Innovative 3D Model of the Human Middle Ear in High Resolution with a Histological Microgrinding Method: A Feasibility Study and Comparison with μCT

Innovative 3D Model of the Human Middle Ear in High Resolution with a Histological Microgrinding Method: A Feasibility Study and Comparison with μCT

Conclusion. The development of a histological 3D model of the tympanic cavity visualizes the exact microanatomy of the sound conduction organ and is therefore essential for finite elements simulations and surgical training. Objectives. So far, no accurate histological 3D model of the sound conductio...

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Main Authors: Susanne Bradel, Laura Doniga-Crivat, Silke Besdo, Franziska Lexow, Michael Fehr, Thomas Lenarz, Nils Prenzler, Gudrun Brandes
Format: Article
Language:English
Published: Hindawi Limited 2017-01-01
Series:International Journal of Otolaryngology
Online Access:http://dx.doi.org/10.1155/2017/6753604
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spelling doaj-f75994d70c52480ba4f61481741e6d7d2020-11-24T22:39:20ZengHindawi LimitedInternational Journal of Otolaryngology1687-92011687-921X2017-01-01201710.1155/2017/67536046753604Innovative 3D Model of the Human Middle Ear in High Resolution with a Histological Microgrinding Method: A Feasibility Study and Comparison with μCTSusanne Bradel0Laura Doniga-Crivat1Silke Besdo2Franziska Lexow3Michael Fehr4Thomas Lenarz5Nils Prenzler6Gudrun Brandes7Department of Otolaryngology, Hannover Medical School, Hannover, GermanyInstitute of Continuum Mechanics, Gottfried Wilhelm Leibniz Universität, Hannover, GermanyInstitute of Continuum Mechanics, Gottfried Wilhelm Leibniz Universität, Hannover, GermanyDepartment of Otolaryngology, Hannover Medical School, Hannover, GermanyClinic for Exotic Pets, Reptiles, Pet, and Feral Birds, University of Veterinary Medicine Hannover, Hannover, GermanyDepartment of Otolaryngology, Hannover Medical School, Hannover, GermanyDepartment of Otolaryngology, Hannover Medical School, Hannover, GermanyInstitute for Neuroanatomy and Cell Biology, Hannover Medical School, Hannover, GermanyConclusion. The development of a histological 3D model of the tympanic cavity visualizes the exact microanatomy of the sound conduction organ and is therefore essential for finite elements simulations and surgical training. Objectives. So far, no accurate histological 3D model of the sound conduction system existed in literature. For 3D reconstruction of the very fine structures inside and outside the auditory ossicles, a method based on histological slices allows a more differential analysis of both hard and soft tissues and could thus be superior to μCT. Method. A complete temporal bone was embedded in epoxy resin and microground in distances of about 34 μm. After photodocumentation of every plane, a 3D reconstruction was performed by using the Computer Aided Design (CAD) program Rhinoceros 5®. For comparison, a μCT of the same specimen resulted in a 3D model of the calcified structures in the middle ear. Results. The histological 3D model gives an excellent overview to all anatomical soft and bony tissues of the human auditory ossicles. Specifically the fine blood vessel system and the exact dimension of cartilage areas inside the ossicles can be illustrated much more precisely than with μCT data. The present technique also allows the evaluation of the fine connecting ligaments inside the tympanic cavity.http://dx.doi.org/10.1155/2017/6753604
collection DOAJ
language English
format Article
sources DOAJ
author Susanne Bradel
Laura Doniga-Crivat
Silke Besdo
Franziska Lexow
Michael Fehr
Thomas Lenarz
Nils Prenzler
Gudrun Brandes
spellingShingle Susanne Bradel
Laura Doniga-Crivat
Silke Besdo
Franziska Lexow
Michael Fehr
Thomas Lenarz
Nils Prenzler
Gudrun Brandes
Innovative 3D Model of the Human Middle Ear in High Resolution with a Histological Microgrinding Method: A Feasibility Study and Comparison with μCT
International Journal of Otolaryngology
author_facet Susanne Bradel
Laura Doniga-Crivat
Silke Besdo
Franziska Lexow
Michael Fehr
Thomas Lenarz
Nils Prenzler
Gudrun Brandes
author_sort Susanne Bradel
title Innovative 3D Model of the Human Middle Ear in High Resolution with a Histological Microgrinding Method: A Feasibility Study and Comparison with μCT
title_short Innovative 3D Model of the Human Middle Ear in High Resolution with a Histological Microgrinding Method: A Feasibility Study and Comparison with μCT
title_full Innovative 3D Model of the Human Middle Ear in High Resolution with a Histological Microgrinding Method: A Feasibility Study and Comparison with μCT
title_fullStr Innovative 3D Model of the Human Middle Ear in High Resolution with a Histological Microgrinding Method: A Feasibility Study and Comparison with μCT
title_full_unstemmed Innovative 3D Model of the Human Middle Ear in High Resolution with a Histological Microgrinding Method: A Feasibility Study and Comparison with μCT
title_sort innovative 3d model of the human middle ear in high resolution with a histological microgrinding method: a feasibility study and comparison with μct
publisher Hindawi Limited
series International Journal of Otolaryngology
issn 1687-9201
1687-921X
publishDate 2017-01-01
description Conclusion. The development of a histological 3D model of the tympanic cavity visualizes the exact microanatomy of the sound conduction organ and is therefore essential for finite elements simulations and surgical training. Objectives. So far, no accurate histological 3D model of the sound conduction system existed in literature. For 3D reconstruction of the very fine structures inside and outside the auditory ossicles, a method based on histological slices allows a more differential analysis of both hard and soft tissues and could thus be superior to μCT. Method. A complete temporal bone was embedded in epoxy resin and microground in distances of about 34 μm. After photodocumentation of every plane, a 3D reconstruction was performed by using the Computer Aided Design (CAD) program Rhinoceros 5®. For comparison, a μCT of the same specimen resulted in a 3D model of the calcified structures in the middle ear. Results. The histological 3D model gives an excellent overview to all anatomical soft and bony tissues of the human auditory ossicles. Specifically the fine blood vessel system and the exact dimension of cartilage areas inside the ossicles can be illustrated much more precisely than with μCT data. The present technique also allows the evaluation of the fine connecting ligaments inside the tympanic cavity.
url http://dx.doi.org/10.1155/2017/6753604
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