key: cord-0827180-5ffsfuh8 authors: Zhang, Xingyu; Hou, Fengsu; Li, Xiaosong; Zhou, Lijun; Liu, Yuanyuan; Zhang, Tao title: Study of surveillance data for class B notifiable disease in China from 2005 to 2014 date: 2016-04-14 journal: Int J Infect Dis DOI: 10.1016/j.ijid.2016.04.010 sha: 2bb3b606e583496a278d710b37da6b0d781ea805 doc_id: 827180 cord_uid: 5ffsfuh8 BACKGROUND: The surveillance of infection is very important for public health management and disease control. It has been 10 years since China implemented its new web-based infection surveillance system, which covers the largest population in the world. METHODS: In this study, time series data were collected for 28 infectious diseases reported from 2005 to 2014 . Seasonality and long-term trends were explored using decomposition methods. Seasonality was expressed by calculating the seasonal indices. Long-term trends in the diseases were assessed using a linear regression model on the deseasonalized series. RESULTS: During the 10-year period, 38 982 567 cases and 126 372 deaths were reported in the system. The proportion of deaths caused by AIDS increased from 12% in 2005 to 78% in 2014. There were six diseases for which the seasonal index range was greater than 2: dengue fever, Japanese encephalitis, leptospirosis, anthrax, cerebrospinal meningitis, and measles . Among the 28 diseases, the incidence of syphilis increased fastest, with an average increase of 0.018626/100 000 every month after adjustment for seasonality. CONCLUSIONS: Effective surveillance is helpful in gaining a better understanding of the infection behaviour of infectious diseases; this will greatly facilitate disease control and management. After the outbreak of severe acute respiratory syndrome (SARS) in 2003, the Chinese government strengthened the country's infectious disease surveillance system. 1 A new web-based reporting system was established utilizing modern information technology. The new surveillance system was implemented formally in 2004. The new surveillance system has played an important role in detecting infectious diseases in a timely fashion, which has helped to protect the lives and health of the entire population and has reduced the economic and health impacts of the diseases on the whole of society. This new system is the largest infectious disease surveillance system covering the largest population in the world. 2 It has become possible to detect more infections and the data have become more complete and reliable since the new reporting system was established. 3 A survey showed that the average omission rate was 13% among the medical institutions throughout the country; the compliance rate for outpatient daily registration was 96%, the registry integrity rate was 97%, and the timely reporting rate for the medical institutions was 91%. 4 Thirty-nine notifiable infectious diseases are currently included in the surveillance system. These are divided into classes A, B, and C. 5 Class A notifiable diseases include the plague and cholera, which can cause large epidemics within a short period of time. Class B notifiable diseases include 28 infectious diseases that might cause epidemics, including AIDS, anthrax, etc. Class C notifiable diseases include less severe and less infectious diseases, such as mumps, rubella, acute haemorrhagic conjunctivitis, leprosy, leishmaniasis, hydatid disease, etc. It has been over 10 years since the implementation of the new web-based surveillance system. Since this system covers a large population, the surveillance data can stably show the behaviour of a disease in terms of occurrence. Statistical modelling has been used previously to summarize the time series behaviour of disease. 6 In the current study, the monthly time series data for 28 class B infectious diseases reported from 2005 to 2014 were collected. The class B infectious diseases were selected for study, as most of these diseases occur more frequently than class A diseases and they cause more severe epidemics than class C diseases. Class B infectious diseases are the main focus of the surveillance process. A descriptive analysis and time series study was performed. 7 Decomposition methods were used to analyse the seasonal pattern and long-term trends of the class B notifiable infectious diseases for the years 2005-2014. Available time series data for the monthly reported cases of 28 class B infectious diseases were gathered for the years 2005-2014. These 28 class B infectious diseases are AIDS, anthrax, avian influenza, brucellosis, cerebrospinal meningitis, dengue fever, diphtheria, dysentery, gonorrhoea, hepatitis disease (including hepatitis A virus (HAV), hepatitis B virus (HBV), hepatitis C virus (HCV), hepatitis E virus (HEV), and other types of hepatitis), haemorrhagic fever, Japanese encephalitis, leptospirosis, malaria, measles, neonatal tetanus, pertussis, polio, rabies, scarlet fever, schistosomiasis, syphilis, tuberculosis, and typhoid fever. The data were reported by the Chinese Centre for Disease Control and Prevention (CDC). The incidences of these diseases are shown in Figure 1 . A descriptive study was first performed, and decomposition methods were used to extract the underlying pattern in the infectious disease time series. The decomposition methods have been reported in previous studies. 6, 8 Decomposition breaks down the underlying patterns of time series into seasonality and longterm trends. The seasonal trend in the infection series can be expressed using seasonal indices. To calculate the seasonal factors, overall incidences are first averaged, and then the averaged incidence is divided by the mean incidence for each month. For example, the average incidence of malaria was 0.1344/100 000 during the 10 years and the mean incidence in May was 0.1059/ 100 000, thus the seasonal index for May is 0.788 (0.1344/0.1059). Seasonality shows the periodic fluctuations that are usually caused by known factors such as rainfall, temperature, timing of the holidays, etc. If the seasonal index is greater than 1, it means that the incidence is higher than the average level. Otherwise, it means that the incidence is lower than the average level. The trend cycle represents the long-term changes in the infection. After the seasonal indices have been calculated, one can deseasonalize the data by dividing by the corresponding index. A linear regression model is a simple way to express the long-term trend, in which a common linear regression model is established between the deseasonalized incidence and time t. The numbers of cases of the 28 class B notifiable diseases during the years 2005-2014 are shown in Table 1 . During the 10-year period, 38 982 567 cases and 126 372 deaths were reported in the system. Tuberculosis, HBV, syphilis, dysentery, and HCV were the top 5 ranking diseases in terms of the number of cases. The numbers of deaths caused by the 28 class B notifiable diseases for the years 2005-2014 are shown in Table 2 . AIDS, tuberculosis, rabies, HBV, Japanese encephalitis, haemorrhagic fever, and neonatal tetanus were the top 7 ranking diseases in terms of the number of deaths; these diseases each caused more than 1000 deaths during the 10 years. With regard to the numbers of cases, tuberculosis represented the highest proportion among the 28 class B notifiable diseases With regard to the numbers of deaths, the disease proportions changed dramatically over the 10 years ( Figure 3 ). In 2005, tuberculosis caused the highest proportion of deaths among the 2007 2008 2009 2010 2011 2012 2013 2014 Total AIDS 968 942 1200 4158 4486 9531 10 726 12 483 11 718 12 317 68 529 Tuberculosis 2618 2475 2073 2368 3075 1742 1930 1935 1887 1772 21 875 Rabies 2191 2692 2873 2350 2103 1986 1902 1372 1082 873 19 424 Hepatitis B virus 849 841 838 930 830 723 686 638 593 398 7326 Japanese encephalitis 160 387 165 135 171 95 73 67 77 36 1366 Hepatitis C virus 102 151 123 131 155 142 137 110 163 134 1348 Haemorrhagic fever 227 145 129 107 107 120 127 99 119 85 1265 Neonatal tetanus 231 187 160 195 130 95 59 57 49 14 1177 Syphilis 81 89 74 91 76 86 102 102 82 87 870 Cerebrospinal meningitis 172 138 104 117 90 34 25 24 22 15 741 Dysentery 131 112 68 57 37 42 28 17 14 5 511 Other hepatitis 103 88 75 59 41 32 18 23 19 13 471 Measles 47 31 64 111 40 27 12 7 28 27 394 Hepatitis E virus 44 40 39 31 24 34 41 23 20 15 311 Malaria 40 30 14 20 10 16 32 14 22 23 221 Hepatitis A virus 36 33 23 13 22 6 14 9 4 8 168 Leptospirosis 41 17 31 17 11 12 5 5 7 8 154 Typhoid 13 18 7 7 10 3 2 6 5 1 72 Anthrax 11 12 1 1 3 6 3 1 1 3 42 Avian influenza 5 8 2 4 4 1 1 1 2 0 28 Gonorrhoea 1 5 0 3 3 1 3 1 1 3 21 Schistosomiasis 2 3 1 0 2 0 2 5 1 0 16 Brucellosis 5 0 0 1 1 1 0 2 2 2 14 Pertussis 1 4 0 0 1 1 2 1 0 2 Table 3 and Figure 4 . The standard deviation and range are given in Table 3 . There were six diseases for which the seasonal index range was greater than 2: dengue fever (high in September and October, and low in all of the other months), Japanese encephalitis (high from July to September, and low in the other months), leptospirosis (high in September and low from January to June), anthrax (high in August and low from December to April), cerebrospinal meningitis (high from February to April, and low from June to November), and measles (high from March to June, and low from August to December). The seasonal indices for malaria (high from July to September, and low from December to April), dysentery (high from June to September, and low from January to March), haemorrhagic fever (high in November and December, and low in August and September), scarlet fever (high in May and June, and low in February), and brucellosis (high from May to July, and low in January) were between 1 and 2. The variations in hepatitis disease, tuberculosis, and sexually transmitted diseases (STDs) (including gonorrhoea, syphilis, and AIDS) were relatively lower than those of the other diseases. From the coefficient of regression (Table 4) , we can derive how much the incidence changes on average by month after removing the effect of seasonality. The incidence of syphilis increased fastest among the 28 diseases. The syphilis incidence rate increased on average by 0.018626/100 000 every month after adjustment for seasonality. Seven other diseases had an increasing incidence, including HCV (0.010042/100 000), AIDS (0.002891/100 000), brucellosis (0.002242/100 000), scarlet fever (0.001311/100 000), dengue fever (0.000959/100 000), HEV (0.000801/100 000), and schistosomiasis (0.000136/100 000). The incidences of 18 diseases decreased, among which tuberculosis (À0.019143/100 000), dysentery (À0.015704/100 000), and HBV (À0.009740/100 000) dropped fastest. The infectious disease surveillance system has been in use for over 10 years since it was established. A descriptive analysis and time series study of 28 class B notifiable diseases was performed. 10 It has been reported that HIV prevalence among men who have sex with men (MSM) has been rising in China, with an estimated prevalence rate of 7.3% in 2013. 11 MSM represent over a quarter of new reported infections; however studies aimed at understanding the epidemic in this population are extremely limited. Another great concern is that the prevalence of AIDS among young people has increased rapidly in China. It has been reported that the prevalence among 15-24-year-olds doubled from 0.9% to 1.7% between 2008 and 2012. 11 Research reported by Tucker et al. indicated that very few Chinese people with symptoms of a STD sought medical attention 10-15 years ago. 12 If people have become more likely to seek medical attention for these diseases in recent years, then this could have contributed in part to the increase in reported AIDS and syphilis cases seen in the current study. Tuberculosis is another very severe disease in China, in terms of both occurrence and deaths; 14 088 313 cases were reported from 2005 to 2014, with 21 875 deaths in all. China has the world's second largest tuberculosis epidemic, behind India. 13 Progress towards the control of tuberculosis was slow before the 2003 SARS outbreaks and the number of detected tuberculosis cases was only about 30% of the estimated total new cases. 14 With the establishment of the new surveillance system, the government has improved public health findings as well as leadership to tackle public health problems. It was reported that the detection of cases previous studies. 15 The incidence of rabies decreased dramatically during the 10 years. Various control policies have been implemented by the government, which have played an important role in reducing rabies incidence in China. 16 The seasonality of this disease series was analysed. Decomposition methods were used to decompose the surveillance time series data into seasonal patterns and long-term patterns; this can help in gaining an understanding of the behaviour of diseases over time. 17 The same methods were used on surveillance data for nine infectious disease for the years 2005-2011 in a previous study. 6 Seasonal patterns are one major pathway for the subtle but potentially drastic effects of climate change on disease dynamics. 18 In the current study, the seasonal patterns were quantified in the form of seasonal indices. Some of the infectious diseases, such as dengue fever, Japanese encephalitis, leptospirosis, anthrax, cerebrospinal meningitis, and measles, showed more obvious seasonality. Other diseases, such as the STDs, hepatitis disease, and tuberculosis showed relatively smooth seasonal index curves. According to the hypothesis of decomposition, long-term patterns and residuals remain in the series after seasonal indices are extracted. Modelling the long-term trends is helpful in understanding their epidemic behaviour. The model can be used to predict the future incidence, which is helpful for public health management and vaccine preparation. The long-term patterns of the 28 class B infectious diseases were also shown with a linear regression model between the deseasonalized series (dependent variable) and time t (independent variable). The model showed that most diseases have decreased with improvements in socioeconomic status and the strengthening of public health management. However, many diseases are still increasing or emerging, including syphilis, HCV, AIDS, brucellosis, scarlet fever, HEV, and schistosomiasis. Fighting these diseases is a big challenge. The incidences of STDs (such as AIDS and syphilis), viral hepatitis, and zoonoses (such as rabies, brucellosis, and schistosomiasis) increased dramatically and they caused great numbers of deaths during the 10-year period studied. One of the biggest challenges in combating STDs and viral hepatitis is the health management of floating immigrants; such immigrants were reported to account for 10% of the total Chinese population in 2005. 11 They have been found to be more vulnerable to infectious diseases, especially STDs and viral hepatitis. Safe sex education, timely physical testing, and the promotion of protection measures are useful in the prevention of STDs and virus hepatitis. The infection surveillance system needs to be strengthened to cover the floating immigrants. The transmission of zoonotic infections relies on the interaction between infected animals and humans. Strengthening the management of pets and other animals is urgently needed to combat zoonotic diseases, which are also a great challenge. It has been reported that only 30% of dog owners register their animals with government authorities and that only 2-8% of dogs are vaccinated against rabies; 19, 20 this is of great concern in the management of zoonotic disease. Effective disease surveillance is helpful in understanding the infectious behaviour of diseases with the help of statistical models. This is useful for public health management and disease control. Future studies are needed to explore other statistical methods and data mining techniques to identify the behaviour of infectious diseases and to predict disease occurrence. 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CSIS Progress in tuberculosis control and the evolving publichealth system in China Human rabies surveillance and control in China Challenges and needs for China to eliminate rabies Seasonal infectious disease epidemiology Seasonal patterns of infectious diseases Human rabies in China Inferior rabies vaccine quality and low immunization coverage in dogs (Canis familiaris) in China Xingyu Zhang would like to gratefully acknowledge financial support from the China Scholarship Council.Financial support: This research was funded by the National Science and Technology Major Special Project ''Data mining and analysis of the surveillance data of five syndrome pathogens'' (grant number 2012ZX10004201-006). The research was supported by Sichuan University grant ''the Fundamental Research Funds for the Central Universities'' (grant number: 2016SCU11006). Xingyu Zhang was supported financially by the China Scholarship Council (CSC) for his doctoral studies.Ethical approval: Ethical approval was not required since the data used in this study are publicly reported surveillance data of the Chinese Centre for Disease Control and Prevention.Conflict of interest: There are no conflicts of interest in relation to the current study.