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Your search keyword '"Cone beam reconstruction"' showing total 5 results
Start Over Descriptor "Cone beam reconstruction" Publisher elsevier bv
5 results on '"Cone beam reconstruction"'

1. Image-guided radiotherapy using a mobile kilovoltage x-ray device

Author

Timothy D. Solberg, Paul M. Medin, Sergey Kriminski, P Chow, and Stephen P. Sorensen

Subjects
Cone beam computed tomography, Tomography Scanners, X-Ray Computed, Radiological and Ultrasound Technology, Phantoms, Imaging, Computer science, Image quality, business.industry, Radiotherapy Planning, Computer-Assisted, Isocenter, Imaging phantom, Oncology, Respiratory Mechanics, Humans, Radiology, Nuclear Medicine and imaging, Tomography, X-Ray Computed, Fiducial marker, Nuclear medicine, business, Image resolution, Biomedical engineering, Image-guided radiation therapy, Cone beam reconstruction
Abstract

— A mobile isocentric C-arm kilovoltage imager has been evaluated as a potential tool for image-guided radiotherapy. The C-arm is equipped with an amorphous silicon flat panel for high-quality image acquisition. Additionally, the device is capable of cone beam computed tomography (CT) and volumetric reconstruction. This is achieved through the application of a modified Feldkamp algorithm with acquisition over a 180° scan arc. The number of projections can be varied from 100 to 1000, resulting in a reconstructed volume 20 cm in diameter by 15-cm long. While acquisition time depends upon number of projections, acceptable quality images can be obtained in less than 60 seconds. Image resolution and contrast of cone-beam phantom images have been compared with images from a conventional CT scanner. The system has a spatial resolution of ≥ 10 lp/cm and resolution is approximately equal in all 3 dimensions. Conversely, subject contrast is poorer than conventional CT, compromised by the increased scatter and underlying noise inherent in cone beam reconstruction, as well as the absence of filtering prior to reconstruction. The mobility of the C-arm makes it necessary to determine the C-arm position relative to the linear accelerator isocenter. Two solutions have been investigated: (1) the use of fiducial markers, embedded in the linac couch, that can subsequently be registered in the image sets; and (2), a navigation approach for infrared tracking of the C-arm relative to the linac isocenter. Observed accuracy in phantom positioning ranged from 1.0 to 1.5 mm using the navigation approach and 1.5 to 2.5 mm using the fiducial-based approach. As part of this work, the impact of respiratory motion on cone-beam image quality was evaluated, and a scheme for retrospective gating was devised. Results demonstrated that kilovoltage cone beam CT provides spatial integrity and resolution comparable to conventional CT. Cone-beam CT studies of patients undergoing radiotherapy have demonstrated acceptable soft tissue contrast, allowing assessment of daily changes in target anatomy. Of the 2 approaches developed to register images to the linac isocenter, the navigation method demonstrated superior accuracy for daily patient positioning relative to the fiducial-based method. Finally, significant image degradation due to respiratory motion was observed. It was demonstrated that this could be improved by correlating the acquisition of individual 2D projections with respiration for retrospective reconstruction of phase-based volumetric datasets.

Published
2006
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2. 3D histomorphometric quantification from 3D computed tomography

Author

L. F. de Oliveira and Ricardo Tadeu Lopes

Subjects
Physics, Nuclear and High Energy Physics, business.industry, Radiography, Context (language use), Sample (graphics), visual_art, visual_art.visual_art_medium, Ceramic, Tomography, business, Anisotropy, Instrumentation, Cone beam reconstruction, Biomedical engineering, Volume (compression)
Abstract

The histomorphometric analysis is based on stereologic concepts and was originally applied to biologic samples. This technique has been used to evaluate different complex structures such as ceramic filters, net structures and cancellous objects that are objects with inner connected structures. The measured histomorphometric parameters of structure are: sample volume to total reconstructed volume (BV/TV), sample surface to sample volume (BS/BV), connection thickness (Tb Th ), connection number (Tb N ) and connection separation (Tb Sp ). The anisotropy was evaluated as well. These parameters constitute the base of histomorphometric analysis. The quantification is realized over cross-sections recovered by cone beam reconstruction, where a real-time microfocus radiographic system is used as tomographic system. The three-dimensional (3D) histomorphometry, obtained from tomography, corresponds to an evolution of conventional method that is based on 2D analysis. It is more coherent with morphologic and topologic context of the sample. This work shows result from 3D histomorphometric quantification to characterize objects examined by 3D computer tomography. The results, which characterizes the internal structures of ceramic foams with different porous density, are compared to results from conventional methods.

Published
2004
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3. First results of micro-neutron tomography by use of a focussing neutron lens

Author

Willy Mondelaers, S Baechler, Manuel Dierick, J. Jolie, Peter Cauwels, and Bert Masschaele

Subjects
Physics, Radiation, business.industry, Astrophysics::High Energy Astrophysical Phenomena, Neutron imaging, Nuclear Theory, Neutron tomography, law.invention, Nuclear physics, Lens (optics), Optics, law, Industrial radiography, Neutron flux, Physics::Accelerator Physics, Neutron detection, Neutron, Nuclear Experiment, business, Cone beam reconstruction
Abstract

Since the appearance of high flux neutron beams, scientists experimented with neutron radiography. This high beam flux combined with modern neutron to visible light converters leads to the possibility of performing fast neutron micro-tomography. The first results of cold neutron tomography with a neutron lens are presented in this article. Samples are rotated in the beam and the projections are recorded with a neutron camera. The 3D reconstruction is performed with cone beam reconstruction software.

Published
2001
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