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Toxoplasma gondii seroprevalence in wild boars (Sus scrofa) in Sweden and evaluation of ELISA test performance

Published online by Cambridge University Press:  06 November 2014

C. WALLANDER ,
J. FRÖSSLING ,
I. VÅGSHOLM ,
A. UGGLA  and
A. LUNDÉN
C. WALLANDER*
Affiliation:
Department of Biomedical Sciences and Veterinary Public Health, Swedish University of Agricultural Sciences, Uppsala, Sweden
J. FRÖSSLING
Affiliation:
Department of Disease Control and Epidemiology, National Veterinary Institute, Uppsala, Sweden Department of Animal Environment and Health, Swedish University of Agricultural Sciences, Skara, Sweden
I. VÅGSHOLM
Affiliation:
Department of Biomedical Sciences and Veterinary Public Health, Swedish University of Agricultural Sciences, Uppsala, Sweden
A. UGGLA
Affiliation:
Department of Biomedical Sciences and Veterinary Public Health, Swedish University of Agricultural Sciences, Uppsala, Sweden
A. LUNDÉN
Affiliation:
Department of Biomedical Sciences and Veterinary Public Health, Swedish University of Agricultural Sciences, Uppsala, Sweden Department of Virology, Immunobiology and Parasitology, National Veterinary Institute, Uppsala, Sweden
*
*Author for correspondence: Ms. C. Wallander, Swedish University of Agricultural Sciences, Department of Biomedical Sciences and Veterinary Public Health, Box 7036, 750 07 Uppsala, Sweden. (Email: camilla.gustafsson@slu.se)
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Summary

Toxoplasma gondii is a zoonotic protozoan parasite, infecting a wide range of warm-blooded animals. The Swedish wild boar population is expanding and increased hunting provides its meat to a growing group of consumers. We performed a spatio-temporal investigation of T. gondii seroprevalence in Swedish wild boars. An ELISA was set up and evaluated against a commercial direct agglutination test, using Bayesian latent class analysis. The ELISA sensitivity and specificity were estimated to 79% and 85%, respectively. Of 1327 serum samples, 50% were positive. Thirty-four per cent of young wild boars and 55% of adults were positive (P < 0·001). The total seroprevalence ranged from 72% in 2005 to 38% in 2011 (P < 0·001), suggesting a declining trend. The highest seroprevalence, 65%, was recorded in South Sweden. In other regions it varied from 29% in Stockholm to 46% in East Middle Sweden.

Keywords

Monitoringserological screeningtest evaluationToxoplasma gondiiwild boar
Type
Original Papers
Information
Epidemiology & Infection , Volume 143 , Issue 9 , July 2015 , pp. 1913 - 1921
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Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/3.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
Copyright © Cambridge University Press 2014

INTRODUCTION

Toxoplasma gondii is a zoonotic, potentially lethal, protozoan parasite with the ability to infect most warm-blooded animals, including humans. Infection occurs by ingesting oocysts, excreted into the environment with the faeces from newly infected cats (the main host of the parasite) or by consuming meat from previously infected intermediate host animals harbouring tissue cysts [Reference Petersen1]. Recently, several studies have estimated T. gondii to be one of the most important pathogens involved in foodborne infections, causing a considerable disease burden and economic losses [Reference Havelaar2, Reference Hoffmann, Batz and Morris3]. The European Food Safety Authority (EFSA) has recommended the implementation of pre-harvest monitoring of T. gondii in sheep, goats, pigs, and game [4]. In Sweden, studies have been performed on T. gondii prevalence in different wildlife species such as brown hares (Lepus europaeus P.) [Reference Gustafsson and Uggla5], red foxes (Vulpes vulpes) [Reference Jakubek6], moose (Alces alces), roe deer (Capreolus capreolus) [Reference Malmsten, Jakubek and Björkman7] and lynx (Lynx lynx) [Reference Ryser-Degiorgis8]. Wild boars (Sus scrofa) are located mainly in the southeastern part of the country but are, according to the Swedish Association for Hunting and Wildlife Management, rapidly and successively spreading north [9]. The destructive behaviour of wild boars in agricultural areas has demanded increased hunting and, as a result, wild boar meat is now available for a larger group of consumers. The prevalence of T. gondii in wild boars in Sweden has not been previously investigated. However, in nearby parts of Europe, studies have indicated seroprevalence rates at high levels, ranging from 25% to 35% [Reference Opsteegh10Reference Deksne and Kirjušina12]. Two of the most widely used methods for seroprevalence studies of T. gondii are direct agglutination tests (DAT) and enzyme-linked immunosorbent assays (ELISA) [Reference Dubey13], the latter being practical and comparatively inexpensive if set up as an in-house system. It is essential that new tests are validated against a gold standard test and/or using sera from a population of animals with known disease status. However, test evaluation is also possible using, for example, a Bayesian statistical approach [Reference Johnson, Gastwirth and Pearson14], which has been used in veterinary diagnostic test evaluations in recent years (e.g. see [Reference Frössling15] and [Reference Mainar-Jaime and Barberán16]). To assess the importance of wild boar meat as a source of T. gondii infection, the aims of this study were to: (a) evaluate the test performance of an in-house ELISA against a commercially available DAT, (b) estimate the prevalence of T. gondii antibodies in wild boars in Sweden based on submitted samples, and (c) investigate possible variations in seroprevalence due to age, region and year.

METHODS

Background population and study sample

The wild boar population in Sweden increased to more than 100 000 wild boars by 2010/2011 (July–June) compared to ~40 000 animals in 2005/2006 [9]. The geographical distribution of wild boars has expanded during the study period from the southern area to include the middle-eastern parts of the country. The population distribution for 2009/2010 and 2010/2011 is shown in Figure 1. The material used in this study is a subset of samples from a national surveillance programme for absent diseases in Swedish wild boars [Reference Bengtsson17]. This programme has been on-going since 2000 and is based on hunters submitting wild boar serum samples to the National Veterinary Institute (SVA) in Uppsala, Sweden. Information on geographical origin is available for most samples, and for samples collected in 2010 and onwards, information on age group based on phenotype (colour and size) is also registered. In this study the age groups were ⩽12 months and >12 months.

Fig. 1. Geographical distribution of hunted wild boars in Sweden during the hunting seasons of 2009/2010 and 2010/2011. Based on data provided by the Swedish Association for Hunting and Wildlife Management, Wildlife Monitoring [9]. Colour scale represents number of animals hunted in each county (white areas represent no wild boars hunted). Regions (Nomenclature of Territorial Units for Statistics level 2) are drawn with black borders and black numbers on the map indicate percentage difference between proportion of hunted animals and proportion of sampled animals in each region. For example, South Sweden is underrepresented in our sample compared to the proportion of wild boars hunted in this region.

The samples analysed in this study were retrieved from samples collected in 2005 and from 2008 to 2011. The strategy was to randomly select 250 samples from each year. This sample size was based on a population size of 100 000–150 000 wild boars, a maximum expected seroprevalence of 25% [Reference Opsteegh10Reference Deksne and Kirjušina12] and an aim to detect a 10% change in seroprevalence with 95% confidence level and 80% power (Win Episcope 2·0 [Reference Thrusfield18]). Between 10% and 30% of the samples were excluded due to poor quality; moreover, only a limited number of samples were available from 2005 and 2009. Finally, 1328 samples were included in the study and these represented six regions in Sweden (Nomenclature of Territorial Units for Statistics (NUTS) system, level 2 [19]) (Fig. 1). Information on animal age was available for 480 samples. The distribution of samples per year, age group and region, is shown in Table 1.

Table 1. Number and distribution of serum samples per year, age group (in months) and region

n.a., Not applicable.

* Total number (⩽12 months/>12 months).

Serology

ELISA

All serum samples were analysed using ELISA. This was based on a previously published assay for sheep sera utilizing a saponin-octylglucoside solubilized tachyzoite antigen from the RH strain of T. gondii, produced at the Moredun Research Institute, UK. The assay was performed as described previously [Reference Opsteegh20] but with a peroxidase-labelled polyclonal rabbit anti-pig immunoglobulin G antibody (Sigma-Aldrich, USA) diluted 1: 10 000, Polysorp microtitre plates (Nunc Immuno Plate, Thermo Fisher Scientific, USA) and buffers and substrate from SVA. Washing was performed with a manual plate washer (Nunc-Immuno Wash 12, Thermo Fisher Scientific) and the optical density (OD) at 450 nm was read in a plate reader (Multiscan FC v. 2·5, Thermo Fisher Scientific). Positive and negative pig sera were used in checkerboard titrations to retrieve optimal dilutions for antigen, serum samples and conjugate, for which the ratio between OD values for positive and negative sera was as high as possible. The positive sera was provided by the National Veterinary Institute, Technical University of Denmark (Kgs. Lyngby, Denmark), and the negative sera were from fattening pigs in a closed herd (Serogrisen, Ransta, Sweden) which tested negative by DAT (described below) and immunoblotting, performed as described previously [Reference Jakubek, Lundén and Uggla21]. Control for plate-to-plate variation was performed as described previously [Reference Opsteegh20], using seven controls, ranging in OD value from 0·10 to 1·52. A total of four ELISA plates were retested based on the calculated R 2 (<0·97) [Reference Opsteegh20]. Further, 25 individual samples were retested because of a coefficient of variation (CV; i.e. standard deviation of samples/mean value of samples) >20% between the duplicates. One sample did not manage to obtain a CV <20% in spite of multiple analyses and was excluded from the dataset.

DAT

To allow estimation of diagnostic sensitivity (Se) and specificity (Sp) of the ELISA on wild boar serum samples, a subset of the samples (n = 242) from 2011 was also analysed using a commercially available DAT, in which IgM-mediated agglutination is prevented by addition of 2-mercaptoethanol (Toxo-Screen DA, bioMérieux SA, France). The DAT was performed according to the manufacturer's instructions except that a serum dilution of 1:20 was used as positive cut-off. This cut-off has previously been evaluated for pig sera [Reference Dubey22]. Samples were also tested in dilution 1:4000 to account for the prozone effect [Reference Desmonts and Remington23]. Sera positive in either dilution were classified as T. gondii positive. Out of 89 DAT-positive samples, 24 were positive only in dilution 1:4000. Seventy per cent of these samples had ELISA OD values >0·8, which agrees well with the prozone effect being a result of high levels of specific antibodies.

Estimation of diagnostic Se and Sp

The test performance of the ELISA was evaluated using Bayesian latent class analysis based on two dependent tests and two populations as described by Branscum et al. [Reference Branscum, Gardner and Johnson24]. For evaluation purposes, a subset of samples from 2011 (n = 242) were grouped into subpopulation 1 [wild boars aged ⩽12 months (n = 143)] and subpopulation 2 [wild boars aged >12 months (n = 99)]. Based on numerous reports of an age-dependent T. gondii prevalence in a wide range of host species [Reference Jokelainen11, Reference Deksne and Kirjušina12], the prevalence in subpopulation 1 (π1), was expected to be lower compared to the prevalence of subpopulation 2 (π2). The latent class model was run using OpenBUGS 3·2·2 [Reference Spiegelhalter25]. After a burn-in period of 5000 iterations, estimates were based on the next 50 000 iterations. Multiple chains (set to different starting values) for every estimate were checked for convergence and stability by assessing history plots [Reference Brooks and Gelman26]. Prior information on the parameters to be estimated was included in the model as beta distributions. The priors for the diagnostic Se and Sp of DAT (SeDAT/SpDAT) were set to a mode and 5th percentile of 0·83 and 0·65, and 0·90 and 0·80, respectively. This corresponded to beta(17·86,4·45) and beta(42·57,5·62) and was based on previously published evaluations of the test [Reference Dubey22, Reference Branscum, Gardner and Johnson24]. To get a rough prior estimate of the seroprevalence in the young and adult population (π1/π2) a commercial ELISA (ID Screen Toxoplasmosis Indirect Multi-species; IDvet Innovative Diagnostics, France) was used. The apparent seroprevalence was 27% (95th percentile = 35%) in the young population and 40% (95th percentile = 51%) in the adult population. Using these estimates, and the 95th percentiles in the confidence intervals as the 95th percentiles for the beta distributions, provided beta(27·57,72·85) and beta(23·60,34·91) as priors for π1/π2, respectively. For Se analysis purposes, the model was also run using uniform priors [beta(1,1)] for both DAT test performance and prevalences. A series of cut-off-values for the ELISA were tested in the analysis to identify a suitable cut-off for our purpose. The selected ELISA cut-off value was based on the results from the latent class analysis and with regard to the calculated maximal Youden's index (Youden's index = Se + Sp – 1) [Reference Youden27]. Using this cut-off, all 1327 samples were classified as positive or negative.

Data management and statistical analysis was performed using R 2·15·2 [28]. Differences between groups were tested using the Pearson's χ 2 test.

RESULTS

Seroprevalence in wild boars

After classifying samples as positive or negative using the selected cut-off (see below), 657/1327 samples [50%; 95% confidence interval (CI) 47–52] scored positive. In total, 94/275 (34%, 95% CI 29–40) young wild boars and 113/205 (55%, 95% CI 48–62) adult wild boars were positive (Fig. 2). The difference in seroprevalence between the two age groups was significant (P < 0·001). The apparent seroprevalence per year varied between 38% (95% CI 32–44) in 2011 and 72% (95% CI 65–78) in 2005 (Fig. 3). The difference was significant between 2005 and 2011 (P < 0·001) and also between 2008 (50%, 95% CI 45–55) and 2011 (P < 0·05). Based on pair-wise comparisons, the apparent seroprevalence within different regions (considering only years 2010 and 2011 together, due to the rapidly changing population) was similar except for South Sweden, which had a significantly higher seroprevalence than all other regions (65%, 95% CI 51–77) (P < 0·05) (Fig. 4). The seroprevalence in other regions varied from 29% (95% CI 18–43) in Stockholm to 46% (95% CI 40–52) in East Middle Sweden.

Fig. 2. Apparent seroprevalence (with 95% confidence intervals) in animals aged ⩽12 months and >12 months in 2010–2012.

Fig. 3. Apparent seroprevalence (with 95% confidence intervals) in different years.

Fig. 4. Apparent seroprevalence (with 95% confidence intervals) in different regions (Nomenclature of Territorial Units for Statistics level 2).

Test performance

The estimated Se and Sp of the ELISA at different cut-offs, based on the latent class analysis, are presented in Figure 5. Of all cut-offs tested (0·30–0·60), cut-off values 0·35–0·41 showed the highest combined values for Se and Sp (Se = 80–78%, Sp = 75–87%). Lower and higher cut-offs displayed either too low Sp or too low Se for our purposes. Having a preference for a higher Se than Sp, the cut-off 0·39 was selected with Se = 79% [95% credibility interval (CrI) 60–95] and Sp = 85% (95% CrI 74–94). The cross-classified test results from the ELISA (cut-off 0·39) and the DAT on the 242 samples included in the latent class analysis are shown in Table 2. Including prior information in the model did not influence the posterior distribution of most parameters, except SeDAT and π2. The results from the Se analysis are presented in Table 3.

Fig. 5. Estimated (a) specificity and (b) sensitivity (including 95% credibility interval) of the in-house ELISA at different cut-offs, based on the latent class analysis.

Table 2. Cross-classified test results from the in-house ELISA (cut-off 0·39) and the DAT on the 242 samples included in the latent class analysis

DAT, Direct agglutination test.

Table 3. Results of latent class sensitivity analysis, showing mean posterior estimate (95% credible interval) for all estimated parameters, when analysed using priors for DAT (SeDAT/SpDAT), prevalences (π1/π2) and both

DAT, Direct agglutination test.

DISCUSSION

This is the first study of T. gondii seroprevalence in wild boars in Sweden. Approximately half of the animals tested in this study were positive. Wild boar meat is becoming increasingly accessible in retail stores, and the modern consumer is not likely to be familiar with all possible health hazards associated with eating this meat undercooked. By analogy with the assumption that a large proportion of domestic pigs with antibodies to T. gondii also harbour viable tissue cysts [Reference Dubey29], it is likely that people consuming wild boar meat in Sweden are at risk of contracting a T. gondii infection if the meat is ingested inadequately cooked.

Our finding of an age-dependent seroprevalence is in agreement with several other studies of T. gondii in wild boars [Reference Jokelainen11, Reference Deksne and Kirjušina12, Reference Berger-Schoch30]. However, not all studies have been able to confirm this [Reference Gauss31]. Moreover, in a recent paper by Opsteegh and co-workers [Reference Opsteegh10], it was suggested that seropositive wild boars might seroconvert back to negative. This was based on the observation that seroprevalence increased with age, but reached a plateau at around age 10 months. Moreover, their data fitted best into a disease spread model with conversion back to susceptibility for previously infected animals. This hypothesis implies that infected wild boars might be able to reduce or eliminate the infection. Thus, further research addressing the relationship between seropositivity and presence of tissue cysts in wild boars, and possibly also in domestic pigs, is needed for a quantitative food safety risk assessment.

The apparent seroprevalence varied between years and it was significantly higher in the first year studied than in the later years. This could reflect decreased contamination with oocysts in the environment, which is believed to be the most important source of infection for wild boars. However, since the age of animals sampled in the earlier years (2005–2009) were not known, the result could be due to a higher proportion of older animals in those years. In addition, the seroprevalence for the years between 2005 and 2008 is missing, which possibly could have given a different picture if included. Lundén et al. [Reference Lundén, Näsholm and Uggla32] showed that the T. gondii prevalence varied between 10% and 45% in the same sheep flock when sampled twice a year for 6 years. This supports the hypothesis that environmental oocyst contamination is fluctuating at least locally, which could be reflected as a varying seroprevalence also in wild boars as in our study.

Due to the rapid expansion of the Swedish wild boar population during the study period and possible time-dependent differences in prevalence, we chose to compare regions only for the years 2010–2011. One region, South Sweden, stood out markedly with a significantly higher seroprevalence (65%, 95% CI 51–77) than all other regions. This difference could not be explained by differences in age distributions since animals from the Småland and the Islands region, located just north of South Sweden, had a similar age distribution but a significantly lower prevalence (45%, 95% CI 38–53, P < 0·05). A north–south gradient in T. gondii seroprevalence has previously been reported for example in moose and lynx in Sweden [Reference Malmsten, Jakubek and Björkman7, Reference Ryser-Degiorgis8] and in Finland [Reference Jokelainen33, Reference Jokelainen34]. These authors suggested that the most likely reason for the low seroprevalence in the far north is a low population density of domestic cats in these sparsely inhabited regions. Although the present study includes only the southern and central parts of Sweden, the recorded differences in seroprevalence might also be due to variations in human and cat populations. Other reasons could be meteorological factors such as precipitation [Reference Afonso, Thulliez and Gilot-Fromont35] and winter temperatures [Reference Beral36], and geographical conditions such as altitude [Reference Richomme37], which have been identified as risk factors for T. gondii infections in outdoor cats and wild boars. However, as the present study was based on a convenience sample, far-reaching conclusions concerning the differences found in seroprevalence between regions cannot be made.

A variety of T. gondii ELISA systems have been developed and used, sometimes without presenting estimations of diagnostic Se and Sp, making comparisons of test performance difficult. Moreover, commercial serological tests validated for use in defined host species, populations and sample materials are often used to screen entirely different ones, even though test evaluations have indicated that the same test can show different characteristics when applied to other species [Reference Mainar-Jaime and Barberán16]. Thus, tests should be evaluated before use in new species and populations, and this should be considered when results are interpreted [Reference Gardner38]. By estimating test performance for a series of cut-off values we were able to select the most suitable cut-off for our prevalence study. At an OD cut-off of 0·39, the Se and Sp were estimated to 79% and 85%, respectively, and this was regarded as adequate for the purposes of the survey. For diagnostic testing of individual animals, a higher Se and Sp would be preferable.

DAT is considered a reliable serological test for T. gondii IgG screening in many animal species [Reference Dubey13]. The test is relatively often performed in new species (and animal populations) without a thorough evaluation of test characteristics. In the current study, DAT was evaluated at a single cut-off (1:20), because our primary goal was to retrieve estimates for the ELISA. The test characteristics derived for DAT at this cut-off were close to those obtained in similar studies of domestic pigs [Reference Gardner, Greiner and Dubey39]. However, which cut-off to use for wild boar samples is a matter of debate. Richomme et al. [Reference Richomme40] isolated viable parasites in 11/24 wild boars with end-point titres of 1:6 or 1:12, which may indicate recent infections with incipiently increasing antibody titres. This finding was interpreted as 1:6 being a biologically more relevant cut-off than 1:24 (i.e. many false-negative samples). On the other hand, Puvanesuaran et al. [Reference Puvanesuaran, Noordin and Balakrishnan41] found a perfect agreement between high serum titres (>1:24) and presence of viable tissue cysts, whereas none of the samples with lower titres (1:6) were positive for tissue cysts. These results indicate that DAT characteristics need to be evaluated (for several cut-offs) when used on novel animal populations such as wild boars.

In the absence of a perfect reference test, the ELISA set up for this study was evaluated using a latent class approach. The Bayesian latent class process for test evaluation has been thoroughly described for chronic T. gondii infection in food animals by Gardner et al. [Reference Gardner, Greiner and Dubey39] and has the advantage that estimates of diagnostic Se and Sp could be based on results from naturally infected animals, i.e. the target population of the investigation. In addition, previously collected information on test performances and population prevalences could be included in the model, giving more impartial and precise estimates. The model chosen was based on test results from two potentially dependent tests (ELISA and DAT) and two populations. Because many studies indicate a higher prevalence of T. gondii in older animals, subpopulations created here were based on age. However, one assumption in the calculations was that test Se and Sp were equal in both populations, and although age has been suggested as an appropriate factor in this model [Reference Gardner, Greiner and Dubey39, Reference Hui and Walter42], others have claimed that this is not advisable [Reference Toft, Jørgensen and Højsgaard43]. One argument is that older individuals may have been exposed to a greater variety of pathogens, which could lead to a difference in immune responses, and consequently, test performance. In our case, the probability of false-positive results may be slightly increased in the adult population (i.e. Sp is lower). If so, the true Se of the test is probably higher than estimated.

This study has demonstrated a high seroprevalence of T. gondii in wild boars in Sweden and suggests that wild boar meat is a potential source of Toxoplasma infection to a growing group of consumers. Further studies are needed to establish risk factors and efforts must be made to inform the public how to prevent infection.

ACKNOWLEDGEMENTS

The authors thank Katarina Näslund and Göran Zakrisson for scientific advice, and Alison Burrells, Peter Lind and Per Wallgren for providing antigen and control sera. This work was funded by a grant from the Billström Foundation (2012). We also thank Lise-Lotte Fernström and Eva-Britt Jakubek for excellent technical assistance.

DECLARATION OF INTEREST

None.

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Figure 0

Fig. 1. Geographical distribution of hunted wild boars in Sweden during the hunting seasons of 2009/2010 and 2010/2011. Based on data provided by the Swedish Association for Hunting and Wildlife Management, Wildlife Monitoring [9]. Colour scale represents number of animals hunted in each county (white areas represent no wild boars hunted). Regions (Nomenclature of Territorial Units for Statistics level 2) are drawn with black borders and black numbers on the map indicate percentage difference between proportion of hunted animals and proportion of sampled animals in each region. For example, South Sweden is underrepresented in our sample compared to the proportion of wild boars hunted in this region.

Figure 1

Table 1. Number and distribution of serum samples per year, age group (in months) and region

Figure 2

Fig. 2. Apparent seroprevalence (with 95% confidence intervals) in animals aged ⩽12 months and >12 months in 2010–2012.

Figure 3

Fig. 3. Apparent seroprevalence (with 95% confidence intervals) in different years.

Figure 4

Fig. 4. Apparent seroprevalence (with 95% confidence intervals) in different regions (Nomenclature of Territorial Units for Statistics level 2).

Figure 5

Fig. 5. Estimated (a) specificity and (b) sensitivity (including 95% credibility interval) of the in-house ELISA at different cut-offs, based on the latent class analysis.

Figure 6

Table 2. Cross-classified test results from the in-house ELISA (cut-off 0·39) and the DAT on the 242 samples included in the latent class analysis

Figure 7

Table 3. Results of latent class sensitivity analysis, showing mean posterior estimate (95% credible interval) for all estimated parameters, when analysed using priors for DAT (SeDAT/SpDAT), prevalences (π1/π2) and both