Background
Pericarditis is a common disorder that has multiple causes and presents in various clinical settings [
1]. Tuberculosis is responsible for more than 50% of cases of pericarditis in developing countries where tuberculosis remains a major public health problem [
2]. By contrast,
Mycobacterium tuberculosis infection accounts for less than 5% of cases of pericarditis in industrialised countries [
1]. In Africa, the incidence of tuberculous pericarditis is said to be rising as a direct result of the human immunodeficiency virus (HIV) epidemic [
3‐
7]. There is a strong association between HIV infection and tuberculous pericarditis in endemic regions, where 40–75% of patients with large pericardial effusion (suspected to be tuberculosis) are infected with HIV [
2,
3].
The effect of HIV infection on the clinical presentation, response to treatment and outcome of patients with tuberculous pericarditis is not well characterised [
8]. HIV infected patients with tuberculous pericarditis have been found to be more likely than HIV negative patients to have disseminated tuberculosis, raising the possibility that dissemination may worsen long-term outcome [
5]. Preliminary evidence suggests that HIV infection may be associated with higher mortality in tuberculous pericarditis; mortality with anti-tuberculosis chemotherapy ranged from 8% to 17% in the pre-HIV era [
9‐
12], whereas higher mortality rates of 17–34% have been reported in HIV infected individuals [
13].
We have conducted the first African multi-centre prospective observational registry of the clinical presentation, diagnostic evaluation, initial treatment, and outcome of patients with suspected tuberculous pericarditis in the HIV era. This study, which is called the
Investigation of the
Management of
Pericarditis
in
Africa (IMPI Africa) Registry, was established mainly to obtain contemporary information that is required for the design of a clinical trial of the effectiveness of adjunctive steroids in tuberculous pericarditis in the HIV era [
2]. In this report we have used the baseline data of the IMPI Africa Registry to assess the impact of clinical HIV disease on the clinical characteristics, diagnostic work-up, and initial treatment of patients with suspected tuberculous pericarditis.
Methods
The IMPI Africa registry is a simple pragmatic multi-centre prospective observational study of patients admitted to hospital with suspected tuberculous pericarditis which was designed to assess the impact of HIV infection on clinical presentation, diagnostic evaluation, initial treatment, and outcome of patients with tuberculous pericarditis in Africa. We set out to enrol a minimum of 100 consecutive suspected tuberculous pericarditis patients presenting to collaborating physicians over 6 months, and follow them prospectively for 6–12 months. The study was approved by the research ethics committee of the University of Cape Town, South Africa, and all participants gave written informed consent.
Twenty seven hospital-based physicians from eight African countries (Cameroon, 2; Ghana, 1; Kenya, 1; Lesotho, 1; Nigeria, 1; South Africa, 19; Uganda, 1; Zimbabwe, 1) were invited by electronic mail in January 2004 to participate in the study. These physicians had expressed an interest in the project to one of the investigators (BMM). Fifteen physicians from three countries (Cameroon, 1; Nigeria, 1; and South Africa, 13) contributed patients to the IMPI Africa Registry (56% response rate). Twelve of the 15 physicians were affiliated to medical schools, and three (all in South Africa) were based in district general hospitals.
Suspected tuberculous pericarditis was defined as a patient presenting to hospital with a clinical syndrome of pericardial disease which was suspected to be caused by tuberculosis on the basis of clinical and/or laboratory findings leading to the commencement of anti-tuberculosis chemotherapy according to the national tuberculosis control programme [
14] Consecutive incident cases of suspected tuberculous pericarditis were enrolled. Adult patients were eligible for inclusion in the study if the collaborating physician felt sufficiently confident with the diagnosis of tuberculous pericarditis to commence anti-tuberculosis treatment. The management of each patient was at the discretion of the collaborating physician in keeping with the observational nature of the study.
Pericardial disease was classified as acute non-effusive pericarditis, pericardial effusion, effusive-constrictive pericarditis, or constrictive pericarditis on the basis of the collaborating physician's assessment of clinical and imaging information.
We classified tuberculous pericarditis as 'definite' or 'probable' depending on the amount of clinical and bacteriological information supporting the diagnosis of tuberculosis, or 'not tuberculous pericarditis' when an alternative (non-tuberculous) cause of pericarditis was found. A diagnosis of 'definite' tuberculous pericarditis was based on the demonstration of tubercle bacilli in pericardial fluid (smear and/or culture) or on histologic section of the pericardium; 'probable' tuberculous pericarditis on the proof of tuberculosis elsewhere in a patient with otherwise unexplained pericarditis, on the basis of indirect tests (e.g., adenosine deaminase level ≥ 40 IU/l in pericardial fluid) and/or an appropriate response to a trial of anti-tuberculosis chemotherapy.
The HIV status of the patients was based on the results of serological testing for HIV. However, serological testing for HIV is not always available or offered in some medical institutions in Africa. Therefore, the physicians were requested to state whether they suspected HIV infection on clinical grounds and to classify each patient as either having evidence of 'clinical HIV disease' or 'no clinical HIV disease' without regard to the HIV serological status of the patient. This assessment was left to the discretion of the collaborating physician, and no criteria were specified.
The effect of pericardial disease on the functional capacity of each patient was defined using New York Heart Association (NYHA) criteria as class I (no limitation in physical activity), class II (ordinary physical activity results in dyspnoea), class III (minimal physical activity results in dyspnoea), or class IV (dyspnoea at rest) [
15]. Haemodynamic instability was defined by the presence of at least two of these signs: pulse rate > 100 beats/minute, systolic blood pressure < 100 mmHg, and cardiac tamponade requiring pericardiocentesis. The radiological, electrocardiographic, echocardiographic, and laboratory results were based on the report provided by the collaborating physician without central verification.
Demographic, clinical, diagnostic and therapeutic information was captured by means of a standardized data collection form (available on request) and transmitted (by fax or e-mail) to the IMPI Africa Coordinating Centre at the Cardiac Clinic, Groote Schuur Hospital, Cape Town, South Africa. Enrolment into the registry started on 1 March 2004 in 11 hospitals and up to two months later in the other four, and ended on 31 October 2004. Patients were reviewed for the study outcomes at three, six and 12 months following entry into the registry, with a minimum follow-up period of 6 months for all participants. Patient follow-up was carried out by personal interview, failing which telephonic enquiry and postal services were used.
On enrolment, each patient provided a contact person (next of kin or neighbour) who could be contacted if the patient's whereabouts were not known at the time of follow-up. In the event of death or illness the contact person would be able to provide information. In the event of death, every effort was made to obtain a copy of the death certificate. We also used the services of the South African Department of Home Affairs (for South African centres) and a private detective company to obtain the vital status of patients lost to follow-up. The follow-up phase of the study ended on 30 April 2005, and (follow-up) data will be reported separately.
Data were analysed using Epi Info 3.3 (CDC, Atlanta, GA, USA). We used the chi-square test (or Fisher's exact test for variables with small number of expected frequencies) and analysis of variance to asses differences between categorical and continuous variables respectively. Significance tests were two-tailed and statistical significance was defined at the 5% alpha level. All patients were stratified by clinical HIV disease status and entered in the analyses regardless of the final diagnosis.
Discussion
This prospective observational study indicates that 40% of patients presenting to hospital with suspected tuberculous pericarditis in parts of Cameroon, Nigeria and South Africa have clinical features of HIV infection. This study reveals for the first time that patients with clinical features of HIV infection have a different clinical presentation of the cardiac disease. Patients with clinical HIV disease and tuberculous pericarditis have greater dyspnoea and electrocardiographic ST segment changes that are suggestive of myopericarditis. In addition, a positive HIV serostatus was associated with greater cardiomegaly and haemodynamic instability in these patients. These data suggest that there may be greater pericardial fluid accumulation and myocardial involvement in patients with HIV-associated pericardial tuberculosis. These findings, if confirmed in prospective studies with less biased assessment of HIV status, suggest that tuberculous pericarditis is a more severe cardiac disease in people with HIV/AIDS.
Preliminary evidence from small single centre studies of tuberculous pericarditis in African patients infected with HIV has suggested that tuberculous pericarditis occurs in the early stages of HIV disease. In a Tanzanian study of HIV and tuberculous pericarditis, only 5 of the 28 HIV infected patients had clinical signs of HIV infection, suggesting that pericardial disease was an early manifestation of HIV infection in Tanzania [
3]. Our finding that nearly half of the patients with suspected tuberculous pericarditis have overt features of HIV infection may be in keeping with the maturity of the HIV/AIDS epidemic in many parts of Africa, which is associated with a greater proportion of patients presenting in advanced stages of HIV disease than was the case 15 years ago when many of the studies were conducted [
3‐
7]. There was, however, marked geographic variation in the prevalence of clinical HIV disease in our study which correlated with the known epidemiology of the HIV epidemic in Africa, with the exception of the Cameroon. In Cameroon we found a prevalence of clinical HIV disease in patients with suspected tuberculous pericarditis of 88.2%, compared to a much lower HIV seroprevalence of 5.5% in the general population [
18].
There is a strong association between HIV infection and extra-pulmonary tuberculosis; about 67% of patients with extra-pulmonary tuberculosis are HIV infected in Zaire [
17]. In Tanzania, 72% of patients with pericardial effusion were HIV seropositive, suggesting that pericardial effusion is strongly associated with HIV infection [
3]. Of the 96 patients who were tested for HIV in the IMPI Africa registry, 53 (55.2%) were HIV infected.
A study of 88 patients from the Western Cape Province of South Africa, which included 39 HIV infected patients, suggested that there were no differences in the electrocardiographic findings between HIV infected and HIV negative patients with tuberculous pericarditis [
19]. By contrast, we observed that more patients with clinical HIV disease than those without had ST segment elevation on ECG (30.4%
versus 13.7%), and there was a trend towards greater PR segment deviation, changes which are associated with involvement of the superficial layers of the myocardium in pericarditis [
20]. The association of HIV infection with ST elevation on ECG was confirmed when the analyses were restricted to the sub-group of patients with known HIV sero-status.
In the pre-HIV era, changes of acute pericarditis in tuberculous pericarditis were reported in a small minority of patients (i.e., 9–11%) [
19,
21,
22]. Whether the greater prevalence of electrical evidence of acute pericarditis bears relation to greater myocardial involvement in the form of a myopericarditis in immunocompromised patients remains to be established by prospective study [
23‐
25]. It is possible that left ventricular dysfunction, associated with myopericarditis in patients with tuberculous pericarditis and HIV, may account for the greater dyspnoea that was observed in these patients.
What are the limitations of the registry?
Our study methods can be criticised on several grounds. First, the economic circumstances of medical practice in many African countries result in frequent shortages that, in this study, preclude complete data acquisition in every patient. For example, 6% of patients enrolled in the registry did not have access to echocardiography for confirmation of the diagnosis of pericardial disease. Secondly, the lack of bacteriological confirmation of tuberculosis in the vast majority and HIV serology tests in half of the patients results from similar considerations. It should be noted, however, that the most intense investigation may fail to yield clear information as to aetiology in patients presenting with pericardial effusion [
26]. The associations with clinical HIV disease should be interpreted with caution, and, given the low percentage tested, even associations with HIV seropositivity may have been subject to bias. This was a simple, large, prospective, observational study in a resource poor environment in which the definition of clinical and laboratory abnormalities were based on self-reports of the collaborating physicians without the verification of the primary data at a central site.
Acknowledgements
The study was made possible by grants from Medical Education for South African Blacks, MESAB (through the 2003 Don Kennedy Scholarship to Dr M Ntsekhe), the South African Medical Research Council (through the 2004/2005 Africa Fellowship to Dr CS Wiysonge), and the UCT Cardiac Clinic Research Fund. The study was conducted independently of the funding agencies.
We are grateful to Mrs Maitele Tshifularo (Research nurse) and Mr Simphiwe Nkephu (Field worker), who manned the IMPI Africa Coordinating Centre alongside CSW, MN, and MSS.
The authors thank Drs Alison Elliott and Lesley J Burgess for critical review of an earlier version of this manuscript.
Competing interests
The authors declare that they have no competing interests.
Authors' contributions
The IMPI Africa Operations Committee (BMM [Chair], CSW [Coordinator], MN, JAV, GM, FG, PJC) designed the study, coordinated data collection, analyses and interpretation, and wrote the first draft of the manuscript. The IMPI Africa Steering Committee (BMM [Chair], CSW, MN, AA, BMT, BT, KNB, KR, KS, BGB) supervised all aspects of the study. All authors contributed intellectually to, read, and approved the final manuscript.