2D/3D deformable registration for endoscopic camera images using self-supervised offline learning of intraoperative pneumothorax deformation

Shape registration of patient-specific organ shapes to endoscopic camera images is expected to be a key to realizing image-guided surgery, and a variety of applications of machine learning methods have been considered. Because the number of training data available from clinical cases is limited, the...

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Bibliographic Details
Published in:Computerized medical imaging and graphics 2024-09, Vol.116, p.102418, Article 102418
Main Authors: Oya, Tomoki, Kadomatsu, Yuka, Chen-Yoshikawa, Toyofumi Fengshi, Nakao, Megumi
Format: Article
Language:English
Subjects:
2D/3D deformable registration
Endoscopic image
Endoscopy - methods
Humans
Imaging, Three-Dimensional - methods
Pneumothorax - diagnostic imaging
Pneumothorax deformation
Self-supervised learning
Supervised Machine Learning
Surgery, Computer-Assisted - methods
Thoracoscopic surgery
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Summary:Shape registration of patient-specific organ shapes to endoscopic camera images is expected to be a key to realizing image-guided surgery, and a variety of applications of machine learning methods have been considered. Because the number of training data available from clinical cases is limited, the use of synthetic images generated from a statistical deformation model has been attempted; however, the influence on estimation caused by the difference between synthetic images and real scenes is a problem. In this study, we propose a self-supervised offline learning framework for model-based registration using image features commonly obtained from synthetic images and real camera images. Because of the limited number of endoscopic images available for training, we use a synthetic image generated from the nonlinear deformation model that represents possible intraoperative pneumothorax deformations. In order to solve the difficulty in estimating deformed shapes and viewpoints from the common image features obtained from synthetic and real images, we attempted to improve the registration error by adding the shading and distance information that can be obtained as prior knowledge in the synthetic image. Shape registration with real camera images is performed by learning the task of predicting the differential model parameters between two synthetic images. The developed framework achieved registration accuracy with a mean absolute error of less than 10 mm and a mean distance of less than 5 mm in a thoracoscopic pulmonary cancer resection, confirming improved prediction accuracy compared with conventional methods. •2D/3D model-based deformable registration for highly occluded endoscopic camera images.•Self-supervised offline learning using a data-driven pneumothorax deformation model.•Use of common image features to transfer the self-supervised model to real scenes.•Performance analysis and application to image-guided pulmonary resection.
ISSN:0895-6111
1879-0771
1879-0771
DOI:10.1016/j.compmedimag.2024.102418