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Using the hierarchical ordinal regression model to analyse the intensity of urinary schistosomiasis infection in school children in Lusaka Province, Zambia

Abstract

Background

Urinary schistosomiasis has been a major public health problem in Zambia for many years. However, the disease profile may vary in different locale due to the changing ecosystem that contributes to the risk of acquiring the disease. The objective of this study was to quantify risk factors associated with the intensity of urinary schistosomiasis infection in school children in Lusaka Province, Zambia, in order to better understand local transmission.

Methods

Data were obtained from 1 912 school children, in 20 communities, in the districts of Luangwa and Kafue in Lusaka Province. Both individual- and community-level covariates were incorporated into an ordinal logistic regression model to predict the probability of an infection being a certain intensity in a three-category outcome response: 0 = no infection, 1 = light infection, and 2 = moderate/heavy infection. Random effects were introduced to capture unobserved heterogeneity.

Results

Overall, the risk of urinary schistosomiasis was strongly associated with age, altitude at which the child lived, and sex. Weak associations were observed with the normalized difference vegetation index, maximum temperature, and snail abundance. Detailed analysis indicated that the association between infection intensities and age and altitude were category-specific. Particularly, infection intensity was lower in children aged between 5 and 9 years compared to those aged 10 to 15 years (OR = 0.72, 95% CI = 0.51–0.99). However, the age-specific risk changed at different levels of infection, such that when comparing children with light infection to those who were not infected, age was associated with a lower odds (category 1 vs category 0: OR = 0.71, 95% CI: 0.50–0.99), yet such a relation was not significant when considering children who were moderately or heavily infected compared to those with a light or no infection (category 2 vs category 0: OR = 0.96, 95% CI: 0.45–1.64). Overall, we observed that children living in the valley were less likely to acquire urinary schistosomiasis compared to those living in plateau areas (OR = 0.48, 95% CI: 0.16–0.71). However, category-specific effects showed no significant association in category 1 (light infection), whereas in category 2 (moderate/high infection), the risk was still significantly lower for those living in the valley compared to those living in plateau areas (OR = 0.18, 95% CI: 0.04–0.75).

Conclusions

This study demonstrates the importance of understanding the dynamics and heterogeneity of infection in control efforts, and further suggests that apart from the well-researched factors of Schistosoma intensity, various other factors influence transmission. Control programmes need to take into consideration the varying infection intensities of the disease so that effective interventions can be designed.

Multilingual abstracts

Please see Additional file 1 for translations of the abstract into five official working languages of the United Nations.

Background

Urinary schistosomiasis caused by the trematode Schistosoma haematobium has been a major public health problem in Zambia for many years [1, 2]. The infection affects people of all ages, however, children bear a huge burden [3]. Indeed, efforts to control the disease have focused on mass treatment of school-aged children, with praziquantel (PZQ) advocated for schools where the prevalence of the disease is 50% or higher. This treatment may be repeated annually to ensure that levels of infection are kept below the levels associated with severe morbidity [4]. However, in communities where reinfection rates are very high, chemotherapy alone may not suppress morbidity and needs to be combined with other interventions such as health education, improvement in the water supply and sanitation, and control of intermediate host snails where applicable [5, 6].

Although prevalence of infection is often used to guide control programmes, it is argued that the intensity of infection is more relevant to understanding transmission dynamics [7–9], since it is generally affected by environmental factors and show great seasonal fluctuations. Moreover, control programmes can have demonstrated impact on intensity of infection than prevalence of infection [10]. Therefore, the intensity of infection can be used to assess the effectiveness of interventions and is essential in deciding whether annual provision of mass treatments with PZQ should be continued [11, 12].

In this study, we developed a statistical model in order to estimate the intensity of infection with urinary schistosomiasis using data collected from two administrative districts in Lusaka Province, Zambia. The main aim of the study was to understand the epidemiology of urinary schistosomiasis in order to support the School Health and Nutrition Programme and the National Bilharzia Control Programme in the country. This includes identification of zones where the risk is high for prioritizing interventions, and designing health education campaigns that are to provide information on the disease, and possible adoption of preventive measures, as well as necessitate behavioural change.

We adapted the approach by Tarafder et al. [9] of using the number of eggs per milliliter (epm) of urine, divided into three category outcomes, to investigate risk factors associated with each level of intensity. In effect, a cumulative ordinal regression model was used to estimate the effects of individual-level variables, such as age and sex, and location-level environmental variables. Because of the small-scale focality of the disease, random effects were introduced to capture any heterogeneity that may exist in the outcome. This is the first time a study like this has been conducted in Zambia and results might lead to an improvement in the understanding of the transmission dynamics of S. haematobium in this part of the country.

Methods

Study area and design

The data were collected as part of a cross-sectional study carried out in two administrative districts, Kafue and Luangwa, in Lusaka Province, Zambia (see Fig. 1), after obtaining ethical clearance from the University of Zambia Ethics Committee. The two districts were selected on the basis of their ecological representativeness of the country [13, 14]. In each of these districts, 10 primary schools were selected. Approximately 100 school children, aged 6 to 15 years, were recruited from each school in both districts. The altitude and geographical location (longitude, latitude) of the surveyed schools were obtained from the archives of the Survey Department (2003). Further details of the study design are given elsewhere [15].

Fig. 1
figure 1

The study areas and its position in Zambia (shaded region in the insert)

Field data collection

Data on S. haematobium intensity were obtained using the quantitative filtration technique [16]. About mid-morning, urine samples were collected from the pupils, and duplicate filters were prepared and examined microscopically. Two laboratory technicians were trained to prepare and read the specimen filters. Both technicians read each specimen independently. This was useful for increasing the sensitivity of the technique, particularly where egg intensity was low [17]. All pupils found infected were treated with PZQ (40 mg/kg body weight). Individual datasheets were used to collect ancillary information on each child. This information included demographic, water contact and personal hygiene variables.

In addition, data on intermediate host snails were obtained through field collections and laboratory-based species identification. The sampling of potential schistosomiasis transmission sites was done based on the proximity of the water body to the respective primary school, i.e. the nearest likely infection source. These water points were also qualified by relevant local people as the most frequented water contact points for both domestic use and/or livestock.

The identified sites were geo-referenced using a handheld global positioning system (GPS) [18]. The prevalence and abundance of intermediate host snails were assessed during malacological surveys conducted before and after the rainy season. Two field operators were allocated a duration of 15 min each for scooping using standardized snail scoops during the snail surveys. Where scoops were not useable, for instance, in muddy semi-dry habitats, the operators handpicked snails for 15 min each.

Collected snails were placed individually in vials containing 10 ml of water and exposed to light for two hours in order to induce cercarial shedding. Due to a lack of facilities for species identification of cercariae, this study used morphology and rhythmic vibrations to differentiate between shaded human and mammalian cercariae, as previously described by Jordan and Webbe [7] and Davis et al. [19]. Snails that were shedding were placed in separate vials for species identification using field guides [20, 21].

Climatic data

Climatic data, of 1-km image files, were downloaded from the website [22]. These images were captured by the Advanced Very High Resolution Radiometer onboard the National Oceanic and Atmospheric Administration polar-orbiting meteorological satellites [23]. The data were then calibrated into normalized difference vegetation index (NDVI) and midday earth surface temperature (T max ) values using the ERDAS Imagine 8.5 software [24] for each 10-day interval between April 1992 and September 1993, and between February 1995 and January 1996.

Statistical analysis

Descriptive analysis

A three-category response variable was analysed using a cumulative ordinal regression model. The response was categorized as follows: no infection (0 epm of urine), light infection (1–100 epm of urine), and moderate/heavy infection (>100 epm of urine). This categorization was based on the World Health Organization (WHO) standard [9, 25], however, the categories of moderate and heavy infection were combined because of the small number of children in those groups. The outcome was further stratified by altitude where the child lived (elevation of 601–1 150 m for plateau and < 601 m for valley); sex (male, female); and age (6–9 years and 10–15 years); and assessed for any significant variations. The chi-square test was used to determine whether there were any associations between the intensity of infection and altitude, sex, and age. The analyses were carried out using the R software [26].

Hierarchical modeling

Three cumulative ordinal regression models were developed to determine the relationship between the intensity outcome, as defined above, and risk factors, i.e. environmental/ecological (altitude, NDVI, T max ); malacological (host snail abundance); and individual-level demographic covariates (sex, age).

The first model fitted was a cumulative ordinal regression model without adjusting for clustering, i.e., we assumed homogeneity in the infection rates across communities. The second model was an extension of the first and included random effects to capture unstructured heterogeneity. To model the unstructured heterogeneity, we assumed an exchangeable Gaussian processes. The third model was a cumulative model with category-specific fixed effects. Here, age and altitude were estimated as fixed effects corresponding to each of the comparative categories. A further modification to the third model was made by fitting smooth (non-linear) effects of age and altitude, which were estimated non-parametrically [27].

The model building strategy considered the same fixed effects covariates with and without random effects. The three models were then compared using the Akaike information criteria (AIC), with small values of AIC implying a better fitting model. All cumulative logit models were estimated in BayesX using the restricted maximum likelihood regression procedure [27]. Model validation used receiver operating characteristic (ROC) curves analysis, a method recently used to validate regression models [14], in which the proportion of true positives (sensitivity) is plotted against the proportion of false negatives (1-specificity) across a range of threshold values. One performance measure used in the ROC analysis is the area under the curve (AUC) of the ROC plot. A purely random model would be expected to be correct half the time (AUC = 0.5), whereas a perfect model would be correct all the time (AUC = 1.0). We validated the ordinary model (model 1) against the random effects models (models 2 and 3).

Results

Table 1 summarizes the characteristics of the study population. A total of 2 040 school children aged 6 to 15 years were enrolled into the study from 20 selected primary schools in the two districts, Kafue and Luangwa, of which 1 912 (94%) provided urine samples for parasitological examination.

Table 1 Characteristics of 2 040 children, and intensity of infection with S. haematobium in 1 912 children from 20 schools in Lusaka Province, Zambia, 2004

The overall prevalence rate for the two districts was 9.6% (range: 0–36.1%), with the prevalence in Kafue slightly higher than that in Luangwa (10.9% vs. 8.4%), although this was not significant. The intensity of infection had a mean of 31.4 eggs/10 ml of urine (range: 0–120 eggs/10 ml), and a significant difference in the mean intensity of infection was observed, with 40.2 eggs/10 ml (range: 3–53.1 eggs/10 ml) observed in Kafue and 22.6 eggs/10 ml (range: 0–116.0 eggs/10 ml) in Luangwa. Significant differences in infection intensities were also noted among communities, ranging from 0 to 100% (see Fig. 2).

Fig. 2
figure 2

Number of children infected in each of the three intensity of infection categories, by school/community

Table 2 shows the association between intensity of infection with the children’s ages, sex, and altitude of village where the child lived. No significant differences in intensity of infection were observed between the two age groups (χ 2 = 4.1, P = 0.13) and sex (χ 2 = 2.5, P = 0.29). However, significant differences in intensity of infection were observed with altitude sex (χ 2 = 42.7, P = 0.001). Figure 3 also shows variability in the number of children infected at each intensity level with respect to altitude.

Table 2 Associations between intensity of infection and sex, age, and altitude, obtained using the chi-square test
Fig. 3
figure 3

Number of children infected in each of the three intensity of infection categories, by altitude

Table 3 gives the AIC for the three estimated models. Model 3 had the lowest log-likelihood (LL) and AIC, and therefore the best fitting (LL = 1 147.77 and AIC = 1 198.28 in model 3 vs. LL = 1 366.64 and AIC = 1 382.64 in Model 1). Moreover, by considering the difference in AIC between Model 2 and 3 (∆AIC=6.88) implies that assuming a category-specific model further improved the model fit to the data.

Table 3 Estimated ORs of factors associated with the prevalence of light and at least moderate intensities of infection obtained from the cumulative logit models

Table 3 also shows the odds ratios (ORs) estimated using Model 3. However, the results of Model 2 are also presented as these give overall effects and for comparison with those obtained in Model 3. The OR compares individuals at least lightly infected (>0 epm) to individuals not infected (0 epm), and individuals moderately or heavily infected (>100 epm) to individuals lightly infected or not infected (0–100 epm). Overall, the risk of urinary schistosomiasis was found to be lower in children aged between 5 to 9 years compared to those aged 10 to 20 years (OR = 0.72, 95% confidence interval (CI) = 0.51–0.99). The risk, however, changed when comparing the effect of age on children with light infections to those not infected (category 1), and between those moderately or heavily infected to those with light or no infection (category 2). In category 1, the effect of age was significantly lower (OR = 0.71, 95% CI: 0.50–0.99), whereas in category 2, the effect of age was lower but not significant (OR = 0.96, 95% CI: 0.45–1.64).

Children living in the valley were less likely to acquire urinary schistosomiasis compared to those living in plateau areas (OR = 0.48, 95% CI: 0.16–0.71). Category-specific effects showed that in category 1, the risk was not significant, although lower for children living in valleys compared to those living in plateau areas (OR = 0.49, 95% CI: 0.14–1.75). In category 2, the risk was still significantly lower for those living in the valley compared to those living in plateau areas (OR = 0.18, 95% CI: 0.04–0.75).

Increased risk of urinary schistosomiasis was also observed in male children (OR = 1.53, 95% CI: 1.09–2.10). We also observed a positive relationship between snail abundance and risk of infection, significant at 5% (OR = 1.01, 95% CI: 1.00–1.01). However, marginal positive associations were observed between urinary schistosomiasis and NDVI (the mean Dec – Nov biannual composites of NDVI) (OR = 1.01, 95% CI: 0.96–1.05), as well as with Tmax (OR = 1.00, 95% CI: 0.94–1.07).

Figure 4 shows the nonlinear effects of age for categories 1 and 2. In the first category, the effect of age showed some form of non-linearity (middle line). Particularly, the risk increased with rising age up to 12 years, and then dropped slightly and remained constant up until 20 years. In the second plot, we show the effects of age in category 2. The age effect in the plot was linear, and the risk was comparatively similar for children of all ages. This is not surprising since the results for category 2 in Table 3 confirm a non-significant association.

Fig. 4
figure 4

Smooth effects of age (middle line) on the intensity of infection (a) for light infection (category 1) shown in plot (a); and (b) moderate/high infection (category 2) shown in panel (b). The outer two lines in both plots represent the corresponding confidence bands at 80% (inner lines from the middle line) and 95% (outer lines)

Figure 5 shows the ROC analysis results for the three models. The solid black reference line represents equal trade-offs between the sensitivity and specificity of the predictivity of the model. The area under the ROC curve of the reference line is equal to 0.500. The AUC for the ordinary logistic regression model (model 1) is 0.61, while for the two random effects models it is 0.738 (model 2) and 0.736 (model 3). The overall predictive performance of the random effects models was higher than the ordinary model. The AUC of 0.738 in model 2 implies that the prevalence of urinary schistosomiasis infection can be as high as 73.8%.

Fig. 5
figure 5

ROC analysis of the ordinary and random effects of urinary schistosomiasis prevalence. The solid black line is the reference line that represents equal trade-off of sensitivity and specificity of the model

Discussion

It is crucial to have insights into the epidemiology of schistosomiasis in order to achieve its successful control using mass chemotherapy with PZQ. For example, a PZQ dose of 40 mg/kg body weight has been reported to have cure rates ranging from 70 to 99% for S. haematobium infections [28, 29]. However, low cure rates are possible, and these have been attributed to high initial worm loads and intense transmission in an area [30]. In places where the disease is endemic, for instance in Zambia, it is imperative to study the epidemiological factors related to the intensity of infection [11].

This study used an ordinal regression model to quantify factors associated with the intensity of S. haematobium infection among school children in Lusaka Province. The intensity of infection was derived by categorizing egg counts into three groups, based on egg counts in the urine samples, namely of no infection, light infection, and moderate/high infection. An alternative approach to modeling intensity is using the actual egg counts and applying a negative binomial model [8].

The proportion of children with moderate to high infection was very small (2.1%) compared to those with no infection (84.6%). Nevertheless, the dynamics of infection were clearly different for different ages, and at diverse locations and altitudes. Children in the younger age category (5–9 years) were found to have a higher intensity of infection than those in the older age range (10–15 years). This could be attributed to the higher infection risk behaviors of younger children compared to older ones. Our findings are consistent with studies conducted by Tingley et al. [31] and Estard et al. [32], who found higher infection intensities in younger children than in older children. Schools located in plateau areas were found to have higher infection rates, which is contrary to findings in many reports, since the climatic and environmental conditions for schistosomes and the different intermediate host snails are not favorable for transmission at high altitudes [33, 34]. However, the findings are not totally surprising and do agree with recent studies from Uganda [35]. Schistosoma transmission, it is argued, is due to the availability of suitable host snails, for example, Biomphalaria pfeifferi, which prefer temporary water bodies. Thus the continuing schistosomiasis transmission at high altitudes is sustained because of such environments (temporary water bodies) which supports snail’s presence and abundance [35]. Indeed, the findings reported here also identified snail abundance as a factor associated with the varying intensities of infection. Indeed snails are easily affected by environmental factors such as vegetation abundance, as measured by the NDVI, and temperature regimes. The role of environmental factors in defining the intensity of infection are well recognized, and a combination of integrated environmental control and chemotherapy is needed to achieve sustainable transmission control [36–38], and thus are crucial for guiding schistosomiasis control.

The improvement in the model after accounting for random effects (model 3) confirmed the presence of spatial clustering or small-scale heterogeneity of schistosomiasis infection [39]. Our analysis could benefit from using Bayesian methods to account for such spatial dependence, however, the sampling design was not optimized for spatial analysis [40, 41].

The significance of random effects further suggests that apart from well-researched factors, for example, the ones mentioned above, various unobserved agents influence the complexity of transmission accounting for the differences in schistosomiasis infection. An immediate example worth considering is water contact behavior, which is critical for transmission among school-aged children [42]. Heterogeneity may similarly be regulated by varying socio-cultural factors, which are also important to explore in order to properly target control regimes in a community; however, such studies are rare and usually comprise just a small component of large baseline studies conducted by control programmes [5, 39]. When available, such variables should be included in the model.

Although carried out using an exploratory approach, the category-specific effects of age and altitude on the intensity of infection do suggest an interesting epidemiological finding, but with broader implications for disease control. The immediate implication is that the epidemiology of schistosomiasis is complex. Evidently, there is a dynamic effect of risk factors with varying intensity of infection. In other words, the risk may vary at different levels of infection (model 3), but may also change at different levels of the risk factor, especially for continuous covariates such as age (Fig. 4a).

Conclusions

Control programmes need to take into consideration the varying intensity of infection. This will help to design and deploy cost-effective interventions. Higher infection intensity might require more frequent treatment regimes. It may also imply combining interventions for morbidity control using chemotherapy and controlling of intermediate host snails, in order to ensure sustainability. Use of models to find hotspots of urinary schistosomiasis of different intensities is necessary. This may assist in informing surveillance and response systems for the elimination and control of re-emerging tropical diseases such as schistosomiasis [43–46].

Abbreviations

AIC:

Akaike information criteria

AUC:

Area under the curve

CI:

Confidence interval

epm:

Eggs per milliliter

LL:

Log-likelihood

NDVI:

Normalized difference vegetation index

OR:

Odds ratio

PZQ:

Praziquantel

ROC:

Receiver operating characteristic

References

  1. Boatin BA, Wurapa FW, Ulrich AM. The prevalence and distribution of schistosomiasis in Zambia. Central Afr J Med. 1985;31:170–6.

    CAS  Google Scholar 

  2. Michelson EH. Schistosomiasis in Zambia: an historical overview and review of the literature. Afr J Med Medical Sci. 1989;18:269–81.

    CAS  Google Scholar 

  3. Mungomba LM, Michelson EH. Urban schistosomiasis in Lusaka, Zambia: a preliminary study. J Trop Med Hyg. 1995;98:199–203.

    CAS  PubMed  Google Scholar 

  4. Chitsulo L, Engels D, Montresor A, Savioli L. The global status of schistosomiasis and its control. Acta Trop. 2000;77:41–51.

    Article  CAS  PubMed  Google Scholar 

  5. Utzinger J, Bergquist R, Shu-Hua X, Singer BH, Tanner M. Sustainable schistosomiasis control--the way forward. Lancet. 2003;362:1932–4.

    Article  PubMed  Google Scholar 

  6. Singer BH, de Castro MC. Bridges to sustainable tropical health. Proc Natl Acad Sci U S A. 2007;104:16038–43.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  7. Jordan P, Webbe G. Human schistosomiasis. London: Publication of the William Heinemann Medical Books Ltd; 1969.

    Google Scholar 

  8. Alexander N, Moyeed R, Stander J. Spatial modelling of individual-level parasite counts using the negative binomial distribution. Biostat. 2000;1:453–63.

    Article  CAS  Google Scholar 

  9. Tarafder MR, Balolong Jr E, Carabin H, Bélisle P, Tallo V, Joseph L, Alday P, Gonzales RO, Riley S, Olveda R, McGarvey ST. A cross-sectional study of the prevalence of intensity of infection with Schistosoma japonicum in 50 irrigated and rain-fed villages in Samar Province, the Philippines. BMC Public Health. 2008;6:61.

    Article  Google Scholar 

  10. Anderson RM, May RM. Population dynamics of human helminth infections: control by chemotheraphy. Nature. 1982;297:557–63.

    Article  CAS  PubMed  Google Scholar 

  11. Chandiwana SK, Woolhouse ME, Bradley M. Factors affecting the intensity of re-infection with Schistosoma haematobium following treatment with praziquantel. Parasitol. 1991;102:73–83.

    Article  Google Scholar 

  12. Carabin H, Marshall CM, Joseph L, Riley S, Olveda R, McGarvey ST. Estimating the intensity of infection with Schistosoma japonicum in villagers of leyte, Philippines. Part I: a Bayesian cumulative logit model. The schistosomiasis transmission and ecology project (STEP). Am J Trop Med Hyg. 2005;72:745–53.

    PubMed  Google Scholar 

  13. Abell R, Underwood E, Olson D, Dinerstein E. Freshwater Ecoregions of Africa. The WWF- US Conservation Science Programme. Maps of the Expert Workshop, Cape Town. South Africa; 1998.

  14. Brooker S, Hay SI, Bundy DAP. Tools from ecology: useful for evaluating infection risk models? Trends Parasitol. 2002;18:70–4.

    Article  PubMed  PubMed Central  Google Scholar 

  15. Simoonga C, Kazembe LN, Kristensen TK, Olsen A, Appleton CC, Mubita P, Mubila L. The epidemiology and small-scale spatial heterogeneity of urinary schistosomiasis in Lusaka province, Zambia. GeoSpatial Health. 2008;3:57–67.

    Article  PubMed  Google Scholar 

  16. Mott KE. Schistosomiasis: New Goal. Geneva: World Health Organization; 1984.

    Google Scholar 

  17. Barreto ML, Smith DH, Sleigh AC. Implications of faecal egg count variation when using the Kato-Katz method to assess Schistosoma mansoni infections. Trans R Soc Trop Med Hyg. 1990;84:554–5.

    Article  CAS  PubMed  Google Scholar 

  18. Magellan Systems Corp., San Dimas, CA, USA. https://www.magellangps.com/. Accessed 26 Oct 2016.

  19. Davis A, Farooq M, Hairston NG, Macdonald G, McMullen DB, Oliver LJ, Ritchie LS, Stirewalt MA, Uemura K, Wright WH. Epidemiology and control of schistosomiasis (bilharziasis). Geneva: World Health Organization; 1973.

  20. Brown DS, Kristensen TK. A field guide to African freshwater snails. Chapter 8: Southern African species. Danish Bilharziasis Laboratory. Denmark; 1989.

  21. Danish Bilharziasis Laboratory. A field guide to African freshwater snails. Introduction. DBL Publication, Charlottenlund, Denmark; 1998.

  22. Global Land Cover Characteristics Data Base. US Geological Services. https://edcftp.cr.usgs.gov/project/glcc/globdoc2_0.html. Accessed 26 Oct 2016.

  23. Cracknell AP. The Advanced Very High Resolution Radiometer. London: Taylor and Francis Publication; 1997.

    Google Scholar 

  24. ERDAS IMAGINE: World-Class Remote Sensing Software. Atlanta, GA, USA. www.hexagongeospatial.com/products/power-portfolio/erdas-imagine. Accessed 26 Oct 2016.

  25. Montresor A, Crompton DWT, Gyorkos TW, Savioli L. Helminth control in school-age children : a guide for managers of control programmes. Geneva: World Health Organisations; 2002.

    Google Scholar 

  26. R Development Core Team. R: A Language and Environment for Statistical Computing. R Foundation for Statistical Computing. Vienna, Austria; 2016. https//: www.r-project.org. Accessed 26 Oct 2016.

  27. Brezger A, Kneib T, Lang S. BayesX: Analysing Bayesian structured additive regression models. J Stat Soft. 2005;14:11.

    Article  Google Scholar 

  28. Kabatereine NB, Brooker S, Koukounari A, Kazibwe F, Tukahebwa EM, Fleming FM. Impact of a national helminth control programme on infection and morbidity in Ugandan schoolchildren. Bull World Health Organ. 2007;85:91–9.

    Article  PubMed  PubMed Central  Google Scholar 

  29. Koukounari A, Gabrielli AF, Toure S, Bosque-Oliva E, Zhang Y, Sellin B. Schistosoma haematobium infection and morbidity before and after large-scale administration of praziquantel in Burkina Faso. J Infect Dis. 2007;196:659–69.

    Article  PubMed  Google Scholar 

  30. Mutapi F, Ndhlovu PD, Hagan P, Woolhouse MF. A comparison of re-infection rates with Schistosoma haematobium following chemotherapy in areas with high and low levels of infection. Parasite Immunol. 1999;21:253–9.

    Article  CAS  PubMed  Google Scholar 

  31. Tingley GA, Butterworth AE, Anderson RM, Kariuki HC, Koech D, Mugambi M, Ouma JH, Arap-Siongok TK, Sturrock RF. Predisposition of humans to infectionwith Schistosoma mansoni: evidence from the reinfection of individuals following chemotherapy. Trans R Soc Trop Med Hyg. 1998;82:448–52.

    Article  Google Scholar 

  32. Estard JF, Borel E, Segala C. Schistosoma haematobium in Mauritania: two years of follow-up after a targeted chemotherapy – a life long table approach of the risk of reinfection. Parasitol. 1990;100:399–406.

    Article  Google Scholar 

  33. Greer GJ, Emaile RM, Malek AJ, Ngoneu E, Rakard C. Human schistosomiais in Cameroon: distribution of snail hosts. Am J Trop Med Hyg. 1990;42:573–80.

    CAS  PubMed  Google Scholar 

  34. Stensgaard A, Jorgensen A, Kabatereine NB, Malone JB, Kristensen TK. Modelling the distribution of Schistosoma mansoni and host snails in Uganda using satellite sensor data and geographical information systems. Parassitologia. 2005;47:115–25.

    CAS  PubMed  Google Scholar 

  35. John R, Ezekiel M, Philbert C, Andrew A. Schistosomiasis transmission at high altitude crate lakes in Western Uganda. BMC Infect Dis. 2008;8:110.

    Article  PubMed  PubMed Central  Google Scholar 

  36. Malone JB. The geographical understanding of snail borne disease in endemic areas using satellite surveillance. Memorias do Instituto Oswaldo Cruzi. 1995;90:205–9.

    Article  CAS  Google Scholar 

  37. Hay SI. An overview of remote sensing and geodesy for epidemiology and public health Applications. Adv Parasitol. 2000;47:2–27.

    Google Scholar 

  38. Kristensen TK, Malone JB, McCarroll JC. Use of satellite remote sensing and geographical information systems to model the distribution and abundance of snail intermediate hosts in Africa: a preliminary model for Biomphalaria pfeifferi in Ethiopia. Acta Trop. 2001;79:73–8.

    Article  CAS  PubMed  Google Scholar 

  39. Utzinger J, Müller I, Vounatsou P, Singer BH, N’Goran EK, Tanner M. Random spatial distribution of Schistosoma mansoni and hookworm infections among schoolchildren within a single village. J Parasitol. 2003;89:686–92.

    Article  PubMed  Google Scholar 

  40. Stein A, Ettema C. An overview of spatial sampling procedures and experimental design of spatial studies for ecosystem comparisons. Agric Ecosyst Environ. 2003;94:31–47.

    Article  Google Scholar 

  41. Wang J-F, Stein A, Gao B-B, Ge Y. A review of spatial sampling. Spatial Stat. 2012;2:1–14.

    Article  Google Scholar 

  42. Sow S, de Vlas J, Stelma F, Vereecken K, Gryseels B, Polman K. The contribution of water contact behaviour to the high Schistosoma mansoni infection rates observed in the Senegal river basin. BMC Infect Dis. 2011;11:198.

    Article  PubMed  PubMed Central  Google Scholar 

  43. Boissier J, Grech-Angelini S, Webster BL, Allienne JF, Huyse T, Mas-Coma S, Toulza E, Barre-Cardi H, Rollinson D, Kincaid-Smith J, et al. Outbreak of urogenital schistosomiasis in Corsica (France): an epidemiological case study. Lancet Infect Dis. 2016;16(8):971–9.

    Article  PubMed  Google Scholar 

  44. Dabo A, Diarra AZ, Machault V, Toure O, Niambele DS, Kante A, Ongoiba A, Doumbo O. Urban schistosomiasis and associated determinant factors among school children in Bamako, Mali. West Africa Infect Dis Poverty. 2015;4:4.

    Article  PubMed  Google Scholar 

  45. Feng Y, Liu L, Xia S, Xu JF, Bergquist R, Yang GJ. Reaching the Surveillance-Response Stage of Schistosomiasis Control in The People’s Republic of China: A Modelling Approach. Adv Parasitol. 2016;92:165–96.

    Article  CAS  PubMed  Google Scholar 

  46. Zhou X, Yap P, Tanner M, Bergquist R, Utzinger J, Zhou XN. Surveillance and response systems for elimination of tropical diseases: summary of a thematic series in Infectious Diseases of Poverty. Infect Dis Poverty. 2016;5:49.

    Article  PubMed  PubMed Central  Google Scholar 

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Acknowledgements

The study was undertaken as part of a PhD research programme of the first author (CS), and was made possible by generous financial and technical support from the DBL – Centre for Health Research and Development, University of Copenhagen, Denmark. Sincere thanks also go to Professor Chris C. Appleton of the University of KwaZulu-Natal, School of Biological and Conservation Sciences, for timely supervisory support. The processing of the risk models would not have been possible without technical support from Professor John B. Malone’s Pathobiological Sciences Laboratory at Louisiana State University. To the University of Zambia, Department of Biological Sciences, and most importantly all the primary school children that participated in the study, thank you very much for your invaluable contributions.

Funding

The first author (CS) received a travel award from the Danish Bilharziasis Laboratory, now the DBL – Centre for Health Research and Development, University of Copenhagen, Denmark. The second author’s (LNK) efforts were partly funded by the University of Namibia.

Availability of data and material

The datasets generated and/or analysed during the current study are not publicly available due restrictions from the Ministry of Health, but are available from the corresponding author upon reasonable request.

Authors’ contributions

CS designed the study and collected the data. CS and LNK performed the statistical analysis. CS and LNK coordinated and drafted the manuscript. Both authors read and approved the final manuscript.

Competing interests

The authors declare that they have no competing interests.

Consent for publication

Not applicable.

Ethics approval and consent to participate

Ethical clearance was granted by the University of Zambia. Participant consent was received from the children themselves and their guardians. Permission to visit school premises was granted by the Ministry of Education, Zambia.

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Correspondence to Lawrence N. Kazembe.

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Simoonga, C., Kazembe, L.N. Using the hierarchical ordinal regression model to analyse the intensity of urinary schistosomiasis infection in school children in Lusaka Province, Zambia. Infect Dis Poverty 6, 43 (2017). https://doi.org/10.1186/s40249-017-0262-x

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