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High burden of invasive β-haemolytic streptococcal infections in Fiji

Published online by Cambridge University Press:  16 July 2007

A. C. STEER*
Affiliation:
Centre for International Child Health, University of Melbourne, Victoria, Australia
A. J. W. JENNEY
Affiliation:
Centre for International Child Health, University of Melbourne, Victoria, Australia
F. OPPEDISANO
Affiliation:
Murdoch Children's Research Institute, Victoria, Australia
M. R. BATZLOFF
Affiliation:
Queensland Institute of Medical Research, Queensland, Australia
J. HARTAS
Affiliation:
Queensland Institute of Medical Research, Queensland, Australia
J. PASSMORE
Affiliation:
Centre for International Child Health, University of Melbourne, Victoria, Australia
F. M. RUSSELL
Affiliation:
Centre for International Child Health, University of Melbourne, Victoria, Australia
J. H. H. KADO
Affiliation:
Fiji Ministry of Health, Suva, Fiji Islands
J. R. CARAPETIS
Affiliation:
Centre for International Child Health, University of Melbourne, Victoria, Australia Menzies School of Health Research, Charles Darwin University, Darwin, Australia
*
*Author for correspondence: Dr A. C. Steer, Centre for International Child Health, University of Melbourne, c/- Fiji Group A Streptococcal Project, PO Box 18009, Suva, Fiji Islands. (Email: andrew.steer@rch.org.au)
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Summary

We undertook a 5-year retrospective study of group A streptococcal (GAS) bacteraemia in Fiji, supplemented by a 9-month detailed retrospective study of β-haemolytic streptococcal (BHS) infections. The all-age incidence of GAS bacteraemia over 5 years was 11·6/100 000. Indigenous Fijians were 4·7 times more likely to present with invasive BHS disease than people of other ethnicities, and 6·4 times more likely than Indo-Fijians. The case-fatality rate for invasive BHS infections was 28%. emm-typing was performed on 23 isolates: 17 different emm-types were found, and the emm-type profile was different from that found in industrialized nations. These data support the contentions that elevated rates of invasive BHS and GAS infections are widespread in developing countries, and that the profile of invasive organisms in these settings reflects a wide diversity of emm-types and a paucity of types typically found in industrialized countries.

Type
Original Papers
Copyright
Copyright © Cambridge University Press 2007

INTRODUCTION

Recent studies have identified an increasing incidence of invasive group A streptococcal (GAS) infections worldwide [Reference Lamagni1, Reference Rogers2]; there has also been a growing number of reports of invasive disease caused by Lancefield group C and group G streptococci (GCS and GGS), also known as Streptococcus dysgalactiae subsp. Equisimilis [Reference Lopardo3, Reference Ikebe4]. The incidence of invasive GAS infections in industrialized nations from well-established population-based studies ranges from 1·9 to 3·8/100 000 with a case-fatality rate of 10–13% [Reference O'Brien5Reference Jasir and Schalen7]. However, the epidemiological picture is not clear in less-developed nations. From the limited published data available it is probable that invasive GAS disease is more common in these regions [Reference Carapetis8]. For example, in a recent study in Kenya, the incidence of GAS bacteraemia in children aged <1 year was 96/100 000 and in children aged <15 years the incidence was 13/100 000 [Reference Berkley9]. Studies in indigenous populations in otherwise wealthy nations have also shown a high incidence of invasive GAS disease; 82/100 000 in Australian Aboriginals in Queensland and 46/100 000 in Native Americans in Arizona [Reference Hoge10, Reference Norton11].

The most common clinical presentation of invasive GAS infection is soft-tissue infection, including necrotizing fasciitis. Other presentations include pneumonia, septic arthritis and bacteraemia without focus. Invasive GAS infection is complicated by the development of streptococcal toxic shock syndrome in about 10% of cases [Reference Holm12]. The clinical presentation of invasive GCS and GGS disease appears to be similar to invasive GAS disease and toxic shock syndrome can also occur [Reference Hashikawa13].

The molecular epidemiology of invasive GAS disease has been carefully recorded in some industrialized nations over the past several years particularly under the auspices of strep-EURO in Europe and the Centers for Disease Control and Prevention in the United States [Reference Lamagni1, Reference O'Brien5, Reference Li14]. These surveillance systems have identified a wide variety of emm-types but with a clear predominance for a smaller number of dominant emm-types including emm-types 1, 3, 12 and 28 [Reference O'Brien5]. In contrast, available molecular data from indigenous populations such as the Aboriginal population in Northern Queensland and the Northern Territory of Australia demonstrate no apparent dominant emm-types [Reference Norton11, Reference Carapetis15].

There are no published data on the incidence of invasive BHS or GAS infections in Pacific Island Countries, where there is a demonstrated high burden of other GAS diseases such as rheumatic fever and post-streptococcal glomerulonephritis [Reference Chun16, Reference Lennon17]. We aimed to document the epidemiology of invasive β-haemolytic streptococcal (BHS) infections in a developing country in the Pacific.

Setting

Fiji is an independent republic of some 300 islands in the Western Pacific north of the Tropic of Capricorn. It has an estimated current population of 832 000 people comprising of two major racial groups of Indigenous Fijians (over 50%) and Indo-Fijians (∼40%). Fiji is ranked 90 out of 177 nations on the United Nations Development Programme Human Development Index and has a GDP per capita of US$ 6066 and an infant mortality rate of 16/1000 [Reference Ross-Larson, Coqureaumont and Trott18]. The overall crude mortality rate in Fiji is 5·3/1000, and life expectancy at birth is 64·5 years for males and 68·7 years for females [19]. More than 53% of the population live in rural areas. The major hospital, the Colonial War Memorial Hospital (CWMH), is located in the capital, Suva, in the Central Division of Fiji, on the main island of Viti Levu. This hospital predominantly serves the Central Division of Fiji, although patients from other divisions of Fiji may be referred to the hospital. We used the population of the Central Division from the most recent complete census in 1996 as the denominator for incidence calculations; the total population of the Central Division at this time was 297 607 with 175 878 being Indigenous Fijian (59·1%) and 98 660 being Indo-Fijian (33·2%).

METHODS

We performed a retrospective review of positive GAS blood cultures at CWMH from people living in the Central Division during the period January 2000 to February 2005. GAS isolates and detailed clinical data were not available for most of these cases, so we supplemented these data with a more comprehensive review of cases of sterile site (blood culture, CSF and sterile site aspirates) BHS isolates during the 9-month period from June 2004 to February 2005. Clinical and demographic data were collected from the hospital electronic database and where available medical charts were reviewed for clinical information. In almost half of the cases the corresponding sterile site isolates were available for emm-typing, which was performed using the current technique devised by the Centers for Disease Control and Prevention (CDC, Atlanta, GA, USA) [20]. In addition, these isolates were all tested for the presence of conserved epitopes in the C-repeat region of the M protein, as described previously [Reference Hayman21, Reference Batzloff22]. Relative risks were calculated as incidence rate ratios with 95% confidence intervals (95% CI). This work was approved by the Fiji National Research Ethics Review Committee.

RESULTS

GAS bacteraemia, 2000–2005

The annual all-age incidence of positive GAS blood cultures in the Central Division for the 5-year period January 2000 to February 2005 was 11·6/100 000 (95% CI 10·0–13·5), with the highest rates in children (<5 years) and the elderly (>64 years, Table 1). There were no seasonal peaks observed.

Table 1. Group A streptococcal bacteraemia in the Central Division of Fiji, January 2000 to February 2005

Invasive BHS infections, 2004–2005

During the 9-month period there were 49 cases of invasive BHS disease (39 GAS, 6 GGS and 4 GCS, Tables 2 and 3). Thirty-nine of these occurred in residents of the Central Division (all-age annual incidence of invasive BHS disease 17·5/100 000, 95%CI 12·4–23·9; Table 3). Thirty-one cases of invasive GAS infection occurred in residents of the Central Division (all-age incidence 13·9/100 000, 95% CI 9·4–19·7), similar to the incidence for the 2000–2005 period). The age distribution paralleled the bimodal distribution seen in the 2000–2005 period, with peaks occurring in children aged <5 years (44·7/100 000, 95% CI 23·1–78·2) and adults aged >64 years (146·3/100 000, 95% CI 70·2–269).

Table 2. Detail of cases of β-haemolytic streptococcal (BHS) invasive disease at the Colonial War Memorial Hospital June 2004 to February 2005, by Lancefield group and by age

n.a., Information not available; BC, blood culture.

* Pyoderma reported in preceding 28 days.

Table 3. Incidence of invasive beta-haemolytic streptococcal (BHS) disease and group A streptococcal (GAS) disease in the Central Division of Fiji, June 2004 to February 2005

Incidence rate ratio (Indigenous Fijians compared to other races): * BHS disease 4·7 (95% CI 1·8–15·4; † GAS disease 3·6 (95% CI 1·4–12).

Ethnicity data were available in 48 cases, of which 42 (88%) were Indigenous Fijians. The incidence rate ratio for invasive BHS infections in the Central Division in Indigenous Fijians was 4·7 (95% CI 1·8–15·4) compared to other races, and 6·4 (95% CI 2·0–32·4) compared to Indo-Fijians (Table 3).

Of the 43 cases of invasive BHS disease with outcome information available there were 12 deaths (case-fatality rate 28%). Two of these occurred in children aged <5 years of age. Of the 34 cases of GAS disease with outcome information available there were 10 deaths (case-fatality rate 29%).

BHS were isolated from blood culture alone in 43 cases, from joint aspirate alone in four cases, from both blood culture and joint aspirate in one case, and from CSF in one case. We were able to ascertain a clinical diagnosis in 42 of these 49 cases. Soft-tissue infections were the most common clinical infection (12 cases, 29%), followed by pneumonia (10, 24%), and septic arthritis (8, 19%). Meningitis occurred in three patients. Accurate data to assess the proportion of cases complicated by streptococcal toxic shock syndrome were not available. The only reliable risk factor data were for diabetes and pyoderma. Of the 22 cases of BHS disease with risk factor information available, 10 (45%) had co-existing diabetes and eight (36%) had had pyoderma in the preceding 28 days.

Twenty-three BHS isolates were available for emm-typing. There were 17 different emm-types, including 12 different emm-types among the 16 GAS isolates. There were four cases with emm-type STN5554, three cases with emm-type STC74A and two cases with emm-type 18, otherwise all other cases were unique emm-types. STC74A was shared between GCS and GGS cases. emm-subtype 12·8, normally associated with GAS, was seen in a GGS isolate. All 23 isolates tested contained a conserved region epitope that is recognized by antisera to the vaccine candidate J8.

DISCUSSION

These data confirm that invasive BHS and GAS infections occur at elevated rates in Fiji compared to industrialized countries, and suggest that previous findings of high rates in Kenya and indigenous populations of Australia and the United States may reflect a general tendency for these diseases to occur more frequently in developing countries. Together with the high case-fatality rate documented here, this study supports our previous contention that the global burden of invasive GAS infections has been considerably underestimated [Reference Carapetis8].

We found a significantly elevated rate of invasive BHS infections in the Indigenous Fijian population compared with people of other racial backgrounds in Fiji. We did not have sufficient data to determine if this reflects an ethnic susceptibility or other factors (e.g. increased exposure to organisms because of overcrowded living conditions). Other studies have found higher rates of bacterial infections in Indigenous Fijians: one study found that Indigenous Fijian children were 29 times more likely than Indo-Fijian to present with chest X-ray-confirmed pneumonia [Reference Macgree23]. It is our observation that the socio-economic status of Indigenous Fijians is not significantly worse than Indo-Fijians; a survey of household income and expenditure in 2002 found that 29·7% of Indigenous Fijian adults and 33·4% of Indo-Fijian adults were in full-time employment [24]. This raises the possibility that Indigenous Fijians may have an increased susceptibility to particular infections and this deserves further study.

The case-fatality rate in this study for invasive BHS and GAS infections was higher than in industrialized nations. Whilst this high rate probably represents late presentation and reduced availability of medical care such as access to intensive care and intravenous immunoglobulin, even under ideal conditions a substantial proportion of cases can be expected to die.

The findings in this study of a high number of invasive skin infections and the apparent association of pyoderma with invasive disease suggests a potential role for skin sore and scabies control programmes in reducing invasive disease incidence. The findings also support the need to consider prevention of pyoderma as well as pharyngitis in the development of GAS vaccines.

Although the number of isolates that were emm-typed in this study was small, there was relatively high genetic diversity, with 17 different emm-types among the 23 isolates from invasive BHS infections and 12 different emm-types among the 16 isolates from invasive GAS infections. In recent surveillance studies of invasive GAS isolates in the United States, only 41 emm-types were found among 1064 isolates [Reference Li14]. In addition to this comparatively higher genetic diversity of emm-types, the emm-types recovered from the isolates in this study were different to those found in the United States. This mirrors the findings for both invasive and non-invasive GAS isolates in other tropical areas, including in Hawaii and in Aboriginal populations in northern Australia, and in other developing countries [Reference Norton11, Reference Erdem25, Reference Sakota26]. These findings have implications for the development of a GAS vaccine. There are a number of GAS vaccine candidates currently under development but only one vaccine has reached clinical trials – this vaccine is a multivalent vaccine containing N-terminal protein fragments from 26 common serotypes of GAS from the United States [Reference McNeil27]. In our study only two of the 17 different emm-types found are included in this vaccine (emm-type 18 and emm-type 22). A vaccine based upon the conserved region of the M protein may circumvent this problem of serotype specificity. An epitope, J8, has been identified in the conserved C-repeat portion of the M protein and is the subject of vaccine research [Reference Batzloff22]; in our study all GAS, GCS and GGS isolates tested contained a conserved region epitope that is recognized by antisera to the J8 vaccine candidate.

The epidemiology of invasive GAS infections and other invasive BHS infections is poorly understood in most developing nations. The data from this study represent the beginning of more detailed epidemiological research in Fiji and indicate that invasive GAS disease is more common in Fiji than in industrialized nations and that the case-fatality rate is high. This study also indicates that emm-type profile is different from industrialized nations, but appears similar to the Aboriginal population in northern Australia and possibly in other developing nations in tropical and subtropical regions.

ACKNOWLEDGEMENTS

The authors acknowledge the technical assistance provided by Mrs Niumai Hicks in the Records Department of the Colonial War Memorial Hospital in searching for hospital case files. Graham Magor assisted with the emm sequencing. The Fiji Group A Streptococcal Project is funded by the National Institutes of Health, USA. Dr Andrew Steer is funded by the National Health and Medical Research Council of Australia.

DECLARATION OF INTEREST

None.

References

REFERENCES

1.Lamagni, T, et al. The epidemiology of severe Streptococcus pyogenes associated disease in Europe. Eurosurveillance 2005; 10: 179184.CrossRefGoogle ScholarPubMed
2.Rogers, S, et al. Strain prevalence, rather than innate virulence potential, is the major factor responsible for an increase in serious group a streptococcus infections. Journal of Infectious Diseases 2007; 195: 16251633.CrossRefGoogle ScholarPubMed
3.Lopardo, H, et al. Six-month multicenter study on invasive infections due to Streptococcus pyogenes and Streptococcus dysgalactiae subsp. equisimilis in Argentina. Journal of Clinical Microbiology 2005; 43: 802807.CrossRefGoogle ScholarPubMed
4.Ikebe, T, et al. Surveillance of severe invasive group-G streptococcal infections and molecular typing of the isolates in Japan. Epidemiology and Infection 2004; 132: 145149.CrossRefGoogle ScholarPubMed
5.O'Brien, K, et al. Epidemiology of invasive group A streptococcus disease in the United States, 1995–1999. Clinical Infectious Diseases 2002; 35: 268276.CrossRefGoogle ScholarPubMed
6.Davies, H, et al. Invasive group A streptococcal infections in Ontario, Canada. Ontario Group A Streptococcal Study Group. New England Journal of Medicine 1996; 335: 547554.CrossRefGoogle Scholar
7.Jasir, A, Schalen, C. Strep-EURO: progress in analysis and research into severe streptococcal disease in Europe, 2003–2004. Eurosurveillance 2005; 10: 179184.Google ScholarPubMed
8.Carapetis, J, et al. The global burden of group A streptococcal diseases. Lancet Infectious Diseases 2005; 5: 685694.CrossRefGoogle Scholar
9.Berkley, J, et al. Bacteremia among children admitted to a rural hospital in Kenya. New England Journal of Medicine 2005; 352: 3947.CrossRefGoogle ScholarPubMed
10.Hoge, C, et al. The changing epidemiology of invasive group A streptococcal infections and the emergence of streptococcal toxic shock-like syndrome. A retrospective population-based study. Journal of the American Medical Association 1993; 269: 384389.CrossRefGoogle ScholarPubMed
11.Norton, R, et al. Invasive group A streptococcal disease in North Queensland (1996–2001). Indian Journal of Medical Research 2004; 119 (Suppl.): 148151.Google Scholar
12.Holm, S. Invasive group A streptococcal infections. New England Journal of Medicine 1996; 335: 590591.CrossRefGoogle ScholarPubMed
13.Hashikawa, S, et al. Characterization of group C and G streptococcal strains that cause streptococcal toxic shock syndrome. Journal of Clinical Microbiology 2004; 42: 186192.CrossRefGoogle Scholar
14.Li, Z, et al. Array of protein gene subtypes in 1064 recent invasive group A streptococcus isolates recovered from the Active Bacterial Core Surveillance. Clinical Infectious Diseases 2003; 188: 15871592.Google ScholarPubMed
15.Carapetis, J, et al. Clinical and epidemiological features of group A streptococcal bacteraemia in a region with hyperendemic superficial streptococcal infection. Epidemiology and Infection 1999; 122: 5965.CrossRefGoogle Scholar
16.Chun, LT, et al. Acute rheumatic fever in Hawaii: 1966 to 1988. Hawaii Medical Journal 1992; 51: 206211.Google ScholarPubMed
17.Lennon, D, et al. Longitudinal study of poststreptococcal disease in Auckland; rheumatic fever, glomerulonephritis, epidemiology and M typing 1981–86. New Zealand Medical Journal 1988; 101: 396398.Google Scholar
18.United Nations Development Programme, 2006. In: Ross-Larson, B, Coqureaumont, MD, Trott, C eds. Human Development Report, 2006.Google Scholar
19.Ministry of Health Annual Report. Suva: Parliament of Fiji, 2005.Google Scholar
20.Centers for Disease Control and Prevention. Streptococcus laboratory: protocol for emm-typing (http://www.cdc.gov/ncidod/biotech/strep/protocol_emm-type.htm), 2006. Accessed 9 November 2006.Google Scholar
21.Hayman, W, et al. Mapping the minimal murine T cell and B cell epitopes within a peptide vaccine candidate from the conserved region of the M protein of the group A streptcoccus. International Immunology 1997; 9: 17231733.CrossRefGoogle Scholar
22.Batzloff, M, et al. Protection against group a streptococcus by immunization with J8-diptheria toxoid: contribution of J8- and Diptheria toxoid-specific antibodies to protection. Journal of Infectious Diseases 2003; 187: 15981608.CrossRefGoogle Scholar
23.Macgree, H, et al. Chest X-ray-confirmed pneumonia in children in Fiji. Bulletin of the World Health Organisation 2005; 83: 427433.Google Scholar
24.Fiji Bureau of Statistics. Key Statistics September 2006. In: Statistics Fiji Bureau of Statistics. Suva, 2006.Google Scholar
25.Erdem, G, et al. Molecular epidemiologic comparison of 2 unusual clusters of group A streptococcal necrotizing fasciitis in Hawaii. Clinical Infectious Diseases 2005; 40: 18511854.CrossRefGoogle Scholar
26.Sakota, V, et al. Genetically diverse group A streptococci from children in far-Western Nepal share high genetic relatedness with isolates from other countries. Journal of Clinical Microbiology 2006; 44: 21602166.CrossRefGoogle Scholar
27.McNeil, S, et al. A double-blinded, randomized, controlled phase II trial of the safety and immunogenicity of a 26 valent group A streptococcus vaccine in healthy adults. The XVIth Lancefield International Symposium on Streptococci and Streptococcal Diseases, 25–29 September 2005; Palm Cove, Australia.Google Scholar
Figure 0

Table 1. Group A streptococcal bacteraemia in the Central Division of Fiji, January 2000 to February 2005

Figure 1

Table 2. Detail of cases of β-haemolytic streptococcal (BHS) invasive disease at the Colonial War Memorial Hospital June 2004 to February 2005, by Lancefield group and by age

Figure 2

Table 3. Incidence of invasive beta-haemolytic streptococcal (BHS) disease and group A streptococcal (GAS) disease in the Central Division of Fiji, June 2004 to February 2005