A validated methodology for the 3D reconstruction of cochlea geometries using human microCT images

Sakellarios, Antonis I.; Tachos, Nikolaos S.; Rigas, George; Bibas, T; Ni, Guangjian; Böhnke, Frank; Fotiadis, Dimitris

doi:10.1088/1361-6501/aa5f18

Cited by 7 publications

(12 citation statements)

References 35 publications

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“…Literature [11] and Literature [13] are always lower than the proposed method. The maximum texture self-similarity coefficient can reach 0.994 in this study.…”

Section: B Evaluation Criteriamentioning

confidence: 76%

“…The method in Literature [10] produces good image contour feature matching effect, but the center part of the image is poorly matched. In comparison, the methods in Literature [11] and Literature [13] have better overall matching effect. However, it can be clearly found from the figure that the image feature matching point of the proposed method has a large amount of data and a wide distribution, and the matching effect is superior to the method in Literature [11] and Literature [13].…”

Section: B Evaluation Criteriamentioning

confidence: 97%

“…where, 1 P and 2 P stand for the power value of effective signal and noise, respectively. (a)Literature [7] (b) Literature [10] (c)Literature [11] (d)Literature [13] (e) The proposed method According to Figure 5. In Literature [7], the feature matching points of the algorithm are basically distributed below the image, but the matching effect of the feature points above the image is poor.…”

Section: B Evaluation Criteriamentioning

confidence: 99%

“…The maximum texture self-similarity coefficient can reach 0.994 in this study. Therefore, the proposed fuzzy medical image 3D reconstruction method using the quantum algorithm has a higher image quality while the reconstruction error of the methods in Literature [7], Literature [11] and Literature [13] is always greater than the proposed method. Literature [7] has the largest error, which can be as high as 1.7mm, while the maximum reconstruction error of the proposed method is not higher than 0.9mm.…”

Section: B Evaluation Criteriamentioning

confidence: 99%

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Three-Dimensional Reconstruction of Fuzzy Medical Images Using Quantum Algorithm

Sui

Wang

2020

IEEE Access

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In order to deal with the problems of poor anti-interference, low reconstruction clarity and large errors in the traditional medical image reconstruction methods, we proposed a fuzzy medical images three-dimensional (3D) reconstruction method using quantum algorithm. First of all, a feature matching model of fuzzy medical image was built. Secondly, this study decomposed the edge contour features by using the Gaussian mixture feature matching method, extracted the edge contour vectors of fuzzy medical image, and enhanced the information of fuzzy medical images by adopting the region edge sharpening. Thirdly, this study reorganized the 3D texture structure of images and reconstructed the sparse scattered points according to its texture and detail regions. Finally, we combined with the gray histogram of fuzzy medical images to achieve the adaptive pixel reconstruction of fuzzy medical images, and completed the 3D reconstruction of fuzzy medical images by employing the quantum algorithm. The results show that the proposed method is characterized by high matching degree of image features and balanced distribution of point clouds, and the self-similarity coefficient of the reconstructed texture can reach 0.994; in addition, the SINR value of the reconstruction result can be maintained around 100dB, and it has lower error rate than the traditional method, thereby improving the detection and recognition capability of medical images, and the algorithm has certain practical application.

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“…Literature [11] and Literature [13] are always lower than the proposed method. The maximum texture self-similarity coefficient can reach 0.994 in this study.…”

Section: B Evaluation Criteriamentioning

confidence: 76%

Section: B Evaluation Criteriamentioning

confidence: 97%

Section: B Evaluation Criteriamentioning

confidence: 99%

Section: B Evaluation Criteriamentioning

confidence: 99%

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Three-Dimensional Reconstruction of Fuzzy Medical Images Using Quantum Algorithm

Sui

Wang

2020

IEEE Access

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“…Another possible solution would be used the vibratory response around the temporal bone area in the LiUHead as the general input for other FE models of the inner ear. For example, Kim et al (2013) published a 3D FE model of the human auditory periphery including a coiled-cochlea model and Sakellarios et al (2017) presented 3D cochlea geometries using human microCT images. Such models could be used to investigate inner ear responses based on vibratory patterns obtained in the LiUHead.…”

Section: Detailed Inner Earmentioning

confidence: 99%

A Finite Element Model of the Human Head for Simulation of Bone-conducted Sound

Chang¹

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Bone conduction (BC) is usually understood as the hearing sensation based on the vibrations of the skull bone and surrounding tissues. The fact that vibration of the skull bones can result in a sound percept has been known for a long time. However, it is difficult to give a general definition of BC sound. Normally, BC sound is described as the sound energy transmitted through the body (comprising the solid and fluid parts) then the outer, middle and inner ear are involved and finally produce a perception of sound.

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Fully Automated Measurement of Cochlear Duct Length From Clinical Temporal Bone Computed Tomography

et al. 2021

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Objectives/Hypothesis: To present and validate a novel fully automated method to measure cochlear dimensions, including cochlear duct length (CDL).Study Design: Cross-sectional study.Methods: The computational method combined 1) a deep learning (DL) algorithm to segment the cochlea and otic capsule and 2) geometric analysis to measure anti-modiolar distances from the round window to the apex. The algorithm was trained using 165 manually segmented clinical computed tomography (CT). A Testing group of 159 CTs were then measured for cochlear diameter and width (A-and B-values) and CDL using the automated system and compared against manual measurements. The results were also compared with existing approaches and historical data. In addition, pre-and postimplantation scans from 27 cochlear implant recipients were studied to compare predicted versus actual array insertion depth.Results: Measurements were successfully obtained in 98.1% of scans. The mean CDL to 900 was 35.52 mm (SD, 2.06; range, [30.91-40.50]), the mean A-value was 8.88 mm (0.47; [7.67-10.49]), and mean B-value was 6.38 mm (0.42; [5.16-7.38]). The R 2 fit of the automated to manual measurements was 0.87 for A-value, 0.70 for B-value, and 0.71 for CDL. For anti-modiolar arrays, the distance between the imaged and predicted array tip location was 0.57 mm (1.25; [0.13-5.28]). Conclusion:Our method provides a fully automated means of cochlear analysis from clinical CTs. The distribution of CDL, dimensions, and cochlear quadrant lengths is similar to those from historical data. This approach requires no radiographic experience and is free from user-related variation.

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A validated methodology for the 3D reconstruction of cochlea geometries using human microCT images

Cited by 7 publications

References 35 publications

Three-Dimensional Reconstruction of Fuzzy Medical Images Using Quantum Algorithm

Three-Dimensional Reconstruction of Fuzzy Medical Images Using Quantum Algorithm

A Finite Element Model of the Human Head for Simulation of Bone-conducted Sound

Fully Automated Measurement of Cochlear Duct Length From Clinical Temporal Bone Computed Tomography

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