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Noninvasive Coronary Imaging with MDCT in Comparison to Invasive Conventional Coronary Angiography: A Fast-Developing Technology

¹ Department of Diagnostic Radiology, University Hospital of Ulm, Steinhoevelstrasse 9, Ulm D 89070, Germany.
² Philips Medical Systems, Cleveland, OH.

Received March 10, 2003; accepted after revision June 13, 2003.

 
Address correspondence to M. H. K. Hoffmann.

Introduction

Top Introduction Basic CT Technique Image Reconstruction Current Applications Future Potential References

 
Coronary artery disease represents the major cause of morbidity and mortality in Western populations [1]. The prime diagnostic tool that allowed the development of rational treatment techniques for this disease is invasive coronary angiography, which is associated with a small rate of life-threatening complications [2]. More than 40% of the invasive coronary angiography studies are not followed up by subsequent interventional or surgical therapy but are conducted only for the purpose of ruling out coronary artery disease [3]. This initiated research on noninvasive imaging of the coronary arteries relying on various methods including MRI [4], electron beam CT [5], and MDCT [6].

In the past couple of years, considerable progress has been achieved in the field of noninvasive coronary angiography. Recent advances in CT technology with the development of MDCT allow a more robust and reliable application of the technique in coronary artery disease [7]. First results indicate high sensitivity ratings, although specificity is still compromised by overestimation of stenotic lesions [6]. The aims of this pictorial essay are to review typical findings of coronary artery disease in noninvasive CT studies and relate them to the corresponding conventional invasive images.

Basic CT Technique

Top Introduction Basic CT Technique Image Reconstruction Current Applications Future Potential References

 
Total coronary tree volume coverage was yielded by a single breath-hold of less than 20 sec using a 16-MDCT scanner (MX 8000 IDT, Philips Medical Systems, Cleveland, OH). CT angiography was performed with a 0.42-sec rotation time. All studies were preceded by a scout acquisition and bolus-tracking protocol.

For bolus tracking, successive axial slices were acquired over the aortic root (slice positioning was related to the position of the carina on the scout images). During slice acquisition 10 mL of contrast medium (Imeron 400 [iomeprol], 400 mg I/mL, Altana, Konstanz, Germany) was given using a power injector at a rate of 4 mL/sec, followed by a saline chaser bolus of 30 mL at 3.5 mL/sec. A region of interest was positioned in the aortic root, and the averaged Hounsfield units for enhancement plotted against time.

For the coronary volume scan, 80 mL of Imeron 400 was given at a rate of 4 mL/sec followed by a saline chaser bolus of 50 mL at 3 mL/sec. The coronary helical scan was timed according to the peak enhancement derived from the bolus-tracking scan. An ECG was recorded during the continuous CT data acquisition and the raw data set registered according to the position of the R spike. A scanning protocol with a collimation of 16 x 0.75 mm was applied at a table increment of 8.57 mm/sec, using a tube voltage of 140 kV and a current of 285 mA. For cardiac imaging, 16-MDCT was available. Depending on the size of the heart, the scanning time varied between 16 and 22 sec.

Patients with a resting heart rate of less than 80 beats per minute were accepted for the scanning protocol. If resting heart rate was equal to or greater than 80 beats per minute, a ß-blocker was started. Bolus application of IV metoprolol at 5-mg aliquots up to a total dose of 20 mg was used to achieve mean heart rates of less than 80 beats per minute.

Image Reconstruction

Top Introduction Basic CT Technique Image Reconstruction Current Applications Future Potential References

 
After acquisition of the helical CT raw data, retrospective ECG synchronized slices were reconstructed. The algorithm used accounts for cone-angle reconstruction and improved temporal resolution slightly, compared with conventional algorithms [8]. In summary, a single slice could be reconstructed from the CT data acquired during a 180° X-ray tube rotation—that is, in 210 msec at a tube rotation time of 420 msec. As heart rate increases, the duration of diastole that is suitable for image reconstruction rapidly decreases. The temporal resolution of 210 msec is therefore suitable only for patients with very low heart rates. When the heart rate is above 55 beats per minute, data from consecutive cycles are combined to improve effective temporal resolution. Cone-beam artifacts are induced by the large cone angle of 16 x 0.75 mm detector rows positioned along the z-axis opposed to a small focal spot emitting X-rays. The multicycle reconstruction algorithm combines both cone-angle correction via 3D back-projection and cardiac phase weighting to improve temporal resolution [8]. Depending on the instantaneous heart rate, the slice reconstruction time varied between 70 and 210 msec. Because data were acquired continuously, the reconstruction window could be positioned at any point within the cardiac cycle.

Routinely, two data sets were acquired at around 80% and 50% of the heart cycle (measured from R to R spike of the QRS complex). They were termed the "mid-diastolic" ( 80%) and the "end-systolic" ( 50%) reconstruction window. Other window positions within the cardiac cycle were reconstructed if no satisfactory results were achieved at the standard windows. In a side-by-side comparison of axial slices and volume-rendered images using a dedicated workstation (MxView 4.1, Philips Medical Systems), the data set with the least motion artifacts was selected for further analysis.

Helical CT also allowed selection of an image reconstruction increment (0.4 mm) below the effective slice thickness (0.8 mm). As a result of the overlapping reconstruction, near-isotropic voxel dimensions were created (0.6 x 0.6 x 0.8 mm).

All image data sets were analyzed using multiplanar reconstruction, thin-slab maximum intensity projections, slab volume rendering, and curved multiplanar reconstruction in addition to the axial source images on the workstation described earlier (MxView 4.1, Philips Medical Systems). The postprocessing entails a first assessment for motion-free images using axial source images. Thereafter, volume rendering is generated using automated rib-cage removal algorithms to obtain a gross anatomic overview and to identify plaque lesions suspected of significant stenosis induction. Semiautomated centerline detection of the coronary vessel lumen is performed on slabs of the 3D cardiac volume rendering. This centerline is used to generate curved-plane maximum intensity projections (slab thickness, 0.8–3mm) longitudinal to the vessel. Stenosis grading is achieved by cross-sectional imaging perpendicular to the longitudinal path generated in the previous step.

Current Applications

Top Introduction Basic CT Technique Image Reconstruction Current Applications Future Potential References

 
Significant Stenosis Detection
For the assessment of coronary artery disease, noninvasive CT angiography provides a lumen image comparable to conventional catheterization. In addition, plaque imaging of the coronary artery wall is possible. Three kinds of plaques can be classified as follows: calcified plaques with more than 300 H, fibrous plaques with enhancements approximately 100 H, and soft plaques with a large lipid core and attenuation below 50 H [9]. For an adequate coronary assessment, noninvasive angiography needs to provide sufficient spatial resolution and contrasting to resolve the coronary cross section for plaque and lumen separation. This has to be possible not only in the proximal parts of the coronary tree but also in the distal third.

Figures 1A, 1B, 1C and 2A, 2B, 2C show the high degree of distal coverage achievable with noninvasive CT angiography that is currently unsurpassed by other noninvasive methods.

View larger version (73K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 1A. —Volume rendering of axial image stack shows excellent distal coverage. Left anterior oblique CT angiogram of left coronary artery in 76-year-old man with heart rate of 65 beats per minute shows heavily calcified left anterior descending coronary artery (LAD), first diagonal branch (D1), intermediately branching first obtuse marginal branch (OM1), and terminal branch of left circumflex artery (OM2).

View larger version (122K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 1B. —Volume rendering of axial image stack shows excellent distal coverage. On diaphragmatic CT angiogram of same patient as shown in A, coverage can be extended into terminal branches of right posterior descending artery (RPDA) of right coronary artery. Imaging beyond crux cordis (Crux) is crucial to cover all territories relevant for revascularization therapy. RPLA = right posterolateral artery.

View larger version (104K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 1C. —Volume rendering of axial image stack shows excellent distal coverage. Diaphragmatic CT angiogram of right coronary artery in 72-year-old man reveals different data set showing consistent distal coverage. Partial overlay of cardiac veins has to be accounted for by clipping volume of interest. RPDA = posterior descending artery, RPLA = right posterolateral artery.

View larger version (91K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 2A. —67-year-old man with bifurcational stenosis of proximal left coronary artery. Stenotic lesion is located at branching point of left anterior descending coronary artery (LAD) and left circumflex artery (LCX). Culprit lesion is impinging on proximal LAD resulting in high-grade stenosis. Volume-rendered CT angiogram shows high-grade proximal LAD lesion with moderate- to low-grade stenosis of proximal LCX (lesion site circled).

View larger version (102K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 2B. —67-year-old man with bifurcational stenosis of proximal left coronary artery. Stenotic lesion is located at branching point of left anterior descending coronary artery (LAD) and left circumflex artery (LCX). Culprit lesion is impinging on proximal LAD resulting in high-grade stenosis. Corresponding curved planar reformation visualizes fibrous plaque stenosis (PS), wall calcifications (short arrow) of proximal LAD, and sectioned branch of LCX.

View larger version (136K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 2C. —67-year-old man with bifurcational stenosis of proximal left coronary artery. Stenotic lesion is located at branching point of left anterior descending coronary artery (LAD) and left circumflex artery (LCX). Culprit lesion is impinging on proximal LAD resulting in high-grade stenosis. Corresponding conventional coronary catheterization radiograph shows bifurcational stenosis (circle) in spider view (left anterior oblique view caudally tilted).

In cases of fibrous- or soft plaque–induced stenosis formation, the culprit lesion can be identified on the 3D volume-rendered images (Fig. 3A, 3B, 3C). Highly calcified sections still challenge the diagnostic reviewer. The calcium plaque oversizing (blooming) is reduced with the 16-MDCT technique as compared to 4-MDCT techniques. It has been postulated that plaque oversizing is due to insufficient spatial resolution [10], and 16-MDCT platforms can operate with increased spatial resolution. Further increase in spatial resolution with upcoming generations of CT scanners may alleviate this problem. In addition, substantial research regarding raw data acquisition and contrast application is currently performed.

View larger version (135K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 3A. —66-year-old man with recurrent angina. Left anterior oblique angiogram of diaphragmatic right coronary artery (crux region) shows long stenosis (arrows) of no significance—less than 50%.

View larger version (180K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 3B. —66-year-old man with recurrent angina. Curved multiplanar reformation of CT image reveals fibrocalcified plaque (arrows) composed of outer calcified and inner fibrous layers.

View larger version (80K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 3C. —66-year-old man with recurrent angina. Volume-rendered CT angiogram of diaphragmatic right coronary artery shows plaque extension (arrows) beyond crux vessel branching point.

The current generation of 16-MDCT scanners allows differentiation of plaque layers in the coronary artery wall (Fig. 3A, 3B, 3C). The spatial resolution of 16-MDCT is not yet comparable to intravascular sonography and does not allow the discrimination of the fibrous cap of unstable plaque formations.

The increased spatial resolution achievable on the current platform allows extending diagnostic access into smaller side branches (Fig. 4A, 4B). CT, as opposed to conventional angiography, offers the potential to visualize chronically thrombosed and occluded coronary segments and may serve as a guidance tool for recanalization therapy (Figs. 5A, 5B, 5C and 6A, 6B, 6C).

View larger version (110K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 4A. —66-year-old woman with exertional thoracic pain. Volume-rendered CT angiogram shows proximal stenosis (arrow) of intermediate artery corresponding to high-grade lesion in catheterization radiograph (B).

View larger version (140K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 4B. —66-year-old woman with exertional thoracic pain. Conventional catheterization radiograph shows stenosis (arrow). Adequate coverage of small side branches is obtainable with this method.

View larger version (100K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 5A. —54-year-old man with known left circumflex occlusion, now presenting with recurrent angina at moderate exertion. Volume-rendered CT angiogram shows calcified lesion of mid third left circumflex artery with occlusion (long arrow) after branching of second obtuse marginal branch. Additional lesion can be identified in first diagonal branch (short arrow). Left anterior descending artery is marked with star.

View larger version (99K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 5B. —54-year-old man with known left circumflex occlusion, now presenting with recurrent angina at moderate exertion. Clipping plane of same volume-rendered image data set as in A shows atrioventricular groove section of left circumflex artery. Chronic occlusion site (arrow) is marked.

View larger version (152K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 5C. —54-year-old man with known left circumflex occlusion, now presenting with recurrent angina at moderate exertion. Corresponding catheterization radiograph shows occlusion (arrow) and new high-grade lesion of first diagonal branch (arrowhead). Left anterior descending artery is marked with star.

View larger version (143K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 6A. —61-year-old woman with coronary artery disease, 3 years after coronary artery bypass grafting. Conventional catheterization radiograph with contrast injection into vein graft anastomosed to mid region of left anterior descending artery shows mild residual stenosis at distal anastomotic site (star). Proximally occluded left anterior descending vessel structures are not discernible.

View larger version (81K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 6B. —61-year-old woman with coronary artery disease, 3 years after coronary artery bypass grafting. Corresponding volume-rendered CT angiogram of distal anastomosis (star) provides some additional information about more proximal vessel region. Inhomogeneous and blurred distal coverage is because of delayed contrast enhancement distal to the residual stenosis.

View larger version (137K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 6C. —61-year-old woman with coronary artery disease, 3 years after coronary artery bypass grafting. Curved planar reformation shows proximally thrombosed left anterior descending artery (black arrow) and well-contrasted vein graft (white arrow). Distal anastomotic site is marked by star. Curved planar reformation contains additional information about chronically occluded segment delineating thrombus formation that might be useful in cases considered for recanalization with either interventional or surgical methods. Curved planar reformation shows much better distal coverage than volume rendering in B.

Other Clinical Applications
Assessment of bypass graft patency is another clinical application for cardiac CT (Fig. 7A, 7B, 7C, 7D, 7E). If the cranial starting point of the scan is placed on the aortic arch, most of the mammary pedicle is assessable (Fig. 7B). The complete free grafted bypass vessel is also included from the proximal anastomotic site at the anterior surface of the ascending aorta to the distal anastomosis on the coronary artery (Fig. 7A).

View larger version (82K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 7A. —56-year-old man with long history of coronary artery disease and follow-up of complete arterial bypass graft surgery. Because of ectatic saphenous vein, only arterial conduits were used. Free radial graft (arrow, A) was anastomosed to right coronary artery. Right internal thoracic artery was grafted to left anterior descending artery (long arrow, B). Left internal thoracic artery was grafted to circumflex artery (short arrow, B). Volume-rendered CT angiogram shows radial artery graft (arrow) surrounded by multiple metallic clips used to ligate side branches. Cone-angle correction suppresses metallic artifacts in these images that would prevent diagnostic access to graft.

View larger version (84K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 7B. —56-year-old man with long history of coronary artery disease and follow-up of complete arterial bypass graft surgery. Because of ectatic saphenous vein, only arterial conduits were used. Free radial graft (arrow, A) was anastomosed to right coronary artery. Right internal thoracic artery was grafted to left anterior descending artery (long arrow, B). Left internal thoracic artery was grafted to circumflex artery (short arrow, B). Volume-rendered CT angiogram shows right mammary graft (long arrow) is well contrasted. Left mammary artery graft (short arrow) appears as faintly contrasted cord structure with no apparent stenotic lesion.

View larger version (133K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 7C. —56-year-old man with long history of coronary artery disease and follow-up of complete arterial bypass graft surgery. Because of ectatic saphenous vein, only arterial conduits were used. Free radial graft (arrow, A) was anastomosed to right coronary artery. Right internal thoracic artery was grafted to left anterior descending artery (long arrow, B). Left internal thoracic artery was grafted to circumflex artery (short arrow, B). Corresponding conventional coronary catheterization radiograph of distal anastomotic site (arrow) of right mammary artery graft confirms patent graft lumen.

View larger version (128K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 7D. —56-year-old man with long history of coronary artery disease and follow-up of complete arterial bypass graft surgery. Because of ectatic saphenous vein, only arterial conduits were used. Free radial graft (arrow, A) was anastomosed to right coronary artery. Right internal thoracic artery was grafted to left anterior descending artery (long arrow, B). Left internal thoracic artery was grafted to circumflex artery (short arrow, B). Conventional catheterization radiograph of left mammary artery graft (arrow) shows bad runoff due to competitive flow in native circumflex artery. These dynamic aspects can only be covered by direct contrast injection during invasive catheterization procedures.

View larger version (12K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 7E. —56-year-old man with long history of coronary artery disease and follow-up of complete arterial bypass graft surgery. Because of ectatic saphenous vein, only arterial conduits were used. Free radial graft (arrow, A) was anastomosed to right coronary artery. Right internal thoracic artery was grafted to left anterior descending artery (long arrow, B). Left internal thoracic artery was grafted to circumflex artery (short arrow, B). Graph shows heartbeat was absolutely arrhythmic during CT scan with heart rate range from 90 to 65 beats per minute. Rate was contained below 90 beats per minute as shown by sine wave appearance of plotting of heart rate versus scanning time duration.

Other applications not covered in this pictorial essay include assessments of coronary anomalies and complex cardiac morphology in patients with congenital heart disease.

Arrhythmia and Motion Artifacts
One of the major shortcomings of current cardiac CT imaging is that it is prone to motion artifacts at higher heart rates or in arrhythmic situations. Substantial progress can be achieved with multicycle reconstruction. By combining data from adjacent heart cycles, temporal resolution can be substantially reduced. The relative positioning of the reconstruction window in the heart cycle allows imaging even in rate-contained arrhythmic situations as is shown in Figure 7E. The current methods still fail in situations of substantial heart rate variations as is shown in Figure 8A, 8B, 8C, 8D.

View larger version (111K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 8A. —59-year-old man referred for follow-up after placement of coronary stent. Patient developed sustained bigeminal rhythm disturbance during CT. Volume-rendered CT angiogram suggests high-grade stenosis (long arrow) distal to left anterior descending artery stent implantation site (short arrow).

View larger version (142K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 8B. —59-year-old man referred for follow-up after placement of coronary stent. Patient developed sustained bigeminal rhythm disturbance during CT. Catheterization radiograph shows no visible stenosis distal to left anterior descending artery stent implantation site (arrow).

View larger version (104K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 8C. —59-year-old man referred for follow-up after placement of coronary stent. Patient developed sustained bigeminal rhythm disturbance during CT. Volume-rendered CT angiogram oriented along z-axis of scan direction shows banding type of motion artifacts (arrows). One banding border matches location of supposedly left anterior descending artery stenosis, classifying it as motion artifact.

View larger version (96K): [in this window] [in a new window] [as a PowerPoint slide]   Fig. 8D. —59-year-old man referred for follow-up after placement of coronary stent. Patient developed sustained bigeminal rhythm disturbance during CT. Artifact (arrow) is also apparent on curved planar reformation covering left anterior descending artery.

Comparison with Other Methods
Multicenter experiences with MR angiography revealed a total mean scanning time of 70 min (range, 33–145 min) [4]. The total mean scanning time for our protocol, including scout images, bolus tracking, and coronary volume acquisition, amounts to less than 10 min (range, 7–14 min). Radiation exposure is still an issue favoring MRI, but in the clinical routine the more time-efficient, and therefore emergency-compatible, technology might prevail. Furthermore, the distal coverage achieved with CT scans has not been achieved with any other noninvasive diagnostic technique.

Future Potential

Top Introduction Basic CT Technique Image Reconstruction Current Applications Future Potential References

 
MDCT noninvasive coronary angiography using current 16-MDCT technology has the potential to play a role as gatekeeper for the invasive studies. MDCT may prove to be a high-sensitivity method to exclude substantial coronary artery disease, although specificity in highly calcified regions seems to be limited. If the limitations induced by calcium oversizing or blooming could be overcome, it would offer a true 3D lumenogram of the coronary arteries combined with plaque detection. It would therefore combine aspects of conventional invasive coronary angiography and intravascular sonography. At the current stage of development, however, no realistic competition with these methods is possible because of inferior spatial and temporal resolution, but a prefiltering or gatekeeping position of cardiac coronary CT is within the scope of immediate clinical application. This is supported by a high degree of certainty to rule out coronary artery disease, whereas the predictive value decreases to below 75% to detect multivessel disease [6].

References

Top Introduction Basic CT Technique Image Reconstruction Current Applications Future Potential References

 

1. American Heart Association. International cardiovascular disease statistics. Dallas, TX: American Heart Association,2003
2. Bashore TM, Bates ER, Berger PB, et al. American College of Cardiology/Society for Cardiac Angiography and Interventions Clinical Expert Consensus Document on cardiac catheterization laboratory standards: a report of the American College of Cardiology Task Force on Clinical Expert Consensus Documents. J Am Coll Cardiol2001; 37:2170 –2214[Free Full Text]
3. Windecker S, Maier-Rudolph W, Bonzel T, et al. Interventional cardiology in Europe 1995: Working Group Coronary Circulation of the European Society of Cardiology. Eur Heart J1999; 20:484 –495[Abstract/Free Full Text]
4. Kim WY, Danias PG, Stuber M, et al. Coronary magnetic resonance angiography for the detection of coronary stenoses. N Engl J Med 2001;354:1863 –1869
5. Lu B, Zhuang N, Mao SS, Bakhsheshi H, Liu SC, Budoff MJ. Image quality of three-dimensional electron beam coronary angiography. J Comput Assist Tomogr 2002;26:202 –209[Medline]
6. Nieman K, Cademartiri F, Lemos PA, Raaijmakers R, Pattynama P, de Feyter PJ. Reliable noninvasive coronary angiography with fast submillimeter multislice spiral computed tomography. Circulation2002; 106:2051 –2054[Abstract/Free Full Text]
7. Heuschmid M, Kuttner A, Flohr T, et al. Visualization of coronary arteries in CT as assessed by a new 16 slice technology and reduced gantry rotation time: first experiences [in German]. Rofo Fortschr Geb Rontgenstr Neuen Bildgeb Verfahr2002; 174:721 –724[Medline]
8. Shechter G, Naveh G, Altman A, Proksa R, Grass M. Cardiac image reconstruction on a 16-slice CT scanner using a retrospectively ECG-gated, multi-cycle 3D back-projection algorithm. In: Sonka M, Fitzpatrick M, eds. Medical imaging 2003: image processing—proceedings, vol. 5032. Bellingham, WA: Society of Photo-Optical Instrumentation Engineers,2003 : 1820–1828
9. Fayad ZA, Fuster V, Nikolaou K, Becker C. Computed tomography and magnetic resonance imaging for noninvasive coronary angiography and plaque imaging. Circulation2002; 106:2026 –2034[Free Full Text]
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This Article Figures Only Full Text (PDF) Alert me when this article is cited Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Hoffmann, M. H. K. Articles by Aschoff, A. J. Search for Related Content PubMed PubMed Citation Articles by Hoffmann, M. H. K. Articles by Aschoff, A. J. Social Bookmarking                      What's this?