CONCLUSION: We present a complete geometric model of the human cochlea, including the segmentation and reconstruction of the fluid-filled chambers scala tympani and scala vestibuli, the lamina spiralis ossea and the vibrating structure (cochlear partition). OBJECTIVE: Future fluid-structure coupled simulations require a reliable geometric model of the cochlea. The aim of this study was to present an anatomical model of the human cochlea, which can be used for further numerical calculations. METHODS: Using high resolution micro-computed tomography (µCT), we obtained images of a cut human temporal bone with a spatial resolution of 5.9 µm. Images were manually segmented to obtain the three-dimensional reconstruction of the cochlea. RESULTS: Due to the high resolution of the µCT data, a detailed examination of the geometry of the twisted cochlear partition near the oval and the round window as well as the precise illustration of the helicotrema was possible. After reconstruction of the lamina spiralis ossea, the cochlear partition and the curved geometry of the scala vestibuli and the scala tympani were presented. The obtained data sets were exported as standard lithography (stl) files. These files represented a complete framework for future numerical simulations of mechanical (acoustic) wave propagation on the cochlear partition in the form of mathematical mechanical cochlea models. Additional quantitative information concerning heights, lengths and volumes of the scalae was found and compared with previous results.
CONCLUSION: We present a complete geometric model of the human cochlea, including the segmentation and reconstruction of the fluid-filled chambers scala tympani and scala vestibuli, the lamina spiralis ossea and the vibrating structure (cochlear partition). OBJECTIVE: Future fluid-structure coupled simulations require a reliable geometric model of the cochlea. The aim of this study was to present an anatomical model of the human cochlea, which can be used for further numerical calculations. METHODS: Using high resolution micro-computed tomography (µCT), we obtained images of a cut human temporal bone with a spatial resolution of 5.9 µm. Images were manually segmented to obtain the three-dimensional reconstruction of the cochlea. RESULTS: Due to the high resolution of the µCT data, a detailed examination of the geometry of the twisted cochlear partition near the oval and the round window as well as the precise illustration of the helicotrema was possible. After reconstruction of the lamina spiralis ossea, the cochlear partition and the curved geometry of the scala vestibuli and the scala tympani were presented. The obtained data sets were exported as standard lithography (stl) files. These files represented a complete framework for future numerical simulations of mechanical (acoustic) wave propagation on the cochlear partition in the form of mathematical mechanical cochlea models. Additional quantitative information concerning heights, lengths and volumes of the scalae was found and compared with previous results.
Authors: H Martin Kjer; Jens Fagertun; Wilhelm Wimmer; Nicolas Gerber; Sergio Vera; Livia Barazzetti; Nerea Mangado; Mario Ceresa; Gemma Piella; Thomas Stark; Martin Stauber; Mauricio Reyes; Stefan Weber; Marco Caversaccio; Miguel Ángel González Ballester; Rasmus R Paulsen Journal: Int J Comput Assist Radiol Surg Date: 2018-01-06 Impact factor: 2.924
Authors: G Jakob Lexow; Daniel Schurzig; Nils-Claudius Gellrich; Thomas Lenarz; Omid Majdani; Thomas S Rau Journal: Int J Comput Assist Radiol Surg Date: 2016-03-19 Impact factor: 2.924
Authors: Nicolas Gerber; Mauricio Reyes; Livia Barazzetti; Hans Martin Kjer; Sergio Vera; Martin Stauber; Pavel Mistrik; Mario Ceresa; Nerea Mangado; Wilhelm Wimmer; Thomas Stark; Rasmus R Paulsen; Stefan Weber; Marco Caversaccio; Miguel A González Ballester Journal: Sci Data Date: 2017-09-19 Impact factor: 6.444