In vivo CT detection of lipid-rich coronary artery atherosclerotic plaques using quantitative histogram analysis: a head to head comparison with IVUS.

BACKGROUND Coronary atherosclerotic plaque characterisation may contribute to risk stratification for future cardiovascular events. The ability of computed tomography to classify plaques as 'fibrous' or 'lipid-rich' based on their average CT attenuation has been investigated but is fraught with substantial limitations. In this study, we evaluated the potential of analysing the distribution of CT attenuation values measured in Hounsfield Units (HU) within coronary atherosclerotic plaques to classify non-calcified plaques into fibrous and lipid-rich subtypes. Intravascular ultrasound (IVUS) served as the gold standard. PATIENTS AND METHODS We evaluated the data sets of 40 patients (30 males, 59±10 years) who had been referred for invasive coronary angiography for clinical reasons and in whom IVUS was performed in at least one coronary vessel. Using dual source CT, coronary CT angiography was performed as a part of a research protocol within 24 h previous to invasive coronary angiography. A contrast-enhanced volume dataset was acquired with retrospective ECG gating (120 kV, 400 mAs/rot, collimation 2 mm×64 mm×0.6 mm, 60-80 ml contrast agent i.v). IVUS was performed using a 40-MHz IVUS catheter (Atlantis, Boston Scientific Corporation, Natick, MA) and motorized pullback at 0.5 mm/s. Fifty five corresponding non-calcified plaques within the coronary artery system were identified in both DSCT and IVUS using bifurcation points as fiducial markers. In DSCT data sets, serial parallel cross-sections (1mm slice thickness) were rendered orthogonally to the centre line of the coronary artery for each of the 55 plaques. For each cross section and each plaque, a histogram of CT attenuation values (increments of 10HU) was determined. The percentage of pixels with a density ≤30 HU was calculated. Using IVUS as the gold standard, plaques were classified as predominantly fibrous (hyperechoic) or predominantly lipid-rich (hypoechoic). RESULTS 15 predominantly fibrous plaques vs. 40 predominantly lipid-rich plaques were identified in IVUS. The mean CT attenuation in both plaque types was significantly different (67±31 HU vs. 96±40 HU, p=0.006), yet with a wide overlap. For the 15 fibrous plaques identified in IVUS, the mean percentage of pixels ≤30 HU in CT was 6±10%. For lipid-rich plaques it was 16±10% (p<0.0001). ROC curve analysis revealed that a cut-off of 5.5% pixels with an attenuation ≤30 HU identified lipid rich plaques in CT angiography with a sensitivity of 95% (38/40, 95% CI 83-99) and a specificity of 80% (12/15, 95% CI 52-96) [AUC 0.9, 95% CI 0.7-1.0]. Using this threshold, the negative predictive value was 86% (12/14, 95% CI 57-98) and the positive predictive value was 93% (38/41, 95% CI 80-98). CONCLUSION Lipid-rich coronary atherosclerotic plaques contain a significantly higher percentage of pixels with low CT attenuation as compared to fibrous plaques. Histogram analysis may help to differentiate both plaque types. A cut-off of 5.5% of pixels with an attenuation of ≤30 HU allowed identification of lipid-rich plaques with a sensitivity of 95% and a specificity of 80%.

[1]  Udo Hoffmann,et al.  Characterization of non-calcified coronary atherosclerotic plaque by multi-detector row CT: comparison to IVUS. , 2007, Atherosclerosis.

[2]  S. Achenbach,et al.  Relationship between degree of remodeling and CT attenuation of plaque in coronary atherosclerotic lesions: an in-vivo analysis by multi-detector computed tomography. , 2008, Atherosclerosis.

[3]  Filippo Cademartiri,et al.  Influence of intracoronary attenuation on coronary plaque measurements using multislice computed tomography: observations in an ex vivo model of coronary computed tomography angiography , 2005, European Radiology.

[4]  Dieter Ropers,et al.  Assessment of changes in non-calcified atherosclerotic plaque volume in the left main and left anterior descending coronary arteries over time by 64-slice computed tomography. , 2008, The American journal of cardiology.

[5]  C Georg,et al.  Noninvasive detection and evaluation of atherosclerotic coronary plaques with multislice computed tomography. , 2001, Journal of the American College of Cardiology.

[6]  W. Bautz,et al.  Diagnostic Accuracy of Noninvasive Coronary Angiography in Patients After Bypass Surgery Using 64-Slice Spiral Computed Tomography With 330-ms Gantry Rotation , 2006, Circulation.

[7]  S. Achenbach,et al.  Assessment of nonstenotic coronary lesions by 64-slice multidetector computed tomography in comparison to intravascular ultrasound: evaluation of nonculprit coronary lesions. , 2009, Journal of cardiovascular computed tomography.

[8]  K Stierstorfer,et al.  Performance evaluation of a 64-slice CT system with z-flying focal spot. , 2004, RoFo : Fortschritte auf dem Gebiete der Rontgenstrahlen und der Nuklearmedizin.

[9]  S. Abbara,et al.  Cardiac CT: State of the art for the detection of coronary arterial stenosis , 2008 .

[10]  J. Ishii,et al.  Atherosclerotic plaque characterization by 0.5-mm-slice multislice computed tomographic imaging. , 2007, Circulation journal : official journal of the Japanese Circulation Society.

[11]  Ulrich Baum,et al.  Usefulness of multidetector row spiral computed tomography with 64- x 0.6-mm collimation and 330-ms rotation for the noninvasive detection of significant coronary artery stenoses. , 2006, The American journal of cardiology.

[12]  K. Stierstorfer,et al.  First performance evaluation of a dual-source CT (DSCT) system , 2006, European Radiology.

[13]  Konstantin Nikolaou,et al.  Accuracy of 64-MDCT in the diagnosis of ischemic heart disease. , 2006, AJR. American journal of roentgenology.

[14]  Konstantin Nikolaou,et al.  Accuracy of multidetector spiral computed tomography in identifying and differentiating the composition of coronary atherosclerotic plaques: a comparative study with intracoronary ultrasound. , 2004, Journal of the American College of Cardiology.

[15]  D. Dey,et al.  Image quality and artifacts in coronary CT angiography with dual-source CT: initial clinical experience. , 2008, Journal of cardiovascular computed tomography.

[16]  M. Reiser,et al.  Diagnostic accuracy of dual-source multi-slice CT-coronary angiography in patients with an intermediate pretest likelihood for coronary artery disease. , 2007, European heart journal.

[17]  J M Tobis,et al.  Variability in tissue characterization of atherosclerotic plaque by intravascular ultrasound: a comparison of four intravascular ultrasound systems. , 1996, American journal of cardiac imaging.

[18]  S. Achenbach,et al.  Influence of slice thickness and reconstruction kernel on the computed tomographic attenuation of coronary atherosclerotic plaque. , 2010, Journal of cardiovascular computed tomography.

[19]  W. Kalender,et al.  Contrast-enhanced coronary artery visualization by dual-source computed tomography--initial experience. , 2006, European journal of radiology.

[20]  Borut Marincek,et al.  Accuracy of dual-source CT coronary angiography: first experience in a high pre-test probability population without heart rate control , 2006, European Radiology.

[21]  C. Meisner,et al.  Accuracy of Density Measurements Within Plaques Located in Artificial Coronary Arteries by X-Ray Multislice CT: Results of a Phantom Study , 2001, Journal of computer assisted tomography.

[22]  C. Tracy,et al.  American College of Cardiology Clinical Expert Consensus Document on Standards for Acquisition, Measurement and Reporting of Intravascular Ultrasound Studies (IVUS). A report of the American College of Cardiology Task Force on Clinical Expert Consensus Documents. , 2001, Journal of the American College of Cardiology.

[23]  M. Potter,et al.  Mechanisms in B-cell neoplasia. Workshop at the National Cancer Institute, National Institutes of Health. Bethesda, MD, USA, March 24-26, 1986. , 1986, Current topics in microbiology and immunology.

[24]  P. Carrascosa,et al.  Characterization of coronary atherosclerotic plaques by multidetector computed tomography. , 2006, The American journal of cardiology.

[25]  S. Achenbach,et al.  Noncalcified and calcified coronary plaque detection by contrast-enhanced multi-detector computed tomography: a study of interobserver agreement. , 2006, Journal of the American College of Cardiology.

[26]  Werner Bautz,et al.  Influence of heart rate on the diagnostic accuracy of dual-source computed tomography coronary angiography. , 2007, Journal of the American College of Cardiology.

[27]  Hirofumi Anno,et al.  Computed tomographic angiography characteristics of atherosclerotic plaques subsequently resulting in acute coronary syndrome. , 2009, Journal of the American College of Cardiology.

[28]  Konstantin Nikolaou,et al.  Ex vivo coronary atherosclerotic plaque characterization with multi-detector-row CT , 2003, European Radiology.

[29]  Zhonghua Sun,et al.  Diagnostic value of multislice computed tomography angiography in coronary artery disease: a meta-analysis. , 2006, European journal of radiology.

[30]  S. Achenbach,et al.  Detection of Calcified and Noncalcified Coronary Atherosclerotic Plaque by Contrast-Enhanced, Submillimeter Multidetector Spiral Computed Tomography: A Segment-Based Comparison With Intravascular Ultrasound , 2003, Circulation.

[31]  Yujie Zhou,et al.  Identification and quantification of coronary atherosclerotic plaques: a comparison of 64-MDCT and intravascular ultrasound. , 2008, AJR. American journal of roentgenology.