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Autori principali: Ali, Sharib, Espinel, Yamid, Jin, Yueming, Liu, Peng, Güttner, Bianca, Zhang, Xukun, Zhang, Lihua, Dowrick, Tom, Clarkson, Matthew J., Xiao, Shiting, Wu, Yifan, Yang, Yijun, Zhu, Lei, Sun, Dai, Li, Lan, Pfeiffer, Micha, Farid, Shahid, Maier-Hein, Lena, Buc, Emmanuel, Bartoli, Adrien
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2401.15753
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author Ali, Sharib
Espinel, Yamid
Jin, Yueming
Liu, Peng
Güttner, Bianca
Zhang, Xukun
Zhang, Lihua
Dowrick, Tom
Clarkson, Matthew J.
Xiao, Shiting
Wu, Yifan
Yang, Yijun
Zhu, Lei
Sun, Dai
Li, Lan
Pfeiffer, Micha
Farid, Shahid
Maier-Hein, Lena
Buc, Emmanuel
Bartoli, Adrien
author_facet Ali, Sharib
Espinel, Yamid
Jin, Yueming
Liu, Peng
Güttner, Bianca
Zhang, Xukun
Zhang, Lihua
Dowrick, Tom
Clarkson, Matthew J.
Xiao, Shiting
Wu, Yifan
Yang, Yijun
Zhu, Lei
Sun, Dai
Li, Lan
Pfeiffer, Micha
Farid, Shahid
Maier-Hein, Lena
Buc, Emmanuel
Bartoli, Adrien
contents Augmented reality for laparoscopic liver resection is a visualisation mode that allows a surgeon to localise tumours and vessels embedded within the liver by projecting them on top of a laparoscopic image. Preoperative 3D models extracted from CT or MRI data are registered to the intraoperative laparoscopic images during this process. In terms of 3D-2D fusion, most of the algorithms make use of anatomical landmarks to guide registration. These landmarks include the liver's inferior ridge, the falciform ligament, and the occluding contours. They are usually marked by hand in both the laparoscopic image and the 3D model, which is time-consuming and may contain errors if done by a non-experienced user. Therefore, there is a need to automate this process so that augmented reality can be used effectively in the operating room. We present the Preoperative-to-Intraoperative Laparoscopic Fusion Challenge (P2ILF), held during the Medical Imaging and Computer Assisted Interventions (MICCAI 2022) conference, which investigates the possibilities of detecting these landmarks automatically and using them in registration. The challenge was divided into two tasks: 1) A 2D and 3D landmark detection task and 2) a 3D-2D registration task. The teams were provided with training data consisting of 167 laparoscopic images and 9 preoperative 3D models from 9 patients, with the corresponding 2D and 3D landmark annotations. A total of 6 teams from 4 countries participated, whose proposed methods were evaluated on 16 images and two preoperative 3D models from two patients. All the teams proposed deep learning-based methods for the 2D and 3D landmark segmentation tasks and differentiable rendering-based methods for the registration task. Based on the experimental outcomes, we propose three key hypotheses that determine current limitations and future directions for research in this domain.
format Preprint
id arxiv_https___arxiv_org_abs_2401_15753
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle An objective comparison of methods for augmented reality in laparoscopic liver resection by preoperative-to-intraoperative image fusion
Ali, Sharib
Espinel, Yamid
Jin, Yueming
Liu, Peng
Güttner, Bianca
Zhang, Xukun
Zhang, Lihua
Dowrick, Tom
Clarkson, Matthew J.
Xiao, Shiting
Wu, Yifan
Yang, Yijun
Zhu, Lei
Sun, Dai
Li, Lan
Pfeiffer, Micha
Farid, Shahid
Maier-Hein, Lena
Buc, Emmanuel
Bartoli, Adrien
Computer Vision and Pattern Recognition
Artificial Intelligence
Graphics
Machine Learning
Augmented reality for laparoscopic liver resection is a visualisation mode that allows a surgeon to localise tumours and vessels embedded within the liver by projecting them on top of a laparoscopic image. Preoperative 3D models extracted from CT or MRI data are registered to the intraoperative laparoscopic images during this process. In terms of 3D-2D fusion, most of the algorithms make use of anatomical landmarks to guide registration. These landmarks include the liver's inferior ridge, the falciform ligament, and the occluding contours. They are usually marked by hand in both the laparoscopic image and the 3D model, which is time-consuming and may contain errors if done by a non-experienced user. Therefore, there is a need to automate this process so that augmented reality can be used effectively in the operating room. We present the Preoperative-to-Intraoperative Laparoscopic Fusion Challenge (P2ILF), held during the Medical Imaging and Computer Assisted Interventions (MICCAI 2022) conference, which investigates the possibilities of detecting these landmarks automatically and using them in registration. The challenge was divided into two tasks: 1) A 2D and 3D landmark detection task and 2) a 3D-2D registration task. The teams were provided with training data consisting of 167 laparoscopic images and 9 preoperative 3D models from 9 patients, with the corresponding 2D and 3D landmark annotations. A total of 6 teams from 4 countries participated, whose proposed methods were evaluated on 16 images and two preoperative 3D models from two patients. All the teams proposed deep learning-based methods for the 2D and 3D landmark segmentation tasks and differentiable rendering-based methods for the registration task. Based on the experimental outcomes, we propose three key hypotheses that determine current limitations and future directions for research in this domain.
title An objective comparison of methods for augmented reality in laparoscopic liver resection by preoperative-to-intraoperative image fusion
topic Computer Vision and Pattern Recognition
Artificial Intelligence
Graphics
Machine Learning
url https://arxiv.org/abs/2401.15753