A dynamic approach to identifying desired physiological phases for cardiac imaging using multislice spiral CT

In this investigation, we describe a quantitative technique to measure coronary motion, which can be correlated with cardiac image quality using multislice computed tomography (MSCT) scanners. MSCT scanners, with subsecond scanning, thin-slice imaging (sub-millimeter) and volume scanning capabilitie...

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Veröffentlicht in:	Medical physics (Lancaster) 2003-07, Vol.30 (7), p.1683-1693
Hauptverfasser:	Vembar, M., Garcia, M. J., Heuscher, D. J., Haberl, R., Matthews, D., Böhme, G. E., Greenberg, N. L.
Format:	Artikel
Sprache:	eng
Schlagworte:	Aged Algorithms Anatomy blood vessels Cardiac dynamics cardiology Computed radiography Computed tomography computerised tomography Coronary Angiography - methods Coronary Artery Disease - diagnostic imaging Coronary Artery Disease - physiopathology Coronary Vessels - physiopathology Electrocardiography - methods Female Heart Heart - diagnostic imaging Heart - physiopathology Hemodynamics Humans Image analysis image reconstruction Image reconstruction tomography Image scanners Imaging, Three-Dimensional - methods Male medical image processing Medical image quality Medical image reconstruction Medical imaging Movement Multislice computed tomography physiological models Pneumodyamics, respiration Radiographic Image Interpretation, Computer-Assisted Reproducibility of Results Sensitivity and Specificity Statistics as Topic Subtraction Technique Tomography, Spiral Computed Vascular system
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creator	Vembar, M. Garcia, M. J. Heuscher, D. J. Haberl, R. Matthews, D. Böhme, G. E. Greenberg, N. L.
description	In this investigation, we describe a quantitative technique to measure coronary motion, which can be correlated with cardiac image quality using multislice computed tomography (MSCT) scanners. MSCT scanners, with subsecond scanning, thin-slice imaging (sub-millimeter) and volume scanning capabilities have paved the way for new clinical applications like noninvasive cardiac imaging. ECG-gated spiral CT using MSCT scanners has made it possible to scan the entire heart in a single breath-hold. The continuous data acquisition makes it possible for multiple phases to be reconstructed from a cardiac cycle. We measure the position and three-dimensional velocities of well-known landmarks along the proximal, mid, and distal regions of the major coronary arteries [left main (LM), left anterior descending (LAD), right coronary artery (RCA), and left circumflex (LCX)] during the cardiac cycle. A dynamic model (called the “delay algorithm”) is described which enables us to capture the same physiological phase or “state” of the anatomy during the cardiac cycle as the instantaneous heart rate varies during the spiral scan. The coronary arteries are reconstructed from data obtained during different physiological cardiac phases and we correlate image quality of different parts of the coronary anatomy with phases at which minimum velocities occur. The motion characteristics varied depending on the artery, with the highest motion being observed for RCA. The phases with the lowest mean velocities provided the best visualization. Though more than one phase of relative minimum velocity was observed for each artery, the most consistent image quality was observed during mid-diastole (“diastasis”) of the cardiac cycle and was judged to be superior to other reconstructed phases in 92% of the cases. In the process, we also investigated correlation between cardiac arterial states and other measures of motion, such as the left ventricular volume during a cardiac cycle, which earlier has been demonstrated as an example of how anatomic-specific information can be used in a knowledge-based cardiac CT algorithm. Using these estimates in characterizing cardiac motion also provides realistic simulation models for higher heart rates and also in optimizing volume reconstructions for individual segments of the cardiac anatomy.
doi_str_mv	10.1118/1.1582812
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The continuous data acquisition makes it possible for multiple phases to be reconstructed from a cardiac cycle. We measure the position and three-dimensional velocities of well-known landmarks along the proximal, mid, and distal regions of the major coronary arteries [left main (LM), left anterior descending (LAD), right coronary artery (RCA), and left circumflex (LCX)] during the cardiac cycle. A dynamic model (called the “delay algorithm”) is described which enables us to capture the same physiological phase or “state” of the anatomy during the cardiac cycle as the instantaneous heart rate varies during the spiral scan. The coronary arteries are reconstructed from data obtained during different physiological cardiac phases and we correlate image quality of different parts of the coronary anatomy with phases at which minimum velocities occur. The motion characteristics varied depending on the artery, with the highest motion being observed for RCA. The phases with the lowest mean velocities provided the best visualization. Though more than one phase of relative minimum velocity was observed for each artery, the most consistent image quality was observed during mid-diastole (“diastasis”) of the cardiac cycle and was judged to be superior to other reconstructed phases in 92% of the cases. In the process, we also investigated correlation between cardiac arterial states and other measures of motion, such as the left ventricular volume during a cardiac cycle, which earlier has been demonstrated as an example of how anatomic-specific information can be used in a knowledge-based cardiac CT algorithm. 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L.</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>A dynamic approach to identifying desired physiological phases for cardiac imaging using multislice spiral CT</atitle><jtitle>Medical physics (Lancaster)</jtitle><addtitle>Med Phys</addtitle><date>2003-07</date><risdate>2003</risdate><volume>30</volume><issue>7</issue><spage>1683</spage><epage>1693</epage><pages>1683-1693</pages><issn>0094-2405</issn><eissn>2473-4209</eissn><coden>MPHYA6</coden><abstract>In this investigation, we describe a quantitative technique to measure coronary motion, which can be correlated with cardiac image quality using multislice computed tomography (MSCT) scanners. MSCT scanners, with subsecond scanning, thin-slice imaging (sub-millimeter) and volume scanning capabilities have paved the way for new clinical applications like noninvasive cardiac imaging. ECG-gated spiral CT using MSCT scanners has made it possible to scan the entire heart in a single breath-hold. The continuous data acquisition makes it possible for multiple phases to be reconstructed from a cardiac cycle. We measure the position and three-dimensional velocities of well-known landmarks along the proximal, mid, and distal regions of the major coronary arteries [left main (LM), left anterior descending (LAD), right coronary artery (RCA), and left circumflex (LCX)] during the cardiac cycle. A dynamic model (called the “delay algorithm”) is described which enables us to capture the same physiological phase or “state” of the anatomy during the cardiac cycle as the instantaneous heart rate varies during the spiral scan. The coronary arteries are reconstructed from data obtained during different physiological cardiac phases and we correlate image quality of different parts of the coronary anatomy with phases at which minimum velocities occur. The motion characteristics varied depending on the artery, with the highest motion being observed for RCA. The phases with the lowest mean velocities provided the best visualization. Though more than one phase of relative minimum velocity was observed for each artery, the most consistent image quality was observed during mid-diastole (“diastasis”) of the cardiac cycle and was judged to be superior to other reconstructed phases in 92% of the cases. In the process, we also investigated correlation between cardiac arterial states and other measures of motion, such as the left ventricular volume during a cardiac cycle, which earlier has been demonstrated as an example of how anatomic-specific information can be used in a knowledge-based cardiac CT algorithm. Using these estimates in characterizing cardiac motion also provides realistic simulation models for higher heart rates and also in optimizing volume reconstructions for individual segments of the cardiac anatomy.</abstract><cop>United States</cop><pub>American Association of Physicists in Medicine</pub><pmid>12906185</pmid><doi>10.1118/1.1582812</doi><tpages>11</tpages></addata></record>
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subjects	Aged Algorithms Anatomy blood vessels Cardiac dynamics cardiology Computed radiography Computed tomography computerised tomography Coronary Angiography - methods Coronary Artery Disease - diagnostic imaging Coronary Artery Disease - physiopathology Coronary Vessels - physiopathology Electrocardiography - methods Female Heart Heart - diagnostic imaging Heart - physiopathology Hemodynamics Humans Image analysis image reconstruction Image reconstruction tomography Image scanners Imaging, Three-Dimensional - methods Male medical image processing Medical image quality Medical image reconstruction Medical imaging Movement Multislice computed tomography physiological models Pneumodyamics, respiration Radiographic Image Interpretation, Computer-Assisted Reproducibility of Results Sensitivity and Specificity Statistics as Topic Subtraction Technique Tomography, Spiral Computed Vascular system
title	A dynamic approach to identifying desired physiological phases for cardiac imaging using multislice spiral CT
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