Three-dimensional human airway segmentation methods for clinical virtual bronchoscopy.
about
CT based computerized identification and analysis of human airways: a review3D MDCT-based system for planning peripheral bronchoscopic procedures.A differential geometric approach to automated segmentation of human airway treeHeterogeneity of specific gas volume changes: a new tool to plan lung volume reduction in COPD.Automatic segmentation of anatomical structures from CT scans of thorax for RTP.Automatic definition of the central-chest lymph-node stationsA "loop" shape descriptor and its application to automated segmentation of airways from CT scansComputational physiology and the Physiome Project.Airway Segmentation and Centerline Extraction from Thoracic CT - Comparison of a New Method to State of the Art Commercialized Methods.3D CT-video fusion for image-guided bronchoscopy.AUTOMATIC AIRWAY ANALYSIS FOR GENOME-WIDE ASSOCIATION STUDIES IN COPD.Investigation of hyperpolarized 3He magnetic resonance imaging utility in examining human airway diameter behavior in asthma through comparison with high-resolution computed tomographyInteractive CT-video registration for the continuous guidance of bronchoscopy.Airway and pulmonary vascular measurements using contrast-enhanced micro-CT in rodents.Optimizing parameters of an open-source airway segmentation algorithm using different CT images.Optimal procedure planning and guidance system for peripheral bronchoscopy.Hands-Free System for Bronchoscopy Planning and GuidanceSegmentation and quantitative analysis of intrathoracic airway trees from computed tomography images.Computer-based route-definition system for peripheral bronchoscopyFully automated system for three-dimensional bronchial morphology analysis using volumetric multidetector computed tomography of the chest.Computer-based System for the Virtual-Endoscopic Guidance of Bronchoscopy.Intrathoracic airway trees: segmentation and airway morphology analysis from low-dose CT scans.Automatic segmentation of airway tree based on local intensity filter and machine learning technique in 3D chest CT volume.Effect of total lung capacity, gender and height on CT airway measurements.Virtual bronchoscopy: comparison of different surface rendering models.Volumetric study of sphenoid sinuses: anatomical analysis in helical computed tomography.Robust bronchoscope motion tracking using sequential Monte Carlo methods in navigated bronchoscopy: dynamic phantom and patient validation.Thoracic cavity segmentation algorithm using multiorgan extraction and surface fitting in volumetric CT.3D airway tree reconstruction in healthy subjects and emphysema.CT-based geometry analysis and finite element models of the human and ovine bronchial tree.Maximizing quantitative accuracy of lung airway lumen and wall measures obtained from X-ray CT imaging.The use of MDCT-based computer-aided pathway finding for mediastinal and perihilar lymph node biopsy: a randomized controlled prospective trial.GPU based multi-histogram volume navigation for virtual bronchoscopy.
P2860
Q27015978-730DCE86-9982-44E2-A9B7-75B5426D5F3DQ30487292-A83CAB3C-322B-4C59-B858-A408E73D021FQ33349806-E810A31C-BC26-469C-BC69-280A81D6C309Q34609926-D189CA45-A9A0-4810-B2D2-52B871CFA8EFQ34799093-9B5B6047-E15E-4C66-9A96-93F8C14BCD67Q35036759-E8775EB9-8AB9-47A9-885D-9C9817489AD5Q35666149-1F8ED96F-1F39-48B2-A723-2DC0BB66B7BFQ35756255-4FD4D1F5-9AE5-4A2A-8CD0-789C4AEFC719Q35866485-CAB40B57-BD20-45CC-87CA-C999142951B1Q36535627-F1606AF5-5A45-4CBA-8FE8-E516EF8C945CQ36894897-AED7D656-4CCA-4D08-85B8-0A213FA2A51EQ36983747-ADFE2E3C-8296-4B0E-9D08-D272C4DA4159Q37547881-ABB35350-9BAF-479A-BBE8-073DCD23FEA4Q39438658-CBC2EBF5-42CB-486B-B2D8-BF18C5754914Q40795585-BA363927-4550-4F4B-A706-FE8A9D95A500Q41443360-8CA7181F-C8C0-431F-80C4-46A355AA949EQ41443371-74D5B149-269A-4684-ACA9-CD26B1DB6A83Q41990929-1D386B04-A02C-42D0-9E5F-CDE3C01819C5Q42594126-767E314F-D216-4D13-852E-0222860E0657Q42633745-5E014252-9770-4095-AD26-D8784C9486AFQ42793793-EE6131C7-EE5C-4611-A1A8-127E02C85696Q42854025-55EE28D4-840A-430D-9551-0BC25C3AE212Q45949637-4AC9BE69-B7BD-4177-96D2-4580A1067D09Q47206276-EEF7DDF8-666B-4C95-A2A9-184858E49ABBQ47870397-27539992-DC44-49D4-8803-E84E7E1CDEC6Q48002381-90A7ED0A-0890-450B-B5CA-E13FE1030863Q50675306-86CA779F-5F10-4C9B-8D50-1F7CD9689C69Q51097826-4C16421F-7D22-4D00-988A-B9E4988D2220Q51556250-2AE2E14A-FE5B-4693-A7A4-1CA87C817D55Q51991486-1E415F10-95FF-4BC1-B583-01CEB601DD07Q52016602-8B1E93BD-2D33-4633-9CBA-BF77CB315BD1Q53472050-FF39DBD0-2588-4D26-9FAD-E4811ABE8AF0Q54970569-2B8005E3-26F7-41FF-9181-3667463F45E2
P2860
Three-dimensional human airway segmentation methods for clinical virtual bronchoscopy.
description
2002 nî lūn-bûn
@nan
2002年の論文
@ja
2002年学术文章
@wuu
2002年学术文章
@zh
2002年学术文章
@zh-cn
2002年学术文章
@zh-hans
2002年学术文章
@zh-my
2002年学术文章
@zh-sg
2002年學術文章
@yue
2002年學術文章
@zh-hant
name
Three-dimensional human airway segmentation methods for clinical virtual bronchoscopy.
@en
Three-dimensional human airway segmentation methods for clinical virtual bronchoscopy.
@nl
type
label
Three-dimensional human airway segmentation methods for clinical virtual bronchoscopy.
@en
Three-dimensional human airway segmentation methods for clinical virtual bronchoscopy.
@nl
prefLabel
Three-dimensional human airway segmentation methods for clinical virtual bronchoscopy.
@en
Three-dimensional human airway segmentation methods for clinical virtual bronchoscopy.
@nl
P2093
P1433
P1476
Three-dimensional human airway segmentation methods for clinical virtual bronchoscopy
@en
P2093
Atilla P Kiraly
Geoffrey McLennan
William E Higgins
P304
P356
10.1016/S1076-6332(03)80517-2
P577
2002-10-01T00:00:00Z