Profile of natural <i>Trypanosoma cruzi</i> infection among dogs from rural areas of southern Espírito Santo, Brazil

Pontes, Beathriz Giostri; Kuster, Marieta Cristina Couto; Freitas, Letícia Azeredo de; Barbosa, Wagner Miranda; Machado-Coelho, George Luiz Lins; Zanini, Marcos Santos; Bahia, Maria Terezinha; Santos, Fabiane Matos dos

doi:10.1590/0037-8682-0712-2021

ABSTRACT

Background:

The emergence of Trypanosoma cruzi infection via oral transmission has a habitual character in its primitive endemic cycle. Recent findings revealed the first death by oral transmission of T. cruzi in the state of Espírito Santo, Brazil, in 2012, which was recorded in the rural area of Guarapari. This study evaluated the characteristics related to the occurrence of natural T. cruzi infection among dogs from the rural areas of Alegre and Iconha, municipalities of Espírito Santo.

Methods:

Logistic regression analysis of factors contributing to serological detection of T. cruzi in dogs was performed in environments where Espírito Santo’s Department of Health Surveillance had previously notified triatomines positive for Trypanosoma spp. from 2014 to 2017.

Results:

A total of 36 dogs were analyzed, of which 10 (27.77%) tested positive, one was borderline (2.79%), and 25 tested negative (69.44%) for T. cruzi infection. São Caetano, a district from the Iconha municipality, presented a 25 times greater chance for the detection of positive tests (OR:25; 95% CI; 2.37->100). Dogs with updated mandatory vaccination presented with a lower risk of positive serodiagnosis (OR:0.12; 95% CI: 0.02-0.63).

Conclusions:

Our results highlight for the first time the occurrence of natural T. cruzi canine infection, detected in the municipality of Iconha, mainly among dogs with un-updated mandatory vaccines in the district of São Caetano.

Keywords:
Chagas disease; Trypanosoma cruzi; Canis familiaris; Natural infection; Serology.

INTRODUCTION

The protozoan parasite Trypanosoma (Schyzotripanum) cruzi (T. cruzi) is the etiologic agent of Chagas disease, an infectious disease classified by the World Health Organization as a tropical and neglected disease due to poor socioeconomic conditions of infected individuals living in endemic countries¹1. Chagas C. Nova tripanozomiase humana. Estudos sobre a morfolojia e o ciclo evolutivo do Schizotrypanum cruzi n. gen., n. sp., ajente etiolójico de nova entidade mórbida do homem. Mem Inst Oswaldo Cruz. 1909;1:159-218.^,²2. Chagas disease (American trypanosomiasis): Epidemiology [homepage on the Internet]. Geneva: World Health Organization [cited 2019 Aug 18]. Available from: https://www.who.int/chagas/epidemiology/en/.
https://www.who.int/chagas/epidemiology/... . Characterized as the etiological agent of complex zoonosis, T. cruzi is mainly transmitted in the enzootic cycle by approximately 130 species of triatomines of the Reduviidae family, capable of infecting over 150 species of domestic and wild mammals³3. Jansen AM, Roque ALR. Domestic and wild mammalian reservoir. In: Telleria J, Tibayrenc M, editors. American trypanosomiasis Chagas Disease one hundred years of research. London: Elsevier; 2010:249-76..

Brazil and other endemic countries in the southern cone of South America fortunately achieved a reduction in T. cruzi vectorial transmission after the development of a control program for Triatoma infestans, a domiciliated triatomine species⁴4. Moncayo A. Chagas Disease: Current epidemiological trends after the interruption of vectorial and transfusional transmission in the Southern Cone countries. Mem Inst Oswaldo Cruz . 2003;98(5):577-91.. However, oral T. cruzi transmission has become noteworthy in Brazil, mainly related to the incorrect manipulation and ingestion of food products from the vector ecosystem, or from direct contact with infected wild triatomines in endemic regions⁵5. Labello Barbosa R, Dias VL, Lorosa ES, Góes Costa E, Pereira KS, Gilioli R, et al. Virulence of Trypanosoma cruzi from vector and reservoir in natura açaí pulp resulting in food-borne acute Chagas disease at Pará State, Brazil. Exp Parasitol. 2018;197:68-75.^,⁶6. Dario MA, Rodrigues MS, Barros JHS, Xavier SCC, Andrea PS, Roque ALR, et al. Ecological scenario and Trypanosoma cruzi DTU characterization of a fatal acute Chagas disease case transmitted orally (Espírito Santo state, Brazil). Parasit Vectors. 2016;9(1):477.. In this new epidemiological scenario of oral transmission, the Amazon region comprises approximately 92.3% human Chagas cases in Brazil, most of which are reported in Pará as a result of food contamination by infected triatomines, mainly due to improper handling of the açaí palm-tree fruit⁷7. Xavier SCC, Roque ALR, Bilac D, Araújo VAL, Neto SFC, Lorosa ES, et al. Distantiae Transmission of Trypanosoma cruzi: A New Epidemiological Feature of Acute Chagas Disease in Brazil. PLoS Negl Trop Dis. 2014;8(5):e2878..

The state of Espírito Santo, Brazil, has a low incidence of autochthonous human cases originating from infected sylvatic triatomine bugs in an epidemiological scenario wherein Triatoma vitticeps exhibits highest rate of natural infection, mainly attributed to its close relationship with wild mammals not refractory to T. cruzi⁸8. Dario MA, Maranhão PHC, Dos Santos GQ, Rocha MM, Falqueto A, Da Silva LFCF, et al. Environmental influence onTriatoma vitticepsoccurrence andTrypanosoma cruziinfection in the Atlantic Forest of south-eastern Brazil. Geospat Health. 2021;16(2):997.^,⁹9. Santos CB, Leite GR, Ferreira GEM, Ferreira AL. Natural infection of Triatoma vitticeps (Stal, 1859) with flagellates morphologically similar to Trypanosoma cruzi (Chagas, 1909) in Espírito Santo Sate. Rev Soc Bras Med Trop. 2006;39(1):89-91.. In 2012, a fatal acute case of 2-year-old was reported after accidental oral ingestion of one T. cruzi-infected triatomine in Rio da Prata, a rural area of Guarapari⁶6. Dario MA, Rodrigues MS, Barros JHS, Xavier SCC, Andrea PS, Roque ALR, et al. Ecological scenario and Trypanosoma cruzi DTU characterization of a fatal acute Chagas disease case transmitted orally (Espírito Santo state, Brazil). Parasit Vectors. 2016;9(1):477.. Therefore, some studies were conducted to understand the ecology of transmission cycles, considering environmental variables such as triatomine species and wild and domestic mammal species responsible for parasite maintenance surrounding Rio da Prata⁶6. Dario MA, Rodrigues MS, Barros JHS, Xavier SCC, Andrea PS, Roque ALR, et al. Ecological scenario and Trypanosoma cruzi DTU characterization of a fatal acute Chagas disease case transmitted orally (Espírito Santo state, Brazil). Parasit Vectors. 2016;9(1):477.^,¹⁰10. Dario MA, Lisboa CV, Costa LM, Moratelli R, Nascimento MP, Costa LP, et al. High Trypanosoma spp. diversity is maintained by bats and triatomines in Espirito Santo state, Brazil. PLoS One. 2017;12(11):e0188412.. In this rural area of Espírito Santo state, T. vitticeps and Panstrongylus geniculatus were reported to be infected by T. cruzi along with wildlife species. In addition, domestic dogs play an important role as a link between the wild and domestic transmission cycles, as they have been shown seropositivity for T. cruzi. Dogs living in locations surrounding the 2012 death were considered a single event, regardless of the address of the acute Chagas death in Rio da Prata⁶6. Dario MA, Rodrigues MS, Barros JHS, Xavier SCC, Andrea PS, Roque ALR, et al. Ecological scenario and Trypanosoma cruzi DTU characterization of a fatal acute Chagas disease case transmitted orally (Espírito Santo state, Brazil). Parasit Vectors. 2016;9(1):477.^,¹⁰10. Dario MA, Lisboa CV, Costa LM, Moratelli R, Nascimento MP, Costa LP, et al. High Trypanosoma spp. diversity is maintained by bats and triatomines in Espirito Santo state, Brazil. PLoS One. 2017;12(11):e0188412..

Serological surveys performed in Northeast Brazil also found dogs naturally infected with T. cruzi, highlighting the role of these animals as parasite reservoirs in households, with the presence of vector Triatoma brasiliensis¹¹11. Freitas YBN, Souza CSF, Magalhães JM, Sousa MLR, d’Escoffier LN, Valle TZ, et al. Natural infection by Trypanosoma cruzi in triatomines and seropositivity for Chagas disease of dogs in rural areas of Rio Grande do Norte, Brazil. Rev Soc Bras Med Trop . 2018;51(2):190-7.^,¹²12. Araújo-Neto VT, Honorato NRM, Santana RO, Barbosa-Silva AN, Guedes PMM, Chiari E, et al. Trypanosoma cruzi circulating among dogs and triatomines in the endemic countryside of the State of Rio Grande do Norte, Brazil. Acta Trop. 2019;200:105067.. Dogs parasitized by T. cruzi are considered sentinels for Chagas disease in enzootic areas¹³13. Crisante G, Rojas A, Teixeira MMG, Añez N. Infected dogs as a risk factor in the transmission of human Trypanosoma cruzi infection in western Venezuela. Acta Trop . 2006; 98(3):247-54.^,¹⁴14. Cardinal MV, Orozco MM, Enriquez GF, Ceballos LA, Gaspe MS, Alvarado-Otegui JA, et al. Heterogeneities in the ecoepidemiology of Trypanosoma cruzi infection in rural communities of the Argentinean Chaco. Am J Trop Med Hyg. 2014;90(6):1063-73.. Furthermore, the evolution of trypanosomiasis by T. cruzi in dogs is similar to the development of clinical forms found in chronic human cases, as demonstrated in experimental studies of pathologic and chemotherapeutic approaches using the dog model of T. cruzi infection¹⁵15. Tafuri WL, Lana M, Chiari E, Caliari MV, Bambirra EA, Rios-Leite VH, et al. Dogs as experimental models for the study of the natural course of Chagas disease. Rev Soc Bras Med Trop . 1988;21(2):77-82.^,¹⁶16. Santos FM, Lima WG, Gravel AS, Martins TAF, Talvani A, Torres RM, et al. Cardiomyopathy prognosis after benznidazole treatment in chronic canine Chagas’ disease. J Antimicrob Chemother. 2012;67(8):1987-95..

A dog survey was conducted in the municipalities of Alegre and Iconha with the aim of evaluating the characteristics that support natural canine T. cruzi infection in an enzootic area with infected sylvatic triatomine bugs; both cities are in the south of Espírito Santo.

METHODS

Geographic origin

Alegre is a municipality located in southeast Brazil, in southern Espírito Santo, covering a total area of 772.7 km². The population was estimated to be 30,768 in 2010, which was Brazil’s last national census¹⁷17. Instituto Brasileiro de Geografia e Estatística [homepage on the Internet]. Brasil Espírito Santo Alegre; 2020 [cited 2020 Apr 24]. Available from: Available from: https://cidades.ibge.gov.br/brasil/es/alegre/panorama .
https://cidades.ibge.gov.br/brasil/es/al... . The climate is hot and rainy in the summer; however, dry in the winter, with an average annual temperature of 22.2°C, varying between 16.9 and 29.0°C. The landscape of Alegre is rugged and elevated, and shallow mineral soils can be found. The municipality is endowed with a vast and dense drainage basin, with the Atlantic Forest as its predominant biome and Rio Itapemirim as the main river. The local economy is based on agriculture.

Iconha is also located in southeastern Brazil, in southern Espírito Santo. Its municipality area is 202.9 km² in total, and its population was estimated to be 12,523 in 2010¹⁸18. Instituto Brasileiro de Geografia e Estatística [homepage on the Internet]. Brasil Espírito Santo Iconha; 2020 [cited 2020 Apr 24]. Available from: Available from: https://cidades.ibge.gov.br/brasil/es/iconha/panorama .
https://cidades.ibge.gov.br/brasil/es/ic... . The tropical climate has an average annual temperature of 23.0°C. The highest annual rainfall occurs between October and January. This municipality includes many mountains owing to its rugged topography, 15% wavy, and only 5% flat. Iconha confines itself to the west with Alfredo Chaves, a neighboring municipality of Guarapari. The local municipal economy is based on agriculture, especially banana production, and the urban area of Iconha has large networks of road carriers.

Study area and sample definition

This cross-sectional study was conducted in the rural localities of Alegre and Iconha, Espírito Santo, Brazil. Each municipality was evaluated for existence of dogs living in households and peridomestic environments, with previous notification of triatomines positive for Trypanosoma spp. The evaluation considered several dog behaviors, clinical symptoms and signs commonly evaluated during an overall veterinary clinical anamnesis, even considering the classical limitation of signs that could be found, for example, in T. cruzi-infected asymptomatic animals or in the coexistence of other parasitic infections in animals naturally infected with T. cruzi.

The area included in this study was characterized by the presence of dogs in households and peridomestic environments, presenting triatomine bugs reported as positive for Trypanosoma spp. between 2014 and 2017, according to unpublished data provided by “Entomology and Malacology Center of Espírito Santo, State Health Department of Espírito Santo (Nemes-SESA/ES)”.

Dogs living in regions with no notification of triatomines or with triatomines reported as negative for Trypanosoma spp. between 2014 and 2017 in the municipalities of Alegre and Iconha were excluded from the study. Another important exclusion criterion was non-consent of owners. Dogs that presented with aggressive behavior or other previously diagnosed diseases were also excluded.

Ethical aspects

All procedures and experimental protocols were performed according to the CONCEA (National Council for Control of Animal Experimentation) and behavioral instructions for the use of animals in research from Brazil. Research project number 20/2018 was approved by the Research Ethics Committee on the Use of Animals of the Federal University of Espírito Santo (CEUA-UFES) on 09/04/2018. The owners of all the dogs included in this study signed an informed consent form that contained descriptions of all the procedures to be performed. The possibility of publication of results in scientific articles and disclosures at events, safeguarding the identity, as well as the freedom to suspend participation at any time, and the absence of monetary gratification were also described in the consent form.

Dog survey

The active search for dogs was conducted with the support of community health agents in all domiciles and peri-domiciles previously characterized for inclusion in the study. In total, 27 domiciles and 27 peri-domiciles were researched, but only four households and 11 peri-domicile environments of T. cruzi-infected triatomine notifications effectively participated in the study during 2018 and 2019. Animal owners were interviewed regarding each dog’s demographic characteristics, habits, and clinical records. These characteristics were: age, sex, municipality of origin, district of origin, environment (domiciliary or peridomiciliary), area in the municipality (urban or rural), localization of dog (outside household or in transit), contactants (absent or people and animals), vaccination (updated or outdated), deworming (updated or outdated), ectoparasites (absence or presence), food - whether adequate (consisting of dog food) or inadequate (such as raw viscera from wild or domestic animals), Canine Body Mass Index-CBMI (eutrophy or irregular), Body Condition Score-BCS (eutrophy or irregular), whether normal or altered for hydration, capillary refill time, mucous, respiratory rate, heart rate, temperature, abdominal palpation, cardiopulmonary auscultation, lymph nodes (non-reactive or reactive), and normal or altered for any other clinical findings which included different signs detected at the moment of evaluation, such as secretions, excretions, discharge and volume increases. CBMI and BCS were measured to evaluate the clinical condition of the dogs¹⁹19. Scheraiber M, Sabchuk TT, Silva JR, Domingues LP, Ramos TA, Félix AP et al. Effect of soybean hulls on blood biochemical profiles and body condition of dogs. Rev Bras Zootec. 2016;45(12):755-9.^,²⁰20. Laﬂamme DP. Development and validation of a body condition score system for dogs. Canine Pract. 1997;22(4):10-5..

Blood samples were collected by puncturing the cephalic vein, and after centrifugation, the serum samples were stored in microtubes and packed at -80 °C until enzyme-linked immunosorbent assay (ELISA) was performed. Blood samples were collected from each dog’s household following hygiene and safety standards. For the anti-T. cruzi immunoglobulin G (IgG) antibody assay using an in-house ELISA protocol, epimastigote forms of T. cruzi Y strain grown in acellular culture medium (liver tryptose infusion - LIT) were used as antigen²¹21. Voller A, Bidwell DE, Bartlett A. Enzyme immunoassays in diagnostic medicine. Theory and practice. Bull World Health Organ. 1976;53(1):55-65.^,²²22. Vitor RW, Chiari E. Evaluation of Trypanosoma cruzi antigens for the indirect hemagglutination reaction. II. Antigens of different samplings and evolutive forms. Rev Inst Med Trop Sao Paulo. 1987;29(3):183-8.. The sera of 10 dogs maintained under experimental conditions at the Federal University of Ouro Preto were used as uninfected controls to estimate the cut-off through their average absorbance plus two standard deviations²³23. Caldas IS, Menezes APJ, Diniz LF, Nascimento AFS, Novaes RD, Caldas S, Bahia MT. Parasitaemia and parasitic load are limited targets of the aetiological treatment to control the progression of cardiac fibrosis and chronic cardiomyopathy in Trypanosoma cruzi-infected dogs. Acta Trop . 2019;189:30-8.^,²⁴24. Guedes PMM, Veloso VM, Tafuri LW, Galvão MC, Carneiro CM, Lana M, et al. The dog as model for chemotherapy of the Chagas’ disease. Acta Trop . 2002;84(1):9-17.. Furthermore, the sera of two other dogs experimentally infected with T. cruzi, also provided by the Federal University of Ouro Preto, were used as positive controls. Serum samples with absorbance values above the cut-off were indicative of reactivity for T. cruzi antigen, serum absorbance equal to at least one decimal case of the cut-off was classified as borderline, and values of absorbance below the cut-off were considered non-reagents. The ELISA was performed twice for all serum samples that showed borderline absorbance during the first examination. This in-house ELISA, previously validated for an experimental dog model of T. cruzi infection¹⁶16. Santos FM, Lima WG, Gravel AS, Martins TAF, Talvani A, Torres RM, et al. Cardiomyopathy prognosis after benznidazole treatment in chronic canine Chagas’ disease. J Antimicrob Chemother. 2012;67(8):1987-95.^,²³23. Caldas IS, Menezes APJ, Diniz LF, Nascimento AFS, Novaes RD, Caldas S, Bahia MT. Parasitaemia and parasitic load are limited targets of the aetiological treatment to control the progression of cardiac fibrosis and chronic cardiomyopathy in Trypanosoma cruzi-infected dogs. Acta Trop . 2019;189:30-8.^,²⁴24. Guedes PMM, Veloso VM, Tafuri LW, Galvão MC, Carneiro CM, Lana M, et al. The dog as model for chemotherapy of the Chagas’ disease. Acta Trop . 2002;84(1):9-17., was used for the first time to test the serum reactivity for anti-T. cruzi immunoglobulin G (IgG) in dogs from rural endemic areas with parasitized reduviid bugs.

Statistical analysis

All characteristic variables collected from each dog and the serology results of the dogs’ blood samples were used for statistical analysis. Serum samples classified as borderline and those with absorbance below the cut-off were grouped as non-positive. Binary logistic regression analysis was performed to estimate the probability of association or risk of detecting serological reactivity to T. cruzi antigens in the presence of other characteristic variables. Serological reactivity to T. cruzi antigens was chosen as the dependent variable, and dogs were categorized as either positive and non-positive, or reactive and non-reactive. Data were analyzed using the STATA version 14.1 (Stata Corp., College Station, United States), expressed as simple frequency and percentage, with 95% confidence interval. A significance level of 5% was used to evaluate the odds ratio (OR) for each variable.

RESULTS

Environmental evaluation and definition of dogs’ sample

After exclusion, although other localities of Alegre and Iconha municipalities could have presented triatomines, a total of eight districts were evaluated in this study (Figure 1)²⁵25. Maps of the municipalities of Alegre and Iconha - administrative limits [homepage on the Internet]. Instituto Jones dos Santos Neves [updated 2012 Aug 23; cited 2020 Jan 20]. Available from: Available from: http://www.ijsn.es.gov.br/mapas/ .
http://www.ijsn.es.gov.br/mapas/... . In the municipality of Alegre (Figure 1A), the districts of Celina and Café were identified with two dogs living in households notified with Trypanosoma spp.-infected triatomines, and a total of nine dogs were detected in peridomiciles of places notified with triatomines positive for Trypanosoma spp. (Figure 2). In addition, six dogs from peridomestic environments were excluded because of their aggressive and inappropriate behavior. A total of five dogs were evaluated in Alegre, compriosing a sample of two dogs from domiciles and three dogs from peridomiciles notified with Trypanosoma spp.-infected triatomines between 2014 and 2017 (Figure 2). The triatomines previously reported by Nemes-SESA/ES were positive for Trypanosoma spp. in these localities from Alegre, which belonged to the T. vitticeps species.

FIGURE 1:
²⁵25. Maps of the municipalities of Alegre and Iconha - administrative limits [homepage on the Internet]. Instituto Jones dos Santos Neves [updated 2012 Aug 23; cited 2020 Jan 20]. Available from: Available from: http://www.ijsn.es.gov.br/mapas/ .
http://www.ijsn.es.gov.br/mapas/... Representative maps (adaptation of IJSN, 2012)²⁵ of the municipalities with dogs evaluated for Trypanosoma cruzi infection, due to the previous detection of triatomines positive for Trypanosoma spp. between 2014 and 2017: (A) Alegre, Espírito Santo state, Brazil; and (B) Iconha, Espírito Santo state, Brazil. The geographic area of localities with dogs evaluated in each municipality are highlighted.

FIGURE 2:
Flowchart of selected dogs in households and peridomiciles from regions notified with triatomines positive for Trypanosoma spp. between 2014 and 2017 in the municipalities of Alegre and Iconha, Espírito Santo, Brazil. *(DH) Dogs from households. **(DP) Dogs from peri-domiciles.

Furthermore, six districts of Iconha were also integrated into the study region of study known by the following names: Solidão, Tocaia, Morro da Palha, Pedra D’Água, Mesa Grande, and São Caetano (Figure 1B). Firstly, 32 dogs from households and 42 dogs from peridomiciles were identified among these districts notified in Iconha with Trypanosoma spp.-infected triatomines between 2014 and 2017 (Figure 2). After the exclusion of dogs without their owners’ consent or exclusion of dogs with aggressive behavior, a total of 31 dogs were included in integrated the sample of animals assessed in the municipality of Iconha, nine dogs from households, and 22 dogs from peridomestic environments of notified places with triatomines positive for Trypanosoma spp. (Figure 2). Triatomines previously reported by Nemes-SESA/ES as positive for Trypanosoma spp. in these localities of Iconha between 2014 and 2017 belonged to T. vitticeps and P. geniculatus species.

**Risk factors for natural T. cruzi infection in dogs**

T. cruzi serological testing showed that 27.77% (10/36) of the assessed dogs were seropositive. One dog had a borderline anti-T. cruzi antigen, and the other 25 animals underwent a seronegative ELISA test (Figure 3). All T. cruzi-seropositive dogs lived in Iconha, two of which were from the district of Solidão, two dogs from Tocaia, and one animal from Morro da Palha, and 50% of seropositive dogs (5/10) lived in São Caetano (Figure 4). Although four dogs were evaluated in Pedra D’Água (Iconha-ES) and four dogs were also tested in Mesa Grande (Iconha-ES), none of them presented seropositive results for T. cruzi by ELISA (Figure 4). Additionally, five dogs were evaluated in Alegre, among which three dogs from the district of Celina and two from the district of Café tested seronegative for T. cruzi (Figure 4).

FIGURE 3:
Serum level of anti-Trypanosoma cruzi antibodies detected in 36 dogs from households and peridomiciles previously reported with positive triatomines for Trypanosoma spp. in Alegre and Iconha municipalities, Espírito Santo state, Brazil.

FIGURE 4:
Locations evaluated in the municipalities of Alegre and Iconha, Espírito Santo state, Brazil, and quantitative identification of dogs that presented seropositive tests for detection of Trypanosoma cruzi antigens.

Concerning eco-epidemiological characteristics, a median age of 36 months was verified among the overall sample of dogs evaluated (95% CI = 5-168 months). Dogs that tested seropositive for T. cruzi had a median age of 36 months (95% CI = 18-72) similar to dogs with seronegative tests (median age, 95% CI = 5-168) (Table 1). The other characteristic variables analyzed were expressed as percentages of occurrence within the 36 dogs’ samples, followed by the percentages categorized as positive and non-positive dogs, since the serological reactivity to T. cruzi antigens was chosen as the dependent variable for bivariate logistic regression analysis (Table 1). Among all characteristic parameters measured, only district and vaccination variables were significantly associated with serological reactivity for T. cruzi (p < 0.05). Concerning the variable district, São Caetano district from Iconha municipality presented a 25 times greater chance of occurrence of T. cruzi seropositive dogs in relation to all the other seven districts evaluated in Alegre and Iconha municipalities (OR:25; p < 0.01). Furthermore, dogs with updated mandatory immunization protocols had an 88% lower risk of positive serological results for T. cruzi infection (OR:0.12; p < 0.05) (Table 1).

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TABLE 1:
Characteristic variables tested by binary logistic regression analysis to assess the existence of associations with serological reactivity to anti-Trypanosoma cruzi antibodies detected in 36 dogs from Alegre and Iconha municipalities, Espírito Santo state, Brazil.

According to the binary logistic regression analysis, no significant associations were observed between serological reactivity for T. cruzi and all the other variables evaluated in this study (p > 0.05) (Table 1). However, it is noteworthy that these parameters were investigated for the first time in the study region, indicating interesting findings, mainly among 10 T. cruzi seroreactive dogs.

The current epidemiological profile of Chagas disease, mainly based on oral transmission, represents a new challenge for public authorities because previously employed control measures were not effective for this infectious disease, which is considered a foodborne illness. Some studies have shown the occurrence of natural T. cruzi infection in dogs, a sentinel reservoir for human infection, through vector and oral route transmissions in endemic areas¹¹11. Freitas YBN, Souza CSF, Magalhães JM, Sousa MLR, d’Escoffier LN, Valle TZ, et al. Natural infection by Trypanosoma cruzi in triatomines and seropositivity for Chagas disease of dogs in rural areas of Rio Grande do Norte, Brazil. Rev Soc Bras Med Trop . 2018;51(2):190-7.

12. Araújo-Neto VT, Honorato NRM, Santana RO, Barbosa-Silva AN, Guedes PMM, Chiari E, et al. Trypanosoma cruzi circulating among dogs and triatomines in the endemic countryside of the State of Rio Grande do Norte, Brazil. Acta Trop. 2019;200:105067.

13. Crisante G, Rojas A, Teixeira MMG, Añez N. Infected dogs as a risk factor in the transmission of human Trypanosoma cruzi infection in western Venezuela. Acta Trop . 2006; 98(3):247-54.^-¹⁴14. Cardinal MV, Orozco MM, Enriquez GF, Ceballos LA, Gaspe MS, Alvarado-Otegui JA, et al. Heterogeneities in the ecoepidemiology of Trypanosoma cruzi infection in rural communities of the Argentinean Chaco. Am J Trop Med Hyg. 2014;90(6):1063-73.^,²⁶26. Arce-Fonseca M, Carrillo-Sánchez SC, Molina-Barrios RM, Martínez-Cruz M, Cedillo-Cobián JR, Henao-Díaz YA, et al. Seropositivity for Trypanosoma cruzi in domestic dogs from Sonora, Mexico. Infect Dis Poverty. 2017;6(1):120.. The incidence of acute Chagas disease due to oral transmission is growing and expanding in several South American countries, including Brazil, mainly in the Amazon Basin⁷7. Xavier SCC, Roque ALR, Bilac D, Araújo VAL, Neto SFC, Lorosa ES, et al. Distantiae Transmission of Trypanosoma cruzi: A New Epidemiological Feature of Acute Chagas Disease in Brazil. PLoS Negl Trop Dis. 2014;8(5):e2878.. Autochthonous human cases and acute oral transmission have also been reported in other localities characterized by wild triatomines branding the existence of T. cruzi biological cycle, as verified in Espírito Santo⁶6. Dario MA, Rodrigues MS, Barros JHS, Xavier SCC, Andrea PS, Roque ALR, et al. Ecological scenario and Trypanosoma cruzi DTU characterization of a fatal acute Chagas disease case transmitted orally (Espírito Santo state, Brazil). Parasit Vectors. 2016;9(1):477..

In the detection of anti-T. cruzi antibodies, our results demonstrated that dogs were exposed to infection by T. cruzi associated with non-domiciled bugs, mainly in the district of São Caetano in Iconha, which presented a 25 times greater chance of disease among the total number of animals evaluated in the other districts. Notably, our data showed the greatest risk of T. cruzi infection in dogs near Guarapari, in the region where death was verified by acute Chagas disease in 2012 and transmitted by oral ingestion of a wild T. cruzi-infected triatomine⁶6. Dario MA, Rodrigues MS, Barros JHS, Xavier SCC, Andrea PS, Roque ALR, et al. Ecological scenario and Trypanosoma cruzi DTU characterization of a fatal acute Chagas disease case transmitted orally (Espírito Santo state, Brazil). Parasit Vectors. 2016;9(1):477.. Previous results also indicated the presence of canine natural T. cruzi infection in Guarapari, varying from 8% to 13% of borderline seroreactivity and 28% of seroconversion to anti-T. cruzi antibodies in dogs near Rio da Prata⁶6. Dario MA, Rodrigues MS, Barros JHS, Xavier SCC, Andrea PS, Roque ALR, et al. Ecological scenario and Trypanosoma cruzi DTU characterization of a fatal acute Chagas disease case transmitted orally (Espírito Santo state, Brazil). Parasit Vectors. 2016;9(1):477.^,¹⁰10. Dario MA, Lisboa CV, Costa LM, Moratelli R, Nascimento MP, Costa LP, et al. High Trypanosoma spp. diversity is maintained by bats and triatomines in Espirito Santo state, Brazil. PLoS One. 2017;12(11):e0188412..

However, none of the five dogs from Alegre presented seroreactivity for anti-T. cruzi antibodies, although all of them lived in an area with non-domiciliated triatomines reported previously by Nemes-SESA/ES as infected by Trypanosoma spp. Other studies have shown the presence of the triatomine species T. vitticeps in 27 municipalities of Espírito Santo, including localities neighboring Alegre and Iconha. More than 85% of the triatomines captured were infected with flagellates morphologically similar to T. cruzi⁸8. Dario MA, Maranhão PHC, Dos Santos GQ, Rocha MM, Falqueto A, Da Silva LFCF, et al. Environmental influence onTriatoma vitticepsoccurrence andTrypanosoma cruziinfection in the Atlantic Forest of south-eastern Brazil. Geospat Health. 2021;16(2):997.^,⁹9. Santos CB, Leite GR, Ferreira GEM, Ferreira AL. Natural infection of Triatoma vitticeps (Stal, 1859) with flagellates morphologically similar to Trypanosoma cruzi (Chagas, 1909) in Espírito Santo Sate. Rev Soc Bras Med Trop. 2006;39(1):89-91.. Recently, molecular approaches confirmed the presence of the flagellate species T. cruzi infecting T. vitticeps and P. geniculatus from the Atlantic Forest in southeastern Espírito Santo, in regions such as Caparaó and Litoral Sul, which geographically encompass the municipalities of Alegre and Iconha²⁷27. Dario MA, Andrade TES, Santos CB, Fux B, Brandão AA, Falqueto A. Molecular characterization of Trypanosoma cruzi samples derived from Triatoma vitticeps and Panstrongylus geniculatus of the Atlantic rainforest, southeast Brazil. Parasite. 2018;25(9):1-9.. Considering this background and the results of our study, future investigations using specific tools such as molecular approaches may be relevant to better clarify the role of dogs as sentinels of T. cruzi infection in the studied area surrounding Alegre, mainly because of the lower number of dogs evaluated in this municipality.

The routine uses of domestic animals, mainly dogs, as sentinels to monitor the epidemiological risk of Chagas disease has been previously proposed, and the diverse spectrum of dog surveys performed in American countries has confirmed the risk for T. cruzi infection¹¹11. Freitas YBN, Souza CSF, Magalhães JM, Sousa MLR, d’Escoffier LN, Valle TZ, et al. Natural infection by Trypanosoma cruzi in triatomines and seropositivity for Chagas disease of dogs in rural areas of Rio Grande do Norte, Brazil. Rev Soc Bras Med Trop . 2018;51(2):190-7.

12. Araújo-Neto VT, Honorato NRM, Santana RO, Barbosa-Silva AN, Guedes PMM, Chiari E, et al. Trypanosoma cruzi circulating among dogs and triatomines in the endemic countryside of the State of Rio Grande do Norte, Brazil. Acta Trop. 2019;200:105067.

13. Crisante G, Rojas A, Teixeira MMG, Añez N. Infected dogs as a risk factor in the transmission of human Trypanosoma cruzi infection in western Venezuela. Acta Trop . 2006; 98(3):247-54.^-¹⁴14. Cardinal MV, Orozco MM, Enriquez GF, Ceballos LA, Gaspe MS, Alvarado-Otegui JA, et al. Heterogeneities in the ecoepidemiology of Trypanosoma cruzi infection in rural communities of the Argentinean Chaco. Am J Trop Med Hyg. 2014;90(6):1063-73.^,²⁶26. Arce-Fonseca M, Carrillo-Sánchez SC, Molina-Barrios RM, Martínez-Cruz M, Cedillo-Cobián JR, Henao-Díaz YA, et al. Seropositivity for Trypanosoma cruzi in domestic dogs from Sonora, Mexico. Infect Dis Poverty. 2017;6(1):120.^,²⁸28. de Sousa Pereira H, Scofield A, Júnior PSB, Lira Dos Santos D, de Sousa Siqueira J, Chaves JF, et al. Chagas disease in urban and peri-urban environment in the Amazon: Sentinel hosts, vectors, and the environment. Acta Trop . 2021;217:105858.

29. Kruse CS, Guerra DA, Gelillo-Smith R, Vargas A, Krishnan L, Stigler-Granados P. Leveraging Technology to Manage Chagas Disease by Tracking Domestic and Sylvatic Animal Hosts as Sentinels: A Systematic Review. Am J Trop Med Hyg . 2019;101(5):1126-34.^-³⁰30. Dario MA, Lisboa CV, Xavier SCDC, D'Andrea PS, Roque ALR, Jansen AM.TrypanosomaSpecies in Small Nonflying Mammals in an Area With a Single Previous Chagas Disease Case. Front Cell Infect Microbiol. 2022;12:812708.. The seropositivity rate was 4.44% in the presence of anti-T. cruzi as demonstrated in dog sera from Sonora, Mexico, and the data highlighted the direct correlation between seropositivity rate in dogs and the presence of antibodies against T. cruzi in humans in different regions of Mexico²⁶26. Arce-Fonseca M, Carrillo-Sánchez SC, Molina-Barrios RM, Martínez-Cruz M, Cedillo-Cobián JR, Henao-Díaz YA, et al. Seropositivity for Trypanosoma cruzi in domestic dogs from Sonora, Mexico. Infect Dis Poverty. 2017;6(1):120.. Recent studies conducted in Brazil showed seropositivity levels of 11%¹¹11. Freitas YBN, Souza CSF, Magalhães JM, Sousa MLR, d’Escoffier LN, Valle TZ, et al. Natural infection by Trypanosoma cruzi in triatomines and seropositivity for Chagas disease of dogs in rural areas of Rio Grande do Norte, Brazil. Rev Soc Bras Med Trop . 2018;51(2):190-7. and 40%¹²12. Araújo-Neto VT, Honorato NRM, Santana RO, Barbosa-Silva AN, Guedes PMM, Chiari E, et al. Trypanosoma cruzi circulating among dogs and triatomines in the endemic countryside of the State of Rio Grande do Norte, Brazil. Acta Trop. 2019;200:105067. for anti-T. cruzi antibodies among dogs from rural areas of Rio Grande do Norte state, and confirmed the relevant sentinel role of dogs as domestic reservoirs of T. cruzi in the biological cycle predominantly maintained by Triatoma brasiliensis in this endemic area¹¹11. Freitas YBN, Souza CSF, Magalhães JM, Sousa MLR, d’Escoffier LN, Valle TZ, et al. Natural infection by Trypanosoma cruzi in triatomines and seropositivity for Chagas disease of dogs in rural areas of Rio Grande do Norte, Brazil. Rev Soc Bras Med Trop . 2018;51(2):190-7.^,¹²12. Araújo-Neto VT, Honorato NRM, Santana RO, Barbosa-Silva AN, Guedes PMM, Chiari E, et al. Trypanosoma cruzi circulating among dogs and triatomines in the endemic countryside of the State of Rio Grande do Norte, Brazil. Acta Trop. 2019;200:105067..

In addition to the evaluation of the seropositivity rate of Chagas disease in dogs from regions with T. cruzi-infected triatomines, a broad analysis of findings in canine disease exceeds the elucidations regarding the development of control strategies to be implemented in endemic regions. Interesting epidemiological findings revealed that the habit of hunting and offering raw viscera and fresh blood to domestic dogs increased the risk of oral infection and transformed the dog into the main domestic reservoir for T. cruzi in the endemic Chagas disease region of a rural community in Chaco, Argentina¹⁴14. Cardinal MV, Orozco MM, Enriquez GF, Ceballos LA, Gaspe MS, Alvarado-Otegui JA, et al. Heterogeneities in the ecoepidemiology of Trypanosoma cruzi infection in rural communities of the Argentinean Chaco. Am J Trop Med Hyg. 2014;90(6):1063-73.. This study evaluated diverse parameters measured in dogs from domiciles and peri-domiciles previously reported with Trypanosoma spp. infected triatomines in Alegre and Iconha, Espírito Santo, Brazil. Although only the district of São Caetano and updated vaccination were associated with the risk of canine natural Chagas disease, several other interesting parameters were measured for the first time in the geographical region studied, out of which the occurrence of inadequate feeding was verified in 32% of the dogs seropositive for anti-T. cruzi antibody.

Our results showed that dogs with updated mandatory vaccination protocols in this Brazilian region had a lower risk of seropositivity for T. cruzi infection. The mandatory vaccines for dogs in Brazil do not include a specific vaccine for canine Chagas disease, considering the non-availability of this vaccine to date. However, our data demonstrate for the first time in a natural endemic area that even a non-specific T. cruzi vaccine may offer a lower risk for natural canine T. cruzi infection. Perhaps future investigations will be able to better explain these results, probably implicated in the improvement of the innate immune system or in other responses to immunological benefits achieved by dogs with updated mandatory immunization protocols in the Brazilian municipalities of Alegre and Iconha. Research on vaccines to prevent T. cruzi infection has demonstrated the potential of finding effective prophylactic options³¹31. Basso B, Marini V, Gauna D, Frias M. Vaccination of dogs with Trypanosoma rangeli induces antibodies against Trypanosoma cruzi in a rural area of Córdoba, Argentina. Mem Inst Oswaldo Cruz . 2016;111(4):271-4.

32. Arce-Fonseca M, Carbajal-Hernández AC, Lozano-Camacho M, Carrilo-Sánchez SdC, Roldán FJ, Aranda-Fraustro A, et al. DNA Vaccine Treatment in Dogs Experimentally Infected with Trypanosoma cruzi. J Immunol Res. 2020;2020:9794575.^-³³33. Williams T, Guerrero-Ros I, Ma Y, Santos FM, Scherer PE, Gordillo R, et al. Induction of effective immunity against Trypanosoma cruzi. Infect Immun. 2020;88(4):1-50.. Dogs immunized by a vaccine with non-pathogenic Trypanosoma rangeli epimastigotes had induced antibodies against T. cruzi for more than three years in their natural habitat in a rural area of Córdoba, Argentina³¹31. Basso B, Marini V, Gauna D, Frias M. Vaccination of dogs with Trypanosoma rangeli induces antibodies against Trypanosoma cruzi in a rural area of Córdoba, Argentina. Mem Inst Oswaldo Cruz . 2016;111(4):271-4.. The pBCSSP4 plasmid immunotherapy, a DNA vaccine treatment, preserved the cardiac structure and function to a greater extent, and prevented cardiomegaly in beagle dogs experimentally infected with T. cruzi³²32. Arce-Fonseca M, Carbajal-Hernández AC, Lozano-Camacho M, Carrilo-Sánchez SdC, Roldán FJ, Aranda-Fraustro A, et al. DNA Vaccine Treatment in Dogs Experimentally Infected with Trypanosoma cruzi. J Immunol Res. 2020;2020:9794575.. Recent findings of a vaccine established by a T. cruzi strain expressing GFP-DDDHA induced by trimethoprim-lactate, which results in the death of intracellular parasites, revealed a very strong protection against re-infection in mice³³33. Williams T, Guerrero-Ros I, Ma Y, Santos FM, Scherer PE, Gordillo R, et al. Induction of effective immunity against Trypanosoma cruzi. Infect Immun. 2020;88(4):1-50.. Immune cells demonstrated earlier and stronger protective responses in immunized mice after re-infection with T. cruzi³³33. Williams T, Guerrero-Ros I, Ma Y, Santos FM, Scherer PE, Gordillo R, et al. Induction of effective immunity against Trypanosoma cruzi. Infect Immun. 2020;88(4):1-50..

CONCLUSIONS

An overall analysis of our findings implies efforts to search for control strategies and prophylactic options to prevent T. cruzi-infectivity spread by non-domestic triatomines that have access to human domiciles in enzootic rural areas, since dogs with updated mandatory vaccines presented a lower risk of natural infection in this endemic scenario. To the best of our knowledge, this is the first time that epidemiological factors involving T. cruzi natural infection with the participation of dogs as sentinels of the disease have been analyzed in the southern Espírito Santo Brazilian municipalities of Iconha and Alegre. The greatest risk for T. cruzi infection was verified among dogs from São Caetano, the nearest rural district to the previous notification of fatal acute oral Chagas disease in Espírito Santo. Future studies should evaluate the efficacy of specific dog vaccines to enhance the level of human protection by decreasing T. cruzi parasite load in triatomines and hosts dispersed in this new scenario of growing risk to oral transmission and human infectiousness in the endemic regions of Chagas disease.

ACKNOWLEDGMENTS

We offer our deepest thanks to the institution Federal University of Espírito Santo that provided technical support for the development and implementation of this study, to the “Entomology and Malacology Center of Espírito Santo, Espírito Santo State Department of Health (Nemes-SESA/ES)” and to all the workers of Health Surveillance of Alegre and Iconha municipalities, mainly to Rodrigo Lopes do Nascimento and João Carlos Bezerra Nunes. We thank all the dogs’ owner which allowed their participation in this study.

REFERENCES

¹
Chagas C. Nova tripanozomiase humana. Estudos sobre a morfolojia e o ciclo evolutivo do Schizotrypanum cruzi n. gen, n. sp., ajente etiolójico de nova entidade mórbida do homem. Mem Inst Oswaldo Cruz. 1909;1:159-218.
²
Chagas disease (American trypanosomiasis): Epidemiology [homepage on the Internet]. Geneva: World Health Organization [cited 2019 Aug 18]. Available from: https://www.who.int/chagas/epidemiology/en/
» https://www.who.int/chagas/epidemiology/en/
³
Jansen AM, Roque ALR. Domestic and wild mammalian reservoir. In: Telleria J, Tibayrenc M, editors. American trypanosomiasis Chagas Disease one hundred years of research. London: Elsevier; 2010:249-76.
⁴
Moncayo A. Chagas Disease: Current epidemiological trends after the interruption of vectorial and transfusional transmission in the Southern Cone countries. Mem Inst Oswaldo Cruz . 2003;98(5):577-91.
⁵
Labello Barbosa R, Dias VL, Lorosa ES, Góes Costa E, Pereira KS, Gilioli R, et al. Virulence of Trypanosoma cruzi from vector and reservoir in natura açaí pulp resulting in food-borne acute Chagas disease at Pará State, Brazil. Exp Parasitol. 2018;197:68-75.
⁶
Dario MA, Rodrigues MS, Barros JHS, Xavier SCC, Andrea PS, Roque ALR, et al. Ecological scenario and Trypanosoma cruzi DTU characterization of a fatal acute Chagas disease case transmitted orally (Espírito Santo state, Brazil). Parasit Vectors. 2016;9(1):477.
⁷
Xavier SCC, Roque ALR, Bilac D, Araújo VAL, Neto SFC, Lorosa ES, et al. Distantiae Transmission of Trypanosoma cruzi: A New Epidemiological Feature of Acute Chagas Disease in Brazil. PLoS Negl Trop Dis. 2014;8(5):e2878.
⁸
Dario MA, Maranhão PHC, Dos Santos GQ, Rocha MM, Falqueto A, Da Silva LFCF, et al. Environmental influence onTriatoma vitticepsoccurrence andTrypanosoma cruziinfection in the Atlantic Forest of south-eastern Brazil. Geospat Health. 2021;16(2):997.
⁹
Santos CB, Leite GR, Ferreira GEM, Ferreira AL. Natural infection of Triatoma vitticeps (Stal, 1859) with flagellates morphologically similar to Trypanosoma cruzi (Chagas, 1909) in Espírito Santo Sate. Rev Soc Bras Med Trop. 2006;39(1):89-91.
¹⁰
Dario MA, Lisboa CV, Costa LM, Moratelli R, Nascimento MP, Costa LP, et al. High Trypanosoma spp. diversity is maintained by bats and triatomines in Espirito Santo state, Brazil. PLoS One. 2017;12(11):e0188412.
¹¹
Freitas YBN, Souza CSF, Magalhães JM, Sousa MLR, d’Escoffier LN, Valle TZ, et al. Natural infection by Trypanosoma cruzi in triatomines and seropositivity for Chagas disease of dogs in rural areas of Rio Grande do Norte, Brazil. Rev Soc Bras Med Trop . 2018;51(2):190-7.
¹²
Araújo-Neto VT, Honorato NRM, Santana RO, Barbosa-Silva AN, Guedes PMM, Chiari E, et al. Trypanosoma cruzi circulating among dogs and triatomines in the endemic countryside of the State of Rio Grande do Norte, Brazil. Acta Trop. 2019;200:105067.
¹³
Crisante G, Rojas A, Teixeira MMG, Añez N. Infected dogs as a risk factor in the transmission of human Trypanosoma cruzi infection in western Venezuela. Acta Trop . 2006; 98(3):247-54.
¹⁴
Cardinal MV, Orozco MM, Enriquez GF, Ceballos LA, Gaspe MS, Alvarado-Otegui JA, et al. Heterogeneities in the ecoepidemiology of Trypanosoma cruzi infection in rural communities of the Argentinean Chaco. Am J Trop Med Hyg. 2014;90(6):1063-73.
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Arce-Fonseca M, Carrillo-Sánchez SC, Molina-Barrios RM, Martínez-Cruz M, Cedillo-Cobián JR, Henao-Díaz YA, et al. Seropositivity for Trypanosoma cruzi in domestic dogs from Sonora, Mexico. Infect Dis Poverty. 2017;6(1):120.
²⁷
Dario MA, Andrade TES, Santos CB, Fux B, Brandão AA, Falqueto A. Molecular characterization of Trypanosoma cruzi samples derived from Triatoma vitticeps and Panstrongylus geniculatus of the Atlantic rainforest, southeast Brazil. Parasite. 2018;25(9):1-9.
²⁸
de Sousa Pereira H, Scofield A, Júnior PSB, Lira Dos Santos D, de Sousa Siqueira J, Chaves JF, et al. Chagas disease in urban and peri-urban environment in the Amazon: Sentinel hosts, vectors, and the environment. Acta Trop . 2021;217:105858.
²⁹
Kruse CS, Guerra DA, Gelillo-Smith R, Vargas A, Krishnan L, Stigler-Granados P. Leveraging Technology to Manage Chagas Disease by Tracking Domestic and Sylvatic Animal Hosts as Sentinels: A Systematic Review. Am J Trop Med Hyg . 2019;101(5):1126-34.
³⁰
Dario MA, Lisboa CV, Xavier SCDC, D'Andrea PS, Roque ALR, Jansen AM.TrypanosomaSpecies in Small Nonflying Mammals in an Area With a Single Previous Chagas Disease Case. Front Cell Infect Microbiol. 2022;12:812708.
³¹
Basso B, Marini V, Gauna D, Frias M. Vaccination of dogs with Trypanosoma rangeli induces antibodies against Trypanosoma cruzi in a rural area of Córdoba, Argentina. Mem Inst Oswaldo Cruz . 2016;111(4):271-4.
³²
Arce-Fonseca M, Carbajal-Hernández AC, Lozano-Camacho M, Carrilo-Sánchez SdC, Roldán FJ, Aranda-Fraustro A, et al. DNA Vaccine Treatment in Dogs Experimentally Infected with Trypanosoma cruzi J Immunol Res. 2020;2020:9794575.
³³
Williams T, Guerrero-Ros I, Ma Y, Santos FM, Scherer PE, Gordillo R, et al. Induction of effective immunity against Trypanosoma cruzi Infect Immun. 2020;88(4):1-50.

Financial Support: This study was funded by Programa de Pós-graduação em Ciências Veterinárias - Universidade Federal do Espírito Santo - Brasil; Escola de Medicina - Universidade Federal de Ouro Preto - Brasil. “This study was financed in part by the Coordenação de Aperfeiçoamento de Pessoal de Nível Superior - Brasil (CAPES) - Finance Code 001”.

Publication Dates

Publication in this collection
16 Dec 2022
Date of issue
2022

History

Received
20 Dec 2021
Accepted
26 Sept 2022

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] ¹
Chagas C. Nova tripanozomiase humana. Estudos sobre a morfolojia e o ciclo evolutivo do Schizotrypanum cruzi n. gen, n. sp., ajente etiolójico de nova entidade mórbida do homem. Mem Inst Oswaldo Cruz. 1909;1:159-218.

[2] ²
Chagas disease (American trypanosomiasis): Epidemiology [homepage on the Internet]. Geneva: World Health Organization [cited 2019 Aug 18]. Available from: https://www.who.int/chagas/epidemiology/en/
» https://www.who.int/chagas/epidemiology/en/

[3] ³
Jansen AM, Roque ALR. Domestic and wild mammalian reservoir. In: Telleria J, Tibayrenc M, editors. American trypanosomiasis Chagas Disease one hundred years of research. London: Elsevier; 2010:249-76.

[4] ⁴
Moncayo A. Chagas Disease: Current epidemiological trends after the interruption of vectorial and transfusional transmission in the Southern Cone countries. Mem Inst Oswaldo Cruz . 2003;98(5):577-91.

[5] ⁵
Labello Barbosa R, Dias VL, Lorosa ES, Góes Costa E, Pereira KS, Gilioli R, et al. Virulence of Trypanosoma cruzi from vector and reservoir in natura açaí pulp resulting in food-borne acute Chagas disease at Pará State, Brazil. Exp Parasitol. 2018;197:68-75.

[6] ⁶
Dario MA, Rodrigues MS, Barros JHS, Xavier SCC, Andrea PS, Roque ALR, et al. Ecological scenario and Trypanosoma cruzi DTU characterization of a fatal acute Chagas disease case transmitted orally (Espírito Santo state, Brazil). Parasit Vectors. 2016;9(1):477.

[7] ⁷
Xavier SCC, Roque ALR, Bilac D, Araújo VAL, Neto SFC, Lorosa ES, et al. Distantiae Transmission of Trypanosoma cruzi: A New Epidemiological Feature of Acute Chagas Disease in Brazil. PLoS Negl Trop Dis. 2014;8(5):e2878.

[8] ⁸
Dario MA, Maranhão PHC, Dos Santos GQ, Rocha MM, Falqueto A, Da Silva LFCF, et al. Environmental influence onTriatoma vitticepsoccurrence andTrypanosoma cruziinfection in the Atlantic Forest of south-eastern Brazil. Geospat Health. 2021;16(2):997.

[9] ⁹
Santos CB, Leite GR, Ferreira GEM, Ferreira AL. Natural infection of Triatoma vitticeps (Stal, 1859) with flagellates morphologically similar to Trypanosoma cruzi (Chagas, 1909) in Espírito Santo Sate. Rev Soc Bras Med Trop. 2006;39(1):89-91.

[10] ¹⁰
Dario MA, Lisboa CV, Costa LM, Moratelli R, Nascimento MP, Costa LP, et al. High Trypanosoma spp. diversity is maintained by bats and triatomines in Espirito Santo state, Brazil. PLoS One. 2017;12(11):e0188412.

[11] ¹¹
Freitas YBN, Souza CSF, Magalhães JM, Sousa MLR, d’Escoffier LN, Valle TZ, et al. Natural infection by Trypanosoma cruzi in triatomines and seropositivity for Chagas disease of dogs in rural areas of Rio Grande do Norte, Brazil. Rev Soc Bras Med Trop . 2018;51(2):190-7.

[12] ¹²
Araújo-Neto VT, Honorato NRM, Santana RO, Barbosa-Silva AN, Guedes PMM, Chiari E, et al. Trypanosoma cruzi circulating among dogs and triatomines in the endemic countryside of the State of Rio Grande do Norte, Brazil. Acta Trop. 2019;200:105067.

[13] ¹³
Crisante G, Rojas A, Teixeira MMG, Añez N. Infected dogs as a risk factor in the transmission of human Trypanosoma cruzi infection in western Venezuela. Acta Trop . 2006; 98(3):247-54.

[14] ¹⁴
Cardinal MV, Orozco MM, Enriquez GF, Ceballos LA, Gaspe MS, Alvarado-Otegui JA, et al. Heterogeneities in the ecoepidemiology of Trypanosoma cruzi infection in rural communities of the Argentinean Chaco. Am J Trop Med Hyg. 2014;90(6):1063-73.

[15] ¹⁵
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Characteristic variables		Total		*Serological reactivity to anti-Trypanosoma cruzi* IgG antibody**				Odds Ratio	Confidence interval (95%)		p value
				Seropositive		Seronegative
Age (months)	36 (5-168)				36 (18-72)		36 (5-168)	1
Sex (%)	Female	19	52.78%	5/19	26.31%	14/19	73.68%	1.66	0.27	5.02	0.836
	Male	17	47.22%	5/17	29.41%	12/17	70.58%
Municipality (%)	Alegre	5	13.89%	0/5	0.00%	5/5	100.00%	1
	Iconha	31	86.11%	10/31	32.25%	21/31	67.74%
District (%)	Other districts	30	83.33%	5/30	16.66%	25/30	83.34%	25	2.37	262.65	0.007*
	São Caetano	6	16.67%	5/6	83.34%	1/6	16.66%
Environment (%)	Domiciliary	11	30.56%	4/11	36.36%	7/11	63.63%	0.55	0.11	2.56	0.448
	Peridomiciliary	25	69.44%	6/25	24.00%	19/25	76.00%
Area (%)	Urban	3	8.33%	0/3	0.00%	3/3	100.00%	1
	Rural	33	91.67%	10/33	30.30%	23/33	69.69%
Localization of dog (%)	Outside	19	52.78%	3/19	15.78%	16/19	84.21%	3.73	0.77	17.87	0.099
	In transit	17	47.22%	7/17	41.17%	10/17	58.82%
Contactants (%)	Absent	0	0.00%	0/0	0.00%	0/0	0.00%	1
	People/animals	36	100%	10/36	27.78%	26/36	72.22%
Vaccination (%)	Updated	10	27.78%	6/10	60.00%	4/10	40.00%	0.12	0.02	0.63	0.012*
	Outdated	26	72.22%	4/26	15.38%	22/26	84.61%
Deworming (%)	Updated	12	33.33%	4/12	33.33%	8/12	66.66%	0.66	0.14	3.03	0.60
	Outdated	24	66.67%	6/24	25%	18/24	75%
Ectoparasites (%)	Absence	10	27.78%	4/10	40%	6/10	60%	0.45	0.94	2.14	0.316
	Presence	26	72.22%	6/26	23.07%	20/26	76.92%
Feed (%)	Adequate	11	30.56%	2/11	18.18%	9/11	81.81%	2.11	0.36	12.15	0.4
	Inadequate	25	69.44%	8/25	32%	17/25	68%
CBMI (%)	Eutrophy	11	30.56%	3/11	27.27%	8/11	81.81%	1.03	0.21	5.07	0.964
	Irregular	25	69.44%	7/25	28%	18/25	72%
BCS (%)	Eutrophy	21	58.33%	8/21	38.09%	13/21	61.90%	0.25	0.44	1.4	0.116
	Irregular	15	41.67%	2/15	13.33%	13/15	86.66%
Hydration (%)	Normal	35	97.22%	10/35	28.57%	25/35	71.42%	1
	Altered	1	2.78%	0/1	0.00%	1/1	100.00%
Capillary refill time (%)	Normal	35	97.22%	10/35	28.57%	25/35	71.43%	1
	Altered	1	2.78%	0/1	0.00%	1/1	100.00%
Mucous (%)	Normocolored	31	86.11%	9/31	29.03%	22/31	70.96%	0.61	0.05	62.464	0.678
	Altered	5	13.89%	1/5	20%	4/5	80%
Respiratory rate (%)	Normal	11	30.56%	1/11	9.09%	10/11	90.90%	5.62	0.61	51.37	0.126
	Altered	25	69.44%	9/25	36%	16/25	64%
Heart rate (%)	Normal	32	88.89%	9/32	28.12%	23/32	71.87%	0.85	0.77	9.30	0.895
	Altered	4	11.11%	1/4	25%	3/4	75%
Temperature (%)	Normal	33	97.06%	10/33	30.30%	23/33	69.69%	1
	Altered	1	2.94%	0/1	0.00%	1/1	100.00%
Lymph nodes (%)	Non-reactive	31	86.11%	8/31	25.80%	23/31	74.19%	1.91	0.26	13.63	0.516
	Reactive	5	13.89%	2/5	40%	3/5	60%
Abdominal palpation (%)	Normal	34	94.44%	10/34	29.41%	24/34	70.58%	1
	Altered	2	5.56%	0/2	0.00%	2/2	100.00%
Cardiopulmonary auscultation (%)	Normal	32	88.89%	10/32	31.25%	22/32	68.75%	1
	Altered	4	11.11%	0/4	0.00%	4/4	100.00%
Other clinical findings (%)	Normal	23	63.89%	8/23	34.78%	15/23	65.21%	0.34	0.06	1.93	0.22
	Altered	13	36.11%	2/13	15.38%	11/13	84.61%

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