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Tympanometry and Reflectance in the Hearing Clinic Presenters: Dr. Robert Withnell Dr. Sheena Tatem.

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Presentation on theme: "Tympanometry and Reflectance in the Hearing Clinic Presenters: Dr. Robert Withnell Dr. Sheena Tatem."— Presentation transcript:

1 Tympanometry and Reflectance in the Hearing Clinic Presenters: Dr. Robert Withnell Dr. Sheena Tatem

2 Accurate assessment of middle ear function is important for appropriate management of hearing loss. Two tools available for assessing middle ear function are tympanometry and wideband reflectance. Tympanometry and reflectance both assess how the middle ear receives sound. Critical to their interpretation is an understanding of how the resonance(s) of the middle ear change with middle ear pathology or static pressure changes in the ear canal. Seminar attendees will discover how to interpret tympanograms obtained at multiple frequencies and what the different tympanogram shapes mean in terms of middle ear resonance. Participants will be given the tools to make a reflectance measurement and be able to interpret the results, as well as be able to describe what tympanometry and reflectance have in common and how they differ. Abstract

3 Learning Outcomes Participants will learn: 1. how to interpret tympanograms obtained at multiple frequencies and what the different tympanogram shapes mean in terms of middle ear resonance. 2. how to make a reflectance measurement and how to interpret the results. 3. what tympanometry and reflectance have in common and how they differ.

4 Finding the Input Impedance of the Ear http://www.cochlea.eu/en/audiometry/objective-methods Outer and middle ear act to impedance match sound in air to sound in fluid If P r = 0 perfect impedance match If P r = P i 100% impedance mismatch Tympanometry: Reflectance: Probe tone frequency Static pressure in ear canal Microphone

5 Tympanometry

6 1960s Clinical measurements from 125 to 1500 Hz was recommended (Zwislocki, 1963; Feldman, 1963, 1964) 226 Hz probe tone 1970s Tympanometry at 226 Hz Tympanometry using high frequency probe tones was not diagnostic (Alberti and Jerger, 1974) ??? Middle ear frequency response reactance The most important parameter from a diagnostic standpoint, the first resonant frequency of the middle ear, is ignored. resonances

7 Tympanometry A Normal Tympanogram: Liden et al. (1970) Probe tone frequency = 800 Hz What probe tone frequency is optimal for measuring a tympanogram?

8 ECV – = Y a @ -400 daPa – estimated volume of air in front of the probe SC – = Y tm – Maximum compliance of the middle ear system (static compliance) TPP – Pressure at which the middle ear system has the greatest absorption of sound energy (tympanometric peak pressure) TW – Width of the tympanogram curve Data Obtained from a Tympanogram www.studyblue.co m TPP

9 –The value of static compliance provides information about the stiffness of the middle ear system –Normal range Adults 0.4 to 1.6 cc –90% range –(Shahnaz & Polka, 1997, E&H 18(4)) Static compliance www.studyblue.co m

10 Ear canal volume Tympanometry estimates of ECV over-estimate the actual volume As static pressure increases from - 400 daPa to 200 daPa the magnitude of the error increases Ear canal volume measured with a 660 Hz probe tone is more accurate than the standard 220 Hz tone Shanks & Lilly 1981

11 Normal range –Adults 48 to 134 daPa 90% range (Shahnaz & Polka, 1997, E&H 18(4)) TW is the width of the tympanogram measured in daPa at half of the height from tympanogram peak to tail (Wiley & Stoppenbach, in Katz, 2002, p. 170) TW Tympanometric width

12 Tympanogram shapes http://pedsinreview.aappublications.org/content/19/5/155

13 Tympanometry @ 226, 678, and 1000 Hz

14 Demonstration Tympanometry @ 226, 678, and 1000 Hz

15 What do these results mean?

16 To understand these different tympanogram shapes, obtained with different probe tone frequencies, we need 1. to understand how changing static pressure influences the middle ear 2. a model of the ear 3. a model for generation of tympanograms

17 To understand these different tympanogram shapes, obtained with different probe tone frequencies, we need 1. to understand how changing static pressure influences the middle ear 2. a model of the ear 3. a model for generation of tympanograms

18 Static pressure change in ear canal Static pressure changes in the ear canal increases the stiffness of the middle ear seeRabinowitz (1981) Huang et al (2000) Increase stiffness increase resonance static pressure = middle ear resonance Middle ear resonance increasing Increasing (+/-) static pressure Middle ear frequency response

19 Tympanogram with a different x- axis Increasing (+/-) static pressure Middle ear frequency response 100 1000 10000 Frequency (Hz) Tympanogram Can think of static pressure axis on tympanograms as middle ear resonance rather than pressure

20 To understand these different tympanogram shapes, obtained with different probe tone frequencies, we need 1. to understand how changing static pressure influences the middle ear 2. a model of the ear 3. a model for generation of tympanograms

21 Modeling input impedance of ear Ear canal Lossy transmission line Middle ear and cochlea Three stiffness terms  Middle ear cavity  Eardrum, ossicles, annular ligament?  Cochlea Six tuned oscillators... six resistance terms RC term for cochlea

22 To understand these different tympanogram shapes, obtained with different probe tone frequencies, we need 1. to understand how changing static pressure influences the middle ear 2. a model of the ear 3. a model for generation of tympanograms

23 Modeling Tympanometry Static pressure change (+ or − )in the ear canal increases the stiffness of middle ear Stiffness change probably not symmetrical... treated as symmetrical for +,− change Static pressure change produces probable change to cavity, middle ear and cochlear stiffness... model change only in middle ear stiffness

24 Model fit to data for tympanograms Model tympanograms normalized to fit tail at +200 daPa at each frequency To get asymmetry in tympanograms, had to have R vary for negative static pressures (in addition to k) data model

25 Model-generated family of Tympanograms - relationship to resonance

26 What is the inverted W? Probe frequency is above the first resonance of the middle ear middle ear resonance Peaks associated with static pressure change shifting first resonance of middle ear to probe frequency

27 Multiple tympanogram frequencies better describes filtering of ME Shape of tympanogram reflects proximity to ME resonance

28 Pathologies of the Middle Ear Tympanogram shapes represent a continuum with respect to resonance of the middle ear For a 226 Hz probe tone: A flat, type B tympanogram, is a long way from resonance A shallow type A tympanogram is far from resonance The bigger the peak, the closer the probe tone frequency is to resonance

29 Reflectance

30 Tympanometry vs Reflectance ZsZs Z ear Tympanometry  Impedance of sound source (Z s ) is not known  Impedance of ear (Z ear ) is estimated Power Reflectance  Impedance of sound source (Z s ) is known  Derive impedance of ear Z ear Sound pressure – measured by a microphone in both cases (P m )

31 Z ec Z me  Z ear Tympanometry –Z ear is a relative measure –Z ear expressed as a volume Power Reflectance –Z ear is derived –P s, Z s obtained from calibration Sound pressure at the microphone is inversely proportional to Z ear Z ear = Z S *P m P s -P m Withnell et al. (2009)

32 Comparing methods Tympanometry Acoustic impedance v. Pressure (Z vs. P) frequency is fixed (e.g., 226 Hz) Power Reflectance Acoustic impedance v. frequency (Z vs. f) static pressure in the ear canal is fixed

33 Calibration 0.5, 2 and 5 cc cavities calibrates 226 Hz 0.5 and 2 cc cavities calibrates 678 Hz 0.5 cc cavity calibrates 1000 Hz (GS Tympstar) TympanometryReflectance A number of cylinders of constant diameter, with different lengths 0.5 2 5 dB SPL

34 Volume calibration Limited to low frequencies (up to 1500 Hz) Cylinder calibration, known radius and lengths Upper frequency limit depends on radius Probably at least 10 kHz Standing waves in cylinders complicate calibration Radius of cylinder must be similar to ear canal (bony portion)

35 Click to edit Master text styles Second level Third level Fourth level Fifth level Reflectance Provides a broad spectrum measure of the impedance mis- match between the ear canal and middle ear Does not require static pressure changes in the ear canal The reflectance transfer function alters predictably with middle ear pathology Withnell et al., 2009

36 Stiffness dominated region of middle ear POWER REFLECTANCE MIDDLE EAR TRANSFER FUNCTION Withnell et al., 2009

37 Increase in stiffness of middle ear POWER REFLECTANCE MIDDLE EAR TRANSFER FUNCTION Power reflectance results from a subject with otosclerosis (Allen et al., 2005) Withnell et al., 2009

38 Decrease in stiffness of middle ear POWER REFLECTANCE MIDDLE EAR TRANSFER FUNCTION Power reflectance results from a subject with middle ear disease as a child (Mimosa data) Withnell et al., 2009

39 OME MIDDLE EAR TRANSFER FUNCTION POWER REFLECTANCE Power reflectance results from a subjects with otitis media with effusion (Allen et al., 2005) mostly INCREASE in M.E. stiffness middle ear not fluid-filled Withnell et al., 2009

40 Tympanometry and Reflectance in the Clinic. The how, what and why. how to do it what the results mean why multiple frequencies Questions?....

41 Dr. Robert Withnell rwithnel@indiana.edu

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