Specification of absorbed-sound power in the ear canal: Application to suppression of stimulus frequency otoacoustic emissions

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The greatest difference in distortion product otoacoustic emission (DPOAE) suppression tuning curves (STCs) in infant and adult ears occurs at a stimulus frequency of 6 kHz. These infant and adult STCs are much more similar when constructed using the absorbed power level of the stimulus and suppressor tones rather than using sound pressure level. This procedure incorporates age-related differences in forward and reverse transmission of sound power through the ear canal and middle ear. These results support the theory that the cochlear mechanics underlying DPOAE suppression are substantially mature in full-term infants.

supporting

confidence: 56%

mentioning

confidence: 99%

mentioning

confidence: 99%

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Distortion-product otoacoustic-emission suppression tuning in human infants and adults using absorbed sound power

Keefe

Abdala

2011

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“…Recently, Keefe and Schairer (2011) proposed specifying in situ sound level of the stimulus in terms of absorbed power. Similar to FPL calibration, absorbed power eliminates the influence of longitudinal standing waves and can be determined noninvasively.…”

Section: Pressure Vs Power Calibrationmentioning

confidence: 99%

Further assessment of forward pressure level for in situ calibration

Scheperle

Goodman

Neely

2011

Quantifying ear-canal sound level in forward pressure has been suggested as a more accurate and practical alternative to sound pressure level (SPL) calibrations used in clinical settings. The mathematical isolation of forward (and reverse) pressure requires defining the Thévenin-equivalent impedance and pressure of the sound source and characteristic impedance of the load; however, the extent to which inaccuracies in characterizing the source and/or load impact forward pressure level (FPL) calibrations has not been specifically evaluated. This study examined how commercially available probe tips and estimates of characteristic impedance impact the calculation of forward and reverse pressure in a number of test cavities with dimensions chosen to reflect human ear-canal dimensions. Results demonstrate that FPL calibration, which has already been shown to be more accurate than in situ SPL calibration, can be improved particularly around standing-wave null frequencies by refining estimates of characteristic impedance. Better estimates allow FPL to be accurately calculated at least through 10 kHz using a variety of probe tips in test cavities of different sizes, suggesting that FPL calibration can be performed in ear canals of all sizes. Additionally, FPL calibration appears a reasonable option when quantifying the levels of extended high-frequency (10-18 kHz) stimuli.

“…Two-tone suppression of SFOAEs indirectly estimated the cochlear gain in terms of the tip-to-tail of a SFOAE pressure suppression tuning curve (Keefe et al, 2008). Combining these SFOAE pressure data with earcanal reflectance measurements, the cochlear gain estimated from the tip-to-tail power level difference of SFOAE suppression increased with increasing frequency between 1 and 8 kHz (Keefe and Schairer, 2011). Such a cochlear mechanism based on nonlinearities in outer-hair-cell function would increase the intra-cochlear pressure levels generated at higher frequencies at sound levels close to threshold in the ear canal.…”

mentioning

confidence: 99%

Human middle-ear model with compound eardrum and airway branching in mastoid air cells

Keefe

2015

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An acoustical/mechanical model of normal adult human middle-ear function is described for forward and reverse transmission. The eardrum model included one component bound along the manubrium and another bound by the tympanic cleft. Eardrum components were coupled by a time-delayed impedance. The acoustics of the middle-ear cleft was represented by an acoustical transmission-line model for the tympanic cavity, aditus, antrum, and mastoid air cell system with variable amounts of excess viscothermal loss. Model parameters were fitted to published measurements of energy reflectance (0.25-13 kHz), equivalent input impedance at the eardrum (0.25-11 kHz), temporal-bone pressure in scala vestibuli and scala tympani (0.1-11 kHz), and reverse middle-ear impedance (0.25-8 kHz). Inner-ear fluid motion included cochlear and physiological third-window pathways. The two-component eardrum with time delay helped fit intracochlear pressure responses. A multi-modal representation of the eardrum and high-frequency modeling of the middle-ear cleft helped fit ear-canal responses. Input reactance at the eardrum was small at high frequencies due to multiple modal resonances. The model predicted the middle-ear efficiency between ear canal and cochlea, and the cochlear pressures at threshold.