Application of the Mössbauer Method to Ear Vibrations

Gilad, P.; Shtrikman, S.; Hillman, P.; Rubinstein, Moran; Eviatar, A.

doi:10.1121/1.1910464

Cited by 37 publications

(9 citation statements)

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“…Experimentelle Schwingungsmessungen am Trommelfell wurden erstmals von v. Békésy [1] mittels einer kapazitiven Sonde, später von Gilad et al [10], Gummer et al [13,14] mit der Mössbauer-Methode, von Tonndorf und Khanna [25] holographisch, von Brenkman et al [2] mit einem SQUID-Magnetometer und durch Hüttenbrink [16] mit der direkten Röntgenvergrößerungstechnik durchgeführt. Experimentelle Schwingungsmessungen am Trommelfell wurden erstmals von v. Békésy [1] mittels einer kapazitiven Sonde, später von Gilad et al [10], Gummer et al [13,14] mit der Mössbauer-Methode, von Tonndorf und Khanna [25] holographisch, von Brenkman et al [2] mit einem SQUID-Magnetometer und durch Hüttenbrink [16] mit der direkten Röntgenvergrößerungstechnik durchgeführt.…”

Section: Laservibrometrieunclassified

Laservibrometrie

Jorge¹,

Zenner²,

Hemmert³

et al. 1997

HNO

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A complete battery of audiometric methods is required for the differential diagnosis of different hearing disabilities (including puretone audiometry, impedance, stapes reflex, speech audiometry, brainstam evoked response audiometry, otoacoustic emissions, etc.). In many cases, a comprehensive diagnosis is not possible. Here we describe a new technique based on a laser-Doppler vibrometer that has the potential for non-invasive diagnosis not only middle ear disease but also cochlear pathologies. Disturbance of cochlear function can be ascertained because the input impedance of the cochlea acts as a mechanical load on the middle ear and therefore influences motion of the umbo. In the present study vibration of the umbo and eardrum were measured with a commercially available laser-Doppler vibrometer coupled directly into a standard surgical microscope. The use of the microscope allowed non-invasive measurements of vibrations without having to introduce reflecting material onto the tympanic membrane. Sound pressure was measured with a calibrated probe microphone placed near the tympanic membrane. The displacement response and the specific acoustic impedance of the umbo were calculated from the velocity and sound pressure measured. For normal hearing subjects, the amplitude of the umbo's displacement for frequencies from 0.1 kHz to 1 kHz was 1 nm at 60 dB SPL and decreased with a slope of 6 dB/octave for frequencies between 1 and 5 kHz. A strong correlation was found between the specific acoustic impedance of the umbo and hearing thresholds for hearing-impaired subjects (having otosclerosis or sensorineural hearing losses). The frequency response of the umbo proved to be a means for evaluating the function of both the middle ear and the cochlea under pathological conditions. The measurement technique described is also suitable for intraoperative investigation of the frequency response of the opened middle ear, as well as for the in situ frequency response of partial and total ossicular replacement prostheses.

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Section: Laservibrometrieunclassified

Laservibrometrie

Jorge¹,

Zenner²,

Hemmert³

et al. 1997

HNO

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“…The present period has seen the development of apparatus by Zwislocki (1963), Guinan and Peake (1967), Moller (1961), Fischler et al (1967, Gilad et al (1967) and others to accurately measure the impedance of the middle ear and its transfer characteristics. Through these methods a mathematical function may be formulated which describes the transmission of sound of various frequencies by the middle ear apparatus.…”

Section: Historic Aspectsmentioning

confidence: 99%

Sound conduction of the diseased ear

Austin¹

1978

J. Laryngol. Otol.

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THE mechanics of sound conduction are generally appreciated in clinical otology. The basic principles of impedance matching by tympanic membrane to oval window areal ratio and by the ossicular lever system have been measured with considerable accuracy by investigators using varied techniques. This body of knowledge has stimulated and been stimulated by the development of surgical methods for sound restoration in conductive hearing loss.The otologist, in attempting to correlate abnormalities of the sound conduction system to the degree of functional hearing loss measured audiometrically, tries to rationalize findings through principles of normal physiology. Clinical texts, however, contain only simple empiric statements about hearing losses associated with certain lesions of the conductive mechanism. The physiology literature, as well, contains few studies of the abnormal middle ear. For these reasons, it is desirable to study in detail the hearing changes associated with abnormalities of the sound conduction system. This presentation will describe the hearing losses associated with various carefully documented and distinct lesions of the sound conduction mechanism, including discussion of these findings in relation to known physiologic principles. The presentation will be organized by first discussing the significant physiologic hypotheses of the past and then the present modifications of these ideas. This will be followed by presentation of the collected observations for each specific disease category. Discussion of the specific findings as they relate to the studies of others will then follow within each category of middle-ear lesion. A general discussion of the problem of mechanisms of hearing loss in diseased ears will then be presented, followed by the conclusions of this study. Historic aspectsHelmholtz initiated the period of modern auditory physiology when he defined the principles of impedance matching and how the middle ear served this function. Formulating the problem of matching low impedance air-borne sound to the high impedance of the fluid filled cochlea, Helmholtz conceived of three means by which pressure transformation could take place. The first was through the tympanic membrane which he felt acted as a catenary lever. He stated that the radial fibres of the tympanic membrane acted as stretched cords which, when vibrated in their central *This was presented as a

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“…The best way to compare mechanical sensitivity across species is to measure the displacement of the various parts of the middle ear in response to sounds. These displacements are exceedingly small and it is only within the last 15 years or so that techniques have been developed or sufficiently refined to allow measurement of the movements in response to physiologically normal sound stimuli (Gilad et al, 1967;Khanna and Tonndorf, 1972;Khanna et al, 1968;Wilson, 1973). Most of the studies in this area have used mammals, especially cats and monkeys (Rhode, 1971;Rhode and Robles, 1974;Tonndorf and Khanna, 1968).…”

Section: Introductionmentioning

confidence: 98%

Middle ear sensitivity in anurans and reptiles measured by light scattering spectroscopy

Moffat

Capranica

1978

J. Comp. Physiol.

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Summary. 1. We have used a light scattering spectroscopy technique to measure the vibration amplitude, in response to sound stimuli, of the eardrums of two species of anurans (Bufo arnericanus and Hyla cinerea) and one reptile species (Chrysemys scripta elegans).2. The amplitude of displacement as a function of frequency of the eardrums for constant sound intensity varies in a species-specific manner (Figs. 2, 5, and 7).3. The middle ear responds like a low-pass filter with the cut-off frequency differing in each species. This frequency is quite well correlated with the highest best excitatory frequencies of eighth nerve fibers in the same species, suggesting that the middle ear may limit the frequency range detected by the auditory system. 4. In anurans the tympanum overlying the site of attachment of the extracolumella vibrates with a smaller amplitude than does the surrounding 'free' membrane (Figs. 3 and 6). This indicates that the tympanum can act as a curved membrane lever thereby increasing the force transmitted by the plectrum to the inner ear and, by so doing, aid in impedance matching.5. Calculations based on data obtained in this study and information available from the literature suggest that, at least over their range of maximum sensitivity, the middle ears of nonmammalian vertebrates can be as efficient as those of mammals.

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Application of the Mössbauer Method to Ear Vibrations

Cited by 37 publications

References 0 publications

Laservibrometrie

Laservibrometrie

Sound conduction of the diseased ear

Middle ear sensitivity in anurans and reptiles measured by light scattering spectroscopy

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