Hostname: page-component-76fb5796d-22dnz Total loading time: 0 Render date: 2024-04-26T11:23:05.427Z Has data issue: false hasContentIssue false
  • English
  • Français

Will integrated surveillance systems for vectors and vector-borne diseases be the future of controlling vector-borne diseases? A practical example from China

Published online by Cambridge University Press:  22 February 2016

Y. WU ,
F. LING ,
J. HOU ,
S. GUO ,
J. WANG  and
Z. GONG
Y. WU
Affiliation:
Zhejiang Provincial Center for Disease Control and Prevention, Hangzhou, People's Republic of China
F. LING
Affiliation:
Zhejiang Provincial Center for Disease Control and Prevention, Hangzhou, People's Republic of China
J. HOU
Affiliation:
Zhejiang Provincial Center for Disease Control and Prevention, Hangzhou, People's Republic of China
S. GUO
Affiliation:
Zhejiang Provincial Center for Disease Control and Prevention, Hangzhou, People's Republic of China
J. WANG
Affiliation:
Zhejiang Provincial Center for Disease Control and Prevention, Hangzhou, People's Republic of China
Z. GONG*
Affiliation:
Zhejiang Provincial Center for Disease Control and Prevention, Hangzhou, People's Republic of China
*
*Author for correspondence: Dr Z. Gong, 3399 Binsheng Road, Zhejiang Provincial Center for Disease Control and Prevention, Binjiang, Hangzhou, People's Republic of China. (Email: Zhygong@cdc.zj.cn)
Rights & Permissions [Opens in a new window]

Summary

Vector-borne diseases are one of the world's major public health threats and annually responsible for 30–50% of deaths reported to the national notifiable disease system in China. To control vector-borne diseases, a unified, effective and economic surveillance system is urgently needed; all of the current surveillance systems in China waste resources and/or information. Here, we review some current surveillance systems and present a concept for an integrated surveillance system combining existing vector and vector-borne disease monitoring systems. The integrated surveillance system has been tested in pilot programmes in China and led to a 21·6% cost saving in rodent-borne disease surveillance. We share some experiences gained from these programmes.

Keywords

Integrated surveillance vectorsvector-borne diseases
Type
Review
Information
Epidemiology & Infection , Volume 144 , Issue 9 , July 2016 , pp. 1895 - 1903
Check for updates
Copyright
Copyright © Cambridge University Press 2016 

INTRODUCTION

Vector-borne diseases, like plague, dengue fever, yellow fever, Japanese encephalitis, Lyme disease, and so on, are widely spread. Taking West Nile fever as an example, since the first isolation of West Nile virus (WNV) in 1937 in Uganda, it has spread to Egypt, Israel, South Africa, Asia, North America and parts of Europe, causing a significant disease burden [Reference Zohrabian1]. In Louisiana, USA, the total cost of a WNV epidemic in 2002 was estimated at US$20.1 million, 54·22% for illness and 45·78% for the public health response [Reference Zohrabian1]. Continual autochthonous transmission of Chikungunya fever in Italy and France, autochthonous transmission of dengue fever in France, Croatia and Madeira, and autochthonous transmission of malaria in The Netherlands, USA, and Spain have been reported [Reference Angelini2Reference Santa-Olalla10]. In China, vector-borne diseases are annually responsible for 5–10% of new cases of reported infectious diseases and 30–50% of deaths reported to the national notifiable disease system [Reference Jianhan11]. Dengue fever broke out in Guangdong Province, China, in 2014, and over 45 000 cases were confirmed, causing huge losses in local economic development. Alongside the constant emergence of new diseases and the continuous expansion of epidemic areas, vector-borne diseases have become one of the most serious global public health threats [Reference Qiyong12]. Monitoring and controlling vectors undoubtedly plays an important role in preventing vector-borne diseases. There is an urgent need to develop efficient surveillance systems to help simultaneously monitor and control hosts, vectors and diseases.

SOME CURRENT SURVEILLANCE SYSTEMS

Different kinds of surveillance systems have gradually been established around the world, such as surveillance systems for WNV, rodents, plague, Aedes aegypti, dengue fever, etc. These systems can be divided into three categories: host surveillance, vector surveillance, and disease surveillance (Table 1). Both host and vector surveillance systems include density surveillance and pathogen carriage surveillance. Host surveillance is meaningful, especially when the data are combined with epidemiology of related diseases. For example, Mulatti et al. [Reference Mulatti17] carried out research on the relationship between serology screening based on an IgM test for WNV in equines and the prevalence of WNV in Italy in 2011, and found that the prevalence of IgM antibody was a sensitive marker for the prevalence of WNV. However, to reduce costs, only some host species tend to be included in surveillance systems [Reference Watson13, Reference Mostashari14, Reference Shuai16, Reference Bernard25]. Vector surveillance focuses on establishing the density and pathogen carriage rate of vectors in a given area, which helps to identify how vectors spread infections to hosts and to determine the best intervention strategies to reduce the risk of infection. Disease surveillance includes early detection of infection in humans and the screening of pathogens in healthy people; the aim of which is to estimate pathogen diffusion through systematic analysis of newly emergent clinical cases and the prevalence of pathogens in the population.

Table 1. Examples of current worldwide surveillance systems for vector-borne diseases

In China, the aim of traditional vector surveillance is to monitor the density of traditional vectors such as mosquitoes, flies, rodents, ticks and cockroaches. There is no separate vector-borne disease surveillance system in China, and cases of vector-borne disease are reported via the national notifiable diseases reporting system. These two systems belong to two different agencies between which there is no direct link. Thus, one agency cannot take full advantage of the surveillance data of the other, which in turn causes repetition of work, and the loss of comprehensive monitoring of risk factors and disease prediction. Integrated surveillance systems can manage, efficiently share, and then take advantage of, information on vectors and vector-borne diseases (Fig. 1). The aim is to provide comprehensive information related to all vector-borne diseases, including public education materials and targeted protective measures.

Fig. 1. The intersection among current host, vector and vector-borne zoonosis surveillance systems.

The concept of integrated surveillance

Integrated surveillance on vectors and vector-borne diseases combines host surveillance, vector surveillance and vector-borne disease surveillance. In mature integrated systems, a large website should be used to collate and disseminate information, and diseases should be the terminal output, connected with specific pathogens related to vectors and hosts. That is to say, if we look at one disease on the website, there should be information on the prevalence of that disease, the epidemiology of its hosts and vectors, and of the related pathogen in those hosts and vectors. At the same time, epidemiology of hosts and vectors can provide information on other diseases that share the same hosts or vectors.

Integrated surveillance has two parts: the primary stage is surveillance for a single disease or virus, such as plague or WNV. Such surveillance covers the whole chain of transmission. The next step – the advanced stage that distinguishes integrated surveillance from traditional single-disease monitoring – is integration of surveillance to cover multiple vector-borne diseases and vector-transmitted pathogens. Different kinds of tissue specimens from hosts and vectors are sampled to test for various pathogens, covering a variety of diseases. In this way, the cost of disease monitoring is much lower than the total for individual disease surveillance systems.

At present, the main monitoring systems in most of the world are primary stage. Only a few surveillance systems have been set up and these focus only on one disease or pathogen, such as the WNV surveillance systems in some countries [Reference Shuai16, Reference Calzolari21, Reference Gosselin26, 27]. In other countries the focus is only on hosts and vectors, not on diseases [Reference Schaffner19, Reference Pautasso20, Reference Lerdthusnee28].

Integrated surveillance pilot programmes in China

Development of an integrated surveillance system is at an early stage in China. Two pilot surveillance programmes have been carried out in Zhejiang Province: one on mosquitoes in Jiande City, and the other on rodents in Longyou City and Lishui City. These cities were chosen randomly from 11 cities undertaking traditional surveillance of mosquitoes and rodents.

Initially, a specific project team for integrated surveillance was established. The Vice-Director of Zhejiang Provincial CDC was appointed to coordinate different departments involved in the integrated surveillance, including laboratories, infectious disease surveillance departments at provincial, regional and county levels, and departments involved in entomological surveillance. Standard criteria for vector surveillance (see below) and for some specific diseases were established by Zhejiang CDC; only a few diseases of great concern were included in these pilot programmes due to limited resources. Professional training of workers involved by Zhejiang CDC was performed on how to conduct standard integrated surveillance. Risk assessment was carried out regularly according to the surveillance data. If the data from routine surveillance predicted an epidemic (reaching the level of an alert event – see Table 2), emergency surveillance would be started (Fig. 2).

Fig. 2. The main programmes and groups involved in the Chinese pilot programme integrated surveillance system for vectors and vector-borne zoonoses.

Table 2. Criteria for suspected clinical cases and the definition of alert events in the integrated surveillance pilot programmes for mosquitoes and rodents

Vector surveillance

The light traps method was used for integrated adult mosquito monitoring by Jiande County CDC from June to October, 2009. The light traps were set in four farmhouses and four livestock sheds at the start, middle and end of every month, i.e. three times per month. Mosquitoes caught were killed by freezing and identified under a stereomicroscope using the identification keys of Ribeiro et al. and Hervy et al. [Reference Ribeiro29, Reference Hervy30]. After classification, they were sent to Zhejiang Provincial CDC for pathogen testing. The container index (CI) was used for Aedes larvae.

Rodents were trapped overnight once per month from 2009 to 2011 and the fleas on their surface were collected. Serum, liver, spleen and lungs were removed from rodents to test for haemorrhagic fever with renal syndrome (HFRS) and plague. Combined with direct rodent surveillance, disease hosts (pigs, cows, frogs, ducks) from Longyou and Lishui cities were also monitored. Kidneys from pigs, frogs, and ducks, and blood from ducks, were collected to test for leptospirosis. All samples were sent to Zhejiang Provincial CDC for testing.

Pathogen testing

Total DNA was extracted from mosquitoes and rodent organs. Epidemic encephalitis B virus, malaria parasites and flaviviruses were tested for using PCR assays on collected mosquitoes. Fleas and some parts of the liver and spleen of rodents were used to culture Yersinia pestis. The remaining liver and spleen material were tested for plague by reverse indirect haemagglutination assay (RIHA). The serum of rodents was tested by the indirect haemagglutination assay (IHA) and radiation immune precipitation test (RIP) methods for the F1 antibody to plague. Rodent lungs were tested by fluorescent antibody technique (FAT) for the HV antigen to HFRS, while serum was tested for the HV antibody by indirect fluorescent antibody technique (IFAT). The kidneys of rodents, pigs, frogs and ducks were used to culture Leptospira, and the blood of ducks was collected to detect antibody to leptospirosis by microscopy.

Human/disease surveillance

Human/disease surveillance was separated into two parts: passive (routine) surveillance and emergency surveillance. Passive surveillance of epidemic encephalitis B, malaria, dengue fever, plague, HFRS and leptospirosis was conducted using the national notifiable disease reporting system. For emergency surveillance, serum, blood, or cerebrospinal fluid samples were obtained from suspected clinical cases and analysed according to the diagnostic criteria for the six diseases being monitored. PCR assays and serum tests were conducted by Zhejiang Provincial CDC.

Alert events triggering emergency surveillance in the mosquito and rodent surveillance systems were discussed and triggered by an expert group including representatives of appropriate government departments, scientists and regional health authorities, using the method of Delphi (Table 2).

Outcomes

In the integrated mosquito surveillance pilot programme, a total of 945 mosquitoes were caught at a density of 4·92 mosquitoes per hour. Table 3 shows the composition of mosquito species and the pathogens they carried. The CI in Jiande City was monitored three times during the surveillance period; 111 containers were found with water, with CI = 2·70%. The carriage of encephalitis B virus in Culex tritaeniorhynchus was zero in Jiande City. No malaria, dengue fever or epidemic encephalitis B cases in Jiande City were reported to the national notifiable disease reporting system in 2009.

Table 3. The composition of vector species and pathogens carried within them in two integrated surveillance pilot programmes

HFRS, Haemorrhagic fever with renal syndrome.

In the integrated rodent surveillance pilot programme, 1020 rodents were caught by night trapping, with a density of 7·02%. Table 3 shows the composition of rodent species and the pathogens they carried. One hundred fleas were collected from 1020 rodents with a rat flea index (i.e. fleas per rat) of 0·098. Seven fleas were tested for plague and none was positive. Fifteen kidneys from pigs, 60 kidneys from ducks, 200 kidneys from frogs and 40 urine samples from cows were tested for leptospirosis, and none was positive. However, when testing duck blood (60 samples), 16 were positive for Leptospira antibodies. During 2009–2011, 11 leptospirosis cases (0·12/100 000), 198 HFRS cases (2·2/100 000) and zero plague cases were reported in Longyou and Lishui cities. No emergency surveillance was started because the density or pathogen carriage rate in hosts and vectors were within normal ranges in the two surveillance pilot areas, according to the definitions of alert events established before commencement (Table 2).

Comparison of cost between traditional surveillance and integrated surveillance

Taking the rodent integrated surveillance programme as an example, one integrated surveillance system could take the place of four traditional surveillance systems (for three diseases and one vector). Traditionally, the information obtained by these four surveillance systems was not shared. That is to say, when we wanted to know the density of rodents and of HFRS, two sets of 700 rodents were caught to perform the experiments, a huge waste of human labour. Table 4 shows that 155 778 yuan would be spent on the traditional rodent surveillance system, whereas the equivalent cost of the integrated programme was 122 178 yuan, a cost saving of 21·6%.

Table 4. The comparison of cost price between traditional surveillance and integrated surveillance of rodents

HFRS, Haemorrhagic fever with renal syndrome; IHA, indirect haemagglutination assay, RIP, radiation immune precipitation test; IFAT, indirect fluorescent antibody technique; EHF, epidemic haemorrhagic fever.

* The number of samples quoted here for traditional surveillance is as recommended by the national plague, leptospirosis and HFRS monitoring programmes.

The salary is 300 yuan per person per day.

The number of samples in this table is the same for both traditional and integrated surveillance to make them comparable. In reality, more samples were tested in the integrated surveillance because of the range of experiments undertaken (see Table 3).

§ 100 yuan = ~10·5 British pounds.

DISCUSSION

Many current surveillance systems combine monitoring of hosts, vectors and pathogens. However, they are mainly for a single disease, like plague, dengue fever, or West Nile fever [Reference Mulatti17, Reference Regis18, Reference Calzolari21, Reference Lerdthusnee28]. Thus, comprehensive surveillance of vector-borne diseases may still require repetitive work and waste resources. However, an integrated surveillance system can provide continual, comprehensive information in a more effective and economic way. In the integrated surveillance system pilot programmes in China that we report here, integrated surveillance combined traditional vector surveillance, surveillance of six specific diseases, and some parts of the national notifiable disease reporting system. This is a reasonable approach, because some vector-borne diseases share the same vectors, and one type of host may bear many different kinds of vectors carrying different pathogens. Hosts, vectors and vector-borne disease-related pathogens represent a large system, which could and should be managed as a whole. The relative inefficiency of single disease surveillance systems can be illustrated by considering the traditional density, plague, leptospirosis and HFRS surveillance systems in China. Rodents (700, 600, 100 and 100, respectively) needed to be caught, and then a fixed number of rodents were dissected to obtain samples of serum, kidney, lungs, etc., according to the requirements of the national monitoring programme. Respectively, 48, 160, 48 and 96 person-days are needed to perform this work (352 person-days in total), while a total of only 240 person-days would be needed when using the integrated surveillance approach (Table 4); thus, 31·8% [(352–240)/352] of the labour was saved.

Development of an integrated surveillance system is just beginning in China. In pilot studies, three cities were chosen, one for mosquito surveillance and two for rodent surveillance. However, no malaria, dengue fever or epidemic encephalitis B cases were found in Jiande City in the study period and the carriage of encephalitis B virus in C. tritaeniorhynchus was zero. Thus, more cities should be included in integrated surveillance pilot programmes. In a mature integrated surveillance system, a real-time extranet website is needed to manage the large quantity of data and to make available the results of information surveyed, as is used by many single disease/pathogen surveillance systems such as the WNV monitoring system in Canada and the UK, and the dengue surveillance system in Thailand and Brazil [Reference Shuai16, Reference Regis18, Reference Gosselin26, 27, Reference Xinbei31, Reference Sithiprasasna32]. Such a website was lacking in our surveillance pilots because of resource limitations. The indicators for alert events must also be appropriate. For example, in our integrated mosquito surveillance, the CI was used for Aedes larvae monitoring, but the Breteau index is used more widely at present [Reference Sanchez33, Reference Nathan34].

The integrated surveillance system combined vectors, hosts and pathogens/diseases. It was consistent with an opinion – ‘one health’ – which emphasizes the unity of people, animals and the environment. A good integrated surveillance system could save much unnecessary, repetitive work and make information available more efficiently. However, such systems require contributions from WHO, OIE and FAO to establish standard criteria, valid programme design, and coordination and/or training of professional staff. These organizations should collaborate with each other, and a specialized committee could be founded (like the specific project team in Zhejiang Province), whose members should include scientists, health authorities, animal authorities and insect authorities. Thus, a series of unified and standard criteria could be established, and a better way of dividing responsibility among agencies could be created. Regionally, the role of coordination should be played by the specific project team as in Zhejiang Province, while internationally, the role should be played by the specialized committee.

ACKNOWLEDGMENTS

This work was supported by the Key Science Program of the National ‘Twelve-Five Plan’ of China (No. 2012ZX10004219) and ‘Thirteen-Five Plan’ of China (No. 2016ZX10004219–002).

DECLARATION OF INTEREST

None.

References

REFERENCES

1. Zohrabian, A, et al. West Nile virus economic impact, Louisiana 2002. Emerging Infectious Diseases 2004; 10: 17361744.Google Scholar
2. Angelini, R, et al. Chikungunya in north-eastern Italy: a summing up of the outbreak. Eurosurveillance 2007; 12: E071122.2.Google Scholar
3. Grandadam, M, et al. Chikungunya virus, southeastern France. Emerging Infectious Diseases 2011; 17: 910913.Google Scholar
4. La, Ruche G, et al. First two autochthonous dengue virus infections in metropolitan France, September 2010. Eurosurveillance 2010; 15: 19676.Google Scholar
5. Gjenero-Margan, I, et al. Autochthonous dengue fever in Croatia, August–September 2010. Eurosurveillance 2011; 16 pii=19805.Google Scholar
6. Alves Alves, MJ, et al. Clinical presentation and laboratory findings for the first autochthonous cases of dengue fever in Madeira island, Portugal, October 2012. Eurosurveillance 2013; 18, pii=20398.Google Scholar
7. ECDC. Autochonous dengue cases in Madeira, Portugal. European Centre for Disease Prevention and Control: Stockholm, Sweden, 2012.Google Scholar
8. Arends, JE, et al. Two cases of Plasmodium falciparum malaria in the Netherlands without recent travel to a malaria-endemic country. American Journal of Tropical Medicine Hygiene 2013; 13, 89: 527530.Google Scholar
9. Doudier, B, et al. Possible autochthonous malaria from Marseille to Minneapolis. Emerging Infectious Diseases 2007; 13: 12361238.Google Scholar
10. Santa-Olalla, P, et al. First autochthonous malaria case due to Plasmodium vivax since eradication, Spain, October 2010. Eurosurveillance 2010; 15: 19684.Google Scholar
11. Jianhan, H. The situation and trend of vectors surveillance in China [in Chinese]. Chinese Journal of Vector Biology and Control 2007; 18: 257260.Google Scholar
12. Qiyong, L, et al. Vector surveillance and control in emergencies in China: proceedings and perspectives [in Chinese]. Chinese Journal of Vector Biology and Control 2011; 22: 14.Google Scholar
13. Watson, JT, et al. Dead crow reports and location of human West Nile virus cases, Chicago, 2002. Emerging Infectious Diseases 2004; 10: 938940.Google Scholar
14. Mostashari, F, et al. Dead bird clusters as an early warning system for West Nile virus activity. Emerging Infectious Diseases 2003; 9: 641646.Google Scholar
15. Yaremych, SA, et al. West Nile virus and high death rate in American crows. Emerging Infectious Diseases 2004; 10: 709711.Google Scholar
16. Shuai, J, et al. A GIS-driven integrated real-time surveillance pilot system for national West Nile virus dead bird surveillance in Canada. International Journal of Health Geoqraphics 2006; 5: 17.Google Scholar
17. Mulatti, P, et al. West Nile virus in north-eastern Italy, 2011: entomological and equine IgM-based surveillance to detect active virus circulation. Zoonoses and Public Health 2013; 60: 375382.Google Scholar
18. Regis, L, et al. An entomological surveillance system based on open spatial information for participative dengue control. Anais da Academia Brasileira de Ciencias 2009; 81: 655662.Google Scholar
19. Schaffner, F, et al. Development of guidelines for the surveillance of invasive mosquitoes in Europe. Parasites & Vectors 2013; 18: 209.Google Scholar
20. Pautasso, A, et al. Mosquito surveillance in northwestern Italy to monitor the occurrence of tropical vector-borne diseases. Transboundary and Emerging Diseases 2013; 60: 154161.Google Scholar
21. Calzolari, M, et al. New incursions of West Nile virus lineage 2 in Italy in 2013: the value of the entomological surveillance as early warning system. Veterinaria Italiana 2013; 49: 315319.Google ScholarPubMed
22. Xiaoqing, L, et al. Surveillance and risk assessment of mosquitoes and mosquito-borne diseases in Nanchang city [in Chinese]. Chinese Journal of Hygienic Insecticides & Equipment 2012; 18: 195199.Google Scholar
23. Yongzhuang, C, et al. Establishment and assessment of graded early warning system for dengue fever in Zhongshan, China [in Chinese]. Chinese Journal of Vector Biology and Control 2013; 24: 332335.Google Scholar
24. Hongmei, M, et al. Study and application of rodent risk assessment in major industries [in Chinese]. Chinese Journal of Vector Biology and Control 2011; 22: 543546.Google Scholar
25. Bernard, KA, et al. West Nile virus infection in birds and mosquitoes, New York State, 2000. Emerging Infectious Diseases 2001; 7: 679685.Google Scholar
26. Gosselin, P, et al. The Integrated System for Public Health Monitoring of West Nile virus (ISPHM-WNV): a real-time GIS for surveillance and decision-making. International Journal of Health Geoqraphics 2005; 13: 21.CrossRefGoogle Scholar
27. British Columbia Centre for Disease Control. Interactive GIS mapping for West Nile virus (http://maps.bccdc.org), 2006.Google Scholar
28. Lerdthusnee, K, et al. Surveys of rodent-borne disease in Thailand with a focus on scrub typhus assessment. Integrative Zoology 2008; 3: 267273.Google Scholar
29. Ribeiro, H, et al. Identification keys of the mosquitoes of continental Portugal, Açores and Madeira. European Mosquito-borne Bulletin 1999; 3: 111.Google Scholar
30. Hervy, J, et al. The Mosquitoes of Europe: An Identification and Training Programme. Montpellier, France: IRD Editions, 2001.Google Scholar
31. Xinbei, H, et al. Study of comprehensive monitoring mechanism for critical vectors and related infectious diseases [in Chinese]. Chinese Journal of Vector Biology and Control 2012; 23: 710.Google Scholar
32. Sithiprasasna, R, et al. The geographic information system as an epidemiological tool in the surveillance of dengue virus-infected Aedes mosquitos. Southeast Asian Journal of Tropical Medicine and Public Health 2004; 35: 918926.Google Scholar
33. Sanchez, L, et al. Breteatu index threshold levels indicating risk for dengue transmission in areas with low Aedes infestation. Tropical Medicine and International Health 2010; 15: 173175.Google Scholar
34. Nathan, MB, et al. Pupal/demographic surveys to inform dengue-vector control. Annals of Tropical Medicine and Parasitology 2006; 100: S1S3.Google Scholar
Figure 0

Table 1. Examples of current worldwide surveillance systems for vector-borne diseases

Figure 1

Fig. 1. The intersection among current host, vector and vector-borne zoonosis surveillance systems.

Figure 2

Fig. 2. The main programmes and groups involved in the Chinese pilot programme integrated surveillance system for vectors and vector-borne zoonoses.

Figure 3

Table 2. Criteria for suspected clinical cases and the definition of alert events in the integrated surveillance pilot programmes for mosquitoes and rodents

Figure 4

Table 3. The composition of vector species and pathogens carried within them in two integrated surveillance pilot programmes

Figure 5

Table 4. The comparison of cost price between traditional surveillance and integrated surveillance of rodents