of cochlea itself. base , apex of basilar membrane differ in stiffness , width, cause basilar membrane respond varying frequencies differently along length. base of basilar membrane narrow , stiff, resulting in responding best high frequency sounds. apex of basilar membrane wider , less stiff in comparison base, causing respond best low frequencies.
this selectivity frequencies can illustrated neural tuning curves. these demonstrate frequencies fiber responds to, showing threshold levels (db spl) of auditory nerve fibers function of different frequencies. demonstrates auditory nerve fibers respond best, , hence have better thresholds @ fiber s characteristic frequency , frequencies surrounding it. basilar membrane said ‘sharply tuned’ due sharp ‘v’ shaped curve, ‘tip’ centered @ auditory fibers characteristic frequency. shape shows how few frequencies fiber responds to. if broader ‘v’ shape, responding more frequencies (see figure 4).
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