Pressure buffering by the tympanic membrane. In vivo measurements of middle ear pressure fluctuations during elevator motion

The tympanic membrane (TM) represents a pressure buffer, which contributes to the overall pressure regulation of the middle ear (ME). This buffer capacity is based on its viscoelastic properties combined with those of the attached ossicular chain, muscles and ligaments. The current work presents a s...

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Bibliographic Details
Published in:Hearing research 2016-10, Vol.340, p.113-120
Main Authors: Padurariu, Simona, de Greef, Daniël, Jacobsen, Henrik, Nlandu Kamavuako, Ernest, Dirckx, Joris J., Gaihede, Michael
Format: Article
Language:English
Subjects:
Acoustic Impedance Tests
Adult
Buffer
Ear Ossicles - physiology
Ear, Middle - physiology
Elevator
Elevators and Escalators
Female
Humans
Male
Middle Aged
Middle ear pressure
Motion
Pressure
Temporal Bone - physiology
Tympanic membrane
Tympanic Membrane - physiology
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Summary:The tympanic membrane (TM) represents a pressure buffer, which contributes to the overall pressure regulation of the middle ear (ME). This buffer capacity is based on its viscoelastic properties combined with those of the attached ossicular chain, muscles and ligaments. The current work presents a set of in vivo recordings of the ME pressure variations normally occurring in common life: elevator motion. This is defined as a situation of smooth ambient pressure increase or decrease on a limited range and at a low rate of pressure change. Based on these recordings, the purpose was a quantitative analysis of the TM buffer capacity including the TM compliance. The pressure changes in seven normal adult ME's with intact TM's were continuously recorded directly inside the ME cavity during four different elevator trips using a high precision instrument. The TM buffer capacity was determined by the ratio between the changes in ME and the ambient pressure. Further, the ME volumes were calculated by Boyle's Law from pressure recordings during inflation-deflation tests; subsequently the TM compliance could also be calculated. Finally, the correlation between the ME volume and buffer function was determined. Twenty-one elevator trips could be used for the analysis. The overall mean TM pressure buffering capacity was 23.3% (SEM = 3.4), whereas the mean overall compliance was 28.9 × 10−3 μL/Pa (SEM = 4.8). A strong negative linear correlation was found between the TM buffer capacity and the ME volumes (R2 = 0.92). These results were in fair agreement with the literature obtained in clinical as well as temporal bone experiments, and they provide an in vivo reference for the normal ME function as well as for ME modeling. The TM buffer capacity was found more efficient in smaller mastoids. Possible clinical implications are discussed. •In vivo pressure changes were recorded in the middle ear during elevator motion.•The physiological buffer capacity of the human tympanic membrane was determined.•Tympanic membrane compliance described asymmetric properties.•Small middle ear volumes correlated with an increased buffer capacity.•Mastoid obliteration may be favorable due to an increased buffer capacity.
ISSN:0378-5955
1878-5891
DOI:10.1016/j.heares.2015.12.004