1Royal Brompton and Harefield NHS Trust, Sydney Street, London SW3 6NP, UK
2London School of Hygiene and Tropical Medicine, London, UK
3Hospital Universitario Gregorio Maranon, Madrid, Spain
4Policlinico S Matteo, Pavia, Italy
5Department of Cardiology, Erasmus Medical Centre, Rotterdam, The Netherlands
6Hopital Europeen Georges Pompidou, Paris, France
7Hopital Cardiovasculaire et Pneumologique Louis Pradel, Lyons, France
8Herzzentrum Luwigshafen, Ludwigshafen, Germany
9University of Newcastle upon Tyne, Newcastle upon Tyne, UK
10Adelaide and Meath incorporating National Children's Hospital, Dublin, Ireland
11Institute of Cardiology, Warsaw, Poland
12Aarhus University Hospital, Aarhus, Denmark
13University Medical Centre St Radboud, Nijmegen, The Netherlands
Received 15 September 2004; revised 7 January 2005; accepted 13 January 2005; online publish-ahead-of-print 18 March 2005.
* Corresponding author. Tel: +44 207 3518289; fax: +44 207 3518643. E-mail address: c.daly{at}rbh.nthames.nhs.uk or carolinenidhal{at}hotmail.com
See page 949 for the editorial comment on this article (doi:10.1093/eurheartj/ehi294)
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Abstract |
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Methods and results Consecutive outpatients with a clinical diagnosis by a cardiologist of stable angina were enrolled in the study and 3779 patients were included in the analysis. The average age was 61 years and 58% were male. The majority of patients (88%) had mild to moderate angina, CCS class I or II. Despite a high prevalence of recognized risk factors, 27% did not have cholesterol and 33% did not have glucose measured within 4 weeks of assessment. The resting ECG was abnormal in 41% of patients. An exercise ECG was performed or planned as part of initial investigation in 76% of patients and 18% had a stress imaging test such as perfusion scanning or stress echo. A coronary angiogram was performed or planned in 41%, and 64% had an echo. The time from assessment to investigation varied widely, particularly for angiography. One in 10 patients had neither any form of stress test nor angiography, with marked regional variation. Availability of invasive facilities increased the likelihood of both non-invasive and invasive investigations. Those with more severe symptoms or longer duration of symptoms or a positive non-invasive test were more likely to have angiography. In multivariable analysis, a positive stress test was the strongest predictor of the use of angiography, associated with a six-fold increase in the likelihood of invasive investigation. However, gender and availability of facilities were also predictive.
Conclusion Considerable variation in features at presentation and use of investigations has been identified in the stable angina population in Europe. The evaluation of biochemical cardiovascular risk factors was suboptimal. Overall rates of non-invasive investigation for angina and the clinical appropriateness of factors predictive of the use of invasive investigation were broadly in line with guidelines. However, the influence of access to facilities, and marked international variation in rates and timing of investigation suggest that factors unrelated to clinical need are also influential in the management of patients with stable angina.
Key Words: Stable angina Presentation Cardiovascular risk factors Non-invasive investigation Stress testing Coronary angiography
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Introduction |
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Patients presenting de novo to a cardiologist with stable angina were selected for study rather than a chronic review population, to facilitate tracing the pattern of investigations implemented, including the temporal relationships between assessment and investigation in a prospective manner. This paper reports the clinical presentation of stable angina, explores the use of investigations and factors predictive of the use of stress testing and coronary angiography in this condition, and evaluates how actual use compares to guideline recommendations.
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Methods |
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Angina severity was assessed using the CCS classification, and breathlessness classified according to the New York Heart Association (NYHA) classification. Definitions for risk factors, comorbid conditions, and ECG abnormalities are reported in Appendix B.
Participating centres
As part of the EHS Programme, the Stable Angina Survey shares many organizational and logistic features with other EHSs.7,27 National coordinators were encouraged to recruit investigators from a variety of clinical centres ranging from tertiary referral or university teaching hospitals to regional or district centres in a manner which reflected facilities and practice on a national level. Local investigators, who participated on a voluntary basis, then collected data. Patients were enrolled from 197 centres in 36 countries in Europe and the Mediterranean basin. The results are described from four pre-defined areas within Europe, northern Mediterranean, central and western, in line with the previous Euro Heart Surveys (EHSs) (Figure 1).7,27
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Data management
The data were collected and stored centrally at the European Society of Cardiology base in Nice. The data collection software ran initial consistency checks at data entry level, with further checking performed by submitting the database to consistency checks as per a pre-written validation plan using SAS software. Missing or inconsistent values were thus highlighted automatically and queried by the data management team using phone or e-mail contact with the investigators.
Statistical analysis
Statistical analysis was performed in collaboration with the London School of Hygiene and Tropical Medicine. Descriptive statistics were used to estimate the prevalence of risk factors, baseline clinical characteristics, and treatment at presentation. The Student's t-test or ANOVA technique were used as appropriate to test differences in quantitative measures and the 2 test was used to test differences in proportions. Two-sided P-values are reported with 0.05 used as critical value to define statistical significance. To explore the variations in their use, logistic regression was employed to determine determinants of the use of exercise testing, stress imaging, or coronary angiography. Univariate analysis of predictors of the use of exercise testing included nine variables, age (>70 years vs. <70 years), sex, employment, education, type of centre, comorbidity, symptom severity (CCS class), duration of symptoms (
6 months vs. <6 months), and anti-anginal drug therapy prior to assessment (one or more anti-anginal drugs vs. one anti-anginal drug). Further variables added for analysis of stress echo and myocardial perfusion scanning as an outcome included the performance of exercise testing (yes/no) and the result of exercise testing (positive vs. negative or inconclusive). For coronary angiography, to these variables were also added the result of stress echocardiography or myocardial perfusion imaging and non-invasive estimation of LV function by echocardiography. Univariate analysis to identify the factors predictive of the use of non-invasive testing and coronary angiography was performed separately for each of the named regions. Multiple logistic regression using a stepwise procedure was used to ascertain the demographic, clinical, and investigative factors that determined the use of exercise testing, stress echo and perfusion imaging, and coronary angiography. Because of the substantial variation in the rates of referral for coronary angiography, separate analysis was also carried out for the countries which had a high rate of referral for coronary angiography (above median) and those which had a low rate of referral (below median). In order to check the robustness of the models, a uniformly distributed random variable was generated. A cutoff was imposed at a value of 0.5 for this variable, and the chosen models were re-run using the observations holding a value of
0.5 for this random variable. Analysis was undertaken using STATATM version 8 statistical software.
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Results |
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Participating centres and referral sources
Patients were enrolled in 197 centres. Of the participating centres, 35% had non-invasive diagnostic facilities only, 20% had non-invasive and invasive facilities, and 34% had, in addition to a catheterization laboratory, cardiac surgery facilities on-site. Facilities were uncategorized in 11% of centres. The majority of patients included (71%), had been referred by a primary care physician, and only 5% were referred from an emergency department for follow-up. Self referrals accounted for 10% of the population, although this figure was appreciably higher in central and Mediterranean Europe compared with northern and western Europe (15 and 17% vs. 0.2 and 2%, respectively, Figure 2). Patients were assessed in specialist chest pain clinics, non-emergency clinics specifically for the purpose of assessing patients with chest pain in 40% of cases. However, there were marked international differences in the proportions of patients assessed in such clinics, ranging from 0% in countries such as Denmark and Portugal to 93% of patients in Sweden.
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Clinical details
All patients with a clinical history of myocardial infarction within 1 year of assessment were excluded and 2398 (63%) patients were enrolled while any prior myocardial infarction was an exclusion criterion for the study. Only 4% of patients had a history of remote (>1 year) myocardial infarction. Angina class was assigned for 3472 patients, 39% had CCS class I, 49% class II, and 12% class III symptoms. The majority, 75% of patients, had symptoms for 1 year before assessment by a cardiologist, but just 52 patients, <2% of patients, had symptoms for <1 month. The median duration of symptoms prior to presentation to a cardiologist was 5 months and did not vary according to symptom severity. Regional variation was apparent, with symptom duration before cardiology assessment ranging from a median of 3 months in western Europe to 5 or 6 months in other regions (P<0.0001). This difference was most pronounced for patients with more severe (class III) symptoms.
Severe heart failure symptoms, NYHA class III or IV, were rare, occurring in 5 and 0.6% of patients, respectively. Physical signs of heart failure, defined as a raised jugular venous pressure, crepitations in the lung fields, a third heart sound, peripheral oedema, or hepatomegaly, were reported in only 8% of cases. The population was overweight, three-quarters had a body mass index (BMI) of 25 or more, mean BMI 28±5. Mean systolic and diastolic blood pressures were 144±21 and 85±11 mmHg, respectively.
Medical therapy prior to cardiology assessment
Almost half (49%) of patients were taking aspirin before assessment by a cardiologist. Only 22% of patients were on a statin prior to assessment by the cardiologist, and even of patients with recognized hyperlipidaemia only 41% were on a statin, and 5% on an alternative lipid lowering agent. Patients were taking at least one anti-anginal drug at presentation to the cardiologist in 62% of cases and two or more in 28%.
Investigations performed
Figure 3 is a flow diagram which depicts the overall pattern of the use of investigations.
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Chest X-ray
Although performed or planned in 51% of patients overall, performance of chest X-rays showed wide regional and international variability, ranging from 19 to 100% in individual countries. One-fifth of chest X-rays showed at least one abnormality, most commonly cardiomegaly, which was reported in 13% of all X-rays performed. Pulmonary congestion was reported in 5% of chest X-rays.
Echocardiography
Echocardiography was planned or performed in 2430 patients, 64% of the population overall, but only in 24% of patients in northern Europe. Of patients from western, central and Mediterranean Europe, 60, 84, and 63%, respectively, had a resting echo. At 4 week follow-up, an echo had been carried out and results were available for 80% of patients in whom the test was planned. Left ventricular hypertrophy (LVH) was detected in 32% of echos, and regional wall motion abnormality (RWMA) in 21% overall. Moderately impaired and poor ventricular function was reported in 17 and 3%, respectively.
Exercise ECG
Exercise testing was planned or performed in 76% of patients (Figure 3), with less regional variation than for other investigations (Figure 4). In northern Europe compared with other parts of Europe, a greater proportion of patients, 65% of all patients in whom an exercise test was planned, had their exercise test performed prior to being seen by a cardiologist. Results of 2328 exercise tests were available within 4 weeks of assessment. A positive result was recorded in 57%, negative in 29%, and inconclusive in 13%. Of patients with a positive test, 68% went on to have a coronary angiogram (Figure 3) compared with only 14% of patients with a negative test (P<0.001). Stress echo or perfusion scanning was performed in 8% of patients with negative result, 29% of patients with an inconclusive result, and 11% of patients with a positive exercise ECG result.
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Stress imaging tests
The use of stress echocardiography and myocardial perfusion scanning was not widespread in this population, with one or other of these tests performed in only 18% of the population overall (Figure 5), although this rose to 34% among patients with a specific patient contra-indication to exercise ECG. Stress imaging techniques were not exclusively employed in patients who did not or could not have an exercise ECG as two-thirds of patients who were scheduled to have stress imaging also had an exercise ECG.
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Coronary angiography
Coronary angiography was either planned or performed in 1564 patients (41%) overall, with considerable regional variation as seen in Figure 6. The rate of coronary angiography was low overall in western Europe, but this masks high performance rates in certain countries with relatively smaller numbers of patients such as in Germany (n=144), where 75% of patients had an angiogram performed or planned. Although coronary angiography was planned in 57% of patients with stable angina in northern Europe, there was frequently considerable delay before performance of the test. Almost 9 out of 10 patients (88%) referred for angiography in northern Europe had their angiogram scheduled >4 weeks after the time of assessment. In central Europe, 62% of patients had to wait for >4 weeks, 40% in Mediterranean, and only 18% in western Europe.
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Factors influencing the use of non-invasive tests
In univariate analysis, females and those >70 years of age were significantly less likely to have an exercise test, as were patients with one or more comorbid condition (see Supplementary material online, Table SII). Patients with symptoms for >6 months, more severe angina or those taking more than one anti-anginal drug were also less likely to have an exercise test. Overall, patients enrolled in a centre with invasive facilities were 50% more likely to have an exercise test than patients enrolled in a centre with non-invasive facilities only. A notable exception when regions were analysed separately was the case of northern Europe, where patients from invasive centres were not more likely to have an exercise test.
Stress echo or myocardial perfusion scanning were more likely to be performed in centres with invasive facilities, with the exception of central Europe, where these tests were significantly less likely to be performed in patients from invasive centres (see Supplementary material online, Table SIII).
Factors influencing the use of coronary angiography
Women and (except in northern and western Europe) those >70 years were significantly less likely to have coronary angiography performed or planned. More severe symptoms, symptoms of longer duration, or greater use of anti-anginal drug therapy were significant predictors of the use of coronary angiography (see Supplementary material online, Table SIV) and remained consistently so across all regions. Overall, patients in hospitals with invasive facilities were 26% more likely to have an angiogram performed or planned than patients in a centre with non-invasive facilities only.
Multivariable analysis
For exercise testing, age >70 years, comorbidity, and longer symptom duration were independently associated with decreased likelihood of referral for exercise testing (Table 4). In countries with low rates of referral for angiography, gender was an independent predictor of the use of exercise testing, but not in countries with high rates of angiography. For stress imaging techniques, not having an exercise ECG performed or planned was an independent predictor of the use of either stress echo or perfusion imaging in all regions.
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Discussion |
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Patient profile
On the whole, the patient profile was similar in the different European regions. Exceptions include a greater prevalence of diabetes in this population in Mediterranean region and a higher proportion of hypertension and hyperlipidaemia in central Europe. There is a higher proportion of women then included in most trials of secondary prevention in coronary disease, but this is not surprising if one considers that angina is the most frequent manifestation of coronary disease in women.31,32
Risk factor assessment
The 1997 European Society Guidelines on the management of stable angina advocate, as a minimum, an assessment of risk factors and resting electrocardiogram in addition to clinical assessment for all patients, and an initial strategy of non-invasive testing for most patients, which will assist in determining the need for coronary angiography.24
Despite the relative ease and lesser expense of lipid and glucose measurements compared with other forms of investigation, lipid analysis was not performed within 1 month in more than a quarter of patients and glucose measurement not performed in one-third of patients. Fewer than half of the 58% of patients with known hyperlipidaemia were on lipid lowering drugs, and of even among those on statin therapy only one-third had achieved target cholesterol levels, reflecting subtherapeutic dosing, and emphasizing the need for cholesterol monitoring even among those on cholesterol lowering therapy from their primary care physician. The low rate of lipid measurement is not dissimilar to that observed in the EUROASPIRE II study33 or studies of the penetration of guidelines regarding the investigation and management of hypertension.34 It is higher than reported rates of measurement during cardiac hospitalizations in the early 1990s, which report as few as 14% of patient having cholesterol measurement.35,36 However, the rate of measurement of cholesterol can be increased considerably with strategic programmes at institutional level to raise awareness of the benefits of measuring and treating cholesterol, and standardize the approach to risk factor assessment in the ischaemic heart disease population. Such targeted programmes can also increase the appropriate use of lipid lowering therapy.35
Although glucose measurement resulted in the discovery of only an additional 4% of the population with previously unknown diabetes, a lower proportion of newly discovered diabetics than in studies of myocardial infarction37 or the EHS of Diabetes and the Heart,38 this is nonetheless an important finding with consequences both for the prognosis of the individual, and for treatment. Clearly successful and effective secondary prevention cannot be achieved if lipid and glucose status are not actively investigated, and routine measurement of these biochemical parameters should be an unquestioned preliminary step in patient assessment.
Resting echocardiography
With the exception of northern Europe, a large proportion of patients surveyed underwent resting echocardiography as part of the work up for stable angina. It is well recognized that left ventricular function is a crucial factor in influencing prognosis in coronary disease,3941 and it is possible to use simple reproducible echocardiographic measurements of ventricular dimensions to assign risk and to combine this information effectively with information obtained from stress testing to discriminate between high and low risk groups.42 The relatively high pick up rate of LVH (32%) and RWMAs (21%) in a population for the most part without clinical heart failure or prior history of MI, are further vindication of this course of action.
Non-invasive stress tests
The sequence of non-invasive investigation of angina observed in the study seems at first to be in line with existing guidelines with regard to the use of functional assessment in almost all patients. Between 70 and 80% of patients had an exercise test performed or planned, and stress imaging techniques were used in 26% of the population who did not have an exercise ECG. However, imaging techniques were used more frequently as an additional test rather than an alternative to exercise ECG in the majority of patients, with the highest rate of stress imaging among patients with inconclusive exercise ECG results.
Importantly, failure to perform some form of functional assessment as a minimum was an issue for a considerable proportion of patients. This was particularly the case in central Europe where neither functional assessment nor angiography was planned in 18% of the population referred to cardiologists. These findings are reconcilable with suggestions that, although modest, the contribution of differences in medical care to the eastwest health gap is not inconsequential.43,44
Nevertheless, the overall rate of non-invasive investigation stress testing compared favourably with that reported from a US study of the use of diagnostic testing within 4 weeks in a population with new onset chest pain, in which only 60% received a specific cardiac investigation, and 22% of patients who met necessity criteria for testing were not tested.45
In this survey, patients with longer symptom duration, more severe symptoms, or those already on more than one anti-anginal medication were less likely to have an exercise ECG or other stress test. This may indicate either that these patients are thought to have more severe disease and more likely to require revascularization and therefore go on to have coronary angiography directly or that in such patients, the diagnosis is considered established and confirmatory testing not required. This latter approach does not take account of the important role exercise testing may have in risk stratifying patients.4648 The use of the Duke treadmill score48 or other prognostic scores was not evaluated by this survey. As only 39% of patients who did not have an exercise test went on to have an angiogram, direct angiography does not fully account for the observed referral patterns and suggests under use of stress testing as a prognostic tool.
Invasive investigation: coronary angiography
The rate of coronary angiography recommended by cardiologists, 41%, is comparable to North American figures from 1990, which estimated that 40% of incident cases of angina undergo elective cardiac catheterization49 over a 5-year-period. Although there has been a progressive increase in cardiac catheterization rates in the USA,50 some reports suggest that referral of incident coronary disease for catheterization after stress testing has not increased dramatically after the late 1980s.19
The variability in length of time between assessment and angiography is a striking feature of the survey, with an almost five-fold difference in the proportion of patients having to wait more than a month for scheduled angiography between regions. This is also a cause for concern given reported rates of adverse cardiac events (including death, MI, and hospitalization for unstable angina) of 9.4% over 8.4 months in previous studies, with increased probability of events as the waiting time for angiography lengthened.51 Future guidelines may need to provide guidance on prioritization of patients for angiography to address this issue.
In line with previous findings,1719 gender was a significant predictor of the use of coronary angiography in both univariate and multivariable analyses. Although less frequently documented in the literature, a bias against the use of angiography in older patients has been reported22. However, in this survey, age was only independently associated with less angiography where overall rates of angiography are low, suggesting that where services are constrained, or practice more conservative, the elderly are less likely to be referred onwards for angiography or potential consideration for revascularization, but where there is more liberal use of angiography age is not a deciding factor. The availability of on-site cardiac catheterization facilities significantly increased the likelihood of referral for coronary angiography in similar fashion to that shown in studies of acute coronary syndrome.52 Again, however, centre type was only a predictive factor in multivariable analysis in countries where overall rates of angiography were low.
Important clinical factors related to appropriateness of use namely, a positive stress test or intensity of medical therapy (more than one anti-anginal at presentation) were universally independent predictors of the use of coronary angiography. But patient symptoms were more influential, and availability of on-site facilities not an influential factor in countries where angiography was more frequently undertaken.
Limitations
Although a survey of stable angina, this is not a population-based study and as such it is not possible to make any inferences from the data about the incidence of angina in any of the regions studied. Furthermore, as assessment by a cardiologist was chosen as the sampling point, the data regarding clinical characteristics may not be generalizable to the overall population with stable angina in the community because of selection bias, but the population is reflective of the patient profile presenting to cardiologists and suitable for the investigation of their management practices. Inclusion in the study was based on the diagnosis of angina by the attending physician and is thus also open to interpretation bias, but as patient management was based on the working diagnosis of angina, the population is suitable for the evaluation of patient management. Because of the existing infrastructure in place at the time this survey was initiated, the survey is somewhat biased towards larger teaching or university affiliated centres, with more centres with on-site catheterization facilities than would be the case in practice. The numbers of patients from some of the 36 countries which contributed data are too small to be representative of practice in that individual country, but where trends in prevalence or practices emerge between countries in a region, the larger regional sample size is likely to be representative. Finally, given the potential sources of bias in the analysis, the results must be considered as indicative rather than factual. In light of this, and as the nature of the study is exploratory rather than definitive, caution is advised in interpretation of the results, but the findings are nonetheless worthy of consideration, and generate important questions as well as providing novel information in this area.
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Conclusions |
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The widespread use of non-invasive investigations appears broadly in line with existing guidelines, but improvements can certainly be made, particularly among the minority of patients who have no form of non-invasive stress test or angiogram, in standardizing the use of echocardiography, and in improving the temporal relationships between assessment and initial investigations in some regions.
However, the influence of access to facilities, and marked international variation in rates and timing of angiography, suggest that factors unrelated to clinical need, including service capacity and patient preference, are also influential in the management of patients with stable angina. The challenge to the European cardiology community is not only to ensure that clear guidelines on the subject, backed by the available evidence, penetrate to all relevant professionals, but also to ascertain the optimal strategies to ensure that the guidelines are put into practice, through implementation of national or institutional programmes and to adapt such programmes to fit into highly variable existing services.
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Supplementary material |
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Appendix A |
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Euro Heart Survey Team (European Heart House, France): Malika Manini, Operations Manager; Claire Bramley, Data Monitor; Valérie Laforest, Data Monitor; Charles Taylor, Database Administrator; Susan Del Gaiso, Administrator.
Main Investigator Centre (London, UK): Kim Fox (Chairman); Caroline Daly (Research Fellow).
Statistical Centre: London School of Hygiene and Tropical Medicine, Felicity Clemens, Bianca de Stavola.
National Co-ordinators: Kurt Huber, Austria; Guy De Backer, Belgium; Vera Sirakova, Bulgaria; Roman Cerbak, Czech Republic; Per Thayssen, Denmark; Seppo Lehto, Finland; François Delahaye, France; Bondo Kobulia, Georgia; Uwe Zeymer, Germany; Dennis Cokkinos, Greece; Kristof Karlocai, Hungary; Emer Shelley, Ireland; Shlomo Behar, Israel; Aldo Maggioni, Italy; Virginija Grabauskiene, Lithuania; Jaap Deckers, The Netherlands; Inger Asmussen, Norway; Janina Stepinska, Poland; Lino Gonçalves, Portugal; Vyacheslav Mareev, Russia; Igor Riecansky, Slovakia; Miran F. Kenda, Slovenia; José Luis Lopez-Sendon, Spain; Annika Rosengren, Sweden; Peter Buser, Switzerland; Tugrul Okay, Turkey; Oleg Sychov, Ukraine; Kevin Fox, UK.
There was no national co-ordinator in the participating countries which are not mentioned in the previous list.
Euro Heart Survey Board Committee: Maarten Simoons (Chairman), The Netherlands; David Wood (Past Chairman), UK; Angeles Alonso, Spain; Shlomo Behar, Israel; Eric Boersma, The Netherlands; Harry Crijns, The Netherlands; Kim Fox, UK; Anselm Gitt, Germany; Malika Manini, France; Keith McGregor, France; Barbara Mulder, The Netherlands; Markku Nieminen, Finland; Sylvia Priori, Italy; Lars Rydén, Sweden; Luigi Tavazzi, Italy; Alec Vahanian, France; Panos Vardas, Greece; William Wijns, Belgium; Uwe Zeymer, Germany.
List of Industry Sponsors: Servier Laboratories Ltd.
Participating Centres, Investigators, and Data Collection Officers: Albania: Ahmet Kamberi, Tirana. Austria: Dagmar Burkart-Küttner, Georg Gaul, Katharina Hohenecker, Vienna. Bosnia Herzegovina: Vulic Dusko, Banjaluka, Republika Sprska. Belgium: Isabelle Liebens, Bruxelles. Bulgaria: Vera Sirakova, Varna; Valentin Asenov Petrov, Shoumen; Dimitar Raev, Sofia. Belarus: Igor Polonetsky, Nikolay Manak, Minsk. Cyprus: Costas Zambartas, Helen Kleanthous, Loizos Antoniades, Nicosia; Joseph A. Moutiris, Marios Ioannides, Limassol. Czech Republic: Jiri Spac, J. Spinar, Brno; Ivana Pirochtova, Brno; Renata Kolosova, Frydek-Mistek; Miroslav Rubacek, Ostrava; Tomas Brabec, Brno. Germany: E. Blank, G. Sabin, L. Waldelich, Essen; H.M. Hoffmeister, Sollingen; C. Seibold, R. Morell, Fürstenfeldbrück; Frank Rupprecht, Mainz; Norbert Schoen, Muhldorf; Ralf Hewing, Munster; Corinna Lenz, U. Zeymer, Kassel; B. Witzenbichler, Heinz Peter Schultheiss, Berlin; Achim Gutersohn, R. Erbel, S. Churzidse, Essen; A. Gitt, Konstanze Gehrke, J. Senges, U. Zeymer, Ludwigshafen am Rhein. Denmark: Helle Cappelen, Lisette Okkels Jensen, P. Thayssen, Odense C; Jan Kyst Madsen, Marie Seibaek, Copenhagen. Spain: L. Lopez Bescos, Madrid; Luis Hilario Villanueva, Raul Moreno, Rosana Hernandez, Madrid; Fernando Olaz Preciado, M. Soledad Alcasena Juango, Pamplona; Josep M. Alegret, Tarragona; C. Permanyer Miralda, Barcelona; Luis Sosa Martin, San Lorenzo de El Escorial; Maria Irurita Latasa, Las Palmas de Gran Canaria; Josep Sadurni i Serrasolsas, Vic; Juan Ramon Siles Rubio, Norbero Herrera Guttierez, Cabra (Cordoba); Isabel Antorrena Miranda, Villajoyosa; Alicia Bautista Paves, Motril; Antonio Salvador Sanz, Valencia; A. Alonso Garcia, Almudena Castro Conde, Madrid; Francisco Marin Ortuno, Alicante; Maria Jesus Salvador Taboada, Barcelona; Fransisco Epelde Gonzalo, Terrassa; Ignacio Santos Rodriguez, Pedro L. Sanchez Fernandez, Salamanca. Finland: Kirsti Savolainen, S. Lehto, Kuopio. France: Thierry Lefevre, Massy; Jean Jacques Blanc, Brest; Herve Le Breton, Jean Michel Clerc, Rennes. UK: Alistair Pell, Judith Anderson, Airdrie; Helen Gracey, Jennifer Adgey, Belfast; Bev Durkin, Wakefield; Bronia Ward, Ian Rushmer, Robert Bain, Grimsby; M.A. Memon, Bridlington; R. Muthusamy, Rotherham; R.A. Perry, S. Aziz, Liverpool; Judith Beevers, Paul Brooksby, Pontefract; Christopher Travill, Susan Gent, Luton; J.M. Glancy, Hereford; Graham Ranson, Phil Keeling, Torquay; Steven Lindsay, Bradford; Ali Khaddam, Merseyside; Lesley Davies, William J. Penny, Cardiff; Emma Birks, Sam Kaddura, London; D. Wood, Joanna Tenkorang, London; Fhiona Holland, Jonathan Pitts, St Leonards-on-Sea; Jane Burton, Moira Marriott, Robert Henderson, Nottingham. Georgia: Gulnara Tabidze, Tbilisi. Greece: Nastasia Tsiavou, Athanassios Dritsas, D. Cokkinos, Athens; Christina Chrysohoou, Athens; Ioannis Vogiatzis, Veria; Alexandros Gotsis, Komotini; Dimitrios Psirropoulos, Thelassoniki; Vasilios Kotsis, Athens; Mary Marketou, Heraklion, Crete; Ioannis Skoularigis, Larisa; Evdokia Adamopoulou, Pireus. Croatia: Vjeran Nikolic Heitzler, Zagreb; Ante Samodol, Sibenik; Josip Vincelj, Zagreb. Hungary: Bato Zoltan, Istvan Preda, Budapest. Israel: A. Battler, Alejandro Solodky, Petach Tikva; Aviva Grosbard, Gisella Kon, Beer Sheva; Mohammed Omari, N. Kogan, Nazareth. Italy: Alfredo Galassi, Giuseppe Giuffrida, Catania; F. Naccarella, Stefano Sdringola Maranga, Bologna; Colomba Falcone, Pavia; Giuseppe Sangiorgi, San Donato Milan; Salvatore Novo, Palermo; Giuseppe Ambrosio, Perugia; Carla Boschetti, Francesco Pelliccia, Roma; Francesco De Tommasi, San Giovanni Valdamo; Paolo Testarmata, Ancona; Emanuele Carbonieri, San Bonifacio; Gaetano Nucifora, Paolo Fioretti, Udine; Antonella Muscella, Giacento Pettinati, Casarano; Massimo Villella, San Giovanni Rotondo; Alessandro Boccanelli, Giorgio Bottero, Roma; Dorita Chersevani, Monfalcone; Andrea Albani, Bolzano; Bruno Casiraghi, Seriate; Gabriella Giuliano, Gorizia; Piera Costanzo, De Marie, Rita Trinchero, Torino; Alessandro Desideri, Castelfranco Veneto; Claudio Pandullo, Trieste. Lebanon: Elie Chammas, Beirut. Lithuania: Ruta Babarskiene, Kaunas; Milda Kovaite, V. Grabauskiene, Vilnius; Vitas Vysniauskas, Marijampole; Eugenijus Kosinskas, Vilnius. Latvia: Gustavs Latkovskis, Uldis Kalnins, Riga. Macedonia: Biljana Filipovska Simic, Skopje. Moldova: Eleanora Vataman, Kishinau. The Netherlands: Chris Jansen, J. Deckers, GD Rotterdam; Arno Breeman, E. de Swart, Metske van der Wal, AB Zwolle; Henriette Tebbe, R. Brons, KA Meppel; Chris Jansen, Jeroen Vos, EA Rotterdam; Chris Jansen, C.M. Leenders, TD Rotterdam; Chris Jansen, Rotterdam; E. de Swart, Metske van der Wal, Harderwijk; Adrie van den Dool, Heidi Fransen, Robby Nieuwlaat, Maastricht; Henriette Tebbe, M.J. De Boer, Zwolle; Herman Broers, Robby Nieuwlaat, Tilburg; Colinda Koppelaar, M. Bijl, Dordrecht. Poland: Alicja Kowalska, Krystyna Loboz-Grudzien, Wroclaw; Beata Wozakowska-Kaplon, Kielce; Malgorzata Krzciuk, Ostrowiec Swietokrzyski; M. Krzeminska-Pakula, Michal Plewka, Lodz; Anna Lewczuk, Teresa Stefankowska-Olenska, Bialystok; Joanna Bakun, Suwalki; Antoni Torunski, Grazyna Swiatecka, Gdansk; Jaroslaw Krol, Miroslaw Dluzniewski, Warszawa; Elzbieta Zinka, Marek Gksecki, Koszalin; Jerzy Jankowski, Poznan; Krystyna Jaworska, Malgorzata Wagrowska, Urszula Kazmierczak, Torun; Lidia Orzechowska-Slomska, Chelmza; Aleksander Kabara, Golub Dobrzyn; Michal Plewka, T. Waszyrowski, Lodz; Teresa Kawka-Urbanek, Michal Plewka, Pawel Wojewoda, Skierniewice; Piotr Kokowicz, Warszawa; Hanna Kalotka-Kreglewska, Warszawa; Joanna Biegajlo, Warszawa; Jerzy Sacha, Wladyslaw Pluta, Opole; Anna Madro, Teresa Widomska-Czekajska, Lublin; Arkadiusz Stasiewski, Krzysztof Sokolowski, Tadeusz Krzys, Poznan; B. Grzegorzewski, Malgorzata Dudek-Niechcial, M. Pruski, Katowice; Jolanta Surwillo, Przemyslaw Aponowicz, Koscierzyna; Wlodzimierz Krasowski, Gdansk; Michal Szpajer, Gdynia; Bozena Adamczyk, Dabrowa Gornicza; Anna Krol, Lipno; Janusz Kostrzewa, Rypin; Marek Bronisz, Inowroclaw; Wlodzimierz Rajewski, Bydgoszcz; Andrzej Stojek, Irena Kulon, Krakow; Andrzej Gebala, Krakow; P. Buszman, Kazimierz Radwan, Iwona Szkrobka, Katowice. Portugal: H. Madeira, Luis Sargento, Lisbon; Daniel Ferreira, Rafael Ferreira, Amadora; Joao Carlos Araujo Morais, Leira; Pedro Sarmento, Lisbon; Madalena Teixeira, Vasco Gama Ribeiro, Gaia. Romania: Mircea Ioachim Popescu, Oradea; Bostaca Ioan, Iasi; Codin T. Olariu, Arad; Istvan Albert, Sfantu Gheorge; Anca Dan, Khalid Tammam, Bucarest; A. Iancu, Camelia Stanescu, Cluj-Napoca; M. Dorobantu, Bucharest; D. L. Dumitrascu, Cluj. Georgia: Bondo Kobulia, Gulnara Tabidze, Irina Jashi, Zaza Chapichadze, Tbilisi. Russia: D. Aronov, Elena Tikhomirova, Olga Goudkova, Moscow; Mirolyubova Olga, Arkhangelsk. Sweden: Jan Erik Karlsson, Jokoping; Matthias Lidin, Pia Oblack, Stockholm; K. Aström-Olsson, Lund; Cecilia Dahlen, Falun. Slovenia: Iztok Gradecki, Novo Mesto; I. Kranjec, Katja Prokselj, Ljubljana; Vojko Kanic, Maribor. Slovakia: Eva Hrbata, Kosice; Daniela Ondusova, Martin Studencan, Kosice; Peter Kurray, Banska Bystrica; Juraj Cencarik, Presov; Jan Murin, Bratislava. Turkey: Baris Ikitimur, Capa-Istanbul; Emrullah Basar, Kayseri; Bahattin Balci, Osman Yesildag, Kuruelit/Samsun; Zerrin Yigit, Haseki Istanbul; Ayhan Olcay, Capa Istanbul; Jale Cordan, Gorukle/Bursa. Ukraine: Mariya Orynchak, Ivano-Frankivsk. Serbia & Montenegro: Masar Gashi, Prishtina.
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For the purposes of recording ECG abnormalities
ST depression: defined as depression of the ST segment >0.5 mm or >0.05 mm below the isoelectric line.
T wave inversion: defined as inversion of the T wave of the QRS complex except in leads AVR, V1, and lead III.
Pathological Q waves: defined as Q waves (except in AVR, V1, and III) which are >0.04 s wide and 0.2 mm deep or >20% of the accompanying R wave.
On examination, clinical signs of heart failure were defined as the following
Elevated venous pressure, hepatomegaly, dependent oedema, crepitations, gallop rhythm, or evidence of cardiac enlargement.
Comorbid conditions and risk factors
Hepatic disease: chronic hepatitis or cirrhosis, or other hepatic disease causing elevation of transaminases more than three times the upper limit of normal.
Peripheral vascular disease: claudication either at rest or exertion, amputation for arterial vascular insufficiency, vascular surgery (reconstruction or bypass) or angioplasty to the extremities, documented aortic aneurysm, or non-invasive evidence of impaired arterial flow.
Chronic renal failure: chronic dialysis or renal transplantation or serum creatinine >200 µmol/L.
Chronic respiratory disease: diagnosis previously made by physician, or patient receiving bronchodilators, or values of FEV1 <75%, arterial pO2 <60%, or arterial pCO2>50% in prior studies.
Chronic inflammatory conditions: diagnosis of rheumatoid arthritis, systemic lupus erythematosis or other connective tissue diseases, polymyalgia rheumatica, etc.
Peptic ulcer disease: Active peptic ulcer disease or on treatment for peptic ulcer disease.
Malignancy: diagnosis within 1 year or active malignancy.
Hypertension: treated hypertension, on anti-hypertensive therapy.
Hyperlipidaemia: treated hyperlipidaemia, on lipid lowering medication, or specific dietary modification.
Diabetes: treated diabetes, on insulin or oral diabetic medication, or specific dietary modification.
Family history of premature coronary artery disease (CAD): a history of angina pectoris, myocardial infarction or sudden death among first-degree relatives under the age of 55 years for male relatives and 65 years for female relatives.
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