Research ArticleArticle

Risk Factors for Clinical Coronary Heart Disease in Systemic Lupus Erythematosus: The Lupus and Atherosclerosis Evaluation of Risk (LASER) Study

SAHENA HAQUE, CAROLINE GORDON, DAVID ISENBERG, ANISUR RAHMAN, PETER LANYON, AUBREY BELL, PAUL EMERY, NEIL McHUGH, LEE SUAN TEH, DAVID G.I. SCOTT, MOHAMED AKIL, SOPHIA NAZ, JACQUELINE ANDREWS, BRIDGET GRIFFITHS, HELEN HARRIS, HAZEM YOUSSEF, JOHN McLAREN, VERONICA TOESCU, VINODH DEVAKUMAR, JAMAL TEIR and IAN N. BRUCE
The Journal of Rheumatology February 2010, 37 (2) 322-329; DOI: https://doi.org/10.3899/jrheum.090306

Abstract

Objective. Accelerated atherosclerosis and premature coronary heart disease (CHD) are recognized complications of systemic lupus erythematosus (SLE), but the exact etiology remains unclear and is likely to be multifactorial. We hypothesized that SLE patients with CHD have increased exposure to traditional risk factors as well as differing disease phenotype and therapy-related factors compared to SLE patients free of CHD. Our aim was to examine risk factors for development of clinical CHD in SLE in the clinical setting.

Methods. In a UK-wide multicenter retrospective case-control study we recruited 53 SLE patients with verified clinical CHD (myocardial infarction or angina pectoris) and 96 SLE patients without clinical CHD. Controls were recruited from the same center as the case and matched by disease duration. Charts were reviewed up to time of event for cases, or the same “dummy-date” in controls.

Results. SLE patients with clinical CHD were older at the time of event [mean (SD) 53 (10) vs 42 (10) yrs; p < 0.001], more likely to be male [11 (20%) vs 3 (7%); p < 0.001], and had more exposure to all classic CHD risk factors compared to SLE patients without clinical CHD. They were also more likely to have been treated with corticosteroids (OR 2.46; 95% CI 1.03, 5.88) and azathioprine (OR 2.33; 95% CI 1.16, 4.67) and to have evidence of damage on the pre-event SLICC damage index (SDI) (OR 2.20; 95% CI 1.09, 4.44). There was no difference between groups with regard to clinical organ involvement or autoantibody profile.

Conclusion. Our study highlights the need for clinical vigilance to identify modifiable risk factors in the clinical setting and in particular with male patients. The pattern of organ involvement did not differ in SLE patients with CHD events. However, the higher pre-event SDI, azathioprine exposure, and pattern of damage items (disease-related rather than therapy-related) in cases suggests that a persistent active lupus phenotype contributes to CHD risk. In this regard, corticosteroids and azathioprine may not control disease well enough to prevent CHD. Clinical trials are needed to determine whether classic risk factor modification will have a role in primary prevention of CHD in SLE patients and whether new therapies that control disease activity can better reduce CHD risk.

Accelerated atherosclerosis and premature coronary heart disease (CHD) are recognized complications of systemic lupus erythematosus (SLE)1. The pathogenesis of CHD in SLE appears to be a complex interaction of inflammatory, metabolic, and therapy-related factors, and those patients at high risk are difficult to identify. There is an increased prevalence of classic risk factors such as hypertension and diabetes mellitus among patients with SLE2,3. It is, however, argued that classic risk factors alone do not fully account for the burden of disease observed4. Additional factors associated with SLE such as inflammatory factors, prothrombotic states, renal disease, and the potential effects of lupus therapies are also believed to be relevant.

There are a large number of studies examining subclinical atherosclerosis in SLE using measures not widely available in the routine clinical setting. Only a few studies have specifically examined the risk factors for clinical events, of which a number include vascular events other than CHD, including stroke, peripheral vascular disease, or venous thromboembolism. It cannot, however, be assumed that these events will share the same precise pathological processes or precipitants1,59. As a result, findings of such studies have been variable and there is a lack of consistency across studies in factors identified.

We examined risk factors for the development of clinical CHD in the clinical setting in a multicenter UK network. The hypothesis tested was that patients with CHD have increased exposure to traditional risk factors, differing disease phenotype, and therapy-related factors compared to patients with SLE free of CHD.

MATERIALS AND METHODS

Patients

Thirteen UK centers from the British Isles Lupus Assessment Group (BILAG) and the British Society of Rheumatology Lupus Special Interest Group participated between August 2003 and July 2006. Rheumatologists identified SLE patients in their clinics using existing clinical or research databases. All subjects fulfilled the modified 1997 American College of Rheumatology (ACR) criteria for SLE10, which were verified by chart review at the time of data collection.

Cases

A case was defined as a patient with SLE who had a history of a first myocardial infarction (MI) or first diagnosis of angina pectoris after SLE diagnosis. MI was confirmed on the basis of 2 of the following 3: typical anterior/retrosternal chest pain; typical electrocardiographic changes or an elevation of cardiac enzymes (creatine kinase or troponin)11. Angina pectoris was defined as exertional or stress-related central chest pain relieved by rest or glyceryl trinitrate. In addition, confirmation of diagnosis of angina by a consultant cardiologist or by objective test such as a stress test or angiography was required.

Controls

For each case identified, 2 control subjects were recruited from the same center. The controls had no history of CHD and were matched for date of SLE onset (within 2 yrs) to enable matching for disease duration. Disease onset in all subjects was defined as the date that 4 ACR criteria were fulfilled10. Where more than 2 potential control subjects were identified for a case, random-number generation was employed to allow unbiased selection of 2 controls. We therefore matched cases and controls only on the basis of disease duration. This is because disease duration and duration of corticosteroid exposure are difficult to distinguish from each other as they are closely associated. By matching on disease duration we hoped to determine better the role of corticosteroid exposure to CHD risk.

Subjects were excluded if inadequate clinical information to confirm diagnosis of SLE and/or CHD was available from case note reviews or if they refused to provide informed consent. Sixty-one suitable cases were identified, of which 8 were excluded, and 121 controls were identified of which 25 were excluded (Figure 1). Two suitable controls were identified for 43/53 cases, and one control subject was identified for each of the 10 remaining cases because of (i) inability to match for disease duration, or (ii) because inadequate information was available from chart review, or (iii) the control subject declined to participate in the study. Therefore a total of 53 cases and 96 controls were recruited.

Figure 1
Figure 1

Selection of cases and controls. CHD: coronary heart disease; SLE: systemic lupus erythematosus.

Study design

Data were collected by retrospective chart review using a predesigned form to standardize the information collected. Clinical and serological data were collected for each case up to the time of the coronary event. For matched controls we collected the same data up to a preassigned “dummy” date that was taken as the date of the event in their respective case (Figure 2).

Figure 2
Figure 2

Overview of study design and data acquisition window for exposures in cases and controls.

Information collected included clinical features, laboratory observations (inflammatory markers, biochemistry, hematology, and autoantibody profile), the Systemic Lupus International Collaborating Clinics/American College of Rheumatology (SLICC/ACR) Damage Index (SDI) score12, and details of therapy exposure. The SDI was assessed in patients using information gathered from clinic note reviews up to the visit prior to diagnosis of the coronary event. Therefore the coronary event did not contribute to this score. Corticosteroid treatment was categorized as “previous use” or “never used,” and the average daily dose was calculated where available. Details of immunosuppressive treatment were also collected. The presence of cardiovascular risk factors prior to the event or dummy date was noted.

Hypertension was defined as a systolic blood pressure of > 140 mm Hg or diastolic > 90 mm Hg or receiving treatment with an antihypertensive drug. Hypercholesterolemia was defined as total cholesterol > 5.2 mmol/l, or receiving lipid-lowering therapy (when total cholesterol had not been recorded prior to an event, a value 3–6 months after the event was sought from the chart review and recorded where available). A positive family history of cardiovascular disease was defined as MI, angina, or sudden cardiac death in a first-degree relative: male < 55 years or female < 60 years of age. Diabetes mellitus was defined as fasting plasma glucose > 7.0 mmol/l or current diabetic therapy. Smoking was recorded if the patient was noted in their medical record to have smoked prior to the clinical event or dummy date.

Clinical features of SLE such as malar rash, serositis, etc., were based on the physician’s contemporaneous notes and clinic letters. In general each clinical feature or laboratory observation was noted as “ever present” and classified into organ systems as per the “classic” BILAG index13. Renal disease was defined as any patient with persistent proteinuria (> 500 mg/day), otherwise unexplained microscopic hematuria, chronic renal insufficiency, nephrotic syndrome, or any grade of verified lupus nephritis. For all cases followup data were also recorded, including recurrent coronary events, interventions undertaken, and vital status at the time of the study. Information was verified from additional primary or secondary care physicians as appropriate.

Statistical analysis and ethics

Data were analyzed using Stata 9.2 statistical software. Comparisons were made between cases and controls by means of a 2-sample t-test for continuous variables and by chi-square analysis for categorical variables. Two-sided p values < 0.05 were considered to be significant. Logistic regression was used for multivariable analyses, with adjustment for disease duration to account for matching. There were some subjects in whom information was missing with regard to cardiovascular risk factors (details of hypertension missing for 1 case and 2 controls; hypercholesterolemia for 8 cases and 16 controls; family history of CHD for 14 cases and 22 controls; smoking status for 3 controls). For those variables where information was missing the analysis was undertaken using only those records that were complete, and raw data figures as well as the percentage are given where appropriate. The study was approved by the North-West Multicentre Research Ethics Committee (Reference number 03/8/012). Informed consent was obtained locally for all subjects. Data collection was permitted by the ethics committee for deceased patients from review of case records.

RESULTS

Cardiovascular events

Cases and controls were well matched for disease duration [mean (SD) 11 (8) vs 10 (8) yrs, respectively]. Of the 53 SLE patients with CHD, 23 (43%) cases had an MI and 30 (56%) had angina. Seven (32%) cases with MI fulfilled 2 of 3 criteria and 15 (68%) fulfilled all 3 criteria for MI. One additional patient presented with central crushing chest pain followed by sudden death attributed to MI. All cases with angina pectoris had a diagnosis verified by a consultant cardiologist, except one patient who presented to a general internist with documented chest pain characteristic of angina associated with a rise in creatine kinase and a minor rise in troponin, consistent with acute coronary syndrome but not MI. In view of the convincing clinical history of angina, supporting biochemical tests, and review by general internist, this case was included. Angina was confirmed using an objective confirmatory test in 24/30 patients. The mean (SD) age at the time of the first coronary event was 53 (10) years. The age at time of the event ranged from 33 to 73 years, and notably 12 (23%) events occurred under age 45 years (Figure 3). Of 52 patients that survived the initial event, 12 (23%) subsequently died over a mean (SD) of 8 (5) years. Eighteen (35%) cases underwent coronary interventions; 12 had balloon angioplasty or coronary stent insertion and 6 underwent coronary revascularization. Seven patients (39% of those with any intervention) underwent multiple interventions, although none had a second bypass graft. Of the 18 patients that underwent an intervention, a successful outcome was achieved in 5 (28%) patients, i.e., they remained symptom and medication-free at the time of study assessment. Of the remainder, 8 (44%) patients continued on medication or remained symptomatic, 3 patients died, and the outcome is unknown in 2 patients.

Figure 3
Figure 3

Distribution of age at onset of first coronary heart disease event in patients with systemic lupus erythematosus.

Demographics

Cases were older than controls at the time of the event [mean (SD) 53 (10) vs 42 (10) yrs; p < 0.001) and were more likely to be male [11 (20%) vs 3 (7%); p < 0.001). All further analyses were adjusted for age and gender. The other subject characteristics are described in Table 1. Prior to the CHD event, cases also had higher body weight compared to controls, and in the 25 cases and 38 controls in whom body mass index (BMI) could be calculated, the mean (SD) BMI was higher in cases [mean 28 (6) vs 25 (5); p < 0.01).

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Table 1

Comparison of demographic and key lupus characteristics in cases and controls. All data are mean (SD) unless otherwise indicated.

Classical CHD risk factors

All classic CHD risk factors examined occurred more frequently in cases compared to controls, and in the age and gender adjusted analysis, hypertension (adjusted OR 2.56, 95% CI 1.05, 6.25) and a family history of premature CHD (adjusted OR 3.62, 95% CI 1.15, 11.34) were associated with CHD events (Table 2). Only 2 subjects in the entire cohort had diabetes mellitus.

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Table 2

Exposure of cardiovascular risk factors in SLE patients with coronary heart disease.

SLE organ involvement

In the whole population studied, the mean (SD) time from onset of autoimmune features (first SLE criterion) to fulfilling 4 ACR criteria was 4.8 (7.8) years. This time was significantly shorter for cases than controls [mean (SD) 3.6 (6.4) vs 6.9 (9.5) yrs; p = 0.02). Cases and controls did not differ with regard to organ system involvement of their SLE. In particular, there were no statistically significant differences between the 2 groups with regard to inflammatory or valvular cardiac involvement. There were only 2 patients who ever had myocarditis and both were cases. The proportion of cases and controls with a history of verified lupus nephritis did not differ. In 33 cases and 63 controls for whom data were available, the maximum creatinine recorded at any time prior to the event date was significantly higher in cases [mean (SD) 137 (23) μmol/l vs 92 (2) μmol/l; p = 0.01]. In the unadjusted analysis, cases were also more likely to have at least one item of damage scored on the SDI (OR 2.20; 95% CI 1.09, 4.44; Table 3). An exploratory analysis of the damage items noted that alopecia (1% vs 6%; p = 0.09), skin scarring (0% vs 4%; p = 0.05), premature gonadal failure (0% vs 6%; p = 0.02), and claudication (0 vs 8%; p = 0.006) were all more frequent in cases than in controls.

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Table 3

Clinical, serological, and therapeutic exposures in SLE patients with coronary heart disease. Values in bold type are statistically significant.

Serology

The 2 groups were similar with regard to serology (Table 3). Notably, there was no significant difference in the proportion of cases and controls that had positive antiphospholipid antibodies (aPL) or lupus anticoagulant (LAC) (adjusted OR 2.6; 95% CI 0.93, 7.1). There were no differences between cases and controls with regard to anti-dsDNA antibody (adjusted OR 0.76; 95% CI 0.37, 1.55) or anti-RNP antibody (unadjusted OR 1.04; 95% CI 0.48, 2.26) positivity.

Therapy

Cases were more likely to have had corticosteroid therapy (OR 2.46; 95% CI 1.03, 5.88), although after adjustment this was no longer significant. Of the 111/149 subjects that were treated with steroids, doses were available for 89 subjects. The mean (SD) steroid dose for cases (n = 40) was 8.1 (10) mg and for controls (n = 49) 9.1 (12) mg. The increased azathioprine exposure was, however, significant in both the unadjusted and adjusted analyses (adjusted OR 3.18; 95% CI 1.33, 7.59). In contrast, there were no differences in exposure to other immunosuppressive agents between the groups. Only 3 patients had been prescribed mycophenolate mofetil. With regard to other therapies, aspirin exposure was similar between the groups [20 (25%) vs 13 (21%); p = 0.37], and a higher proportion of cases had been prescribed a lipid-lowering drug prior to the event date [7 (14%) vs 2 (2%); p = 0.005], consistent with the increased frequency of hypercholesterolemia.

DISCUSSION

In this UK-wide case-control study we found that SLE patients with clinical CHD were older, more likely to be male, and had more exposure to classic CHD risk factors. They were also more likely to have been treated with corticosteroids and azathioprine and have evidence of damage on the pre-event SLICC damage index. The older age at event is consistent with other studies that have shown an older age at time of diagnosis is associated with CHD1,14. The mean age at the time of first coronary event in this study was 53 years, which accords with the range of 47–51 years reported in previous studies1,6,7,9. Male patients were overrepresented in the cases, as noted by Petri, et al7. Overall, 20% of cases were male compared to 7% of controls. The control group is consistent with the expected background gender distribution of SLE in the UK15 and confirms the risk of CHD in men with SLE to be particularly increased.

Classic risk factors for CHD, i.e., hypercholesterolemia, hypertension, smoking, and family history of CHD, were associated with clinical CHD; after adjustment for age and gender, hypertension and family history of CHD remained significantly associated with CHD events. These results are in keeping with 3 previous North American studies that used clinical CHD as an outcome1,6,7, and contrasts with studies that included other cardiovascular outcomes in addition to CHD5,8,16,17, where the contribution of classic risk factors is less clear (Table 4). This is because additional factors may contribute to the risk of other outcomes, e.g., atrial fibrillation and valvular heart disease are likely to also be important in stroke risk1820; similarly, the hierarchy of risk factors for peripheral vascular disease also differs from CHD21. Our study confirms the findings of previous prospective cohort studies that classic risk factors play a key role in the development of CHD in lupus patients7,22. A recent study has suggested that, although our recognition and treatment of classic risk factors such as hypertension and hypercholesterolemia has improved over time, a number of SLE patients eligible for treatment remain untreated23. One contributing factor for this observation may be the lack of any trials to delineate whether aggressive risk factor modification will reduce clinical events in SLE and the logistical difficulties of conducting such studies in the setting of SLE24. Our study, however, highlights the need for such intervention trials against clinical outcomes to answer this key question in SLE.

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Table 4

Summary of studies examining risk factors for clinical cardiovascular events in patients with SLE. Values are mean (range or ± SD).

In agreement with others, we found that SLE-related factors are also important in CHD development8,9,17. The SLICC/ACR damage index (SDI) prior to the event showed a significant association with clinical CHD in the unadjusted analysis. It has been noted that patients who develop SLE at an older age accrue damage at a higher rate than SLE patients with a younger age of onset25 and hence the less significant result after age and gender adjustment. The main damage items that scored among cases were skin scarring, alopecia, premature gonadal failure, and claudication. Interestingly, few SDI items in these patients included factors directly attributable to the consequences of corticosteroid use, e.g., cataracts or osteoporosis, suggesting that SLE-associated disease activity and damage resulting from this may be important in the predisposition to CHD. Of note, the proportion of patients with lupus nephritis did not differ between cases and controls, and this finding is also consistent with previous studies1,68. Information regarding lupus nephritis was verified by chart review and biopsy reports in all cases. Importantly, however, cases had a higher peak serum creatinine “ever” compared to controls, suggesting that (as in the general population) renal impairment, regardless of etiology, is important to consider as a risk factor for CHD26.

Corticosteroid treatment and azathioprine were both associated with CHD, and azathioprine remained significant in our adjusted analysis. Azathioprine exposure has been shown to be associated with both subclinical and clinical vascular events in SLE17,27,28. This association may be explained in part by disease severity; however, other “severity” features such as vasculitis, nephritis, or neurological involvement were not significantly different between groups, and exposure to other immunosuppressive agents showed no significant differences between groups. The higher SDI and the association of clinical CHD with corticosteroids and azathioprine suggest that current therapies may not sufficiently control persistent grumbling disease activity to prevent irreversible damage in SLE. In addition, a recent study suggested that episodes of disease activity and episodes of higher steroid use both independently contribute to exacerbation of classic risk factors in SLE, which may provide a further mechanism by which persistent disease and therapy together mediate cardiovascular risk in SLE29.

A surprising finding is the lack of association between CHD events and aPL or LAC. Other studies using clinical outcomes have been inconsistent in this regard (Table 4). A lack of statistical power in most studies to date is the most likely explanation for this inconsistency. Others have found an association between LAC and cardiovascular disease outcomes in studies that include stroke, MI, and peripheral vascular disease8,16. There is also evidence that aPL may be pro- or anti-atherogenic27,30 and therefore measurement of specific aPL subtypes may have more predictive value than routine clinical tests.

Of the cases surviving their initial event 18 (35%) subsequently underwent a coronary intervention including balloon angioplasty, coronary artery stent insertion, or revascularization. A favorable outcome was observed in one-third of these patients over a mean (SD) of 8 (5) years’ follow-up. Although a few small case series have described an acceptable immediate outcome in patients with SLE undergoing coronary intervention, the long or medium term outcome in these patients remains unknown3133.

It is important to consider the limitations of a study such as this. The association between SDI and azathioprine exposure is interesting; however, in view of the retrospective data collection, we lacked accurate disease activity measures over time on which to base any firm conclusions from these observations. The relatively small sample size is also a key limitation. Some difficulty was encountered collecting data because of missing information in medical records. For example, information was missing in up to 20% of subjects with regard to patient-assigned ethnicity, hyperlipidemia, and family history. However, we deliberately designed the study to match by center as we anticipated that the quality of data collection and missing information might be an issue, and our analysis suggested that data quality did indeed balance out between cases and controls according to the recruiting center. Complete data regarding most other variables were available in 98% or more of the subjects. To limit information bias, data were verified from other sources including cardiology and general practice records. In keeping with many studies, an accurate measure of corticosteroid exposure was difficult to ascertain owing to the retrospective nature of data collection. As a result, previous corticosteroid exposure of any length or dose appeared to be the most robust and verifiable measure and was therefore used in the analysis. As with any case-control study, bias introduced regarding case ascertainment and left censorship may be an issue. However, all participating centers had clinical or research databases allowing sampling from all eligible patients, including those that had died. Cases did have a shorter time from first criteria being met to diagnosis. This might have resulted in an underestimation of the exposure to immunosuppressant therapy in some subjects as data regarding treatment were collected from the time of diagnosis, i.e., the time 4 ACR criteria were fulfilled. A longer delay to fulfilling criteria in the controls, however, would bias our results towards the null hypothesis. This observation of shorter time between onset of symptoms and diagnosis in cases with CHD is also consistent with the hypothesis that these patients had more aggressive active disease34.

To our knowledge, this is the largest study to date examining risk factors for verified CHD as a discrete clinical outcome in SLE. Our results confirm that classic risk factors and certain SLE-related characteristics are associated with an increased risk of CHD35. Our study highlights the importance of male gender and classic risk factors and the need for clinical vigilance to identify modifiable risk factors in the clinical setting. The higher pre-event SDI, azathioprine exposure prior to events, shorter time to diagnosis from symptom onset, and the pattern of damage items in cases suggest that a persistent active lupus phenotype contributes to CHD risk. In this regard, corticosteroids and azathioprine may not control disease well enough to prevent CHD. Evidence from clinical trials is now needed to resolve the question of whether classic risk factor modification will have a role in preventing clinical CHD events in SLE patients and to determine whether new therapies that better control disease activity can reduce the CHD risk.

Acknowledgments

The authors would like to acknowledge Donna Taylor-Fesler and Nicola Dale for their administrative support; and Dr. Kathleen McElhone, Alice Muir, Joanna Shelmerdine, and Margaret McQuilkin for help with data collection at individual study centers.

Footnotes

  • Supported by a grant from Lupus UK. Additional support was obtained from the arc Epidemiology Unit core support grant. Prof. Bruce received support from The Manchester Academic Health Science Centre and The Manchester NIHR Biomedical Research Centre.

    • Accepted for publication August 31, 2009.

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