The objective of this study was to estimate the prevalence and identify risk factors associated with the presence of Toxoplasma gondii in pig-fattening farms from Yucatan, Mexico. A cross-sectional study was conducted with a two-stage sampling. There were 429 pigs sampled from 39 farms randomly selected. Blood samples were collected to obtain DNA and serum. The presence of IgM and IgG antibodies was determined by indirect ELISA. Prevalence was estimated by diagnostic test. Potential risk factors to be included in a marginal logistic regression were tested by chi-square or Fisher. The prevalence of IgM and IgG was 92.5% (397/429) (CI 89.9–95.1%) and 95.8% (411/429) (CI 93.7–97.8%), respectively. Regarding PCR, a prevalence of 50.8% (218/429) (CI 45.9–55.6%) was found. The logistic regression showed an association with herd size and type of feeder (P<0.05). The risk of a case in farms with ≤400 pigs was 27.9 times higher than in farms with >400 pigs. The manual feeder was a significant protective factor associated with the seropositive against T. gondii. Results indicate a high circulation of T. gondii in pig-fattening farms from Yucatan, finding an increased risk of infection for those farms with less than 400 animals and automatic feeders.
1. Introduction
Toxoplasmosis is an infectious disease caused by the protozoan parasite Toxoplasma gondii (T. gondii), being the pig among other animals intermediate hosts [1]. This is a zoonotic disease with a high impact on public health [2]. Human infections may go unnoticed or may cause various signs and symptoms depending on the patient’s immune status and general health status (i.e., immunocompetent state, eye disease, congenital toxoplasmosis) [3]. Reactivation of disease and infection to the central nervous system (CNS) occurs in immunosuppressed patients resulting in severe encephalitis [4]. The toxoplasmic chorioretinitis in humans can be congenitally or postnatally acquired as a result of an acute infection or reactivation of the disease [5]. Congenitally infected fetuses with toxoplasmosis may develop hydrocephalus, microcephaly, intracranial calcifications, chorioretinitis, strabismus, blindness, epilepsy, mental retardation, and anemia among others [6].
The route of infection with T. gondii in man and animals is by incidental ingestion of oocysts from the feces of cats. Oocysts are highly resistant to environmental conditions and contaminate water, soil, dust, vegetables, and fruits [7]. However, infection through the ingestion of tissue cysts in meat is considered one of the main sources of infection to humans. Between 30% and 60% of pregnant women who consumed inadequately cooked meat may suffer from acute toxoplasmosis [8]. The low prevalence of toxoplasmosis found in a group of vegetarians (24%) confirms the suspicion that consumption of meat is one of the most important ways of transmission of T. gondii to man [9].
Swine plays an important role in the transmission of infection to humans [10]. A study reveals that, in the period 1983-1984 in the United States, 23.9% of pigs presented specific titers against T. gondii; from those, 42% were breeders and 23% were commercial fattening farms [11]. By 1992, prevalence in the same region dropped to 20.8% in breeders and 3.1% in fattening pigs due to changes in their production systems and preventive measures taken [12]. Toxoplasmosis is found in different animal production systems in Mexico. In pigs sampled in central Mexico, 8.9% were positive [13]. The mortality associated with toxoplasmosis in pigs is greater in young than in adult pigs. It is also responsible for pneumonia, myocarditis, encephalitis, and placental necrosis in this species [14].
Seroepidemiological studies have demonstrated the huge impact of pork contaminated with tissue cysts on the transmission to humans from this disease [15, 16]. Also, it is known that a single pig intended for consumption that is contaminated with cysts in muscle tissue is capable of transmitting infection between 200 and 400 individuals [17]. On the other hand, molecular studies may demonstrate the presence of circulating genome from the parasite given a broader panorama of the epidemiological situation of T. gondii in the studied population.
The State of Yucatan is an important pork producer in Mexico, with about 95.933 tons of pork each year, and has a per capita consumption of 10 kilos per year [18]. However, there is little information on the presence of T. gondii in pig farms and even more in pork intended for consumption. Therefore it is necessary to conduct epidemiological studies to determine the situation in pig populations in the region, with the aim of establishing prevention and control measures to reduce their impact at farm level and public health risk.
The aim of this study was to estimate the prevalence and risk factors associated with the presence of T. gondii in pig-fattening farms in the state of Yucatan, Mexico, destined for human consumption, by serological and molecular detection of the etiological agent.
2. Material and Methods2.1. Study Area
The study was conducted in the state of Yucatan, located in southeastern Mexico (19° 30′ and 21° 35′ north latitude and 90° 24′ west of the meridian of Greenwich). The climate is tropical subhumid with summer rains. The maximum monthly temperature varies between 35 and 40°C, with an average temperature of 26.6°C. The relative humidity varies between 65 to 100% taking the mean value over 78%. The annual rainfall is from 415 to 1290 mm [19].
2.2. Sample Collection
A two-stage cross sectional study was performed during September to December 2008. Four hundred and twenty-nine pigs from 39 farms, between 18 and 20 weeks of age, were randomly selected. The sample size to estimate prevalence was determined by the formula: n=D(z2p(1-p)/d2), considering a confidence level of 95% (z=1.96), absolute precision of 5% (d), a design effect (D) of 2, and a prevalence of 25% (p). The estimated prevalence was obtained from a pilot study that included 45 animals. The number of animals sampled at each farm (b=11) was calculated based on the formula b=√(ce/cd)(1-re/re), where ce is cost of a sample into two clusters (10); cd, sample cost of two units of interest in a same cluster (1) and the correlation intra-conglomerates (re) was (0.04) [20]. The number of farms (m=n/b) was calculated by dividing the sample size (n=429) between the numbers of animals sampled in each establishment (b=11).
2.3. Serum and DNA Extraction from Blood
Two blood samples per animal were collected in vacutainer tubes with and without EDTA for subsequent DNA extraction and to obtain serum, respectively. Samples for serum collection were centrifuged at 2500 g for 10 min and were stored at −20°C until further evaluation.
Genomic DNA was extracted using the QIAamp DNA mini kit (Qiagen, CA, USA). Before extraction, a pre-lysis of the sample was conducted as suggested by Jalal et al. [21]. Samples were stored at −20°C until further PCR assay.
In order to verify the viability of purified DNA samples, PCR was performed establishing the β actin gene. Amplification conditions were 20 pM of each primer: β1 5′-ATCTTGATCTTCATGGTGCTGGGC 3′ and β2 5′-ACCACTGGCATTGTCATGGACTCT3′ [22], containing 1 U of enzyme GoTaq Hot Start Polymerase (Promega, WI, USA), 1X PCR Buffer Colorless GoTaq Flexi Buffer, and MgCl2 at a concentration of 2 mM in a final reaction volume of 25 μL. The alignment temperature was 60°C, awaiting a product size of 545 bp [22].
2.4. Serology
The presence of specific IgM and IgG antibodies against T. gondii was determined separately by the use of indirect ELISA tests (Human-GmbH, Wiesbaden, Germany), on a 96-well plate coated with tachyzoites of T. gondii. Serum samples were diluted to a ratio of 1 : 100 in phosphate-buffered saline (PBS; pH 7.2). A secondary goat anti-IgG pig antibody labeled with peroxidase (HRP) (Santa Cruz Inc. CA, USA) and a goat anti-IgM pig also marked with HRP (Serotec, Oxford, UK) were used, respectively, at a dilution of 1 : 5,000. Sera from pigs showing high anti-IgG antibodies titer by ELISA (1 : 1024) and positive results to PCR against T. gondii were used as positive controls, and sera pools from 10 healthy pigs previously tested by triplicate with ELISA IgM, IgG, and PCR were used as negative controls. On the basis of the ELISA, subjects were diagnosed as either positive/negative for specific IgG and IgM antibodies to T. gondii. The optical density (OD) was measured in a spectrophotometer at 450 nm (Multiskan Multisoft Primary EIA) and was used to compute the percent positivity (PP) using the formula mean OD (sample or negative control) divided by the mean OD value positive control multiplied by 100. Percent positivity of 15% or above was considered positive.
2.5. Polymerase Chain Reaction for T. gondii Detection
Conventional PCR was performed to amplify the B1 gene of T. gondii, which is highly conserved in the parasite. Primers Tg1 (5′-AAAAATGTGGGAATGAAAGAG-3′) and Tg2 (5′-ACGAATCAACGGAACTGTAAT-3′) were used because of the high specificity (100%) for the B1 gene [21] of T. gondii. Amplification conditions were 40 pM of each primer, 1 U of GoTaq enzyme Hot Start Polymerase (Promega, WI, USA), containing 1X PCR Buffer Colorless GoTaq Flexi Buffer and MgCl2 at a concentration of 0.8 mM, in a total volume of 25 μL per reaction. The alignment temperature was 51°C and an amplified product of 469 bp was obtained. The PCR protocol was performed as follows: denaturation at 95°C for 10 min, followed by 35 cycles of 95°C, 52°C, and 72°C during 60 sec, 30 sec, and 60 sec, respectively—with a final elongation at a temperature of 72°C during 7 min. For the PCR performance, a thermal cycler was used (Applied Biosystems, Foster City, USA). Subsequently the PCR products were analyzed by electrophoresis on agarose gels and stained with ethidium bromide 1.8% (10 mg/mL) for 15 minutes and visualized with UV light, imaged them using a photo document (Applied Biosystems, Foster City, USA). As a positive-control PCR assay, the amplification of a clone obtained in the laboratory was carried out (PmosBlue plasmid with a PCR amplificate as an insert of the B1 gene of T. gondii RH strain). The bacterial clone was transformed into E. coli strain TOP10 and was purified with a commercial kit (Roche High Pure Kit, Manhein, GER). From the elution obtained, 32 ng × 106 of the clone was used as a positive control in the PCR reaction.
2.6. Risk Factors
The information on risk factors was obtained by applying a questionnaire. The risk factors considered were herd size (≤400 and >400 pigs), presence or absence of cats, cats number (≤3 cats, >3 cats, and no presence of cats), presence of rodents (yes/no), pest control (yes/no), type of feeder (automatic/manual), cannibalism (yes/no), production system (complete cycle/fattening), and place of storage food (warehouse/silo).
2.7. Statistical Analysis
The adjusted prevalence by herd size was estimated by the formula p=ΣNipi/N, where Ni is the size of the ith farm, pi is the prevalence of the ith farm, and N is the total number of pigs in the studied population. Confidence interval (95%) was also calculated [20].
A positive pig was defined as one positive to IgG ELISA or PCR. Contingency tables were constructed to identify those risk factors with cells with zeros, which were discarded for further analysis. Factors that were significant (P<0.20) in the Chi-square or Fisher tests were included in a binomial logistic regression model adjusted for the effect of farm using the procedure GENMOD [23].
3. Results3.1. Serology
The seroprevalence of IgM anti-T. gondii found was 92.5% (397/429) (CI 89.9–95.1). From the sampled farms, 36 showed seroprevalence of 100% and 3 of 90%. Regarding IgG antibodies, a prevalence of 95.8% (411/429) (CI 93.7–97.8) was found; 33 farms showed prevalence of 100%, 1 farm of 90%, 3 farms with prevalence between 30 and 70%, 1 farm with prevalence <30%, and 1 farm seronegative to T. gondii.
3.2. PCR for T. gondii Detection
A T. gondii prevalence of 50.8% (218/429) (CI 45.9–55.6) was found with the PCR technique. Of the 39 farms, nine had a prevalence of 100%, five were positive in 90%, seven showed values between 50 and 90%, and 18 farms’ prevalence found was between <50 and 0%. An example of positive pigs identified by PCR and electrophoresis is shown in Figure 1.
Agarose electrophoresis (1.8%) with BrEt staining showing the PCR amplified products of B1 gene from Toxoplasma gondii. Lane 1: molecular weight marker (100 bp. Promega), lane 2: positive control of Toxoplasma gondii RH strain, lane 3: negative control (uninfected pig), lanes 4–12: positive pigs from Yucatan, Mexico.
Two hundred and eleven pigs were positive to ELISA (IgM and IgG) as well as in PCR, showing a total prevalence of T. gondii with these 3 tests of 49.1% (95% CI 45.9–55.6) (Table 1). The amplified products were purified and were sequenced, showing homology of >99% identity with the B1 gene of T. gondii.
Serological and molecular status of fattening pigs in Yucatan, Mexico.
IgM (−)
IgM (−)
IgM (+)
IgM (+)
IgM (+)
IgM (+)
IgG (−)
IgG (+)
IgG (+)
IgG (+)
IgG (−)
IgG (−)
n
PCR (−)
PCR (−)
PCR (−)
PCR (+)
PCR (+)
PCR (−)
3
29
171
211
7
8
429
p (%)
0.7
6.75
39.8
49.1
1.63
1.86
100%
p: prevalence.
3.3. Risk Factors
The risk factors farm size, food storage, and type of feeder showed statistic association by univariated analysis (χ2). Presence of cats, cats number, cannibalism, and production system the showed significant values (P<0.05) but were not considered in the logistic regression model because of the low number of cases in contingency tables. Also, the variable presence of rodents was significant but it was not included in the multivariate study because the data obtained in the contingency table were not consistent (Table 2).
Variables measured in the study of cross section for T. gondii in fattening pigs from 39 farms in the state of Yucatan, Mexico.
Variable
Category
Positive
Negative
Chi2 value
P
Farm size
≤400
272
3
45
0.0001
>400
125
29
Presence of cats
Yes
301
29
4
0.055
No
96
3
Cats number
>3
176
22
7
0.026
<3
136
7
0
85
3
Food storage
Ensilage
31
13
34
0.001
Warehouse
366
19
Type of feeder
Automatic
75
13
9
0.003
Manual
322
19
Cannibalism
Yes
155
0
19
0.0001
No
242
32
Production system
Full cycle
309
32
9
0.0028
Fattening
88
0
Presence of rodents
Yes
95
147
28
0.000
No
122
65
Pest control
Yes
109
108
0.19
0.65
No
111
101
The logistic regression model adjusted for farm showed association with herd size and type of feeder (P<0.05). The risk of a case on farms with ≤400 pigs was 27.9 times higher than on farms with >400 pigs. The manual feeder was a significant protective factor associated with the seropositive towards T. gondii (Table 3).
Logistic regression analysis adjusted for the effect of farm for T. gondii in 429 fattened pigs from 39 pig farms in the state of Yucatan, Mexico.
Risk factor
b
EE
OR
95% IC
P
Size of the farm
≤400
3.33
0.76
27.9
6.29–125.2
0.0001
>400
0
1
Food storage
Ensilage
0
1
Warehouse
−0.23
0.71
0.11
0.19–3.18
0.74
Type of feeder
Automatic
0
1
Manual
−1.67
0.70
0.18
0.04–1.32
0.018
4. Discussion
Results obtained in this study showed a high circulation of T. gondii in fattening pigs on farms in the state of Yucatan, Mexico. The prevalence of IgG antibodies (95.8%) is higher than the 8.9% found by García-Vazquez et al. [13] on commercial pig-fattening farms from central states of Mexico. Toxoplasmosis in pigs has a wide worldwide variation, ranging from 2.7% in the USA [24] to 37% in Brazil [25], and can show a yearly variation of 11.6% in 2001, 0% in 2003, and 1.2% in 2004 as reported in Canada [26]. These wide variations occur as result of different risk factors and control measures adopted in the pig production systems from each country.
There are few epidemiological studies in naturally infected pigs using immunoglobulin IgM. The study of IgM and IgG immunoglobulins at the same time in the study population may demonstrate the dynamic response of these antibodies during natural infections with T. gondii. During experimental infections in pigs, IgM reached a peak 10 days after infection and remained 21 to 24 days later. The persistence of IgM after the acute phase of infection may be normal for this immunoglobulin [27]. The IgM immunoglobulin was found in most of the pigs sampled even in the presence of IgG. This finding suggests that pigs were probably in a state of reinfection or persistence of antigenic stimulation of the agent.
It is known that IgM immunoglobulin is produced during the acute phase of toxoplasmosis [28] and can also be observed during secondary responses (chronic phase in the presence of IgG), only being hidden by the predominance of the latter [27, 29]. The possibility of reinfection of pigs may explain the PCR results found since this technique directly identified the presence of the genome of the parasite in the blood samples [30]. Serological tests only explain previous contact with the agent. When placed together, the molecular and serological status may indicate the phase of infection. In cats, the presence of IgM or PCR-positive T. gondii cases may indicate acute cases, whereas IgM + IgG + PCR positive cases indicate chronic reactivated cases [31]. In the present study almost half of the studied animals were in the chronic reactivated stage indicating a constant exposure.
The likely source of reinfection of pigs can be caused by constant contact with infective oocysts of T. gondii present in the farms, either in water sources, soil, or air, which is commonly found in swine production systems [32]. T. gondii oocysts can be viable for a couple of years (540 days) and tolerate extremes of temperature and humidity promoting their persistence in the environment [33], and they are capable of producing infection by contact with susceptible animals. Likewise, the presence of cats in farm production systems can increase the spread of pollutant oocysts. Moreover, the presence of agents causing immunosuppression in farms such as arterivirus (PRRS), Mycoplasma hyopneumoniae (enzootic pneumonia), and Circovirus (PCV2) [34, 35] could cause the reactivation of cysts tissue [36]. A case of systemic toxoplasmosis associated with concurrent infection with Circovirus in a pig fattening farm has been reported, probably due to immunosuppression caused by the virus [37].
A higher risk of infection by T. gondii in those farms where the population size was less than 400 individuals was identified, similarly as reported by Assadi-Rad et al. [38] in farms with a population of less than 29 breeding females. Also Villari et al. [39] found that the prevalence in pig farms decreased beyond 50 animals. This could indicate that small farms increased risk of exposure to the agent as risk factors are distributed in few animals [40].
So it is likely that in the most densely populated farms, the hygiene, intensive management and more infrastructures can lead to the reduction of T. gondii in the environment [41].
Although in this study the presence of cats was not significantly associated with T. gondii, prevalence results suggest that cats may have an important role, and although they were not currently present, oocysts contamination may persist in the farms; feline species is crucial to increasing environmental pollution [26, 39, 42]. It is important to consider that other risk factors such as cannibalism have proved to be another route of infection of T. gondii when pigs eat tissue cysts from rodents or from other pigs. Place of food storage is another factor to take into consideration. In outdoors or in warehouses without control of cats, food contamination by oocysts may happen [10, 12, 39, 43].
In the present study, manual feeder was protective against the presence of T. gondii probably because in automatic feeders, the food is maintained for longer periods, increasing the possible contamination with oocysts or oocysts eliminated by cats; surplus of food in manual feeders is more regularly cleaned for the replacement of a new ration.
The findings reported here have important public health implications as they suggest that the pork produced in the Yucatan for human consumption is an important source of contamination with great potential for transmission of T. gondii. It is important to consider that children, pregnant women without any previous contact with the agent, immunosuppressed people, and individuals working in pig farms and slaughterhouses are vulnerable groups where prevention is essential [40, 44].
We conclude that there is a high presence of T. gondii in intensive pig-fattening systems of the state of Yucatan. There are risk factors that promote their presence causing reinfection and factors that limit their contact in pigs. The level of infection must be reduced on pig farms with special emphasis on the control of cats and rodents.
Conflict of Interests
The authors declare no conflict of interests in this working paper submitted.
Acknowledgments
The authors gratefully acknowledge Programa de Mejoramiento del Profesorado (PROMEP 103.5/07/2785) and Dra. Carmen Guzman Bracho from INDRE/SSA (National Institute of Epidemiological Reference) for providing the Toxoplasma gondii RH strain, and the students Cecilia Zapata-Campos and Veronica Aranda-Chan for their technical support in some of the laboratory tests described here.
Carrada-BravoT.Toxoplasmosis: parasitosis re-emergente del nuevo milenio200552151162DubeyJ. P.The history of Toxoplasma gondii—the first 100 years20085564674752-s2.0-5774917664210.1111/j.1550-7408.2008.00345.xMontoyaJ. G.LiesenfeldO.Toxoplasmosis20043639425196519762-s2.0-294254158310.1016/S0140-6736(04)16412-XLuftB. J.HafnerR.KorzunA. H.LeportC.AntoniskisD.BoslerE. M.BourlandD. D.UttamchandaniR.FuhrerJ.JacobsonJ.MorlatP.VildeJ. L.RemingtonJ. S.PhillipsC.GlauserM.ChaveJ.CliffordD.PowderlyW.KlebertM.Toxoplasmic encephalitis in patients with the acquired immunodeficiency syndrome19933291499510002-s2.0-002749380110.1056/NEJM199309303291403MontoyaJ. G.RemingtonJ. S.Toxoplasmic chorioretinitis in the setting of acute acquired toxoplasmosis19962322772822-s2.0-0029789925McAuleyJ.BoyerK. M.PatelD.MetsM.SwisherC.RoizenN.WoltersC.SteinL.SteinM.ScheyW.RemingtonJ.MeierP.JohnsonD.HeydemanP.HolfelsE.WithersS.MackD.BrownC.PattonD.McLeodR.Early and longitudinal evaluations of treated infants and children and untreated historical patients with congenital toxoplasmosis: the Chicago collaborative treatment trial199418138722-s2.0-0028013088HillD.DubeyJ. P.Toxoplasma gondii: transmission, diagnosis, and prevention20028106346402-s2.0-003680312110.1046/j.1469-0691.2002.00485.xCookA. J. C.GilbertR. E.BuffolanoW.ZuffereyJ.PetersenE.JenumP. A.FoulonW.SempriniA. E.Sources of toxoplasma infection in pregnant women: European multicentre case control study200032112712810.1136/bmj.321.7254.127RoghmannM. C.FaulknerC. T.LefkowitzA.PattonS.ZimmermanJ.MorrisJ. G.Decreased seroprevalence for Toxoplasma gondii in Seventh Day Adventists in Maryland19996057907922-s2.0-0032959254van der GiessenJ.FonvilleM.BouwknegtM.LangelaarM.VollemaA.Seroprevalence of Trichinella spiralis and Toxoplasma gondii in pigs from different housing systems in The Netherlands20071483-43713742-s2.0-3454796631510.1016/j.vetpar.2007.06.009DubeyJ. P.LeightyJ. C.BealV. C.AndersonW. R.AndrewsC. D.ThulliezP.National seroprevalence of Toxoplasma gondii in pigs19917745175212-s2.0-0025936132DubeyJ. P.WeigelR. M.SiegelA. M.ThulliezP.KitronU. D.MitchellM. A.MannelliA.Mateus-PinillaN. E.ShenS. K.KwokO. C. H.ToddK. S.Sources and reservoirs of Toxoplasma gondii infection on 47 swine farms in Illinois19958157237292-s2.0-002897062110.2307/3283961García-VazquezZ.CruzR. R.Díaz-GarcíaG.Hernández-BaumgartenO.Seroprevalence of Toxoplasma gondii infection in cattle, swine and goats in four Mexican states19931712713210.1016/0167-5877(93)90061-WHillD. E.ChirukandothS.DubeyJ. P.Biology and epidemiology of Toxoplasma gondii in man and animals20056141612-s2.0-26044470703DubeyJ. P.MurrellK. D.FayerR.Persistence of encysted Toxoplasma gondii in tissues of pigs fed oocysts19844510194119432-s2.0-0021690935DubeyJ. P.GambleH. R.HillD.SreekumarC.RomandS.ThulliezP.High prevalence of viable Toxoplasma gondii infection in market weight pigs from a farm in Massachusetts2002886123412382-s2.0-0036939248KijlstraA.JongertE.Control of the risk of human toxoplasmosis transmitted by meat20083812135913702-s2.0-5144910812310.1016/j.ijpara.2008.06.002Villamar-AnguloL.Barrera-WadgymarM. A.2006SAGARPAhttp://www.sagarpa.gob.mx/ganaderia/Publicaciones/Lists/Estudios%20de%20situacin%20actual%20y%20perspectiva/Attachments/14/sitpor06d.pdfINEGI (Instituto Nacional de Estadística, Geografía e Informática)2002Instituto Nacional de Estadistica, Geografía e Informática de México.Segura-CorreaJ. C.HonholdN.2000Yucatan, MexicoUniversidad Autónoma de YucatánJalalS.NordC. E.LappalainenM.EvengårdB.BuffalanoW.GuyE.JenumP.PellouxH.Stray-PedersenB.EdvinssonB.Rapid and sensitive diagnosis of Toxoplasma gondii infections by PCR200410109379392-s2.0-644422955410.1111/j.1469-0691.2004.00948.xCarlinR.DavisD.WeissM.SchultzB.TroyerD.Expression of early transcription factors Oct-4, Sox-2 and Nanog by porcine umbilical cord (PUC) matrix cells200641132-s2.0-3314448438610.1186/1477-7827-4-8SAS Institute2002Cary, NC, USASAS InstituteHillD. E.HaleyC.WagnerB.GambleH. R.DubeyJ. P.Seroprevalence of and risk factors for Toxoplasma gondii in the US swine herd using sera collected during the national animal health monitoring survey (Swine 2006)201057153592-s2.0-7404914873910.1111/j.1863-2378.2009.01275.xCavalcanteG. T.AguiarD. M.ChiebaoD.DubeyJ. P.RuizV. L. A.DiasR. A.CamargoL. M. A.LabrunaM. B.GennariS. M.Seroprevalence of Toxoplasma gondii antibodies in cats and pigs from Rural Western Amazon, Brazil20069248638642-s2.0-3374894244010.1645/GE-830R.1PoljakZ.DeweyC. E.FriendshipR. M.MartinS. W.ChristensenJ.OjkicD.WuJ.ChowE.Pig and herd level prevalence of Toxoplasma gondii in Ontario finisher pigs in 2001, 2003, and 200420087243033102-s2.0-48749126550LindP.HaugegaardJ.WingstrandA.HenriksenS. A.The time course of the specific antibody response by various ELISAS in pigs experimentally infected with Toxoplasma gondii19977111152-s2.0-003080639210.1016/S0304-4017(97)00010-1LehmannT.GrahamD. H.DahlE.SreekumarC.LaunerF.CornJ. L.GambleH. R.DubeyJ. P.Transmission dynamics of Toxoplasma gondii on a pig farm2003321351412-s2.0-003750363110.1016/S1567-1348(03)00067-4TizardI. R.2002SextaNew York, NY, USAMcGraw-HillSwitajK.MasterA.SkrzypczakM.ZaborowskiP.Recent trends in molecular diagnostics for Toxoplasma gondii infections20051131701762-s2.0-1484435720510.1111/j.1469-0691.2004.01073.xCastillo-MoralesV. J.Acosta VianaK. Y.Guzmán-MarínE.Jiménez-CoelloM.Segura-CorreaJ. C.Aguilar-CaballeroA. J.Ortega-PachecoA.Prevalence and risk factors of Toxoplasma gondii infection in domestic cats from the tropics of Mexico using serological and molecular Tests20122012652910810.1155/2012/529108DumétreA.DardéM. L.How to detec Toxoplasma gondii oocyst in enviroment samples20032765166110.1016/S0168-6445(03)00071-8DubeyJ. P.Toxoplasma gondii oocyst survival under defined temperatures19988448628652-s2.0-003187074410.2307/3284606DrewT. W.A review of evidence for immunosuppression due to Porcine Reproductive and Respiratory Syndrome Virus200031127392-s2.0-0033629104CorreaR.CedeñoI.de EscobarC.FuentesI.Increased urban seroprevalence of Toxoplasma gondii infecting swine in Panama20081531-29112-s2.0-4134909055910.1016/j.vetpar.2008.01.017DubeyJ. P.AjiokaJ. W.SoldatiD.The life of cycle of Toxoplasma gondii2007Oxford, UKHorizon Bioscience37KleinS.WendtM.BaumgärtnerW.WohlseinP.Systemic toxoplasmosis and concurrent porcine circovirus-2 infection in a pig2009140208211Assadi-RadA. M.NewJ. C.PattonS.Risk factors associated with transmission of Toxoplasma gondii to sows kept in different management systems in Tennessee19955742892972-s2.0-002906232510.1016/0304-4017(94)00677-5VillariS.VescoG.PetersenE.CrispoA.BuffolanoW.Risk factors for toxoplasmosis in pigs bred in Sicily, Southern Italy20091611-2182-s2.0-6314916418510.1016/j.vetpar.2009.01.019WeigelR. M.DubeyJ. P.SiegelA. M.HoeflingD.ReynoldsD.HerrL.KitronU. D.ShenS. K.ThulliezP.FayerR.Prevalence of antibodies to Toxoplasma gondii in swine in Illinois in 1992199520611174717512-s2.0-0029314354HoveT.LindP.MukaratirwaS.Seroprevalence of Toxoplasma gondii infection in domestic pigs reared under different management systems in Zimbabwe20057232312372-s2.0-33644828520Solaymani-MohammadiS.PetriW. A.Zoonotic implications of the swine-transmitted protozoal infections20061403-41892032-s2.0-3375069533710.1016/j.vetpar.2006.05.012DubeyJ. P.A review of toxoplasmosis in pigs1986193-41812232-s2.0-0022618124DubeyJ. P.HillD. E.JonesJ. L.HightowerA. W.KirklandE.RobertsJ. M.MarcetP. L.LehmannT.ViannaM. C. B.MiskaK.SreekumarC.KwokO. C. H.ShenS. K.GambleH. R.Prevalence of viable Toxoplasma gondii in beef, chicken, and pork from retail meat stores in the United States: risk assessment to consumers2005915108210932-s2.0-2844448854510.1645/GE-683.1