4-D Imaging in cerebrovascular disorders by using 320-slice CT: feasibility and preliminary clinical experience.

RATIONALE AND OBJECTIVES The authors report study protocols and initial clinical experience in assessing patients with acute and chronic cerebrovascular disorders using the recently introduced technique of volume computed tomography (VCT). MATERIALS AND METHODS Thirteen patients with presumptive cerebrovascular insufficiency underwent VCT using a 320-slice scanner (detector width, 160 mm), including time-resolved whole-brain perfusion and cerebral angiography (four-dimensional computed tomographic angiography [CTA] and computed tomographic perfusion [CTP]). Unenhanced cranial CT (cCT) and helical cervicocranial CT (three-dimensional CTA) were added according to clinical requirements. Study protocols are presented, and image quality, data management, and radiation exposure issues are discussed. RESULTS In 12 of 13 patients, the procedure was performed successfully on admission; in the other patient, the study was aborted for clinical reasons and repeated. Total scan time amounted to about 5 minutes, and data reconstruction times were up to 10 minutes. About 9000 primary images were generated, partially in the enhanced Digital Imaging and Communications in Medicine format, thus requiring new data postprocessing and management strategies. Image artifacts restricted the use of single-rotation cCT and incremental VCT (three-dimensional CTA). Overall exposure figures (computed tomographic dose index and dose-length product) were increased by 65% on average when three-dimensional CTA was added to volume cCT and four-dimensional CTA and CTP (5.0 mSv and 2178 mGy . cm, respectively). CONCLUSION Preliminary clinical experience indicates that whole-brain four-dimensional CTA and CTP is a robust technique that provides relevant clinical information with respect to whole-brain perfusion as well as cerebral hemodynamics. The exposure benefit of deriving time-resolved perfusion and vessel images from one source data set is compromised when adding three-dimensional CTA to the protocol. Other acquisition techniques specific to VCT, such as single-rotation cCT and incremental three-dimensional CTA, suffer from restrictions in terms of image quality at present.

[1]  M Cohnen,et al.  Radiation exposure of patients in comprehensive computed tomography of the head in acute stroke. , 2006, AJNR. American journal of neuroradiology.

[2]  Bernd Hamm,et al.  Three-vessel coronary artery disease examined with 320-slice computed tomography coronary angiography. , 2008, European heart journal.

[3]  Sung Hyun Kim,et al.  Perfusion CT of the brain using 40-mm-wide detector and toggling table technique for initial imaging of acute stroke. , 2008, AJR. American journal of roentgenology.

[4]  H. Bauknecht,et al.  Comparative evaluation of 64-slice CT angiography and digital subtraction angiography in assessing the cervicocranial vasculature , 2008, Vascular health and risk management.

[5]  M. Wintermark Brain perfusion-CT in acute stroke patients , 2005, European radiology.

[6]  W P Dillon,et al.  Multisection dynamic CT perfusion for acute cerebral ischemia: the "toggling-table" technique. , 2001, AJNR. American journal of neuroradiology.

[7]  K Murase,et al.  Comparison of patient doses in 256-slice CT and 16-slice CT scanners. , 2006, The British journal of radiology.

[8]  R. Klingebiel,et al.  Multi-slice CT angiography in the evaluation of patients with acute cerebrovascular disease – a promising new diagnostic tool , 2002, Journal of Neurology.

[9]  T. Obata,et al.  Volumetric perfusion CT using prototype 256-detector row CT scanner: preliminary study with healthy porcine model. , 2005, AJNR. American journal of neuroradiology.