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CLINICAL RESEARCH: NUCLEAR IMAGING

Ethnic Differences in the Prognostic Value of Stress Technetium-99m Tetrofosmin Gated Single-Photon Emission Computed Tomography Myocardial Perfusion Imaging

Leslee J. Shaw, PhD^_*,_*, Robert C. Hendel, MD, Manuel Cerquiera, MD, Jennifer H. Mieres, MD, Naomi Alazraki, MD^||, Elizabeth Krawczynska, MD^||, Salvador Borges-Neto, MD^¶, Jamshid Maddahi, MD^# and C. Noel Bairey Merz, MD^_*

^_* Cedars-Sinai Medical Center, Los Angeles, California
Midwest Heart Specialists, Fox River Grove, Illinois
Cleveland Clinic Foundation, Cleveland, Ohio
North Shore University, Long Island Jewish Health System, Long Island, New York
^|| Emory University, Atlanta VA Medical Center, Atlanta, Georgia
^¶ Duke University, Durham, North Carolina
^# UCLA Medical Center, Los Angeles, California.

Manuscript received December 29, 2003; revised manuscript received January 11, 2005, accepted January 25, 2005.

^_* Reprint requests and correspondence: Dr. Leslee J. Shaw, Taper Building, Room 125, 8700 Beverly Boulevard, Cedars-Sinai Medical Center, Los Angeles, California 90048. (Email: leslee.shaw{at}cshs.org).

Preliminary findings from this report were presented at the Annual Scientific Sessions of the American Heart Association in Orlando, Florida, November 2003.

	Abstract

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OBJECTIVES: This study was designed to evaluate the differential prognostic value of gated single-photon emission computed tomographic imaging (SPECT) imaging in an ethnically diverse multicenter registry.

BACKGROUND: Ethnic minority patient populations have reportedly higher coronary heart disease mortality with greater comorbidity and a clustering of risk factors at a significantly younger age when compared with Caucasian, non-Hispanic patients. Despite our increasingly diverse population, the predictive accuracy of cardiac imaging in ethnic minority patients is ill-defined.

METHODS: A total of 7,849 patients were prospectively enrolled in a registry of patients undergoing exercise (44%) or pharmacologic stress (56%) technetium-99m tetrofosmin SPECT. Scans were scored using a 20-segment myocardial model with a 5-point severity index. Multivariable Cox proportional hazards models were employed to assess time to death or myocardial infarction.

RESULTS: A total of 1,993 African-American, 464 Hispanic, and 5,258 Caucasian non-Hispanic patients underwent SPECT imaging. African-American and Hispanic patients more often had a history of stroke, peripheral arterial disease, angina, heart failure, diabetes, hypertension, and smoking at a younger age. Moderate or severely abnormal SPECT scans were noted in 21%, 17%, and 13% of African-American, Hispanic, and Caucasian non-Hispanic patients, respectively (p < 0.0001). Cardiovascular death rates were highest for ethnic minority patients (p < 0.0001). Annual rates of ischemic heart disease death ranged from 0.2% to 3.0% for Caucasian non-Hispanic and 0.8% to 6.5% for African-American patients with low-risk to severely abnormal SPECT scans (p < 0.0001). For post-stress ejection fraction <45%, annualized risk-adjusted death rates were 2.7% for Caucasian non-Hispanic patients versus 8.0% and 14.0% for African-American and Hispanic patients (p < 0.0001).

CONCLUSIONS: The current results from a large observational registry reveal that exercise and pharmacologic stress SPECT effectively predicts major cardiovascular events in a large cohort of African-American and Hispanic patients evaluated for suspected myocardial ischemia. These results provide further evidence that ethnic minority patient populations have a worsening outcome related to cardiovascular disease.

Abbreviations and Acronyms   EF = ejection fraction   MI = myocardial infarction   SPECT = single-photon emission computed tomographic imaging   Tc = technetium   Tl = thallium

Because of a greater risk factor and comorbidity burden, it may be hypothesized that ethnic minority patient populations might have specific challenges that limit the predictive accuracy of noninvasive cardiac tests for the estimation of near-term outcome. The purpose of the current report was to evaluate the differential prognostic value of the extent and severity of myocardial perfusion and left ventricular function measurements from gated single-photon emission computed tomographic imaging (SPECT) imaging in a ethnically diverse multicenter registry.

	Methods

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Patient inclusion.   Five geographically diverse centers enrolled 7,849 consecutively tested outpatients in a prospectively designed multicenter registry of technetium (Tc)-99m tetrofosmin SPECT; 134 Asian patients were excluded because of low statistical power for outcome analysis and our inability to discern ethnicity type (e.g., Indian). Site enrollment was 20% from Duke University Medical Center, 18% from Georgetown University Medical Center, 18% from Emory University Veterans Administration Hospital, 14% from Rush University Medical Center, and 30% from University of California at Los Angeles Medical Center. Patients gave informed consent and underwent SPECT for clinically referred reasons from April 1, 1997, to December 31, 1999. Patient enrollment occurred during the initial (approximate) 1 year of this study, with average daily site enrollment of 8 to 12 patients. A previous report included patients with low-risk perfusion SPECT was published (9).

Data collection procedures.   Data elements, definitions, and procedures were prospectively defined and uniformly applied across all institutions.

Stress testing procedures.   A total of 3,442 patients underwent symptom-limited exercise testing using a modified or standard Bruce protocol. Heart rate, blood pressure, and 12-lead electrocardiograms were recorded before (supine and upright positions) and during each minute of exercise and recovery. Standards for test conductance and termination were consistent with the current guidelines (10). Patients exercised until the point of volitional fatigue unless marked electrocardiographic abnormalities, hemodynamic instability, chronotropic incompetence, ventricular tachycardia or fibrillation, or disabling chest pain symptoms occurred. Exercise was discontinued if exertional hypotension, malignant ventricular arrhythmias, marked ST-segment depression, or limiting chest pain occurred. An abnormal electrocardiogram was defined as 1 mm ST-segment depression (J point + 60 ms) developed from rest to peak stress.

Pharmacologic stress testing.   Adenosine or dipyridamole pharmacologic stress testing was performed in 37% and 11% of patients, respectively. The remaining 8% of patients underwent dobutamine SPECT. Dipyridamole was infused at 0.142 mg/kg/min for 4 min (11). Patients exhibiting persistent side effects were administered 75 to 125 mg of aminophylline intravenously followed by nitroglycerin as needed. Adenosine was infused intravenously at a dose of 140 mg/kg/min over 6 min, with administration of the radiopharmaceutical at the midpoint of the infusion (11).

Dobutamine was infused using standard incremental dosing from 5 to 40 µg/kg/min, during which patients remained under continuous clinical and electrocardiographic monitoring (11). Test end points included completion of the final stage of the protocol, severe ischemia (severe angina, >2 mm ST-segment depression), hypertension (systolic blood pressure >220 mm Hg), hypotension (drop in systolic blood pressure >20 mm Hg), arrhythmias, or side effects intolerable to the patient. Atropine (1 mg intravenous) was used in patients who failed to attain 85% of age-predicted maximal heart rate at peak dose.

During testing, each patient was queried for symptoms of chest pain, dyspnea, fatigue, flushing, headache, nausea, and dizziness.

SPECT procedures.   The SPECT protocol utilized at each site was previously described (9) and performed in accordance with usual practice at each institution. For SPECT imaging, rest and stress Tc-99m (10% of patients) or thallium (Tl)-201 rest/Tc-99m stress (90% of patients) tetrofosmin was performed. Tomographic imaging was performed immediately following exercise and during the resting state using a gamma camera with a computer interface where acquisitions were performed over a 180° semicircular orbit. Data were acquired in a 64 x 64 matrix for 32 and 64 projections for Tl-201 and Tc-99m in a step-and-shoot format. Each image set (horizontal and vertical long-axis and short-axis planes) was normalized to maximal myocardial activity.

20-segment myocardial model interpretation.   Each scan was interpreted using a 20-segment myocardial model (12). Segments were graded using a 5-point scoring system ranging from 0 (normal) to 4 (absent perfusion). The 20-segment myocardial model has been previously reported and validated (11–13). Scores were summed from rest and stress scans to derive the summed rest and stress score. The difference between the summed stress and rest score is the amount of inducible ischemia or summed difference score. Risk-based categories for the summed stress score are low risk (scores 0 to 3), mildly abnormal (scores 4 to 8), moderately abnormal (scores 9 to 13), and severely abnormal (scores >13). We also categorized post-stress gated ejection fraction (EF) values <45% and 45% (n = 4,575).

Scans were interpreted by an experienced investigator blinded to the patient’s clinical history, ethnicity, and stress test results.

Follow-up procedures.   Each patient gave informed consent for the follow-up portion of this study. Each center had institutional review board approval for this registry and for the collection of follow-up data. Patients were contacted at six months and then yearly thereafter. During the telephone contact, an experienced nurse or physician completed a scripted interview in which each patient or a family member was queried for the occurrence of death and major cardiovascular events or hospitalizations.

Major adverse events included all-cause or cardiovascular death and hospitalization for acute myocardial infarction (MI), as well as the use of coronary revascularization procedures. Cardiovascular death was defined as that related to stroke, congestive heart failure, fatal MI, sudden cardiac death, or complications associated with cerebrovascular or peripheral arterial disease. An ischemic death was defined as that related to ischemic cardiomyopathy, sudden cardiac death, or fatal MI.

When a cardiac event was identified, medical records were reviewed or the referring physician was contacted to confirm the date and event circumstances. For all deaths, a death certificate was requested. This confirmation was conducted under the guidance of each site’s human investigations committee and performed by an experienced physician blinded to the clinical and stress test data. Follow-up was complete in 99% of patients. Time to follow-up for surviving patients was a median of 1.6 years (25th to 75th percentile 1.2 to 2.0).

Statistical analyses.   Continuous variables were summarized as means ± SD and categorical variables as percentages. Continuous variables were compared within subsets by analysis of variance techniques. Categorical variables were compared using a chi-square statistic. A probability value of <0.05 was considered statistically significant.

This study’s primary end point was time to cardiovascular death and the secondary end point was death or nonfatal MI. Cardiovascular death was subdivided as total cardiovascular and ischemic heart disease-related death.

We examined the univariable relations of clinical and stress variables to freedom from death and death or nonfatal MI. The Cox proportional hazards model was used to examine individual relations between clinical and stress imaging variables and outcome. Individual models estimating the relationship between SPECT and outcome were risk-adjusted by controlling for covariates (age, gender, diabetes, hypertension, smoking, angina, stroke or coronary disease history, heart failure, and peripheral arterial disease; the summed difference score was added to predictive models including EF). From the multivariable models, risk-adjusted relative risk ratios and 95% confidence intervals were calculated. A stratified Cox model was employed to calculate differences in survival for patients undergoing exercise and pharmacologic stress. A test for interaction of ethnicity by gender was calculated. A Bonferroni correction was applied for multiple comparisons.

	Results

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Past medical history and presenting symptoms by SPECT results (Table 1).   African-American and Hispanic patients were more often women (p < 0.0001) and less likely to have a prior history of coronary disease or revascularization procedure (p < 0.0001) as compared with Caucasian non-Hispanic patients (p < 0.0001). In general, African-American and Hispanic patients had a greater degree of comorbidity including more prior stroke, heart failure symptoms, peripheral arterial disease, as well as a greater frequency and clustering of traditional cardiac risk factors (all p < 0.0001).

View larger version (14K): [in this window] [in a new window]   Figure 1 Frequency of low risk, mildly abnormal, moderately abnormal, and severely abnormal summed stress scores in African American, Hispanic, and Caucasian non-Hispanic patients. Black bars = severe; hatched bars = moderate; dotted bars = mild; white bars = low. p < 0.0001.

View larger version (31K): [in this window] [in a new window]   Figure 2 Estimated annual death rates by summed stress score risk group in African-American, Hispanic, and Caucasian non-Hispanic patients. All-cause death: chi-square = 33, p < 0.0001; cardiovascular death: chi-square = 127, p < 0.0001; ischemic heart disease death: chi-square = 109, p < 0.0001. CV= cardiovascular; IHD = ischemic heart disease. *No ischemic heart disease deaths reported.

The time to cardiovascular death or nonfatal MI is plotted in Figures 3A and 3B for African-American, Hispanic, and Caucasian non-Hispanic patients (model chi-square = 192, p < 0.00001). At two years, the overall rate of event-free survival was 96% for Caucasian non-Hispanic patients with a low risk SPECT as compared with 93% and 91% for African-American and Hispanic patients, respectively (p < 0.0001). Decrementally worsening event-free survival was noted with an increasing extent and severity of the summed stress score but was lowest, at approximately 60% to 65%, for African-Americans and Hispanics with severely abnormal SPECT scans (p < 0.0001). Of the low risk, those with a summed stress score of 0 had higher event-free survival (p < 0.0001) where 2-year event-free survival was 94% for African-American, 91% for Hispanic, and 97% for Caucasian non-Hispanic patients, respectively (p < 0.0001).

View larger version (24K): [in this window] [in a new window]   Figure 3 (A) Survival free from cardiovascular death or myocardial infarction in African-American and Hispanic patients. Model chi-square = 192; p < 0.0001. *n = available sample every 0.5 years of follow-up for low, mild, moderate, and severely abnormal scans. (B) Survival free from cardiovascular death or myocardial infarction in Caucasian non-Hispanic patients. Model chi-square = 192; p < 0.0001. *n = available sample every 0.5 years of follow-up for low, mild, moderate, and severely abnormal scans. Asian patients were not included in this analysis because of small sample scans.

View larger version (23K): [in this window] [in a new window]   Figure 4 Annualized risk-adjusted cardiovascular death or myocardial infarction rate by post-stress left ventricular ejection fraction for African-American, Hispanic, and Caucasian non-Hispanic patients. Line of best fit was a cubic spline fit with 95% confidence intervals.

View larger version (15K): [in this window] [in a new window]   Figure 5 Risk-adjusted relative risk of cardiac death or myocardial infarction (MI) by summed stress score risk in African-American and Hispanic patients versus Caucasian non-Hispanic patients undergoing Tc-99m myoview single-photon emission computed tomographic imaging. CI = confidence interval.

View larger version (17K): [in this window] [in a new window]   Figure 6 Risk-adjusted relative risk of cardiac death or myocardial infarction (MI) by summed stress score risk in African-American and Hispanic patients versus Caucasian non-Hispanic patients undergoing adenosine/dipyridamole Tc-99m myoview single-photon emission computed tomographic imaging. CI = confidence interval.

	Discussion

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The current results support prior evidence that ethnic minority patient populations have a disproportionate burden of worsening outcome related to cardiovascular disease (14). Prior evidence, in largely Caucasian non-Hispanic populations, suggests that noninvasive stress testing may be used to assess a patient’s risk of major adverse cardiac events (10). In contrast to prior reports, we compared the prognostic value of SPECT imaging results in a large cohort of African-American and Hispanic stable outpatients. Our results reveal that risk stratification is highly effective at predicting cardiac death and MI in a large cohort of African-American and Hispanic patients based upon exercise and pharmacologic stress myocardial perfusion and ventricular function measures. Notably, African-American and Hispanic patients had a greater risk of events at all levels of SPECT scan severity as compared with Caucasian non-Hispanic patients (10). Adjustments for baseline group differences did not significantly alter these results.

Differential prognosis and coronary disease extent in racial and ethnic subsets.   Higher coronary heart disease death rates have been reported in ethnic minority populations; in particular a higher risk profile at younger ages when compared with Caucasian non-Hispanic cohorts (2–5,14). Numerous investigators have proposed that increases in risk factor prevalence and clustering across racial and ethnic minority populations are an explanation for the excess cardiovascular mortality (3–5,14). Notably, these prior reports also demonstrate less obstructive coronary disease on angiography and less extensive coronary calcification, suggesting an uncoupling between risk factor burden and coronary stenosis extent and severity (3–5,8). The current results demonstrate that there is a higher prevalence of stress-induced perfusion abnormalities in minority populations. Ethnic minority patients with stress-induced myocardial perfusion and ventricular function abnormalities were associated with a higher risk of cardiovascular death at all levels of scan severity and similarly point to ethnic differences in coronary disease pathophysiology. That is, there is a notable increased risk of events in the setting of abnormal perfusion abnormalities.

However, overall rates of acute coronary syndromes were significantly higher for Caucasian non-Hispanics (Table 3). Thus, ethnic differences in event rates appear to be largely driven by fatal ischemic and other vascular events. Issues of financial means, health care access, and having a regular source of care may affect differential hospitalization rates for ethnic minority patients (3–5,14). From the current series, the decidedly higher rates of diabetes in our ethnic minority patients could result in a greater frequency of silent MIs due to the prevalence of diabetic neuropathy. This is supported by an increased incidence of significant Q waves on minority patient’s resting electrocardiogram (Table 2).

Racial and ethnic differences in cardiac imaging.   Limited prior research suggests that phenotypic differences in coronary disease imaging between ethnic groups may explain differences in outcome (7,8,15–19). For ethnic minority patients, differences with regards to vascular function or vasomotor responsiveness, which are modulated by a patient’s risk factor burden, may facilitate higher event risk at any level of obstructive coronary disease burden. In the current series, we noted a higher prevalence and worsening risk with inducible myocardial perfusion abnormalities for African-American and Hispanic patients. For the largest ethnic minority population discussed herein, African Americans, higher rates and protracted years of hypertension (14,20) promote focal and generalized retinal artery narrowing leading to greater rates of carotid plaque, stroke, and MI (21). Asymptomatic African Americans enrolled in the CARDIA study also exhibited a higher diastolic and systolic reactivity to stress, leading to a greater proclivity toward hypertension development (22). Additionally, published reports on brachial artery reactivity testing in African Americans have noted a greater prevalence of endothelial dysfunction (23).

Our results also reveal a greater prevalence and risk associated with moderate or severely abnormal myocardial perfusion imaging in ethnic minority patients as compared with Caucasian non-Hispanic patients. Synthesizing this evidence suggests that physiologic abnormalities may play a greater role in risk assessment than does obstructive disease burden for ethnic minority patients. Prior evidence on racial differences in cardiac stress testing is limited to very small series of patients (1,2). The majority of prognostic data are largely based on Caucasian non-Hispanic populations. A synthesis of this evidence reports that normal perfusion is associated with an exceedingly low rate of cardiac death or MI (i.e., <1% per year) (13). In the current ethnically diverse series, risk stratification resulted in patients with a low-risk scan having an associated death rate exceeding 1% over 2 years for African-American and Hispanic patients (24,25). Similarly, Akinboboye et al. (2) noted a similarly high 2% annual risk of major cardiovascular events in 592 African-American patients with low risk SPECT results.

Study limitations.   Although we enrolled a large cohort of ethnic minority patients, differences among specific subsets may be underpowered, in particular for the small series of Hispanic patients. Despite this, we do have sufficient statistical power to detect differences between African-American and Caucasian non-Hispanic patients. Finally, patient outcomes are influenced multifactorially, and our current predictive models likely fail to account for the gamut of explanatory variance in predictive models. We attempted hierarchical predictive models for all-cause, cardiovascular, and ischemic deaths. Although event classification improved when estimating cardiac events, misclassification of death cause could confound these results. We examined the comparative prognostic value of SPECT imaging across multiple groups; although many of these analyses were highly significant, we did not routinely employ statistical corrections for multiple comparisons.

Conclusions.   There is currently a paucity of evidence as to the prognostic value of many commonly performed cardiac diagnostic tests in ethnic minority patients. The recent National Healthcare disparities report, released by the Department of Health and Human Services, recognized that racial and ethnic disparities in health care were a national problem (26). Unraveling differences in health care disparities are complex and may be affected by clinical, genetic, and financial differences that influence clinical outcomes. Furthermore, in many urban environments, there is a growing diversity of stress testing laboratory populations, including a greater representation of African-American and Hispanic patients. Rapid population shifts in ethnicity may challenge the health care system and further contribute to suboptimal health care for minorities. In fact, our results from a prospectively designed multicenter registry of 7,849 patients include greater ethnic and racial diversity than previously reported.

A synopsis of this evidence reveals that SPECT imaging is capable of providing prognostication based upon the extent and severity of perfusion abnormalities as well as with gated EF results for African-American and Hispanic patients. As ethnic minority patients have a greater degree of comorbidity and vascular disease, higher than expected cardiovascular events were noted within low- to high-risk SPECT results when compared with Caucasian non-Hispanic patients. Thus, for African-American and Hispanic patients, post-SPECT management strategies should aggressively focus on ameliorating their ischemic and atherosclerotic disease burden. For our ethnic minority patients, a differential threshold for initiation of targeted care should be considered even for those patients with mildly abnormal SPECT scans. A greater intensity of post-SPECT treatment may reduce the excess morbidity and mortality for our ethnic minority patients. Unfolding this evidence should aid in developing management strategies optimized for ethnically diverse patient populations.

	Footnotes

 
This registry was supported in part by an unrestricted grant from Amersham Health.

	References

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