On the functional compartmentalization of the normal middle ear. Morpho-histological modelling parameters of its mucosa

Middle ear physiology includes both sound pressure transmission and homeostasis of its static air pressure. Pressure gradients are continuously created by gas exchange over the middle ear mucosa as well as by ambient pressure variations. Gas exchange models require actual values for regional mucosa...

Full description

Saved in:
Bibliographic Details
Published in:Hearing research 2019-07, Vol.378, p.176-184
Main Authors: Padurariu, Simona, Röösli, Christof, Røge, Rasmus, Stensballe, Allan, Vyberg, Mogens, Huber, Alex, Gaihede, Michael
Format: Article
Language:English
Subjects:
Adult
Aged
Aged, 80 and over
Air Pressure
Cadaver
Diffusion
Ear, Middle - anatomy & histology
Ear, Middle - physiology
Female
Hearing
Homeostasis
Humans
Male
Middle Aged
Motion
Respiratory Mucosa - anatomy & histology
Respiratory Mucosa - physiology
Sound
Young Adult
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Middle ear physiology includes both sound pressure transmission and homeostasis of its static air pressure. Pressure gradients are continuously created by gas exchange over the middle ear mucosa as well as by ambient pressure variations. Gas exchange models require actual values for regional mucosa thickness, blood vessel density, and diffusion distance. Such quantitative data have been scarce and limited to few histological samples from the tympanic cavity (TC) and the antrum. However, a detailed regional description of the morphological differences of the TC and mastoid air cell system (MACS) mucosa has not been available. The aim of the present study was to provide such parameters. The study included sets of three histological H&E-slides from 15 archived healthy temporal bones. We performed a comparison of the mucosa morphology among the following regions: (1) anterior TC; (2) inferior TC; (3) posterior TC; (4) superior TC; (5) MACS antrum; (6) superior MACS; (7) central MACS; (8) inferior MACS. Regions (1)–(3), situated below the inter-attico-tympanic diaphragm, had the largest proportion of high respiratory epithelium, cilia and loose lamina propria within the mucosa, as well as the thickest mucosa and the largest diffusion distance. Regions (6)–(8), situated above the diaphragm, had the thinnest mucosa, the shortest distance to the blood vessels, together with the largest proportion of flat epithelium and very few cilia. Regions (4)–(5), still supradiaphragmatic, had intermediary values for these parameters, but generally closer to regions (6)–(8). The blood vessel density and the proportion of active mucosa were not significantly different among the regions. Mucosa of regions (1), (2) and (3) represented a predominantly clearance-specific morphology, whereas in regions (4)–(8) it seemed adapted to gas exchange. However, the lack of statistically significant differences in blood vessel density and proportion of active mucosa indicated that all regions could be involved in gas exchange with the highest adaptation in the superior MACS. This pattern divides the middle ear functionally along the inter-attico-tympanic diaphragm rather than the anatomical division into TC and MACS. •Mucosa morphology differs between antero-inferior and postero-superior middle ear.•Mucosa morphology is divided by the inter-attico-tympanic diaphragm.•The postero-superior mucosa is thinner with shorter diffusion distances for gases.•The blood vessel density is approximately u
ISSN:0378-5955
1878-5891
DOI:10.1016/j.heares.2019.01.023