Epidemiological data

HFMD has been upgraded to a Class C communicable disease since 2008. An implication of this classification is that nationwide cases of HFMD have been officially reported to the National Diseases Reporting System (NDRS), and the Chinese Center for Disease Control and Prevention (Chinese CDC). The clinical criteria for diagnosis of HFMD cases were provided in a guidebook published by the Chinese Ministry of Health in 2010. Patients with the following symptoms are defined as having HFMD: fever, papules, and herpetic lesions on the hands or feet, rashes on the buttocks or knees, inflammatory flushing around the rashes and little fluid in the blisters, or sparse herpetic lesions on oral mucosa. Clinical diagnoses of HFMD are strictly examined and verified by various levels of CDC. At the provincial level, at least 10 cases were serotyped each month. Serotyping and sequencing were performed at provincial surveillance laboratories with quality control from the Chinese CDC [Reference Huang27, 28]. For this study, HFMD data was obtained from the Chinese CDC for the period between 1 January 2008 and 31 December 2010. The recorded information included basic patient information (e.g. name, gender, age, date of birth), spatial information (e.g. patient's address, reporting company), and temporal information (e.g. patient's onset date, diagnosis date). We selected patient onset date as the temporal information and patient address as the spatial information.

When we analysed the temporal distribution of reported HFMD cases, we tested the correlation using Pearson's rank correlation with SPSS software v. 16.0 (SPSS Inc., USA). Two-tailed analysis was used for statistical tests and P < 0·05 was considered statistically significant. When we analysed the spatial distribution of reported HFMD cases, incidence rate refers to the frequency of new infected cases during a given time interval, which is equivalent to the number of new cases divided by the population during a given time interval. Although raw incidence rate data may not effectively reflect true risks, incidence rate represented in spatial units for areas of high population density is more reliable due to reduced randomness. Conversely, the incidence rate in spatial units with a lower population density is not reliable. To solve this problem, we re-estimated the incidence rate using Bayesian adjustments to uncover the true risks for an exposed population [Reference Cao12, Reference Anselin, Kim and Syabri29]. We also searched for any association between the number of reported HFMD cases and meteorological and social factors using Spearman's rank correlation. Spearman's rank correlation is a non-parametric measure of statistical dependence between two variables, and it is non-parametric in that its exact sampling distribution can be obtained without requiring knowledge of the probability distribution of variables.

Meteorological data

Meteorological data collected in 2009 was obtained from the Meteorological Bureau of Shenzhen Municipality. There are a total of 54 meteorological stations in Shenzhen, including eight in Futian district, six in Luohu district, seven in Nanshan district, seven in Yantian district, 11 in Baoan district, 13 in Longgang district, and two in Guangming new district. The Meteorological Bureau of Shenzhen Municipality publishes daily data regarding temperature (°C) and precipitation (mm) for each meteorological station. In addition, this source also publishes a Shenzhen climate bulletin each year, in which the annual average temperature and precipitation are included. The annual average temperature and precipitation are calculated by averaging the daily data. By interpolating the annual average temperature and precipitation for meteorological stations, we were able to obtain a distribution map of the annual average temperature and precipitation in Shenzhen. Finally, the annual average temperature for each street was calculated by averaging the annual temperature distribution map for each street, and the same calculations were performed for the annual average precipitation for each street.

Social data

In this study, the social data included the road and drainage density, population, and number of hospitals. Both the scale of the road data and river data in Shenzhen were 1:1000, and these data were obtained in 2008. Road density (RD) refers to the ratio of the road length (RL) divided by the study area (A), and drainage density (DD) refers to the ratio of the length of the river (L) divided by the study area (A); these values can be obtained using equation (1) and equation (2), respectively.

(1)$${\rm RD}\,{\rm =} \,{\rm RL/A,}$$

(2)$${\rm DD}\,{\rm =} \,{\rm L/A.}$$

The study period for HFMD ranged from 2008 to 2010. This was about the time of the sixth census in 2010 in China, so the population data were mainly obtained from the sixth census, which was published by the administrative districts of Shenzhen. The number of hospitals was recorded in 2008.

Geographically weighted regression (GWR) model

Traditional linear regression is often used for the analysis of quantitative geography. As a general technique for investigating the linkage between geographical variables, this method has featured in countless publications. The well-known components of this type of regression model include X, which is a matrix containing a set of independent or predictor variables, and y, which is a vector of the dependent or response variables [Reference Brunsdon, Fotheringham and Charlton30, Reference Nelder and Wedderburn31]. The relationship between these variables is modelled as follows:

(3)$$y_i = \beta _0 + \sum\limits_{k = 1}^p {\beta _k x_{ik} + \varepsilon _i} ,$$

where β is a vector of regression coefficients and ε _i ∼ N(0, σ ²). The inclusion of two strongly collinear independent variables in a regression model may lead to an erroneous conclusion [Reference Næs and Mevik32]; therefore, we need to eliminate the collinear variables in the independent variables before we establish the regression model.

However, there may be situations when the nature of such models is not fixed in space, which is referred to as spatial non-stationarity. To include spatial heterogeneity in the model, Fotheringham and colleagues proposed the GWR model, which extends the traditional regression model by allowing local variations in rates of change such that the coefficients in the model are specific to a given location, rather than serving as global estimates [Reference Brunsdon, Fotheringham and Charlton30, Reference Fotheringham, Charlton and Brunsdon33]. This regression equation is shown as equation (4)

(4)$$\eqalign{\tab y_i = \beta _0 (u_i, v_i ) + \sum\limits_{k = 1}^p {\beta _k (u_i, v_i )x_{ik} + \varepsilon _i} \; \; \cr{\rm}\tab\quad (i = 1,2,3, \ldots, n),$$

where (u _i, ν_i) is the coordinate at location i, β _k(u _i, ν_i) is the value of the kth parameter at location i, ε _i ∼ N(0, σ ²), and Cov(ε _i, ε_j) = 0(i ≠ j). If β _k(u ₁, v ₁) = β _k(u ₂, v ₂) = … = β _k(u _n, v_n), the GWR model will be converted to the ordinary linear regression model. The advantage of the GWR model is that, once the model has been calibrated, it is possible to map the variation in the original regression parameters and gain some understanding of the spatial patterns in the association between predictor and response variables [Reference Fotheringham, Charlton and Brunsdon33]. A geographical surface of models is derived with associated goodness-of-fit statistics and localized parameter estimates such as R ², standard error, and t values. We used the GWR coefficient values to explore the spatial variability of relationships between reported HFMD cases and meteorological and social factors. For the purpose of comparison, the traditional linear regression model was also derived and compared to the GWR model output using the global R ². Lin & Wen used Ordinary Least Squares (OLS) and GWR models to analyse spatial relationships and identify the geographical heterogeneities by using the information of entomology and dengue cases, and they demonstrated that a GWR model could be used to geographically differentiate the relationships of dengue incidence with immature mosquito and human densities [Reference Lin and Wen34]. Grillet et al. used local spatial statistics and GWR to determine the spatial pattern of malaria incidence and persistence in northeastern Venezuela. The GWR model greatly improved predictions of malaria risk compared to OLS regression models [Reference Grillet35].

In this study, we eliminated the collinearity in all independent variables, and then constructed the traditional linear regression model for the number of reported HFMD cases in 2009 using the selected explanatory variables. In addition, we excluded the explanatory variables which had little impact on the regression model. Finally, we used GWR tools in ArcGIS 9.3 (ESRI, USA) to construct the GWR model to study the spatial varying relationships between the number of reported HFMD cases and explanatory variables.