Seroprevalence of malaria in inhabitants of the urban zone of Antananarivo, Madagascar

The study was conducted using existing serum samples from inhabitants of Antananarivo who had been enrolled in February 2004 for a study on hepatitis C. Volunteers were selected by cluster sampling with two degrees of freedom, based on the cluster sampling method used in immunisation coverage programmes [10]. This mode of random and cluster sampling yielded a cohort of subjects representative of the population of Antananarivo. Seventy clusters of 13 to 18 people were selected for this investigation, to maximise the effect of clusters and displacements (as described in [10]). Once informed consent had been obtained, the subjects were interviewed and serum samples were obtained from blood collected in dry tubes for biological analyses. A questionnaire was designed to evaluate the influence of associated factors: the number of journeys involving at least one night outside the city in the last six months, number of antimalarial treatments in the last six months and level of schooling (to evaluate socio-economic status).

For antibody screening, the indirect fluorescent antibody test (IFAT) was used [11, 12]. Slides were coated with the Palo Alto strain of P. falciparum from continuous in vitro culture. Serum samples, at successive dilutions between 1/64 and 1/4,096, were incubated with the parasites on the slide. A reaction with the 1/64 dilution is generally regarded as the threshold for a positive reaction [13]. The antibody-antigen complex was detected using sheep F(ab')2 anti-human-IgM conjugated with fluorescein isothiocyanate (FITC), or sheep (H+L) anti-human-IgG+IgA+IgM conjugated with FITC (Bio-Rad, France). All incubations were performed at room temperature, in a dark, humid chamber, for 45 minutes. Between incubations, slides were washed three times in phosphate-buffered saline. All tests were done in parallel with seropositive and seronegative control samples from the serum libraries of the laboratory. Slides were examined with an epifluorescence microscope. Antibody concentration was determined semi-quantitatively, by noting the highest dilution factor at which the serum gave fluorescent spots on incubation with the parasites.

Data were analysed in two different ways. A dichotomous classification of samples as seronegative or seropositive was used for analyses of seroprevalence and statistical analysis. To take into account the range of antibody concentrations and transformed individual into collective data, subjects were assigning into categories, according to common criteria, and the geometric mean of antibody rates (GMAR) were calculated according to the following formula (n_x is the number of subjects positive at the dilution rate of x; d_x is the dilution factor for the dilution rate of x, for example, the d_x value for 1/64 is 64; for sera negative for all dilution rates, Log(d_x) = 1):

GMAR = 10 ∑ n x ⋅ Log ( d x ) ∑ n x MathType@MTEF@5@5@+=feaafiart1ev1aaatCvAUfKttLearuWrP9MDH5MBPbIqV92AaeXatLxBI9gBaebbnrfifHhDYfgasaacH8akY=wiFfYdH8Gipec8Eeeu0xXdbba9frFj0=OqFfea0dXdd9vqai=hGuQ8kuc9pgc9s8qqaq=dirpe0xb9q8qiLsFr0=vr0=vr0dc8meaabaqaciaacaGaaeqabaqabeGadaaakeaacqqGhbWrcqqGnbqtcqqGbbqqcqqGsbGucqGH9aqpcqaIXaqmcqaIWaamdaahaaWcbeqaamaalaaabaWaaabqaeaacqqGUbGBdaWgaaadbaGaeeiEaGhabeaaliabgwSixlabbYeamjabb+gaVjabbEgaNjabcIcaOiabbsgaKnaaBaaameaacqqG4baEaeqaaSGaeiykaKcameqabeGdcqGHris5aaWcbaWaaabqaeaacqqGUbGBdaWgaaadbaGaeeiEaGhabeaaaeqabeGdcqGHris5aaaaaaaaaa@494E@

Rice fields are thought to be the most favourable environment for the development of malaria vectors in the ecosystems of Antananarivo [1‐3, 7]. Two types of image were used to identify rice fields [14]. The Landsat Enhanced Thematic Mapper (ETM+) image was acquired on May 2000 and radar images (Envisat) were acquired in January and July 2004. Rice fields differ from other types of vegetation in continually changing state over the course of the year.

Landsat images were enhanced by creating a colour composite image from the seven spectral bands of the original image, to make it easier to recognise objects on the ground. This was achieved by assigning bands to one of the three channels (blue, red, green). This makes it possible to calibrate various responses on the image: differences in colour and texture are associated with different classes of land cover. Principal component analysis (PCA) was then used to create neo-channels with more than 95% of information in the first axis, PCA1 [15, 16].

Two periods of field work were carried out. The first period was used to identify training sites and test sites. The GPS (Gerographical Positionning System) co-ordinates of the rice fields visited during these field studies are given. The second period of field work was used to check that the features on the ground corresponded to the images obtained. The training sites were digitised and supervised classification by the maximum likelihood method was used to generate a map of rice fields. The accuracy of this classification accuracy was estimated, using the Kappa coefficient [17]. The test sites were used to produce a confusion matrix, for assessing the overall accuracy of the land cover classification map.

Radar images were calibrated before absolute georeferencing. Image enhancement was designed to reduce speckling but to preserve accuracy. Adaptive filters were applied to ensure the highest possible image quality. Landscape changes between January and July were compared by visual image interpretation and backscatter coefficient analysis [18, 19]. A rice field index was calculated by dividing the area under rice by the area of the "Fokontany", the basic administrative district in the city [20].

Values of p < 0.05 were considered significant in all statistical analyses. Univariate analysis was carried out with Pearson's chi-squared test as implemented in EPI-info software. Chi² tests were used to compare qualitative variables. Multivariate analysis was carried out by means of backward stepwise logistic regression, using SPSS^® software (version 11.5). The dependent variable was positive IgG+IgA+IgM tests for malaria. Variables with p values below 0.2 in univariate analysis were introduced into the model and kept constant during the first step.

The study was carried out on 1,059 subjects (70 clusters of 13 to 18 subjects) with a male/female sex ratio of 0.59. The mean age of the subjects was 29.56 ± 17.66 years. Most (89.6%) had settled in Antananarivo in the four years before the survey. The investigators asked the subjects how many times they had spent at least one night outside of Antananarivo in the previous six months: 28.14% had spent at least one night outside the city on journeys to the Central Highlands (17.75%) or coastal zones (10.39%). Patients were asked about the frequency of malaria treatment during the previous six months: 82.63% had no malaria treatment, 12.65% had one course of malaria treatment and 4.72% had more than one course of malaria treatment. Socio-economic status was estimated, using a classification based on education level: no schooling (4.63%), primary school level (35.41%), secondary school level (49.01%) and post-secondary studies (10.95%).

The rice field index, calculated from satellite images, was used to classify city districts according to the percentage of the surface area suitable for potential anopheline mosquito breeding sites (Figure 1). Its value varied from 0% to 86% (median = 4.76%; first quartile 0%; third quartile = 26.99%).

Table 1 shows the results for IgG+IgA+IgM testing. The seroprevalence was 56.10%. The seroprevalence in men was significantly higher than that in women (60.1% and 53.7%, respectively; chi² test, p = 0.044). The serological prevalence of IgG+IgA+IgM increased significantly with age (under or over 15 years of age, chi² test, p < 0.0001). Univariate analysis (Table 1) showed significant associations between IgG+IgA+IgM-positive IFAT, travel outside the city, and rice field index. Travels outside the city were associated with a higher seroprevalence, and the GMAR of those who travelled (coast or Central Highlands) was higher than that of subjects who did not travel (GMAR coast group = 29.3; GMAR Central Highlands group = 30.2; GMAR for the group that did not travel = 16.1). Seroprevalence was analysed as a function of rice field index. A significant difference was observed between the subjects of the third quartile (rice field index > 26.99%) and the other subjects, with people living in districts with a high rice field index having a lower IgG+IgA+IgM prevalence. Sex, socio-economic level, history of travel outside Antananarivo and rice field index were included in a logistic regression model. Multivariate analysis confirmed that age, travelling outside Antananarivo and rice field index were significantly associated with the presence of IgG+IgA+IgM (Table 2). The seroprevalence of IgM was about 5.85%, and was not associated with other variables.