Deformation correction for image guided liver surgery: An intraoperative fidelity assessment

Clements, Logan W.; Collins, Jerry C.; Weis, Jared A.; Simpson, Amber L.; Kingham, T. Peter; Jarnagin, William R.; Miga, Michael I.

doi:10.1016/j.surg.2017.04.020

Cited by 25 publications

(25 citation statements)

References 18 publications

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“…During hepatic surgery, they used real‐time data obtained from instruments tracked along the liver surface. They were then able to appropriately adjust the relationships of their preoperative models . Paulus et al introduced a physics‐based model in which a single monocular camera was used to detect topographical changes of anatomy due to deformation; the preoperative AR images were then adjusted accordingly .…”

Section: Discussionmentioning

confidence: 99%

Development of augmented‐reality applications in otolaryngology–head and neck surgery

et al. 2019

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Objectives/Hypothesis: Augmented reality (AR) allows for the addition of transparent virtual images and video to one's view of a physical environment. Our objective was to develop a head-worn, AR system for accurate, intraoperative localization of pathology and normal anatomic landmarks during open head and neck surgery.Study Design: Face validity and case study. Methods: A protocol was developed for the creation of three-dimensional (3D) virtual models based on computed tomography scans. Using the HoloLens AR platform, a novel system of registration and tracking was developed. Accuracy was determined in relation to actual physical landmarks. A face validity study was then performed in which otolaryngologists were asked to evaluate the technology and perform a simulated surgical task using AR image guidance. A case study highlighting the potential usefulness of the technology is also presented.Results: An AR system was developed for intraoperative 3D visualization and localization. The average error in measurement of accuracy was 2.47 AE 0.46 millimeters (1.99, 3.30). The face validity study supports the potential of this system to improve safety and efficiency in open head and neck surgical procedures.Conclusions: An AR system for accurate localization of pathology and normal anatomic landmarks of the head and neck is feasible with current technology. A face validity study reveals the potential value of the system in intraoperative image guidance. This application of AR, among others in the field of otolaryngology-head and neck surgery, promises to improve surgical efficiency and patient safety in the operating room.

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Section: Discussionmentioning

confidence: 99%

Development of augmented‐reality applications in otolaryngology–head and neck surgery

et al. 2019

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“…Both surface-based methods have demonstrated effective correction of soft-tissue deformation in phantom and clinical applications for hepatic resection. [26][27][28][29][30] With respect to thermal dose guidance, predictive, biophysical modeling of MWA presents a strong alternative to the manufacturer-provided estimates of ablation outcome by utilizing numerical approaches to solve the physical governing equations defining energy deposition and heat transfer. Other direct thermographic measurement strategies such as MR 31 and US 32 thermography are on the horizon, but these also have high technical and economic hurdles for practical use in the operating room or interventional suite.…”

Section: Localization and Therapy Guidancementioning

confidence: 99%

Multiphysics modeling toward enhanced guidance in hepatic microwave ablation: a preliminary framework

2019

J. Med. Imag.

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We compare a surface-driven, model-based deformation correction method to a clinically relevant rigid registration approach within the application of image-guided microwave ablation for the purpose of demonstrating improved localization and antenna placement in a deformable hepatic phantom. Furthermore, we present preliminary computational modeling of microwave ablation integrated within the navigational environment to lay the groundwork for a more comprehensive procedural planning and guidance framework. To achieve this, we employ a simple, retrospective model of microwave ablation after registration, which allows a preliminary evaluation of the combined therapeutic and navigational framework. When driving registrations with full organ surface data (i.e., as could be available in a percutaneous procedure suite), the deformation correction method improved average ablation antenna registration error by 58.9% compared to rigid registration (i.e., 2.5 AE 1.1 mm, 5.6 AE 2.3 mm of average target error for corrected and rigid registration, respectively) and on average improved volumetric overlap between the modeled and ground-truth ablation zones from 67.0 AE 11.8% to 85.6 AE 5.0% for rigid and corrected, respectively. Furthermore, when using sparse-surface data (i.e., as is available in an open surgical procedure), the deformation correction improved registration error by 38.3% and volumetric overlap from 64.8 AE 12.4% to 77.1 AE 8.0% for rigid and corrected, respectively. We demonstrate, in an initial phantom experiment, enhanced navigation in image-guided hepatic ablation procedures and identify a clear multiphysics pathway toward a more comprehensive thermal dose planning and deformation-corrected guidance framework.

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“…The depth information of LRS is matched with the model thanks to a modified Iterative Closest Point (ICP) algorithm. In [24] authors provides evidence of benefits of deformation correction with an evaluation across 20 patients. Nevertheless, the method remains sensitive to unavoidable occlusions of the liver (for instance by the hand of the surgeons), and the ICP may provide misscorrespondences for large deformations.…”

Section: Related Workmentioning

confidence: 99%

“…The initial registration (including segmentation of the contour and initial rigid alignment) has been performed in approximately 5 minutes (with a frame rate in the simulation of 40 FPS). Then the tracking method was applied for 10 minutes providing 2 For later investigation, the hardware part could be replaced by all in one commercial system such as the system used in [24] 3 The study was approved by the local ethics committee, and the patient gave informed consent prior to the procedure. convincing registration results even for large deformations and occlusions by the hands of surgeons or when the organ is pushed inside the abdominal cavity.…”

Section: Application To Liver Surgerymentioning

confidence: 99%

Marker-Based Registration for Large Deformations - Application to Open Liver Surgery

Adagolodjo

Golse

Vibert

et al. 2018

2018 IEEE International Conference on Robotics and Automation (ICRA)

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This paper introduces an Augmented Reality (AR) system for open liver surgery. Although open surgery remains the gold-standard for the treatment of complex tumors and central lesions, technological issues actually prevent using AR with sufficient accuracy for clinical use. We propose a markersbased method allowing for the tracking and the deformation of a preoperative model in real-time during the surgery. Markers are manually placed on the surface of the organ after opening the abdominal cavity, and tracked in real-time by a set of infrared cameras. Our framework is composed of both a nonrigid initial registration method, providing an estimation of the location of the markers in the preoperative model, and a realtime tracking algorithm to deform the model during the surgery (even for large deformation or partial occlusion of the organ). The method is validated on both synthetic and ex-vivo samples; in addition, we demonstrate its applicability in the operating room during a liver resection surgery on a human patient. Preliminary studies provided promising results to improve the location of tumors, and to help surgeons into planning the ideal resection intraoperatively.

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Deformation correction for image guided liver surgery: An intraoperative fidelity assessment

Cited by 25 publications

References 18 publications

Development of augmented‐reality applications in otolaryngology–head and neck surgery

Development of augmented‐reality applications in otolaryngology–head and neck surgery

Multiphysics modeling toward enhanced guidance in hepatic microwave ablation: a preliminary framework

Marker-Based Registration for Large Deformations - Application to Open Liver Surgery

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