Abstract

? This competitive renewal continues the goal of devising a computer-based virtual-endoscopic system for more effective lung-cancer assessment. It is driven by the following hypothesis: A synergistic combination of 3D MDCT imaging, image processing, and bronchoscopy improves current procedures for the staging, diagnosis, and treatment of lung cancer. The system devised to date known as the Virtual Navigator combines three-dimensional (3D) multidetector computed tomography (MDCT) imaging and bronchoscopy. It has shown great promise for 3D pulmonary CT image assessment and for image-guided bronchoscopic biopsy within the mediastinum. The objectives of this renewal are to build on these successes. In particular we now propose to develop and test methods that enable: (1) comprehensive nonsurgical staging of the mediastinal lymph nodes; (2) extension of our basic guidance system for the bronchoscopic biopsy of peripheral lung nodules; (3) positive characterization and selection of lung nodules needing biopsy. The project's specific aims are as follows:
Aim 1 -- Devise computer-based methods for planning and guiding the bronchoscopic biopsy of peripheral lung nodules and mediastinal lymph nodes, thereby reducing the number of surgical biopsies and nodule resections and enabling less-invasive mediastinal lymph-node staging.
Aim 2 -- Devise methods for MDCT-based analysis of diagnostically important pulmonary structures, thereby enabling more thorough and effective use of MDCT images.
Aim 4 -- Perform human studies to compare the complete system to standard practice. Recent studies applying CT to population-based screening of at-risk smokers yield a large number of subjects with pulmonary nodules, as well as subjects with asymptomatic mediastinal lymph node enlargement. Most of these nodules and lymphadenomegaly will not be due to cancer. Further, bronchoscopic biopsy of small peripheral nodules and 1-2 cm lymph nodes have low yield, because of the considerable skill needed in traversing the 3D airway structure and the difficulty in making judgments on blind sites. Transcutaneous needle biopsy also has low yield for small nodules and has other potential complications. This leaves surgical removal, which has many drawbacks in terms of morbidity, cost, and the high rate of resecting benign structures. Finally, once lung cancer has been diagnosed, the impact of therapy and treatment remains largely unchanged over the last twenty years. Thus, methods are needed for: (1) early assessment of suspect lung pathologies; (2) planning and guidance of the biopsy procedure to improve yields and consequently improve early diagnosis and staging; and (3) accurate delivery of new therapies directly into the lung tumor nodule or involved lymph nodes. This competitive renewal proposes such methods. If successful, the project will have a major impact on the management of lung nodules detected by lung cancer screening or other MDCT applications to the lung, and on the appropriate staging of lung cancer. Finally, the methods should be generalizable to other organ systems, in particular to applications in neurology, urology, gynecology and gastroenterology. ? ?

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Cancer Institute (NCI)
Type
Research Project (R01)
Project #
5R01CA074325-08
Application #
6898400
Study Section
Diagnostic Imaging Study Section (DMG)
Program Officer
Farahani, Keyvan
Project Start
1997-05-01
Project End
2008-05-31
Budget Start
2005-06-01
Budget End
2006-05-31
Support Year
8
Fiscal Year
2005
Total Cost
$329,457
Indirect Cost

  Institution

Name
Pennsylvania State University
Department
Engineering (All Types)
Type
Schools of Engineering
DUNS #
003403953
City
University Park
State
PA
Country
United States
Zip Code
16802

  Publications

Khare, Rahul; Bascom, Rebecca; Higgins, William E (2015) Hands-Free System for Bronchoscopy Planning and Guidance. IEEE Trans Biomed Eng 62:2794-811
Gibbs, Jason D; Graham, Michael W; Bascom, Rebecca et al. (2014) Optimal procedure planning and guidance system for peripheral bronchoscopy. IEEE Trans Biomed Eng 61:638-57
Merritt, Scott A; Khare, Rahul; Bascom, Rebecca et al. (2013) Interactive CT-video registration for the continuous guidance of bronchoscopy. IEEE Trans Med Imaging 32:1376-96
Graham, Michael W; Gibbs, Jason D; Higgins, William E (2012) Computer-based route-definition system for peripheral bronchoscopy. J Digit Imaging 25:307-17
Lu, Kongkuo; Taeprasartsit, Pinyo; Bascom, Rebecca et al. (2011) Automatic definition of the central-chest lymph-node stations. Int J Comput Assist Radiol Surg 6:539-55
Lu, Kongkuo; Higgins, William E (2011) Segmentation of the central-chest lymph nodes in 3D MDCT images. Comput Biol Med 41:780-9
Yu, Kun-Chang; Gibbs, Jason D; Graham, Michael W et al. (2010) Image-based reporting for bronchoscopy. J Digit Imaging 23:39-50
Graham, Michael W; Gibbs, Jason D; Cornish, Duane C et al. (2010) Robust 3-D airway tree segmentation for image-guided peripheral bronchoscopy. IEEE Trans Med Imaging 29:982-97
Gibbs, Jason D; Graham, Michael W; Higgins, William E (2009) 3D MDCT-based system for planning peripheral bronchoscopic procedures. Comput Biol Med 39:266-79
Higgins, William E; Helferty, James P; Lu, Kongkuo et al. (2008) 3D CT-video fusion for image-guided bronchoscopy. Comput Med Imaging Graph 32:159-73

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