Yaxuan Zhou1,2, Rachel L Eimen3, Eric J Seibel2, Audrey K Bowden3,4. 1. Department of Electrical and Computer EngineeringUniversity of Washington Seattle WA 98195 USA. 2. Human Photonics LaboratoryDepartment of Mechanical EngineeringUniversity of Washington Seattle WA 98195 USA. 3. Department of Biomedical EngineeringVanderbilt University Nashville TN 37232 USA. 4. Department of Electrical Engineering and Computer ScienceVanderbilt University Nashville TN 37232 USA.
Abstract
OBJECTIVE: 3D reconstruction of the shape and texture of hollow organs captured by endoscopy is important for the diagnosis and surveillance of early and recurrent cancers. Better evaluation of 3D reconstruction pipelines developed for such applications requires easy access to extensive datasets and associated ground truths, cost-efficient and scalable simulations of a range of possible clinical scenarios, and more reliable and insightful metrics to assess performance. METHODS: We present a computer-aided simulation platform for cost-effective synthesis of monocular endoscope videos and corresponding ground truths that mimic a range of potential settings and situations one might encounter during acquisition of clinical endoscopy videos. Using cystoscopy of the bladder as model case, we generated an extensive dataset comprising several synthesized videos of a bladder phantom. We then introduce a novel evaluation procedure to reliably assess an individual 3D reconstruction pipeline or to compare different pipelines. RESULTS: To illustrate the use of the proposed platform and evaluation procedure, we use the aforementioned dataset and ground truths to evaluate a proprietary 3D reconstruction pipeline (CYSTO3D) for bladder cystoscopy videos and compared it with a general-purpose 3D reconstruction pipeline (COLMAP). The evaluation results provide insight into the suggested clinical acquisition protocol and several potential areas for refinement of the pipeline to improve future performance. CONCLUSION: Our work proposes an endoscope video synthesis and reconstruction evaluation toolset and presents experimental results that illustrate usage of the toolset to efficiently assess performance and reveal possible problems of any given 3D reconstruction pipeline, to compare different pipelines, and to provide technically or clinically actionable insights.
OBJECTIVE: 3D reconstruction of the shape and texture of hollow organs captured by endoscopy is important for the diagnosis and surveillance of early and recurrent cancers. Better evaluation of 3D reconstruction pipelines developed for such applications requires easy access to extensive datasets and associated ground truths, cost-efficient and scalable simulations of a range of possible clinical scenarios, and more reliable and insightful metrics to assess performance. METHODS: We present a computer-aided simulation platform for cost-effective synthesis of monocular endoscope videos and corresponding ground truths that mimic a range of potential settings and situations one might encounter during acquisition of clinical endoscopy videos. Using cystoscopy of the bladder as model case, we generated an extensive dataset comprising several synthesized videos of a bladder phantom. We then introduce a novel evaluation procedure to reliably assess an individual 3D reconstruction pipeline or to compare different pipelines. RESULTS: To illustrate the use of the proposed platform and evaluation procedure, we use the aforementioned dataset and ground truths to evaluate a proprietary 3D reconstruction pipeline (CYSTO3D) for bladder cystoscopy videos and compared it with a general-purpose 3D reconstruction pipeline (COLMAP). The evaluation results provide insight into the suggested clinical acquisition protocol and several potential areas for refinement of the pipeline to improve future performance. CONCLUSION: Our work proposes an endoscope video synthesis and reconstruction evaluation toolset and presents experimental results that illustrate usage of the toolset to efficiently assess performance and reveal possible problems of any given 3D reconstruction pipeline, to compare different pipelines, and to provide technically or clinically actionable insights.
Entities:
Keywords:
3D surface reconstruction; Virtual 3D endoscopy; computer evaluation; medical simulation; video synthesis
Authors: Mingxing Hu; Graeme Penney; Michael Figl; Philip Edwards; Fernando Bello; Roberto Casula; Daniel Rueckert; David Hawkes Journal: Med Image Anal Date: 2010-12-10 Impact factor: 8.545
Authors: Rosebet Miranda-Luna; Christian Daul; Walter C P M Blondel; Yahir Hernandez-Mier; Didier Wolf; François Guillemin Journal: IEEE Trans Biomed Eng Date: 2008-02 Impact factor: 4.538
Authors: Óscar G Grasa; Ernesto Bernal; Santiago Casado; Ismael Gil; J M M Montiel Journal: IEEE Trans Med Imaging Date: 2013-09-20 Impact factor: 10.048