Optimal Procedure Planning and Guidance System for Peripheral Bronchoscopy

Gibbs, Jason D.; Graham, Michael W.; Bascom, Rebecca; Cornish, Duane C.; Khare, Rahul; Higgins, William E.

doi:10.1109/tbme.2013.2285627

Cited by 27 publications

(75 citation statements)

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“…MDCT Analysis: Use existing methods to automatically segment the 3D airway tree, define the airway endoluminal surfaces, and compute the airway centerlines. [27][28][29][30] This gives an MDCT-based chest model. The final output consists of a multimodal data structure that establishes linkages between the video data and specific 3D locations within the MDCT-based chest model.…”

Section: Methodsmentioning

confidence: 99%

“…First, Bronchoscopy Path-History Construction employs the processing flow below: (a) Interactively locate an MDCT-based endoluminal rendering I Θ CT that appears to be at approximately the same airway-tree pose as I K (i), where Θ is the standard 6-parameter pose vector indicating the virtual camera's field of view within the MDCT-based airway tree. 8,30 (b) Apply CT-video registration to the image pair {I Θ CT , I K (i)} to arrive at a pose Θ i that aligns the MDCT-based virtual space and real space (as imaged by the video); i.e., after registration, the following relationship holds:…”

Section: Final Model Construction Stepsmentioning

confidence: 99%

“…Since the tree structure produced by these methods involves an ordered hierarchy of airway branches and associated view sites, the computation of the bronchoscopy path history is straightforward. 30 CT-video registration (step 1. (b)) uses the heavily validated method of Merritt et al 8 Finally, in CT-Video Model Construction, we use the previously developed methodology of Rai and Higgins for video-to-CT texture mapping.…”

Section: Final Model Construction Stepsmentioning

confidence: 99%

“…The system builds upon our previous CT-video efforts described by Higgins et al 7,8,27,30 In particular, we augment this system to allow for the storage and interaction of all data elements in the model. Next, we have made initial prototypes of the following tools: 1.…”

Section: Interactive Visualization Systemmentioning

confidence: 99%

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Construction of a multimodal CT-video chest model

Byrnes

Higgins

2014

SPIE Proceedings

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Bronchoscopy enables a number of minimally invasive chest procedures for diseases such as lung cancer and asthma. For example, using the bronchoscope's continuous video stream as a guide, a physician can navigate through the lung airways to examine general airway health, collect tissue samples, or administer a disease treatment. In addition, physicians can now use new image-guided intervention (IGI) systems, which draw upon both three-dimensional (3D) multi-detector computed tomography (MDCT) chest scans and bronchoscopic video, to assist with bronchoscope navigation. Unfortunately, little use is made of the acquired video stream, a potentially invaluable source of information. In addition, little effort has been made to link the bronchoscopic video stream to the detailed anatomical information given by a patient's 3D MDCT chest scan. We propose a method for constructing a multimodal CT-video model of the chest. After automatically computing a patient's 3D MDCT-based airway-tree model, the method next parses the available video data to generate a positional linkage between a sparse set of key video frames and airway path locations. Next, a fusion/mapping of the video's color mucosal information and MDCT-based endoluminal surfaces is performed. This results in the final multimodal CT-video chest model. The data structure constituting the model provides a history of those airway locations visited during bronchoscopy. It also provides for quick visual access to relevant sections of the airway wall by condensing large portions of endoscopic video into representative frames containing important structural and textural information. When examined with a set of interactive visualization tools, the resulting fused data structure provides a rich multimodal data source. We demonstrate the potential of the multimodal model with both phantom and human data.

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Section: Methodsmentioning

confidence: 99%

Section: Final Model Construction Stepsmentioning

confidence: 99%

Section: Final Model Construction Stepsmentioning

confidence: 99%

Section: Interactive Visualization Systemmentioning

confidence: 99%

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Construction of a multimodal CT-video chest model

Byrnes

Higgins

2014

SPIE Proceedings

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“…4,5,7,8 With such a system, a patient's X-ray computed tomography (CT) scan is used to plan a procedure to regions of interest (ROIs); this plan is then used during follow-on guided bronchoscopy. Recent clinical guidelines for lung cancer, however, now also dictate using positron emission tomography (PET) imaging for identifying suspicious ROIs and aiding in the cancer-staging process.…”

Section: Introductionmentioning

confidence: 99%

Image-guided endobronchial ultrasound

et al. 2016

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Endobronchial ultrasound (EBUS) is now recommended as a standard procedure for in vivo verification of extraluminal diagnostic sites during cancer-staging bronchoscopy. Yet, physicians vary considerably in their skills at using EBUS effectively. Regarding existing bronchoscopy guidance systems, studies have shown their effectiveness in the lung-cancer management process. With such a system, a patient's X-ray computed tomography (CT) scan is used to plan a procedure to regions of interest (ROIs). This plan is then used during follow-on guided bronchoscopy. Recent clinical guidelines for lung cancer, however, also dictate using positron emission tomography (PET) imaging for identifying suspicious ROIs and aiding in the cancer-staging process. While researchers have attempted to use guided bronchoscopy systems in tandem with PET imaging and EBUS, no true EBUS-centric guidance system exists. We now propose a full multimodal image-based methodology for guiding EBUS. The complete methodology involves two components: 1) a procedure planning protocol that gives bronchoscope movements appropriate for live EBUS positioning; and 2) a guidance strategy and associated system graphical user interface (GUI) designed for image-guided EBUS. We present results demonstrating the operation of the system.

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