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Air-Leak Effects on Ear-Canal Acoustic Absorbance

OBJECTIVE: Accurate ear-canal acoustic measurements, such as wideband acoustic admittance, absorbance, and otoacoustic emissions, require that the measurement probe be tightly sealed in the ear canal. Air leaks can compromise the validity of the measurements, interfere with calibrations, and increas...

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Autores principales: Groon, Katherine A., Rasetshwane, Daniel M., Kopun, Judy G., Gorga, Michael P., Neely, Stephen T.
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Williams And Wilkins 2015
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4272628/
https://www.ncbi.nlm.nih.gov/pubmed/25170779
http://dx.doi.org/10.1097/AUD.0000000000000077
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author Groon, Katherine A.
Rasetshwane, Daniel M.
Kopun, Judy G.
Gorga, Michael P.
Neely, Stephen T.
author_facet Groon, Katherine A.
Rasetshwane, Daniel M.
Kopun, Judy G.
Gorga, Michael P.
Neely, Stephen T.
author_sort Groon, Katherine A.
collection PubMed
description OBJECTIVE: Accurate ear-canal acoustic measurements, such as wideband acoustic admittance, absorbance, and otoacoustic emissions, require that the measurement probe be tightly sealed in the ear canal. Air leaks can compromise the validity of the measurements, interfere with calibrations, and increase variability. There are no established procedures for determining the presence of air leaks or criteria for what size leak would affect the accuracy of ear-canal acoustic measurements. The purpose of this study was to determine ways to quantify the effects of air leaks and to develop objective criteria to detect their presence. DESIGN: Air leaks were simulated by modifying the foam tips that are used with the measurement probe through insertion of thin plastic tubing. To analyze the effect of air leaks, acoustic measurements were taken with both modified and unmodified foam tips in brass-tube cavities and human ear canals. Measurements were initially made in cavities to determine the range of critical leaks. Subsequently, data were collected in ears of 21 adults with normal hearing and normal middle-ear function. Four acoustic metrics were used for predicting the presence of air leaks and for quantifying these leaks: (1) low-frequency admittance phase (averaged over 0.1–0.2 kHz), (2) low-frequency absorbance, (3) the ratio of compliance volume to physical volume (CV/PV), and (4) the air-leak resonance frequency. The outcome variable in this analysis was the absorbance change (Δabsorbance), which was calculated in eight frequency bands. RESULTS: The trends were similar for both the brass cavities and the ear canals. ΔAbsorbance generally increased with air-leak size and was largest for the lower frequency bands (0.1–0.2 and 0.2–0.5 kHz). Air-leak effects were observed in frequencies up to 10 kHz, but their effects above 1 kHz were unpredictable. These high-frequency air leaks were larger in brass cavities than in ear canals. Each of the four predictor variables exhibited consistent dependence on air-leak size. Low-frequency admittance phase and CV/PV decreased, while low-frequency absorbance and the air-leak resonance frequency increased. CONCLUSION: The effect of air leaks can be significant when their equivalent diameter exceeds 0.01 in. The observed effects were greatest at low frequencies where air leaks caused absorbance to increase. Recommended criteria for detecting air leaks include the following: when the frequency range of interest extends as low as 0.1 kHz, low-frequency absorbance should be ≤0.20 and low-frequency admittance phase ≥61 degrees. For frequency ranges as low as 0.2 kHz, low-frequency absorbance should be ≤0.29 and low-frequency admittance phase ≥44 degrees.
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spelling pubmed-42726282015-01-06 Air-Leak Effects on Ear-Canal Acoustic Absorbance Groon, Katherine A. Rasetshwane, Daniel M. Kopun, Judy G. Gorga, Michael P. Neely, Stephen T. Ear Hear Research Articles OBJECTIVE: Accurate ear-canal acoustic measurements, such as wideband acoustic admittance, absorbance, and otoacoustic emissions, require that the measurement probe be tightly sealed in the ear canal. Air leaks can compromise the validity of the measurements, interfere with calibrations, and increase variability. There are no established procedures for determining the presence of air leaks or criteria for what size leak would affect the accuracy of ear-canal acoustic measurements. The purpose of this study was to determine ways to quantify the effects of air leaks and to develop objective criteria to detect their presence. DESIGN: Air leaks were simulated by modifying the foam tips that are used with the measurement probe through insertion of thin plastic tubing. To analyze the effect of air leaks, acoustic measurements were taken with both modified and unmodified foam tips in brass-tube cavities and human ear canals. Measurements were initially made in cavities to determine the range of critical leaks. Subsequently, data were collected in ears of 21 adults with normal hearing and normal middle-ear function. Four acoustic metrics were used for predicting the presence of air leaks and for quantifying these leaks: (1) low-frequency admittance phase (averaged over 0.1–0.2 kHz), (2) low-frequency absorbance, (3) the ratio of compliance volume to physical volume (CV/PV), and (4) the air-leak resonance frequency. The outcome variable in this analysis was the absorbance change (Δabsorbance), which was calculated in eight frequency bands. RESULTS: The trends were similar for both the brass cavities and the ear canals. ΔAbsorbance generally increased with air-leak size and was largest for the lower frequency bands (0.1–0.2 and 0.2–0.5 kHz). Air-leak effects were observed in frequencies up to 10 kHz, but their effects above 1 kHz were unpredictable. These high-frequency air leaks were larger in brass cavities than in ear canals. Each of the four predictor variables exhibited consistent dependence on air-leak size. Low-frequency admittance phase and CV/PV decreased, while low-frequency absorbance and the air-leak resonance frequency increased. CONCLUSION: The effect of air leaks can be significant when their equivalent diameter exceeds 0.01 in. The observed effects were greatest at low frequencies where air leaks caused absorbance to increase. Recommended criteria for detecting air leaks include the following: when the frequency range of interest extends as low as 0.1 kHz, low-frequency absorbance should be ≤0.20 and low-frequency admittance phase ≥61 degrees. For frequency ranges as low as 0.2 kHz, low-frequency absorbance should be ≤0.29 and low-frequency admittance phase ≥44 degrees. Williams And Wilkins 2015-01 2014-12-23 /pmc/articles/PMC4272628/ /pubmed/25170779 http://dx.doi.org/10.1097/AUD.0000000000000077 Text en Copyright © 2015 Wolters Kluwer Health, Inc. All rights reserved This is an open-access article distributed under the terms of the Creative Commons Attribution-NonCommercial-NoDerivatives 3.0 License, where it is permissible to download and share the work provided it is properly cited. The work cannot be changed in any way or used commercially.
spellingShingle Research Articles
Groon, Katherine A.
Rasetshwane, Daniel M.
Kopun, Judy G.
Gorga, Michael P.
Neely, Stephen T.
Air-Leak Effects on Ear-Canal Acoustic Absorbance
title Air-Leak Effects on Ear-Canal Acoustic Absorbance
title_full Air-Leak Effects on Ear-Canal Acoustic Absorbance
title_fullStr Air-Leak Effects on Ear-Canal Acoustic Absorbance
title_full_unstemmed Air-Leak Effects on Ear-Canal Acoustic Absorbance
title_short Air-Leak Effects on Ear-Canal Acoustic Absorbance
title_sort air-leak effects on ear-canal acoustic absorbance
topic Research Articles
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4272628/
https://www.ncbi.nlm.nih.gov/pubmed/25170779
http://dx.doi.org/10.1097/AUD.0000000000000077
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