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CiiS Lab
Johns Hopkins University
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Baltimore, MD 21218
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Russell Taylor
127 Hackerman Hall
rht@jhu.edu
Last checked: 05/08/13, 10:00 pm
The aim of this project is to construct brain phantoms and acquire CT images for a quantitative analysis and assessments of (a) image quality and (b) metal artifact removal algorithm application.
Clinical Background
Neurovascular interventions are minimally invasive interventional radiology procedures performed in blood vessels of head and neck for treatment of diseases such as aneurysms, intercranial stenosis, and arteriovenous malformations(AVMs). Treatment of these diseases, which include the use of clips, coils, stents and other metal-based materials, depend on 3D CT imaging acquisition in the surgical environment.
Technical Background
X-ray computed tomography (CT) is a radiographic imaging modality that uses reconstruction methods to create cross-sectional images from x-ray attenuation data. Artifacts is a terms that refers to any discrepancy between attenuation data of the reconstructed image and the true attenuation coefficient of the object. Metal artifacts are artifacts caused by the presence of dense metal materials in the object. These are caused mainly by a phenomenon called beam-hardening, which refers to the change of the mean energy of the exiting-photons energy spectrum due to the greater absorbance of lower-energy photons by the object. Metal artifacts can seriously degrade the image quality of a CT image. Metal Artifact Removal (MAR) algorithms have been developed to reduce and/or remove these artifacts, and are ready for clinical testing.
Specific Aims
1. Construction of anthropomorphic brain phantoms to simulate varying metal artifacts (coils, clips, etc) and the surrounding vasculature.
2. Image acquisition in C-arm Cone-Beam CT scanner.
3. Quantitative data analysis of image quality and segmentation accuracy.
4. MAR algorithm application, analysis and assessment.
Significance
Optimizing image quality through MAR algorithms will ensure a safer, more accurate use of CT imaging in the surgical environment for both diagnoses and treatments.
Available for the project is a hollow anthropomorphic head phantom, ‘scarecrow’, which can be filled with materials that can simulate cerebral tissue, contrast vasculature, metal materials used in surgical interventions (coils and/or clips), etc.
CT dual energy Cone-Beam imaging system available at the I-STAR lab, Johns Hopkins Medical Campus
C-arm Cone-Beam 3D CT imaging system available at the Interventional Radiology suite, Johns Hopkins Medical Campus
The project is comprised of four (Original plan: three) stages: each will consist of the construction of a brain phantom, acquisition of phantom images and the assessment and analysis of image quality and MAR algorithm data. Below are quantitative and/or measurable variables and parameters.
Manipulation of these variables will produce wanted measurable parameters (such as attenuation and contrast).
All scans were performed on a C-arm Cone-Beam Axiom Artis Zee (Axiom Artis Zeego, Siemens Medical Solutions, Elangen, Germany) with a standard DynaCT Head 20s 70keV acquisition.
The MAR algorithm will be available in the Syngo workstation (Software in the Zeego console). We will have constructed the phantom with objects of known size and shape in particular locations so that we will be able to accurately assess the precision of the MAR algorithm in improving the image. Parameters for quantifying the exact discrepancies in the reduction of metal artifacts will be developed as needed.
Note: 'planned date' refers to the planning period while 'expected date' refers to the end of the milestone.
Original Schedule
Revised Schedule
Materials last updated: 04/29 7:00pm
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[8] Prell, D., Y. Kyriakou, T. Struffert, A. Dorfler, and W. A. Kalender. “Metal Artifact Reduction for Clipping and Coiling in Interventional C-Arm CT.” American Journal of Neuroradiology 31.4 (2010): 634-39. Print.