Top

Journal of the Association for Research in Otolaryngology

Published in:

01-08-2013 | Research Article

Experimental Study of Vibrations of Gerbil Tympanic Membrane with Closed Middle Ear Cavity

Authors: Nima Maftoon, W. Robert J. Funnell, Sam J. Daniel, Willem F. Decraemer

Published in: Journal of the Association for Research in Otolaryngology | Issue 4/2013

Abstract

The purpose of the present work is to investigate the spatial vibration pattern of the gerbil tympanic membrane (TM) as a function of frequency. In vivo vibration measurements were done at several locations on the pars flaccida and pars tensa, and along the manubrium, on surgically exposed gerbil TMs with closed middle ear cavities. A laser Doppler vibrometer was used to measure motions in response to audio frequency sine sweeps in the ear canal. Data are presented for two different pars flaccida conditions: naturally flat and retracted into the middle ear cavity. Resonance of the flat pars flaccida causes a minimum and a shallow maximum in the displacement magnitude of the manubrium and pars tensa at low frequencies. Compared with a flat pars flaccida, a retracted pars flaccida has much lower displacement magnitudes at low frequencies and does not affect the responses of the other points. All manubrial and pars tensa points show a broad resonance in the range of 1.6 to 2 kHz. Above this resonance, the displacement magnitudes of manubrial points, including the umbo, roll off with substantial irregularities. The manubrial points show an increasing displacement magnitude from the lateral process toward the umbo. Above 5 kHz, phase differences between points along the manubrium start to become more evident, which may indicate flexing of the tip of the manubrium or a change in the vibration mode of the malleus. At low frequencies, points on the posterior side of the pars tensa tend to show larger displacements than those on the anterior side. The simple low-frequency vibration pattern of the pars tensa becomes more complex at higher frequencies, with the breakup occurring at between 1.8 and 2.8 kHz. These observations will be important for the development and validation of middle ear finite-element models for the gerbil.

Available only for authorised users

Alm P, Bloom G, Hellström S, Stenfors L, Widemar L (1983) Middle ear effusion caused by mechanical stimulation of the external auditory canal: an experimental study in the rat. Acta Oto-Laryngologica 96(1–2):91–98PubMedCrossRef

Aziz PM, Sorensen HV, Van Der Spiegel J (2002) An overview of sigma-delta converters. Signal Processing Magazine, IEEE 13(1):61–84CrossRef

Bigelow DC, Swanson PB, Saunders JC (1996) The effect of tympanic membrane perforation size on umbo velocity in the rat. Laryngoscope 106(1):71–76PubMedCrossRef

Cheng JT, Aarnisalo AA, Harrington E, Hernandez-Montes MS, Furlong C, Merchant SN, Rosowski JJ (2010) Motion of the surface of the human tympanic membrane measured with stroboscopic holography. Hear Res 263(1–2):66–77PubMedCrossRef

Cohen YE, Doan DE, Rubin DM, Saunders JC (1993) Middle-ear development. V: development of umbo sensitivity in the gerbil. Am J Otolaryngol 14(3):191–198PubMedCrossRef

Decraemer WF, Khanna SM, Funnell WR (1989) Interferometric measurement of the amplitude and phase of tympanic membrane vibrations in cat. Hear Res 38(1–2):1–17PubMedCrossRef

Decraemer WF, Khanna SM, Funnell WR (1991) Malleus vibration mode changes with frequency. Hear Res 54(2):305–318PubMedCrossRef

Decraemer WF, Khanna SM, Funnell WRJ (1994a) A method for determining three-dimensional vibration in the ear. Hear Res 77(1–2):19–37PubMedCrossRef

Decraemer WF, Khanna SM, Funnell WRJ (1994b) Bending of the manubrium in cat under normal sound stimulation. Proc Opt Imaging Tech Biomed 2329:74–84CrossRef

Decraemer, W. F., Khanna, S. M., & Funnell, W. R. J. (1999). Vibrations at a fine grid of points on the cat tympanic membrane measured with a heterodyne interferometer. EOS/SPIE International Symposia on Industrial Lasers and Inspection, Conference on Biomedical Laser and Metrology and Applications.

Decraemer, W. F., de La Rochefoucauld, O., & Olson, E. S. (2011). Measurement of the three-dimensional vibration motion of the ossicular chain in the living gerbil. In C. A. Shera & E. S. Olson (Eds.), Proceedings of the 11th International Mechanics of Hearing Workshop 1403:528–533

Dirckx JJJ, Decraemer WF, von Unge M, Larsson C (1998) Volume displacement of the gerbil eardrum pars flaccida as a function of middle ear pressure. Hear Res 118(1–2):35–46PubMedCrossRef

Dirckx JJJ, Decraemer WF (2001) Effect of middle ear components on eardrum quasi-static deformation. Hear Res 157(1–2):124–137PubMedCrossRef

Doyle WJ, Alper CM, Seroky JT (1999) Trans-mucosal inert gas exchange constants for the monkey middle ear. Auris Nasus Larynx 26(1):5–12PubMedCrossRef

Doyle WJ, Seroky JT, Alper CM (1995) Gas exchange across the middle ear mucosa in monkeys: estimation of exchange rate. Arch Otolaryngol Head Neck Surg 121(8):887–892PubMedCrossRef

Ellaham, N. N., Akache, F., Funnell, W. R., & Daniel, S. J. (2007). Experimental study of the effects of drying on middle-ear vibrations in the gerbil. 30th Ann Conf Can Med Biol Eng Soc

Emgård P, Hellström S (1997) An animal model for external otitis. European Archives of Oto-rhino-laryngology 254(3):115–119PubMedCrossRef

Eriksson P, Mattsson C, Hellstrom S (2003) First forty-eight hours of developing otitis media: an experimental study. Ann Otol Rhinol Laryngol 112(6):558–566PubMed

Flisberg K, Ingelstedt S, Örtegren U (1963) On middle ear pressure. Acta Oto-Laryngologica 56(S182):43–56CrossRef

Fulghum RS, Marrow HG (1996) Experimental otitis media with Moraxella (Branhamella) catarrhalis. Ann Otol Rhinol Laryngol 105(3):234–241PubMed

Funnell WRJ (1983) On the undamped natural frequencies and mode shapes of a finite-element model of the cat eardrum. J Acoust Soc Am 73:1657–1661

Funnell WRJ, Khanna SM, Decraemer WF (1992) On the degree of rigidity of the manubrium in a finite-element model of the cat eardrum. J Acoust Soc Am 91(4):2082–2090

Funnell WRJ, Laszlo CA (1982) A critical review of experimental observations on ear-drum structure and function. ORL 44(4):181–205PubMedCrossRef

Gea SLR, Decraemer WF, Funnell WRJ, Dirckx JJJ, Maier H (2009) Tympanic membrane boundary deformations derived from static displacements observed with computerized tomography in human and gerbil. J Assoc Res Otolaryngol 11(1):1–17PubMed

Hellström S, Goldie P, Salén B, Stenfors L-E (1985) Mechanisms in middle ear effusion production caused by irritation of the external auditory canal. Am J Otolaryngol 6(3):220–222PubMedCrossRef

Hiraide F, Eriksson H (1978) The effects of the vacuum on vascular permeability of the middle ear. Acta Oto-Laryngologica 85(1–6):10–16PubMedCrossRef

Hiraide F, Paparella MM (1972) Vascular changes in middle ear effusions. Archives of Otolaryngology—Head & Neck Surgery 96(1):45–51CrossRef

Hutchings, M. (1987) The gerbil as an animal model of otitis media with effusion. J Physiol (London), 396:175

Ishihara M (1989) Experimental study of vibration analysis in middle ear models by holographic interferometry. Effects of the cross-sectioned area of aditus on the vibration of tympanic membrane. Nihon Jibiinkoka Gakkai Kaiho 92(5):726–735PubMedCrossRef

Khanna SM, Tonndorf J (1972) Tympanic membrane vibrations in cats studied by time-averaged holography. J Acoust Soc Am 51:1904PubMedCrossRef

Kohllöffel LUE (1984) Notes on the comparative mechanics of hearing. III. On Shrapnell’s membrane. Hear Res 13(1):83–88PubMedCrossRef

Konrádsson KS, Ivarsson A, Bank G (1987) Computerized laser Doppler interferometric scanning of the vibrating tympanic membrane. Scand Audiol 16(3):159–166PubMedCrossRef

de La Rochefoucauld O, Olson ES (2010) A sum of simple and complex motions on the eardrum and manubrium in gerbil. Hear Res 263(1–2):9–15CrossRef

Larsson C, Dirckx JJJ, Bagger-Sjöbäck D, von Unge M (2005) Pars flaccida displacement pattern in otitis media with effusion in the gerbil. Otol Neurol 26(3):337CrossRef

Lee C-Y, Rosowski JJ (2001) Effects of middle-ear static pressure on pars tensa and pars flaccida of gerbil ears. Hear Res 153(1–2):146–163PubMedCrossRef

Maeta M (1991) Effects of the perforation of the tympanic membrane on its vibration—with special reference to an experimental study by holographic interferometry. Nihon Jibiinkoka Gakkai Kaiho 94(2):231–240PubMedCrossRef

Nambiar S (2010) An experimental study of middle-ear vibrations in gerbils. Master of Engineering thesis. McGill University, Montréal, Canada

Okano K (1990) Influence of liquid volume in the middle ear on tympanic membrane vibration (experimental study by holographic interferometry). Nihon Jibiinkoka Gakkai Kaiho 93(11):1847–1855PubMedCrossRef

Qin Z, Wood M, Rosowski JJ (2010) Measurement of conductive hearing loss in mice. Hear Res 263(1–2):93–103PubMedCrossRef

Ravicz, M. E., & Rosowski, J. J. (1997) Sound-power collection by the auditory periphery of the Mongolian gerbil Meriones unguiculatus: III. Effect of variations in middle-ear volume. J Acoust Soc Am 10:2135

Ravicz ME, Rosowski JJ, Voigt HF (1992) Sound-power collection by the auditory periphery of the Mongolian gerbil Meriones unguiculatus. I: middle-ear input impedance. J Acoust Soc Am 92(1):157–177

Ravicz, M. E., Rosowski, J. J., & Voigt, H. F. (1996) Sound-power collection by the auditory periphery of the Mongolian gerbil Meriones unguiculatus. II. External-ear radiation impedance and power collection. J Acoust Soc Am 99:3044

Rosowski JJ, Cheng JT, Ravicz ME, Hulli N, Hernandez-Montes M, Harrington E, Furlong C (2009) Computer-assisted time-averaged holograms of the motion of the surface of the mammalian tympanic membrane with sound stimuli of 0.4–25 kHz. Hear Res 253(1–2):83–96

Rosowski JJ, Lee CY (2002) The effect of immobilizing the gerbil’s pars flaccida on the middle-ear’s response to static pressure. Hear Res 174(1–2):183–195PubMedCrossRef

Rosowski JJ, Ravicz ME, Teoh SW, Flandermeyer D (1999) Measurements of middle-ear function in the Mongolian gerbil, a specialized mammalian ear. Audiol Neuro-otol 4(3–4):129–136CrossRef

Rosowski JJ, Teoh SW, Flandermeyer DT (1997) The effect of the pars flaccida of the tympanic membrane on the ear’s sensitivity to sound. In: Lewis ER, Long GR, Lyon RF, Narins PM, Steele CR, Hect-Poiner E (eds) Diversity in auditory mechanics. World Scientific, New Jersey, pp 129–135

Sadé J, Ar A (1997) Middle ear and auditory tube: middle ear clearance, gas exchange, and pressure regulation. Otolaryng Head Neck 116(4):499–524

Stenfors L, Carlsöö B, Winblad B (1981) Structure and healing capacity of the rat tympanic membrane after eustachian tube occlusion. Acta Oto-Laryngologica 91(1–6):75–84CrossRef

Suehiro M (1990) Effects of an increase or decrease in the middle ear pressure on tympanic membrane vibrations (experimental study by holographic interferometry). Nihon Jibiinkoka Gakkai Kaiho 93(3):398–406PubMedCrossRef

Teoh SW, Flandermeyer DT, Rosowski JJ (1997) Effects of pars flaccida on sound conduction in ears of Mongolian gerbil: acoustic and anatomical measurements. Hear Res 106(1–2):39–65PubMedCrossRef

Tonndorf J, Khanna SM (1972) Tympanic-membrane vibrations in human cadaver ears studied by time-averaged holography. J Acoust Soc Am 52:1221PubMedCrossRef

Tos M, Poulsen G (1980) Attic retractions following secretory otitis. Acta Oto-Laryngologica 89(3–6):479–486PubMedCrossRef

von Unge M, Decraemer W, Bagger-Sjöbäck D, Van den Berghe D (1997) Tympanic membrane changes in experimental purulent otitis media. Hear Res 106(1–2):123–136CrossRef

von Unge M, Decraemer WF, Bagger-Sjöbäck D, Dirckx JJ (1993) Displacement of the gerbil tympanic membrane under static pressure variations measured with a real-time differential moiré interferometer. Hear Res 70(2):229–242CrossRef

Voss SE, Rosowski JJ, Merchant SN, Peake WT (2000) Acoustic responses of the human middle ear. Hear Res 150(1–2):43–69PubMedCrossRef

Wada H, Ando M, Takeuchi M, Sugawara H, Koike T, Kobayashi T, Hozawa K et al (2002) Vibration measurement of the tympanic membrane of guinea pig temporal bones using time-averaged speckle pattern interferometry. J Acoust Soc Am 111:2189PubMedCrossRef

Zheng Y, Ohyama K, Hozawa K, Wada H, Takasaka T (1997) Effect of anesthetic agents and middle ear pressure application on distortion product otoacoustic emissions in the gerbil. Hear Res 112(1–2):167–174PubMedCrossRef

Title: Experimental Study of Vibrations of Gerbil Tympanic Membrane with Closed Middle Ear Cavity
Authors: Nima Maftoon
W. Robert J. Funnell
Sam J. Daniel
Willem F. Decraemer
Publication date: 01-08-2013
Publisher: Springer US
Published in: Journal of the Association for Research in Otolaryngology / Issue 4/2013
Print ISSN: 1525-3961
Electronic ISSN: 1438-7573
DOI: https://doi.org/10.1007/s10162-013-0389-9

At a glance: The STEP trials

Springer Medicine

Experimental Study of Vibrations of Gerbil Tympanic Membrane with Closed Middle Ear Cavity

Abstract

At a glance: The STEP trials

Springer Medicine

Abstract

Please log in to get access to this content

Other articles of this Issue 4/2013

Behavioral Sensitivity to Broadband Binaural Localization Cues in the Ferret

An Energetic Limit on Spatial Release from Masking

Perception of Across-Frequency Asynchrony by Listeners with Cochlear Hearing Loss

Detection of Tones and Their Modification by Noise in Nonhuman Primates

Early Development of Hearing in Zebrafish

Conductive Hearing Loss Induced by Experimental Middle-Ear Effusion in a Chinchilla Model Reveals Impaired Tympanic Membrane-Coupled Ossicular Chain Movement