Digital Subtraction Angiography : Implementation and Demonstration of Feasibility

BACKGROUND AND PURPOSE: Conventional 3D-DSA volumes are reconstructed from a series of projections containing temporal information. It was our purpose to develop a technique which would generate fully time-resolved 3D-DSA vascular volumes having better spatial and temporal resolution than that which is available with CT or MR angiography. MATERIALS AND METHODS: After a single contrast injection, projections from the mask and fill rotation are subtracted to create a series of vascular projections. With the use of these projections, a conventional conebeam CT reconstruction is generated (conventional 3D-DSA). This is used to constrain the reconstruction of individual 3D temporal volumes, which incorporate temporal information from the acquired projections (4D-DSA). RESULTS: Typically, 30 temporal volumes per second are generated with the use of currently available flat detector systems, a factor of ∼200 increase over that achievable with the use of multiple gantry rotations. Dynamic displays of the reconstructed volumes are viewable from any angle. Good results have been obtained by using both intra-arterial and intravenous injections. CONCLUSIONS: It is feasible to generate time-resolved 3D-DSA vascular volumes with the use of commercially available flat detector angiographic systems and clinically practical injection protocols. The spatial resolution and signal-to-noise ratio of the time frames are largely determined by that of the conventional 3D-DSA constraining image and not by that of the projections used to generate the 3D reconstruction. The spatial resolution and temporal resolution exceed that of CTA and MRA, and the small vessel contrast is increased relative to that of conventional 2D-DSA due to the use of maximum intensity projections.

[1]  M. McNitt-Gray,et al.  Computed tomography dose assessment for a 160 mm wide, 320 detector row, cone beam CT scanner , 2009, Physics in medicine and biology.

[2]  Charles A. Mistretta,et al.  4D-DSA and 4D fluoroscopy: preliminary implementation , 2010, Medical Imaging.

[3]  R A Kruger,et al.  Clinical applications of computerized fluoroscopy: the extracranial carotid arteries. , 1980, Radiology.

[4]  M. Kowarschik,et al.  Monitoring Peri-Therapeutic Cerebral Circulation Time: A Feasibility Study Using Color-Coded Quantitative DSA in Patients with Steno-Occlusive Arterial Disease , 2012, American Journal of Neuroradiology.

[5]  Kevin M. Johnson,et al.  Time resolved contrast enhanced intracranial MRA using a single dose delivered as sequential injections and highly constrained projection reconstruction (HYPR CE) , 2011, Magnetic resonance in medicine.

[6]  R A Kruger,et al.  Computer simulation of image intensifier-based computed tomography detector: vascular application. , 1988, Medical physics.

[7]  S J Riederer,et al.  Computerized fluoroscopy in real time for noninvasive visualization of the cardiovascular system. Preliminary studies. , 1979, Radiology.

[8]  C. A. Mistretta,et al.  Computerized Fluoroscopy Techniques For Non-Invasive Cardiovascular Imaging , 1978, Optics & Photonics.

[9]  R Fahrig,et al.  Cerebral CT Perfusion Using an Interventional C-Arm Imaging System: Cerebral Blood Flow Measurements , 2011, American Journal of Neuroradiology.

[10]  R A Kruger,et al.  Image intensifier-based computed tomography volume scanner for angiography. , 1996, Academic radiology.

[11]  M Zellerhoff,et al.  Parametric Color Coding of Digital Subtraction Angiography , 2010, American Journal of Neuroradiology.

[12]  D. Holdsworth,et al.  Use of a C-arm system to generate true three-dimensional computed rotational angiograms: preliminary in vitro and in vivo results. , 1997, AJNR. American journal of neuroradiology.

[13]  R Fahrig,et al.  Three-dimensional computed tomographic reconstruction using a C-arm mounted XRII: correction of image intensifier distortion. , 1997, Medical physics.