Applied Radiology

EDITOR'S NOTE

This article documents the clinical value of PET and how PET imaging data is enhanced by computer software. Software can help process and analyze the data and manage the department at every level. Our experience with PET software analysis reveals the remarkable reproducibility and accuracy of PET Rb-82 myocardial perfusion imaging. It is in the best interest of everyone performing PET Rb-82 imaging to make use of such software analysis to achieve greater uniformity of quality.--Randolph E. Patterson, MD

Impact of Computer Analysis on the Clinical Value of Positron Emission Tomographic Myocardial Perfusion Imaging with Rubidium-82 (Rb-82)

Positron emission tomographic (PET) myocardial perfusion imaging (MPI) with rubidium-82 (Rb-82) offers a powerful approach to cost-effective management of coronary artery disease (CAD). ^1-5 This article will discuss how computer software can enhance the value of PET MPI.

Technical Advantages of PET Rb-82

Several features of PET provide images that are far superior to those obtained from single-photon emission computed tomography (SPECT), including: simultaneity correction; better spatial resolution (full width at half max [FWHM]) values of 4 to 10 mm, rather than 15 to 20 mm with SPECT ^1,5 ; enhanced signal-to-noise (PET achieving count rates that are about ten-fold higher than with SPECT); and correction for attenuation (absorption or deflection of counts by the body of the person lying in the camera, creating artifactual defects on SPECT images). ^1,5

Although there are continuing efforts to compensate for attenuation in SPECT, it is a much more difficult problem than in PET, requiring many more assumptions. ⁶ Clinical trials of attenuation-corrected SPECT MPI have been somewhat disappointing. ⁷ PET, on the other hand, offers very straightforward and well-established attenuation correction. ^1,5 In brief, a "blank" scan is performed by rotating a source of positron emitting radionuclide around the scanning table, before the patient is in the camera, and recording the number of counts measured by each detector. Later, this procedure is repeated with the patient lying on the table in the camera, producing an image that resembles a CT scan of the chest ("transmission" scan; Figure 1). The data from the transmission and blank scans are then used to correct the patient's PET Rb-82 myocardial perfusion images for the degrading effects of attenuation. ⁶ The practical effect of this correction is to produce MPIs that are free of distortions created by overlying structures in the chest. ^1,5 PET Rb-82 myocardial perfusion images can be acquired, processed, interpreted, and reported within 75 minutes.

Computer Software for Quantitative Analysis of PET Rb-82 Myocardial Images

Each PET manufacturer offers software packages for the analysis of PET images from their scanner. There are also a variety of programs available to supplement the manufacturers' software. In this article, we report on our experience with PET analysis software we've developed (INPET) to illustrate how PET image analysis and quantification works. However, such analysis can be performed with any similar software.

Software can analyze PET Rb-82 myocardial images, in terms of relative counts in regions of the left ventricle (LV). ⁸ The short axis images of the left ventricle (LV) can be displayed as polar maps, and these images can be summed in a group of normal individuals to represent the average LV distribution of PET Rb-82, as we have done previously for SPECT. ^8,9 Then each individual patient could be compared with this average LV count distribution, quantitatively, to express the differences from average as standard deviations (SD) below or above the mean normal value for that region or voxel. Enhanced resolution and attenuation correction with PET suggests that quantitative software for PET MPI can determine the extent and severity of perfusion defects more accurately than when the same software is applied to SPECT MPI. ¹⁰

In looking at a group of patients, we found remarkable advantages of PET Rb-82 for MPI acquired at rest and with dipyridamole-induced vasodilation ("stress"). ⁵ We compared the spatial heterogeneity of MPI in subjects with low clinical probability of CAD: 25 men and 25 women for PET Rb-82 and 25 men and 29 women for tread-mill stress Sestamibi and rest Tl-201. ¹¹ The same software was used to generate average and standard deviation polar maps (PMs) (Figure 2) from short-axis slices. For quantitative comparisons, PMs were segmented into 13 regions. PET Rb-82 MPI showed little heterogeneity with only small differences between men and women. Stress Mibi PMs were more heterogeneous, and virtually identical to rest Tl-201 PMs [ P = NS for 13 segments, Sestamibi versus Tl-201 [men (M) and women (W)]. Table 1 lists count ratios between different myocardial wall segments.

In summary, PET MPI was uniform and eliminated the following uncertainties caused by attenuation on SPECT: (a) differences between women and men on stress MPI, (b) the inferior wall "defect" in men, and the lateral wall "hot spot" in women and men. Of note, there was no difference between rest Tl-201 and stress sestamibi for SPECT in either women or men. ¹¹

Also, our INPET software aids in the identification of fixed versus reversible defects from Stress and rest PET Rb-82 myocardial perfusion images. Defect areas and normal areas from stress are mapped to the rest polar maps (SMAP polar display). Likewise, defect areas from the rest polar map are mapped to the stress polar map (RMAP). Finally, defect areas from rest are subtracted from the corresponding defect areas at stress and mapped to the stress and rest polar maps (S-R MAP) to indicate regions of "reversible defects"­­abnormal on stress but normal on rest. Numerical data are presented to quantify changes in defect size and severity, and the change in the ratio of ischemic zone counts to normal zone counts between stress and rest images. Figure 3 presents a patient study illustrating the clinical value of using quantitative PET MPI computer software.

Clinical Studies Comparing PET MPI with Coronary Angiography Using PET MPI software

Patient Population: Churchwell et al, ^2,12,13 in our group, compared quantitative PET Rb-82 MPI data with clinical data (n = 52) or coronary angiography (n = 91) to determine whether or not patients had CAD. Clinical data, including history of symptoms and risk factors and resting electrocardiogram findings, were used to identify a group with a very low probability of CAD, based on Framingham data ^13,14 for our normal file. Coronary angiography results were analyzed by computer to define the percentage diameter stenosis. ⁵ For the purpose of this study, CAD was defined as >40% reduction in lumen diameter; 72 of 91 patients had one or more arteries with lesions that met these criteria.

We analyzed PET MPI by varying the threshold values for defect size (% LV) and severity (average SD below mean of normal file) and found by this receiver-operator characteristic curve analysis ^1,12 that the best results to define an abnormal stress PET are: containing defect(s) of >=5% LV, with Rb-82 activity >=2.5 SD below normal.

Interobserver Agreement in PET MPI Interpretation

One of the most striking results was the remarkable interobserver agreement among all three interpreting physicians in 94% of 142 patients, with 95% confidence intervals (CI ) of 90% to 97%; and between two of the physicians in 97% of cases (CI = 95% to 98%). ^2,12,13 Our group had previously found a lower 89% (CI = 83% to 94%) agreement between two observers with SPECT, even though the quantitative software was similar. ^2,8,9 Such a high level of interobserver agreement with interpretation of PET MPI was a direct benefit of using quantitative software, and has major implications for the clinical usefulness of the test.

Comparison of PET MPI with Coronary Angiography

Using the same criteria for CAD, 71 of 72 patients with angiographic CAD were identified with PET MPI (99% sensitivity, CI = 96% to 100 %). Sixteen of 19 patients with no evidence of CAD on angiography were identified as "normal" (84% specificity, CI = 67% to 100%) (Table 2). ^2,12,13

Impact of "Referral Bias" on PET/Angiography Comparisons

Identification of patients as normal by coronary angiography creates a major disadvantage in that the people had some significant symptoms or disease that led to the referral to the cardiac catheterization laboratory. ^15,16 This problem of referral bias tends to select a small minority of people with normal test results for cardiac catheterization, so that calculated specificity is reduced artificially. ^15,16 Conversely, referral bias also means that only a small minority of people with normal test results are referred for cardiac catheterization, so that calculated sensitivity is inflated. ^15,16 One way to understand this issue is to study test results in people with a low probability of CAD based on clinical information. ^14,16 Thus, with PET MPI evaluation of 52 people with very low clinical probability of CAD, we found that all of them were normal (100% "normalcy rate"). ^2,12,13

Impact of PET on Uncertainties in Interpretation of MPI

In one year, 1997, we documented another benefit of PET. In 2748 patients there was a dramatic reduction in the number of interpretations by two experienced physicians that were classified as "probably" instead of "definitely" normal or abnormal; from 37% with SPECT, to 21% with PET (Table 3). The possibility of a nondiagnostic or uncertain interpretation of a noninvasive test has been one of the major factors driving physicians to recommend more costly invasive diagnostic studies. These results indicate that PET can produce unequivocal results in the great majority of patients.

Summary

PET Rb-82 offers a remarkably reliable, accurate assessment of myocardial perfusion that can improve clinical practice of cardiology. This article demonstrates how quantitative analysis of the images and comparison to normal files can enhance the value of the information of PET data. ¹⁷ The benefits of this analysis include: enhanced reproducibility of interpretations among different physicians; enhanced accuracy of discriminating whether or not a patient has CAD; increased certainty of diagnosis; rapid generation of reports that show uniformity; and creation of a database that allows comparison of clinical factors with quantitative image analysis.

17. For more information on the software, see our Web site: www.emory.edu/CRL.