Abstract
PurposeInjury or inflammation of the middle ear often results in the persistent tympanic membrane (TM) perforations, leading to conductive hearing loss (HL). However, in some cases the magnitude of HL exceeds that attributable by the TM perforation alone. The aim of the study is to better understand the effects of location and size of TM perforations on the sound transmission properties of the middle ear.MethodsThe middle ear transfer functions (METF) of six human temporal bones (TB) were compared before and after perforating the TM at different locations (anterior or posterior lower quadrant) and to different degrees (1 mm, ¼ of the TM, ½ of the TM, and full ablation). The sound-induced velocity of the stapes footplate was measured using single-point laser-Doppler-vibrometry (LDV). The METF were correlated with a Finite Element (FE) model of the middle ear, in which similar alterations were simulated.ResultsThe measured and calculated METF showed frequency and perforation size dependent losses at all perforation locations. Starting at low frequencies, the loss expanded to higher frequencies with increased perforation size. In direct comparison, posterior TM perforations affected the transmission properties to a larger degree than anterior perforations. The asymmetry of the TM causes the malleus-incus complex to rotate and results in larger deflections in the posterior TM quadrants than in the anterior TM quadrants. Simulations in the FE model with a sealed cavity show that small perforations lead to a decrease in TM rigidity and thus to an increase in oscillation amplitude of the TM mainly above 1 kHz.ConclusionSize and location of TM perforations have a characteristic influence on the METF. The correlation of the experimental LDV measurements with an FE model contributes to a better understanding of the pathologic mechanisms of middle-ear diseases. If small perforations with significant HL are observed in daily clinical practice, additional middle ear pathologies should be considered. Further investigations on the loss of TM pretension due to perforations may be informative.
Highlights
Perforations of the tympanic membrane (TM) can be the result of acute and chronic middle-ear disease or after trauma
This study aims to investigate how the size and location of a TM perforation influence the middle ear transfer function (METF), which is the ratio between the stapes pistonlike displacement and the acoustic ear canal sound pressure
Finite Element (FE) model simulations with a sealed tympanic cavity show that small perforations lead to a decrease in TM rigidity and to an increase in oscillation amplitude of the TM, possibly explaining the larger middle ear transfer functions (METF) amplitudes observed in 1 mm perforations of the lower anterior quadrant
Summary
Perforations of the tympanic membrane (TM) can be the result of acute and chronic middle-ear disease or after trauma. Invasive procedures such as intratympanic injection, transtympanic electrical stimulation of the cochlea or the frequently performed tympanic tube insertion lead to a perforation of the TM [1], but not necessarily to conductive hearing loss (HL). The TM has a high spontaneous healing tendency [2], long-term perforations may occur. These perforations can lead to conductive HL and recurrent middle-ear infections [3]. In addition to solitary TM perforations, other pathologies are frequently discovered during surgery.
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