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Seroepidemiology of dengue virus infection in the adult population in tropical Singapore

Published online by Cambridge University Press:  23 September 2014

L. W. ANG*
Affiliation:
Epidemiology & Disease Control Division, Ministry of Health, Singapore
J. CUTTER
Affiliation:
Communicable Diseases Division, Ministry of Health, Singapore
L. JAMES
Affiliation:
Epidemiology & Disease Control Division, Ministry of Health, Singapore
K. T. GOH
Affiliation:
Communicable Diseases Division, Ministry of Health, Singapore Saw Swee Hock School of Public Health, National University of Singapore, Singapore
*
*Author for correspondence: Ms. L. W. Ang, Epidemiology & Disease Control Division, Ministry of Health, Singapore, College of Medicine Building, 16 College Road, Singapore 169854. (Email: ang_li_wei@hotmail.com)
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Summary

To assess the impact of past dengue epidemics in Singapore, we undertook a national seroepidemiological study to determine the prevalence of past dengue virus (DENV) infection in the adult population in 2010 and make comparisons with the seroprevalence in 2004. The study involved residual sera from 3293 adults aged 18–79 years who participated in a national health survey in 2010. The overall prevalence of anti-DENV IgG antibodies was 56·8% (95% confidence interval 55·1–58·5) in 2010. The seroprevalence increased significantly with age. Males had significantly higher seroprevalence than females (61·5% vs. 53·2%). Among the three major ethnic groups, Malays had the lowest seroprevalence (50·2%) compared to Chinese (57·0%) and Indians (62·0%). The age-standardized seroprevalence in adults was significantly lower in 2010 (54·4%) compared to 2004 (63·1%). Older age, male gender, Indian ethnicity, permanent residency and being home-bound were independent risk factors significantly associated with seropositivity. About 43% of the Singapore adult resident population remain susceptible to DENV infection as a result of the successful implementation of a comprehensive nationwide Aedes surveillance and control programme since the 1970s. Vector suppression and concerted efforts of all stakeholders in the community remain the key strategy in the prevention and control of dengue.

Type
Original Papers
Copyright
Copyright © Cambridge University Press 2014 

INTRODUCTION

Dengue, a mosquito-borne arboviral disease, is endemic in more than 100 countries in Africa, the Americas, the Eastern Mediterranean, Southeast Asia and the Western Pacific, with the American, Southeast Asian and the Western Pacific regions most seriously affected [1].

In Singapore, a highly urbanized tropical city-state, the vectors Aedes aegypti and Aedes albopictus breed throughout the year. The first outbreak of dengue fever (DF) was reported in 1901 [Reference Moore2]. An outbreak of dengue haemorrhagic fever (DHF) involving 70 hospitalized cases was first recorded in 1960 [Reference Chew3, Reference Lim4]. Since then, dengue has become endemic in Singapore with large epidemics occurring almost annually, and it was a major paediatric problem in the 1960s [Reference Chan5, Reference Goh6]. Based on surveillance and research data gathered in the field, a comprehensive nationwide Aedes prevention and control programme incorporating source reduction, health education and law enforcement was launched in 1969 and successfully implemented since 1973, as evidenced by a sharp reduction in Aedes premises index (percentage of premises found to be breeding Aedes mosquitoes) and low disease incidence [Reference Ooi7, Reference Chan8]. However, since the 1980s, dengue epidemics of increasing magnitude occurred on a 6-year cycle in 1986/1987 [Reference Goh9] (13·0 and 15·7/100 000 population), 1992 [10] (89·1/100 000 population), 1998 [11] (133·9/100 000 population), 2004/2005 [Reference Koh12] (227·0 and 333·1/100 000 population), 2007 [Reference Ler13] (192·3/100 000 population) and 2013 [Reference Low14] (410·6/100 000 population). During the 10-year period between 2004 and 2013, excluding the epidemic years, the dengue incidence/100 000 population ranged from 87·2 in 2012 to 145·3 in 2008 [15]. All four dengue virus (DENV) serotypes circulate throughout the year; serotype 1 was the predominant serotype in the 2004/2005 epidemic [Reference Koh12], serotype 2 in the 2007 epidemic [Reference Ler13] and serotype 1 in the 2013 epidemic [16].

Several seroprevalence studies were conducted in the Singapore general population aged 6 months to >45 years to monitor the changing immune status and to assess the effectiveness of the national Aedes control programmes [Reference Goh17, 18]. These surveys supplemented disease notification in monitoring trends and changing epidemiology of dengue in the community. However, all these seroepidemiological studies undertaken were not representative of the Singapore general population. The first seroprevalence survey representative of the adult population in Singapore was conducted in 2004 [Reference Yew19]. It was based on 4152 residual sera obtained during the National Health Survey (NHS) in 2004. The NHS was a population-based cross-sectional survey conducted by the Ministry of Health (MoH) to determine the prevalence of chronic diseases and lifestyle-related risk factors in Singapore adult residents (Singapore citizens and permanent residents). Collection of blood samples was made between September and December 2004 which coincided with a nationwide dengue epidemic.

To assess the impact of the 2004/2005 and 2007 dengue epidemics, we undertook another national seroepidemiological study in the adult resident population in 2010 to determine the prevalence of past DENV infection in Singapore, and compare this with the findings in 2004.

MATERIALS AND METHODS

As in the last seroepidemiological study [Reference Yew19] on DENV infection conducted in 2004 in Singapore adult residents, we made use of residual sera obtained during the NHS in 2010 [20]. Selection of the survey population was by a combination of disproportionate stratified sampling and systematic sampling. Five government primary-care clinics and one community club geographically well spread out across Singapore were selected as the sites for NHS 2010. The household units in the vicinity of these survey sites provided a good combination of the different types of dwelling and the three major ethnic groups in Singapore. The fieldwork for the NHS was carried out over a 3-month period from 17 March to 13 June 2010. There was no increase in dengue incidence during this period. Ethical approval was given by the Ethics Committee of the Health Promotion Board, Singapore (reference number 006-2010). Only sera from survey participants who had consented to having their residual sera used for further research were included in this study. Personal identifiers of survey participants were permanently removed and new study numbers tagged to the residual sera, so as to ensure strict anonymity of the participants via this delinking process.

A total of 4337 persons out of an eventual sample of 7512 eligible Singapore residents aged 18–79 years participated in NHS 2010, giving a response rate of 57·7%. Residual sera from 3293 participants aged 18–79 years from NHS 2010 (75·9%) were included in the dengue seroprevalence study.

The stored residual sera from NHS 2010 were screened for anti-DENV IgG antibodies by ELISA using a commercial test kit (EUROIMMUN, Germany) according to the manufacturer's recommended procedure. Levels ⩾20 relative units/ml were considered to be reactive. For the earlier study based on residual sera from NHS 2004, a commercial test, the Panbio Dengue IgG Capture/Indirect ELISA system (Panbio, Australia), was used to determine past exposure to DENV [Reference Yew19]. Individuals that tested positive for IgG (PanBio Indirect ELISA), excluding high-titre IgG (PanBio Capture ELISA), were classified as having past DENV infection in 2004.

To ensure that the characteristics of the sample for NHS 2010 conformed to that of the general population, post-stratification weights were computed based on the age, gender, ethnic group and dwelling type attributes of the Singapore resident population. The overall sample weight was the product of weights for unequal probability of selection and non-response from the household enumeration exercise and survey fieldwork, respectively, and post-stratification weight.

The weighted respondent sample of 4337 participants of NHS 2010 was similar to the Singapore resident population in socio-demographic profile [20]. The socio-demographic profile of 3293 survey subjects included in our dengue seroprevalence study and the Singapore resident population aged 18–79 years was also found to be similar (Table 1).

Table 1. Socio-demographic profile (%) of 3293 study subjects and resident population aged 18–79 years in Singapore, 2010

* HDB, Housing Development Board, refers to public apartments.

Refers to bungalow/detached house, semi-detached house and terrace house.

Refers to temporary residences and dormitories.

The χ 2 test or Fisher's exact test, where appropriate, was used to test for group differences. Proportions between two groups were compared using two-sample independent z tests, with standard error estimated using pooled value of the two proportions. The Mantel–Haenszel linear-by-linear association χ 2 test was used to evaluate whether there was linear trend in seroprevalence in the age groups.

Age-standardization of dengue seroprevalence was calculated by the direct method, using the 2010 census Singapore resident population as the standard. Differences in the age-standardized rates between genders and ethnic groups were computed and tested for statistical significance using the z test [Reference Armitage21]. The 95% confidence intervals (CI) were reported.

For comparison with the dengue seroepidemiological study based on 4152 residual sera from NHS 2004 [Reference Yew19], the study sample in 2010 was confined to 3091 Singapore residents aged 18–74 years who were ethnic Chinese, Malay and Indian; subjects aged 75–79 years and other ethnic groups were omitted. Tests for statistical significance between the two studies were based on age-standardized seroprevalence.

Bivariate analysis using logistic regressions was performed to compute crude odds ratios of demographic characteristics for DENV seroprevalence. Multivariable logistic regression analysis was used to determine independent risk factors of past DENV infection, using forward stepwise selection based on maximum partial likelihood estimates. All P values reported were two-sided and statistical significance was taken at P < 0·05. Statistical analysis was performed using SPSS Statistics software, v. 19·0 (IBM, USA).

RESULTS

The overall prevalence of anti-DENV IgG antibodies in the adult population aged 18–79 years was 56·8% (95% CI 55·1–58·5) in 2010. The seroprevalence increased significantly from 17·8% in young adults aged 18–29 years to 77·8% in those aged 50–59 years (test for trend, P < 0·0005) (Table 2). It was maintained at 92·4% or higher in older age groups of 60–69 years and 70–79 years. Males (61·5%) had a significantly higher seroprevalence than females (53·2%) (P < 0·0005). Of the three major ethnic groups, the seroprevalence in Chinese (57·0%) and Indians (62·0%) (P = 0·09) were similar, but Malays had a significantly lower seroprevalence (50·2%) than Chinese (P = 0·01) and Indians (P = 0·001). No significant difference was detected by residency status (Singapore citizens vs. permanent residents, P = 0·10).

Table 2. Seroprevalence (%) and odds ratios of DENV infection in logistic regression analysis by demographic characteristics in 3293 adults aged 18–79 years in Singapore, 2010

OR, Odds ratio; CI, confidence interval.

* Refers to bungalow/detached house, semi-detached house and terrace house.

Refers to temporary residences and dormitories.

We observed no significant difference in the seroprevalence by the three main types of dwelling (P = 0·34). Of those living in public and private housing apartments, there was also no discernible trend in seroprevalence by floor level (P = 0·25).

In the multivariable logistic regression analysis, older age, male gender, Indian ethnicity, residency status (permanent resident) and occupation (homemaker and retiree) were independent risk factors significantly associated with past DENV infection (Table 2).

Compared to 2004, the seroprevalence in 2010 was significantly lower in all age groups except in the youngest (18–24 years) and oldest (55–74 years) age groups (Fig. 1). The decrease in seroprevalence was most marked in the 35–44 years age group; 61·7% in 2004 vs. 44·2% in 2010 (P < 0·0005).

Fig. 1. Age-specific DENV seroprevalence in adults aged 18–74 years in Singapore, 2004 and 2010. *Age-adjusted using the 2010 census population as the standard.

The age-standardized seroprevalence in 2010 (54·4%, 95% CI 52·7–56·2) was significantly lower than in 2004 (63·1%, 95% CI 61·6–64·6) (P < 0·005). There were significant decreases in the age-standardized seroprevalence for both genders and in the three major ethnic groups between 2004 and 2010 (all P < 0·01).

While there was a significant difference in seroprevalence by gender in 2010, no significant difference was observed in 2004 (P = 0·13). In 2004, Indians had a significantly higher seroprevalence (69·3%) compared to Chinese (58·2%) and Malays (57·1%) (P < 0·0005). There were no significant differences in seroprevalence for each type of dwelling (landed residential property, public housing apartment, private flat, condominium) between 2004 and 2010 (all P ≥ 0·10).

DISCUSSION

Periodic seroprevalence surveys conducted in Singapore since 1982 show a declining level of immunity against dengue infection in the population aged 6 months to >45 years. The overall proportion who possessed haemagglutination-inhibition (HI) antibody to DENV serotype 2 decreased from 45·6% in 1982–1984 to 39·6% in 1993 and 29·4% in 1998 [Reference Goh17, 18]. Dengue is no longer a childhood infection, as only 4·3% of children and young adults aged <20 years possessed HI antibody to DENV serotype 2 in 1998. The low seroprevalence in children aged 6–15 years was also observed in a survey conducted between 1996 and 1997 when less than 7% tested positive for anti-DENV IgG antibodies [Reference Ooi22]. In a national paediatric seroprevalence survey (NPSS) involving residual diagnostic sera collected prospectively from 1200 Singapore residents aged 1–17 years at two public acute-care hospitals from August 2008 to July 2010, the low prevalence in children and adolescents was again confirmed with 10·4% having evidence of past DENV infection. The median age of reported dengue cases has gradually increased from 14 years in 1973 [Reference Goh23] to 27 years in 1996 [Reference Goh6], 31 years in 2005 [Reference Koh12] and 37 years in 2007 [Reference Ler13], with the highest incidence rate of indigenous cases in adults aged 35–44 years in 2010 (132·8/100 000 population) [24]. The increasing age of dengue cases poses new challenges, including increased risk of severe disease [Reference Low14].

The first serological survey representative of the adult population aged 18–74 years who participated in NHS 2004 showed an overall DENV seroprevalence of 59·0% (95% CI 57·5–60·5) [Reference Yew19]. This was within the range from 44·6% in a survey of 298 asymptomatic volunteers aged 18–45 years comprising staff and visitors to a large public tertiary hospital in 2002 [Reference Wilder-Smith25] to 65·9% in another study conducted during the 2007 epidemic involving 3939 blood samples from residents in seven outbreak areas [Reference Yap26]. In the second study representative of the adult population which was conducted during the non-epidemic period in 2010, the overall prevalence of anti-DENV IgG antibodies was 56·8% (95% CI 55·1–58·5). When we combined the results from NPSS 2008–2010 and our study in adults aged 18–79 years, we estimated an overall seroprevalence of 46·9% in the Singapore general population aged 1–79 years in 2010. This was not much different from the finding that 45·6% had HI antibody to DENV serotype 2 in 1982–1984 [Reference Goh17].

There were two dengue epidemics which occurred in 2005 and 2007 before the seroprevalence study was conducted in 2010. In fact, the 2005 epidemic was the largest epidemic recorded prior to the survey until it was overtaken by an even larger epidemic in 2013 (Fig. 2). The dengue incidence rate in the Singapore resident population was highest in the 15–24 years age group in the 2004/2005 and 2013 epidemics, while it was the highest in the elderly aged ⩾55 years in the 2007 epidemic. Singapore adolescents and young adults had less cumulative exposure to DENV as discerned from the age-specific incidence rate of dengue cases, which could have accounted for the low dengue seroprevalence in those aged 25–54 years over the 6-year period. Those who had been infected during large dengue epidemics in the 1960s would have reached the age of ⩾55 years in 2004. This age group was the most affected in the 2007 epidemic and as the older cohorts died and were replaced by new cohorts, it was not unexpected that no significant difference in seroprevalence in those aged 55–74 years was detected between 2004 and 2010. Similarly, the relatively unchanged seroprevalence in those aged 18–24 years over the 6-year period could also be partly attributed to replacement of new cohorts in this age group. In periodic studies on blood donors conducted by the Environmental Health Institute (EHI) under the National Environment Agency (NEA), decreases in the prevalence of anti-DENV IgG antibodies were observed in the 20–40 years age group and older adults aged >40 years, while the seroprevalence remained stable in those aged <20 years between 2004 and 2009 [Reference Ng27]. The overall declining trend of dengue seroprevalence observed in about 4000 blood donors tested each year between 2004 and 2013 corroborated with our finding.

Fig. 2. Monthly incidence of reported dengue cases in Singapore, 2004–2013.

The overall prevalence of anti-DENV IgG antibodies in adults has remained relatively stable despite the two large epidemics in 2005 and 2007. This could also be partly attributed to the unprecedented national efforts to curb the first largest ever recorded epidemic in 2005 with the formation of an Inter-Ministerial Committee, an Interagency Dengue Coordination Committee to ensure that various policy initiatives were well coordinated, a Dengue Watch Committee to coordinate outreach to the community, an Expert Panel comprising local and international experts to advise the government on prevention and control measures, and an Interagency Dengue Task Force to enhance communication and coordination on dengue control efforts among various government agencies and private organizations. Manpower was increased by almost 400%, indoor and outdoor inspections for Aedes breeding increased by 50% compared to the previous year and a 2-month ‘carpet combing’ exercise was carried out for all the electoral constituencies [Reference Koh12]. Similar enhanced Aedes prevention and control measures were implemented in the 2007 epidemic [Reference Ler13].

The nationwide vector surveillance and control programme implemented since the early 1970s has reduced the overall Aedes premises index from more than 25% in the 1960s to 1–2% since 1985 [Reference Ooi7, 28]. With less exposure to infected female Aedes mosquitoes, the herd immunity of the human population has declined over the decades as evidenced by the findings of periodic seroprevalence surveys. This has resulted in a paradoxical situation in that epidemics tend to occur more frequently and with greater intensity since the 1980s. Mathematical modelling shows that dengue transmission by the Aedes mosquito becomes more efficient with declining herd immunity of the human population [Reference Newton29, Reference Reiter, Halstead and Gomez-Dantes30]. In another mathematical model based on local seroprevalence data, the rise in dengue incidence in Singapore was attributed to a declining trend in the force of infection (defined as per capita rate at which susceptible individuals in the community acquire infection), partly due to a vector-control-driven reduction in herd immunity and an increase in the average age of first infection since the comprehensive Aedes control programme was implemented nationwide [Reference Egger31]. Susceptibility in developing clinical dengue is higher in older than younger individuals [Reference Halstead, Gubler and Kuno32].

In both the 2004 and 2010 studies of the adult population, older age, male gender and Indian ethnicity were identified as independent risk factors significantly associated with past DENV infection. In addition, homemakers or retirees were also found to be at higher odds of past DENV infection in 2010 after adjusting for age in the regression model. The increase in seroprevalence with age was expected, due to long-term or lifelong persistence of anti-DENV IgG antibodies following infection [Reference Peeling33, Reference Shu34]. The higher seroprevalence in retirees was probably age-related. The higher seroprevalence in those aged ⩾50 years in 2010 was also anticipated, as large epidemics had occurred almost annually in the 1960s. The higher seroprevalence in men corresponded to the pattern of gender-specific dengue incidence rates/100 000 population. This gender differential in the risk of DENV infection could be attributed to specific behaviour such as less tendency towards individual protection (i.e. use of insect repellents) that resulted in higher exposure to Aedes mosquito bites in men [Reference Guha-Sapir35].

In the multivariable logistic regression analysis of the 2010 study, residency status was found to be an independent risk factor; compared to Singapore citizens, permanent residents were at significantly higher odds of past DENV infection (adjusted odds ratio 1·34, 95% CI 1·05–1·70). This could be due to the influx of foreign immigrants over the decades from other regions with higher level of dengue endemicity such as Malaysia where the majority of the adults (91·6% of a Malaysian cohort in 2008) have been found to be seropositive [Reference Muhammad Azami36].

Dengue seroprevalence was highest in residents of landed residential properties, although it was not significantly different from that of other types of dwelling, whereas significant difference had been detected in past serological studies [18, 37]. The annual incidence rates of indigenous dengue have consistently been the highest in residents of landed residential properties where more potential breeding habitats are detected [Reference Goh and Goh38, 39].

The main limitation in our study in comparing the dengue seroprevalence between 2004 and 2010 is that the laboratory methods employed in the two studies were different. However, based on the manufacturer's document (EUROIMMUN, Germany), there was a 100% agreement between the results obtained using the EUROIMMUN Anti-Dengue Virus IgG ELISA and the Panbio Dengue Capture IgG ELISA, excluding borderline results from either test. Moreover, the significant decline in overall prevalence of anti-DENV IgG antibodies in adults between 2004 and 2010 was consistent with the trend observed in EHI's periodic studies on blood donors, who are screened to exclude potential donors with dengue infection without symptoms [40].

Another limitation is the comparison of findings with other serological surveys which were not representative of the general population; these should be interpreted with caution. Serotype-specific seroprevalence has not been determined and we only measured total IgG antibodies in the two nationally representative studies in 2004 and 2010, as there is no serological test that can accurately detect the serotype associated with past DENV infections due to cross-reactivity of anti-DENV antibodies [Reference van Panhuis41]. The most widely used and recommended method to determine serotype-specific antibodies against DENV is the plaque reduction neutralization test (PRNT) [Reference Peeling33, Reference van Panhuis41, 42].

In conclusion, despite epidemics occurring between the surveys in 2004 and 2010, the herd immunity of the adult population in Singapore is low, as about 43% remain susceptible to DENV infection. The city-state continues to be receptive to dengue despite sustained vector suppression measures implemented during both epidemic and non-epidemic periods to maintain a consistently low Aedes population. It is also vulnerable to the introduction of different DENV strains because of the large influx of travellers and visitors from other endemic regions. The only definitive long-term solution to the control of dengue in Singapore is vaccination of the population when a safe and effective dengue vaccine against all the four dengue serotypes becomes commercially available. In the meantime, more aggressive vector suppression through concerted efforts of all stakeholders in the community remains the main strategy in the prevention and control of dengue in Singapore.

DECLARATION OF INTEREST

None.

References

REFERENCES

1. WHO Fact sheet. Dengue and severe dengue (http://www.who.int/mediacentre/factsheets/fs117/en/). Accessed 6 December 2013.Google Scholar
2. Moore, FW. Observations of dengue fever in Singapore. Journal of the Malaya Branch of the British Medical Association 1904; 1: 2429.Google Scholar
3. Chew, A, et al. A haemorrhagic fever in Singapore. Lancet 1961; 1: 307310.CrossRefGoogle ScholarPubMed
4. Lim, KA, et al. Dengue-type viruses isolated in Singapore. Bulletin of the World Health Organization 1964; 30: 2272240.Google ScholarPubMed
5. Chan, YC, et al. Recent epidemics of haemorrhagic fever in Singapore. Japanese Journal of Medical Science & Biology 1996; 20: 8188.Google Scholar
6. Goh, KT. Dengue: a re-emerging infectious disease in Singapore. Annals Academy of Medicine Singapore 1997; 26: 664670.Google ScholarPubMed
7. Ooi, EE, et al. Dengue prevention and 35 years of vector control in Singapore. Emerging Infectious Diseases 2006; 12: 887893.CrossRefGoogle ScholarPubMed
8. Chan, KL. Singapore's dengue haemorrhagic fever control program: a case study on the successful control of Aedes aegypti and Aedes albopictus using mainly environmental measures as a part of integrated vector control. Tokyo: Southeast Asian Medical Information Center, 1985.Google Scholar
9. Goh, KT, et al. Epidemiological aspects of an outbreak of dengue fever/dengue haemorrhagic fever in Singapore. Southeast Asian Journal of Tropical Medicine and Public Health 1987; 18: 295302.Google ScholarPubMed
10. Committee of Epidemic Diseases, Singapore. Surveillance of dengue fever/dengue haemorrhagic fever, 1992. Epidemiological News Bulletin; 1993; 19: 1317.Google Scholar
11. Committee of Epidemic Diseases, Singapore. Dengue surveillance in Singapore, 1998. Epidemiological News Bulletin 1999; 25: 13.Google Scholar
12. Koh, BK, et al. The 2005 dengue epidemic in Singapore: epidemiology, prevention and control. Annals Academy of Medicine Singapore 2008; 37: 538545.CrossRefGoogle ScholarPubMed
13. Ler, TS, et al. Epidemiological characteristics of the 2005 and 2007 dengue epidemics in Singapore – similarities and distinctions. Western Pacific Surveillance and Response Journal 2011; 2: 2429.Google ScholarPubMed
14. Low, JG, et al. Dengue – old disease, new challenges in an ageing population. Annals Academy of Medicine Singapore 2013; 42: 373375.CrossRefGoogle Scholar
15. Ministry of Health, Singapore. Communicable diseases surveillance in Singapore 2012. Singapore: Ministry of Health, 2013.Google Scholar
16. National Environment Agency, Singapore. Parliament Q&A – Oral reply by Dr Vivian Balakrishnan, Minister for the Environment and Water Resources to Parliamentary Question on the recent spike in dengue cases, 23 February 2013 (https://app.mewr.gov.sg/web/Contents/Contents.aspx?Yr=2013&ContId=1785). Accessed 22 April 2014.Google Scholar
17. Goh, KT, et al. Serological survey on dengue virus infection in Singapore. Transactions of the Royal Society of Tropical Medicine and Hygiene 1987; 81: 687689.CrossRefGoogle ScholarPubMed
18. Committee on Epidemic Diseases, Singapore. Seroprevalence of dengue virus infection in Singapore. Epidemiological News Bulletin 2000; 26: 3031.Google Scholar
19. Yew, YW, et al. Seroepidemiology of dengue virus infection among adults in Singapore. Annals Academy of Medicine Singapore 2009; 38: 667675.CrossRefGoogle ScholarPubMed
20. Ministry of Health, Singapore. National Health Survey 2010. Singapore: Ministry of Health, 2011.Google Scholar
21. Armitage, P, et al. Statistical Methods in Medical Research, 4th edn. Oxford: Blackwell Science, 2002, pp. 662663.CrossRefGoogle Scholar
22. Ooi, EE, et al. Dengue seroepidemiology in Singapore. Lancet 2001; 357: 685686.CrossRefGoogle ScholarPubMed
23. Goh, KT. Changing epidemiology of dengue in Singapore. Lancet 1995; 346: 1098.CrossRefGoogle ScholarPubMed
24. Ministry of Health, Singapore. Communicable diseases surveillance in Singapore 2010. Singapore: Ministry of Health, 2011.Google Scholar
25. Wilder-Smith, A, et al. Seroepidemiology of dengue in the adult population of Singapore. Tropical Medicine & International Health 2004; 9: 305308.CrossRefGoogle ScholarPubMed
26. Yap, G, et al. High rates of inapparent dengue in older adults in Singapore. American Journal of Tropical Medicine and Hygiene 2013; 88: 10651069.CrossRefGoogle ScholarPubMed
27. Ng, LC. Confronting the challenge of vector borne diseases in Singapore. Presentation at the 1st One Health Symposium, Singapore, 8 August 2014.Google Scholar
28. Committee on Epidemic Diseases, Singapore. Surveillance for dengue fever/dengue haemorrhagic fever in Singapore. Epidemiological News Bulletin 2002; 28: 2528.Google Scholar
29. Newton, EA, et al. A model of the transmission of dengue fever with an evaluation of the impact of ultra-low volume (ULV) insecticide application on dengue epidemics. American Journal of Tropical Medicine and Hygiene 1992; 47: 709722.CrossRefGoogle Scholar
30. Reiter, P. Status of current Aedes aegypti control strategies. In: Halstead, SB, Gomez-Dantes, H, eds. Dengue: a Worldwide Problem, a Common Strategy. Mexico. Ministry of Health, Mexico and Rockefeller Foundation, 1992, pp. 4148.Google Scholar
31. Egger, JR, et al. Reconstructing historical changes in the force of infection of dengue fever in Singapore: implications for surveillance and control. Bulletin of the World Health Organization 2008; 86: 187196.CrossRefGoogle ScholarPubMed
32. Halstead, SB. Epidemiology of dengue and dengue hemorrhagic fever. In: Gubler, D, Kuno, G, eds. Dengue and Dengue Hemorrhagic Fever. Wallingford/New York: CAB International, 1997, pp. 2344.Google Scholar
33. Peeling, RW, et al. Evaluation of diagnostic tests: dengue. Nature Reviews Microbiology 2010; 8: S30–3S7.CrossRefGoogle ScholarPubMed
34. Shu, PY, et al. Current advances in dengue diagnosis. Current advances in dengue diagnosis. Clinical and Diagnostic Laboratory Immunology 2004; 11: 642650.Google ScholarPubMed
35. Guha-Sapir, D, et al. Dengue fever: new paradigms for a changing epidemiology. Emerging Themes in Epidemiology 2005; 2: 1.CrossRefGoogle ScholarPubMed
36. Muhammad Azami, NA, et al. Dengue epidemic in Malaysia: not a predominantly urban disease anymore. BMC Research Notes 2011; 4: 216.CrossRefGoogle Scholar
37. Committee on Epidemic Diseases, Singapore. Seroprevalence of dengue virus infection in Singapore. Epidemiological News Bulletin 1991; 17: 4951.Google Scholar
38. Goh, KT. Seroepidemiology of dengue virus infection in Singapore. In: Goh, KT, ed. Dengue in Singapore. Singapore: Institute of Environmental Epidemiology, Ministry of the Environment, 1998, pp. 5072.Google Scholar
39. Committee on Epidemic Diseases, Singapore. Prevalence of dengue virus infection in two highly endemic areas in Singapore. Epidemiological News Bulletin 1995; 21: 12.Google Scholar
40. Health Science Authority, Singapore. HSA updates, No. 6/2008. Dengue & blood transfusion: HSA assures on the continued safety of national blood supply. 7 October 2008 (http://www.hsa.gov.sg/content/dam/HSA/News_and_Events/HSA_Updates/2008/HSAUpdates_DengueAndBloodTransfusionHSAAssuresOnTheContinuedSafetyOfNationalBloodSupply_07Oct08.pdf). Accessed 12 August 2014.Google Scholar
41. van Panhuis, WG, et al. Inferring the serotype associated with dengue virus infections on the basis of pre- and postinfection neutralizing antibody titers. Journal of Infectious Diseases 2010; 202: 10021010.CrossRefGoogle ScholarPubMed
42. WHO. Laboratory diagnosis, chapter 4. In: Dengue Haemorrhagic Fever: Diagnosis, Treatment, Prevention and Control, 2nd edn. Geneva: World Health Organization, 1997, pp. 3447.Google Scholar
Figure 0

Table 1. Socio-demographic profile (%) of 3293 study subjects and resident population aged 18–79 years in Singapore, 2010

Figure 1

Table 2. Seroprevalence (%) and odds ratios of DENV infection in logistic regression analysis by demographic characteristics in 3293 adults aged 18–79 years in Singapore, 2010

Figure 2

Fig. 1. Age-specific DENV seroprevalence in adults aged 18–74 years in Singapore, 2004 and 2010. *Age-adjusted using the 2010 census population as the standard.

Figure 3

Fig. 2. Monthly incidence of reported dengue cases in Singapore, 2004–2013.