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2D reconstruction of small intestine's interior wall

2D reconstruction of small intestine's interior wall
2D reconstruction of small intestine's interior wall

Examining and interpreting of a large number of wireless endoscopic images from the gastrointestinal tract is a tiresome task for physicians. A practical solution is to automatically construct a two dimensional representation of the gastrointestinal tract for easy inspection. However, little has been done on wireless endoscopic image stitching, let alone systematic investigation. The proposed new wireless endoscopic image stitching method consists of two main steps to improve the accuracy and efficiency of image registration. First, the keypoints are extracted by Principle Component Analysis and Scale Invariant Feature Transform (PCA-SIFT) algorithm and refined with Maximum Likelihood Estimation SAmple Consensus (MLESAC) outlier removal to find the most reliable keypoints. Second, the optimal transformation parameters obtained from first step are fed to the Normalised Mutual Information (NMI) algorithm as an initial solution. With modified Marquardt-Levenberg search strategy in a multiscale framework, the NMI can find the optimal transformation parameters in the shortest time. The proposed methodology has been tested on two different datasets - one with real wireless endoscopic images and another with images obtained from Micro-Ball (a new wireless cubic endoscopy system with six image sensors). The results have demonstrated the accuracy and robustness of the proposed methodology both visually and quantitatively - registration residual error of 0.93±0.33 pixels on 2500 real endoscopy image pairs and residual error accumulation of 16.59 pixels and without affecting the visual registration quality on stitching 152 images of Micro-Ball.

Image registration, Image stitching, Wireless endoscopy
0010-4825
54-63
Attar, Rahman
f5efd538-042a-4647-9d46-1370d3049b72
Xie, Xiang
df1bf1bb-92ac-410b-9b16-d7b029e91972
Wang, Zhihua
3ce1b58e-105e-428e-82c0-0358269cae75
Yue, Shigang
1da026a7-21db-4328-bfa1-b1cb30040143
Attar, Rahman
f5efd538-042a-4647-9d46-1370d3049b72
Xie, Xiang
df1bf1bb-92ac-410b-9b16-d7b029e91972
Wang, Zhihua
3ce1b58e-105e-428e-82c0-0358269cae75
Yue, Shigang
1da026a7-21db-4328-bfa1-b1cb30040143

Attar, Rahman, Xie, Xiang, Wang, Zhihua and Yue, Shigang (2019) 2D reconstruction of small intestine's interior wall. Computers in Biology and Medicine, 105, 54-63. (doi:10.1016/j.compbiomed.2018.12.001).

Record type: Article

Abstract

Examining and interpreting of a large number of wireless endoscopic images from the gastrointestinal tract is a tiresome task for physicians. A practical solution is to automatically construct a two dimensional representation of the gastrointestinal tract for easy inspection. However, little has been done on wireless endoscopic image stitching, let alone systematic investigation. The proposed new wireless endoscopic image stitching method consists of two main steps to improve the accuracy and efficiency of image registration. First, the keypoints are extracted by Principle Component Analysis and Scale Invariant Feature Transform (PCA-SIFT) algorithm and refined with Maximum Likelihood Estimation SAmple Consensus (MLESAC) outlier removal to find the most reliable keypoints. Second, the optimal transformation parameters obtained from first step are fed to the Normalised Mutual Information (NMI) algorithm as an initial solution. With modified Marquardt-Levenberg search strategy in a multiscale framework, the NMI can find the optimal transformation parameters in the shortest time. The proposed methodology has been tested on two different datasets - one with real wireless endoscopic images and another with images obtained from Micro-Ball (a new wireless cubic endoscopy system with six image sensors). The results have demonstrated the accuracy and robustness of the proposed methodology both visually and quantitatively - registration residual error of 0.93±0.33 pixels on 2500 real endoscopy image pairs and residual error accumulation of 16.59 pixels and without affecting the visual registration quality on stitching 152 images of Micro-Ball.

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More information

Published date: February 2019
Additional Information: Funding Information: This work was supported by: EU FP7 projects EYE2E (Grant No. 269118 ) and LIVCODE (Grant No. 295151 ); EU Horizon 2020 projects ENRICHME ( Grant No. 643691 ) and STEP2DYNA ( Grant No. 691154 ). Publisher Copyright: © 2018
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Keywords: Image registration, Image stitching, Wireless endoscopy
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Identifiers

Local EPrints ID: 479097
URI: http://eprints.soton.ac.uk/id/eprint/479097
DOI: doi:10.1016/j.compbiomed.2018.12.001
ISSN: 0010-4825
PURE UUID: 44bb4a4e-8b11-48f2-989e-001888cd4121

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Date deposited: 20 Jul 2023 16:33
Last modified: 17 Mar 2024 13:18

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Contributors

Author: Rahman Attar
Author: Xiang Xie
Author: Zhihua Wang
Author: Shigang Yue

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