(Circulation. 1999;100:e61-e62.)
© 1999 American Heart Association, Inc.
Circulation Electronic Pages |
Four-Dimensional Cardiac Image by Helical Computed Tomography
From the Departments of Cardiology (Y.K., H.M., H.K., K.I., T.I), Radiology (H.H.), and Radiological Technology (M.D.), Ehime Prefectural Imabari Hospital; and the Department of Radiological Technology of Ehime University (S.N.) and the Department of Radiology, Ehime University School of Medicine (T.M.), Onsengun, Ehime, Japan.
Correspondence to Yasushi Koyama, MD, Cardiology, Ehime Prefectural Imabari Hospital, 794-0006, Imabari, Ehime, Japan. E-mail dyasusi{at}dokidoki.ne.jp
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Introduction |
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 Top Introduction Method of 4D-CT-VG |
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Ultrasound and MRI are useful in assessing wall motion and systolic thickening with 2D images. Volumetric data of the helical CT provide frozen 3D images. We sought to determine whether helical CT could assess left ventricular wall motion with 3D animation. We have developed a new cardiac application, ventriculography by 4D enhanced helical CT (4D-CT-VG), which can assess wall motion with 3D animation from any perspective. We demonstrate representative 4D-CT-VG in 3 patients with acute myocardial infarction. In all 3 patients, akinetic areas assessed by 4D-CT-VG were concordant with those evaluated by conventional left ventriculography (LVG) (Figure
).
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Method of 4D-CT-VG |
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TopIntroductionMethod of 4D-CT-VG |
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At 50 seconds from the beginning of intravenous administration of a contrast medium (1.5 mL/s, total dose 100 mL), the scan was started and covered the patient's entire heart during a single breath-hold, by use of an ECG-gating technique. Scan parameters used were 3-mm-thick collimation, 3-mm per rotation table speed, 0.8 second per rotation, and
40 rotations (32
seconds) through 12 cm in total. The helical CT scanner was a
ProSeed-SA (GE Yokogawa Medical Systems; the American version is called
ProSpeed-Advantage, GE Medical Systems). The workstation was Indigo2
(Silicon Graphics Japan), and the software used was a Dr View R 4.0
(Asahikasei Jouhou System). By use of a 0.3-mm (0.08-second) interval
(10 slices per rotation) overlapping reconstruction, 400 transaxial
slices, including various cardiac phases, were obtained and transferred
to the workstation. Data sets in identical cardiac phases were
extracted (10 to 13 phases, depending on the heart rate) from the 400
transaxial images. Then, 3D images of all cardiac phases were
reconstructed. Left ventricular cavity images were
extracted by application of a certain threshold (CT attenuation number)
to render 3D images. The 3D animation was produced by paging these 3D
images in cardiac phase order. The interval between transaxial slices
within a data set of the cardiac phase often had different relative
table distances from beat to beat. Gaps between slices were seen in
patients whose heart rate was <75 bpm (R-R interval >0.8
second). The workstation could deal with the interval variances and
could interpolate the gaps. It took 30 minutes to prepare 3D
animation, or 4D-CT-VG. Our method will potentially provide assessment of left ventricular volumes, such as end-diastolic and end-systolic volumes, and ejection fraction in 3D fashion. The 4D-CT-VG will be more practical when a packaged software that can handle all procedures within a few minutes is developed. Recently released subsecond helical CT with multirow detectors will promote cardiac application of the helical CT.
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Footnotes |
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The editor of Images in Cardiovascular Medicine is Hugh A. McAllister, Jr, MD, Chief, Department of Pathology, St Luke's Episcopal Hospital and Texas Heart Institute, and Clinical Professor of Pathology, University of Texas Medical School and Baylor College of Medicine.
Circulation encourages readers to submit cardiovascular images to Dr Hugh A. McAllister, Jr, St Luke's Episcopal Hospital and Texas Heart Institute, 6720 Bertner Ave, MC1-267, Houston, TX 77030.
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