Details of human middle ear morphology based on micro‐CT imaging of phosphotungstic acid stained samples

Greef, DaniÃ«l De; Buytaert, Jan A.N.; Aerts, Johan R.M.; Hoorebeke, Luc Van; Dierick, Manuel; Dirckx, Joris J.J.

doi:10.1002/jmor.20392

Cited by 61 publications

(58 citation statements)

References 60 publications

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“…In the unloaded state the distance between the articular surfaces for all four TBs was within the range of 25 to 280 µm which is comparable to recent investigations of De Greef et al (2015). Dirckx et al (2005) proposed that friction effects are important in the quasi-static regime, but viscoelasticity may be the remaining factor at acoustic frequencies.…”

Section: Diathroidal Jointssupporting

confidence: 87%

Biomechanics of the incudo-malleolar-joint – Experimental investigations for quasi-static loads

et al. 2016

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Under large quasi-static loads, the incudo-malleolar joint (IMJ), connecting the malleus and the incus, is highly mobile. It can be classified as a mechanical filter decoupling large quasi-static motions while transferring small dynamic excitations. This is presumed to be due to the complex geometry of the joint inducing a spatial decoupling between the malleus and incus under large quasi-static loads. Spatial Laser Doppler Vibrometer (LDV) displacement measurements on isolated malleus-incus-complexes (MICs) were performed. With the malleus firmly attached to a probe holder, the incus was excited by applying quasi-static forces at different points. For each force application point the resulting displacement was measured subsequently at different points on the incus. The location of the force application point and the LDV measurement points were calculated in a post-processing step combining the position of the LDV points with geometric data of the MIC. The rigid body motion of the incus was then calculated from the multiple displacement measurements for each force application point. The contact regions of the articular surfaces for different load configurations were calculated by applying the reconstructed motion to the geometry model of the MIC and calculate the minimal distance of the articular surfaces. The reconstructed motion has a complex spatial characteristic and varies for different force application points. The motion changed with increasing load caused by the kinematic guidance of the articular surfaces of the joint. The IMJ permits a relative large rotation around the anterior-posterior axis through the joint when a force is applied at the lenticularis in lateral direction before impeding the motion. This is part of the decoupling of the malleus motion from the incus motion in case of large quasi-static loads. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. AbstractUnder large quasi-static loads, the incudo-malleolar joint (IMJ), connecting the malleus and the incus, is highly mobile. It can be classified as a mechanical filter decoupling large quasi-static motions while transferring small dynamic excitations. This is presumed to be due to the complex geometry of the joint inducing a spatial decoupling between the malleus and incus under large quasi-static loads.Spatial Laser Doppler Vibrometer (LDV) displacement measurements on isolated malleus-incus-complexes (MICs) were performed. With the malleus firmly attached to a probe holder, the incus was excited by applying quasi-static forces at different points. For each force application point the resulting displacement was measured ...

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Section: Diathroidal Jointssupporting

confidence: 87%

Biomechanics of the incudo-malleolar-joint – Experimental investigations for quasi-static loads

et al. 2016

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“…Nevertheless, this is to the best of our knowledge the first description of human inner ear development integrating high resolution μ CT 3D imaging and mineral density measurement with histomorphological analysis of undecalcified skeletal samples. We thus combined accurate 3D imaging (vs. histology sections that may be misaligned using manual reconstruction softwares) at ultra high resolution (higher than MRI 16 ) with the high spatial resolution of histology on specimens with preserved bone tissue characteristics (undecalcified). Moreover, we are here providing observational developmental data on a highly sensitive population, and these are of direct interest for the interpretation of clinical symptoms.…”

Section: Discussionmentioning

confidence: 99%

Inner ear ossification and mineralization kinetics in human embryonic development - microtomographic and histomorphological study

Richard

Courbon

Laroche

et al. 2017

Sci Rep

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Little is known about middle and inner ear development during the second and third parts of human fetal life. Using ultra-high resolution Microcomputed Tomography coupled with bone histology, we performed the first quantitative middle and inner ear ossification/mineralization evaluation of fetuses between 17 and 39 weeks of gestational age. We show distinct ossification paces between ossicles, with a belated development of the stapes. A complete cochlear bony covering is observed within the time-frame of the onset of hearing, whereas distinct time courses of ossification for semicircular canal envelopes are observed in relation to the start of vestibular functions. The study evidences a spatio-temporal relationship between middle and inner ear structure development and the onset of hearing and balance, critical senses for the fetal adaptation to birth.

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“…It is reasonable to assume that the same is true for anatomical details that could have a significant influence on the system's mechanics and transfer function (e.g. (De Greef et al, 2015)). 385 Some recent finite element models of the middle include a simplified geometry for the TMC (Aernouts et al, 2012;De Greef et al, 2014;Hoffstetter et al, 2010;Koike et al, 2002;Volandri et al, 2012;Yao et al, 2013).…”

Section: Accepted Manuscriptmentioning

confidence: 99%

On the connection between the tympanic membrane and the malleus

et al. 2016

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Details of human middle ear morphology based on micro‐CT imaging of phosphotungstic acid stained samples

Cited by 61 publications

References 60 publications

Biomechanics of the incudo-malleolar-joint – Experimental investigations for quasi-static loads

Biomechanics of the incudo-malleolar-joint – Experimental investigations for quasi-static loads

Inner ear ossification and mineralization kinetics in human embryonic development - microtomographic and histomorphological study

On the connection between the tympanic membrane and the malleus

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