Rev Inst Med Trop São Paulo. 2018;60:e33 Page 1 of 6

ORIGINAL ARTICLE
http://dx.doi.org/10.1590/S1678-9946201860033

1Universidade de São Paulo, Faculdade 
de Saúde Pública, São Paulo, São Paulo, 
Brazil

2Universidade de São Paulo, Instituto de 
Medicina Tropical de São Paulo, São Paulo, 
São Paulo, Brazil

3Divisão de Vigilância de Zoonoses, 
Laboratórios de Identificação e Pesquisa 
em Fauna Sinantrópica, São Paulo, São 
Paulo Brazil

4Universidade Estadual de Campinas, 
Departamento de Biologia Animal, 
Campinas, São Paulo, Brazil 

5Secretaria de Estado da Saúde, 
Superintendência de Controle de 
Endemias, Divisão de Programas 
Especiais, São Paulo, São Paulo Brazil

6Secretaria de Estado da Saúde, 
Superintendência de Controle de 
Endemias, Departamento de Combate a 
Vetores, São Paulo, São Paulo Brazil

7Universidade Estadual Paulista Júlio de 
Mesquita Filho, Departamento de Ciências 
Biológicas, Araraquara, São Paulo, Brazil

Correspondence to: Mauro Toledo Marrelli 
Universidade de São Paulo, Faculdade 
de Saúde Pública, Departamento de 
Epidemiologia, Av. Dr. Arnaldo, 715, CEP 
01246-904, São Paulo, SP, Brazil 
Tel: +55 11 30617922

E-mail: mmarelli@usp.br

Received: 1 March 2018

Accepted: 24 May 2018

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

Occurrences of triatomines (Hemiptera: Reduviidae) and first 
reports of Panstrongylus geniculatus in urban environments 

in the city of Sao Paulo, Brazil

Walter Ceretti-Junior1, Daniel Pagotto Vendrami2, Marco Otavio de Matos-
Junior3, Aline Rimoldi-Ribeiro4, Julia Vono Alvarez3, Sandro Marques3, 
Agnaldo Nepomuceno Duarte5, Rubens Antonio da Silva6, João Aristeu da 
Rosa7, Mauro Toledo Marrelli1,2

ABSTRACT

This note reports on occurrences of triatomine species in the city of Sao Paulo, Brazil, 

registered between 1988 and 2017. Records of triatomines captured in Sao Paulo are based 

on specimens received spontaneously from Health Surveillance Centers, Health Centers 

and Zoonosis Control Centers in the city as well as from citizens. Species were identified 

morphologically at the Public Health Entomology Laboratory, Faculty of Public Health, 

University of Sao Paulo, where the triatomines, which are vectors of Chagas disease, were 

tested for Trypanosoma cruzi infection. The first reported occurrence of triatomine bugs 

in urban Sao Paulo was in 1988. The specimen, which was captured in Jardim Sao Luiz 

district, was from the genus Panstrongylus and was registered as Panstrongylus sp. but was 

not sexed. Since this first recorded occurrence, the following species have been found in 

the city: Panstrongylus geniculatus (2 occurrences), P. megistus (15 occurrences), Triatoma 

infestans (1 occurrence) and T. sordida (3 occurrences). In this paper, the importance of 

reporting occurrences of triatomine bugs in the city of Sao Paulo, one of the largest metropolis 

in the world, is discussed with an emphasis on P. megistus. The occurrences discussed here 

indicate the importance of entomological surveillance for these vectors even in urban centers 

although the possibility of vector transmission of Chagas disease in these centers is very low.

KEYWORDS: Hemiptera. Reduviidae. Triatominae species. Entomological surveillance. 

Urban center, Trypanosoma cruzi, Chagas disease.

INTRODUCTION

Chagas disease is caused by the protozoan Trypanozoma cruzi and is an endemic 
disease in 21 Latin American countries1. It is one of 17 diseases classified as 
neglected tropical diseases by the World Health Organization, and it is estimated 
that there are around 8 million people worldwide infected by this parasite1, with 
Brazil accounting for more than 1.1 million of them2. Trypanosoma cruzi is naturally 
transmitted to humans and other mammals through feces and urine eliminated by 
infected triatomine bugs. Transmission occurs during or shortly after the vector sucks 
blood from the host, when its feces or urine penetrate the host’s skin or mucous 
membranes3. Other forms of transmission include the oral transmission following 
ingestion of food contaminated with T. cruzi, blood transfusion, organ transplantation 
from donors with Chagas disease, congenital transmission, breastfeeding and 
accidental transmission4.

mailto:mmarelli%40usp.br?subject=


Ceretti-Junior et al.

Rev Inst Med Trop São Paulo. 2018;60:e33Page 2 of 6

Triatomines are currently distributed in five tribes 
and 18 genera, totaling 153 recognized species5. Of these 
genera, Panstrongylus, Rhodnius and Triatoma have the 
most described epidemiologically important species6. 
This note reports on occurrences of triatomine bugs in the 
municipality of Sao Paulo, SP, Brazil, registered between 
1988 and 2017 by the Synanthropic Fauna Identification and 
Research Laboratory (Labfauna), Zoonosis Surveillance 
Division, City of Sao Paulo, and the Public Health 
Entomology Laboratory (LESP), Faculty of Public Health, 
University of Sao Paulo.

MATERIALS AND METHODS

The records of triatomines captured in the city of 
Sao Paulo discussed in this note are based on specimens 
sent spontaneously to Labfauna and LESP by Health 
Surveillance Centers, Health Centers and Zoonosis Control 
Centers in the city as well as by citizens. 

Morphological species identification and confirmation 
and, when possible, testing of specimens for T. cruzi 

infection is normally performed by LESP that keeps  
records of occurrences of triatomines dating from 1983. 
The records refer to triatomine bugs in Brazil as well as in 
other countries. 

Labfauna has provided taxonomic identification of 
synanthropic animals since 1982. The service, which is 
free, consists of the receiving, taxonomic identification 
and preservation or disposal of specimens and preparation 
of technical reports. Specimens received at the laboratory 
act as sentinels for the presence of species associated with 
human health risks. Here we discuss only occurrences of 
triatomines in the municipality of Sao Paulo.

RESULTS

The results are shown in Table 1 in alphabetical order 
by species and consist of sex, parasitological tests results, 
district where the specimen came from, corresponding 
coordinates and year of registration. 

Although it was initiated in the years 1982 (Labfauna) 
and 1983 (LESP), the first occurrence of triatomines 

Table 1 - Occurrences of Triatominae species in the city of Sao Paulo from 1988 to 2017 recorded by Labfauna and LESP, in 
chronological order. The following data are shown for each occurrence: sex, result of parasitological examination, district where 
the specimen was captured, coordinates and year of registration. (N: number of specimens; NS: not sexed; NI: no information)

Taxon N/Sex Infect. T. cruzi District Coordinates Year

P. geniculatus 1/NS NI Cursino 23°36'10" S 46°37'32" W 1999

P. geniculatus 1/♂ NI Morumbi 23º35’46” S 46º41’42” W 2014

P. megistus 1/NS NI Sacoma 23°38'57" S 46°36'49" W 1996

P. megistus 1/♂ NI Jabaquara 23°37’33” S 46°38’26” W 1999

P. megistus 1/♂ NI Jabaquara 23°39’33” S 46°38’48” W 1999

P. megistus 1/NS NI Cursino 23°38'30" S 46°36'45" W 2003

P. megistus 1/♂ NI Cursino 23°37’43” S 46°37’12” W 2003

P. megistus 1/NS NI Jaragua 23°27'21" S 46°45'’46" W 2004

P. megistus 1/NS NI Jardim Angela 23°41'41" S 46°45'30" W 2005

P. megistus 1/NS NI Cursino 23°37'50" S 46°36'47" W 2007

P. megistus 1/♂ NI Jaragua 23°27'50" S 46°45'15" W 2007

P. megistus 1/♀ NI Jabaquara 23°38'7" S 46°38'39" W 2007

P. megistus 1/♂ Positive Jabaquara 23°39'18" S 46°38'39" W 2011

P. megistus 1/♂ NI Pedreira 23°41'51" S 46°37'46" W 2012

P. megistus 1/♀ Negative Sacoma 23°38'30" S 46°36'45" W 2014

P. megistus 1/♀ NI Raposo Tavares 23°36'10" S 46°47'43” W 2015

P. megistus 1/♀ NI Raposo Tavares 23°36'19.31"S 46°47'22" W 2017

Panstrongylus sp. 1/NS NI Jardim São Luiz 23°42'23.17"S 46°44'21." W 1988

T. infestans 1/♂ NI Vila Mariana 23°35’51” S 46°39’65” W 2004

T. sordida 1/♂ NI Jose Bonifacio 23°32'43.98"S 46°26'17" W 2008

T. sordida 1/♀ NI Vila Curuça 23°31'42" S 46°23'49” W 2013

T. sordida 1/♀ NI Vila Prudente 23°35'40" S 46°34'53" W 2017



Rev Inst Med Trop São Paulo. 2018;60:e33

Occurrences of triatomines (Hemiptera: Reduviidae) and first reports of Panstrongylus geniculatus in urban environments in the city of Sao Paulo, Brazil

Page 3 of 6

reported by these laboratories in the city of Sao Paulo was 
in 1988. The specimen, which was captured in the Jardim 
Sao Luiz district, was from the genus Panstrongylus and 
was registered as Panstrongylus sp. but was not sexed. Since 
this first occurrence, the following species of triatomine 
bugs have been found in Sao Paulo: P. geniculatus 
(2 occurrences), P. megistus (15 occurrences), T. infestans 
(1 occurrence) and T. sordida (3 occurrences). None of the 
reports indicated domiciliation of the insect. Most of the 
vectors occurrences in the municipality of Sao Paulo are 
related to areas in the South of the city that are near remnants 
of the Atlantic Rainforest (Figure 1). Among the triatomines 
submitted to parasitological examination, one P. megistus 
specimen, a male captured in the district of Jabaquara, was 
positive for T. cruzi, according to Ribeiro et al.7.

DISCUSSION

The city of Sao Paulo, one of the largest metropolis in 
the world with an estimated population of 12 million, the 
largest in the Southern hemisphere, suffers from severe 
environmental stress. Because of an extensive human 
interference in the natural environment, the remaining 
forest fragments are now found only in parks, gardens and 
environmental protection areas8,9.

The city of Sao Paulo is located in what was formerly the 
Atlantic rainforest, an environment with high biodiversity 
considered one of the 23 “biodiversity hotspots” 
worldwide10. Despite the intense expansion of the city in 
the last five decades, there have been sporadic occurrences 
of triatomine bugs on the outskirts of Sao Paulo, some in 
unusual situations7,11

.

The only occurrence of T. infestans reported in the 
city of Sao Paulo was in 2004 in the men’s restroom at 
the Dante Pazzanese Hospital, a national reference center 
for treatment of Chagas disease. The specimen may have 
escaped from the triatomine colonies maintained by the 
hospital for xenodiagnosis. In 2006, Brazil received the 
international certification for interruption of transmission 
of Chagas disease by this species from the Pan American 
Health Organization12,13.

In the State of Sao Paulo, a campaign against the vector 
of Chagas disease began in 195114,15. Although T. infestans 
was eliminated from the State by 1990 as a result of the 
campaign, control activities were not interrupted because 
of the possibility of sporadic passive reintroduction of 
T. infestans in isolated locations, as reported by Leite et al.14 
following the finding of 109 specimens of this species in the 
municipality of Paulinia, in the State of Sao Paulo, between 
1999 and 2000. This was the last reported occurrence of 
the species in the State.

One reason for continued triatomine surveillance and 
control activities in the city of Sao Paulo was the presence 
of species considered important in the transmission of 
T. cruzi, such as T. sordida and P. megistus, in large areas 
of Brazil, including the State of Sao Paulo. These species 
are found colonizing households mainly in annexes and 
outhouses. Another reason for continued surveillance was 
the report of invasions of households by Rhodnius neglectus 
in the area of the State corresponding to the Eastern Plateau, 
Peripheral Depression and Western Plateau and by Triatoma 
tibiamaculata on the State coastline15.

In the case of T. sordida, it is most likely that specimens 
were taken to the capture locations by passive dispersion 
as the residents in these locations reported that they had 
returned from trips to endemic regions. Another possibility 
is the dispersion by animals, particularly birds, as T. sordida 
feeds preferentially on birds16. Nymphs and eggs of the 
species can be dispersed over large areas extending far 
from the original source of infestation/colonization. The 
species has a widespread distribution and is found in 
Argentina, Bolivia, Uruguay and Paraguay and the States 
of Bahia, Goias, Mato Grosso, Mato Grosso do Sul, Minas 
Gerais, Parana, Pernambuco, Piaui, Rio Grande do Sul, 
Santa Catarina and Sao Paulo in Brazil17,18. In Sao Paulo 
and other States, it is found mainly in cerrado (savannah-
like grasslands) biomes. It is the most captured vector of 
Chagas disease, and there have been numerous reports of 
the species in chicken coops in peridomestic areas with a 
low T. cruzi infection rate16,19,20.

Triatoma sordida populations infected by T. cruzi persist 
even after insecticide has been sprayed because they are 
autochthonous to the territories where they occur and, after 

Figure 1 - Occurrences of triatomines in the city of Sao Paulo 
from 1982 to 2017 recorded by Labfauna and LESP



Ceretti-Junior et al.

Rev Inst Med Trop São Paulo. 2018;60:e33Page 4 of 6

sheltering in the peridomestic area, can reinfest dwellings 
once the residual effect of the insecticide has worn off16,21.

Most captures of P. megistus in the city of Sao Paulo 
have been in neighborhoods on the Southern outskirts of the 
city in areas close to Sao Paulo Zoo, Safari Zoo, the Botanic 
Gardens and the USP Science and Technology Park, all 
of which receive large numbers of visitors (Table 1). This 
suggests that populations of this species remain in forest 
fragments, where they can perpetuate the T. cruzi sylvatic 
transmission cycle within the boundaries of the municipality 
of Sao Paulo. In 2016, Ribeiro et al.7 reported positivity for 
T. cruzi in a P. megistus bug captured in an urban area of 
the city. In a study of epidemiological surveillance in Sao 
Paulo between 2010 and 2012, Silva et al.20 found that this 
species was the most important vector of Chagas disease in 
the State, a finding reflected in its increasing domiciliation 
and high natural-infection index (23.6%).

Panstrongylus geniculatus (Latreille 1811), which has 
been found naturally infected with T. cruzi, has a distribution 
extending from Southern Mexico to Northern Argentina. 
Although its habitats include a wide range of biomes 
and climates17,22, its most common habitat is wild forest 
environments, where it is found in armadillo (Dasypodidae) 
burrows and opossum (Didelphis) dens23,24. Although 
associated with wild environments, there are reports of 
the species attacking people24. It has been captured in 
pigsties and in environments occupied by humans, where 
it is attracted to light, although without forming colonies 
in the domicile23-26. Despite the limited vector potential of 
P. geniculatus, this triatomine can be epidemiologically 
important and has been involved in domestic cycles of 
T. cruzi in Venezuela27,28, Colombia29, Brazil23,30-32, Peru33,34, 
Bolivia35,36 and Argentina37, in the former in an outbreak of 
Chagas disease due to oral transmission at a school on the 
outskirts of Caracas38,39 and Colombia40. 

Two occurrences of P. geniculatus in the city of Sao 
Paulo have been reported. The first was of an adult bug 
found in a neighborhood in the Southern area of the city in 
1999, and the second was in July 2014 when a specimen 
was captured in a Culex quinquefasciatus mosquito-
breeding facility next to the Pinheiros River (Figure 1). 
After the specimen had been identified, analysis to detect 
T. cruzi infectivity was conducted according to Ribeiro et 
al.7, with negative result. Fifteen days after the specimen 
was captured, an active search was conducted within a 
radius of about 250 m of the capture site to locate possible 
shelters of this triatomine, and five Noireau traps41 adapted 
according to Obara et al.42 were installed. However, none 
of the procedures resulted in any further captures.

Although the active search for triatomines was negative, 
the presence of colonies in the area surrounding the breeding 

facility cannot be completely ruled out as there are remnants 
of reforestation and landscaping that provide shelter for 
rodents and other food sources for triatomines, such as 
opossums and birds. This species has a wide distribution 
and could be authoctonous in the area17,22.

Chagas disease is associated with poverty and inadequate 
sanitation in the dwellings of at-risk populations2, and 
transmission of the disease to humans typically occurs 
in wild, rural and periurban areas. However, with 
fragmentation of the natural habitats of the vectors of the 
disease as a result of urbanization and the increasing use 
of land for crops and pastures, triatomines, which were 
previously found exclusively in wild environments, are 
now commonly found in households, particularly on the 
outskirts of cities39,42,43-45. 

Data on occurrences of triatomines in the city of Sao 
Paulo indicate the importance of entomological surveillance 
of these vectors even in urban centers. Although the 
possibility of vector transmission of Chagas disease in 
major urban centers is very small, it cannot be ignored. 
If infected, triatomines that have invaded households and 
other buildings, to which they are attracted to by various 
factors, including light, can transmit the etiological agent 
of Chagas disease to humans and animals. As triatomines 
can contaminate food and other household items with their 
urine and feces, it is also important to consider the risk of 
oral transmission, the main form of transmission of T. cruzi 
today. Examples of this type of transmission have been 
reported in urban centers in recent decades and include a 
case involving T. sordida in the State of Bahia, Brazil, and 
another involving P. geniculatus in Caracas, Venezuela, in 
which contaminated water and guava juice, respectively, 
were ingested39,46. Accidents as a result of handling of the 
insect by humans or ingestion by domestic animals can also 
occur in large urban centers, where people are often not 
familiar with the appearance of these vectors.

These facts imply that in order to prevent the eventual 
transmission of T. cruzi in the municipality of Sao Paulo, 
the community is encouraged to send any suspicious 
insects to the local Health Supervisors (SUVIS) and 
that the communication between the laboratories that 
participated in this article, together with the Department of 
Health Coordination Sanitary Surveillance (COVISA) and 
Superintendence of Control of Endemic Diseases (SUCEN) 
are further narrowed, allowing a faster flow of specimens 
for identification and parasitological examinations, as well 
as more effective sharing of information.

CONFLICT OF INTERESTS

No competing financial conflicts of interest exist.



Rev Inst Med Trop São Paulo. 2018;60:e33

Occurrences of triatomines (Hemiptera: Reduviidae) and first reports of Panstrongylus geniculatus in urban environments in the city of Sao Paulo, Brazil

Page 5 of 6

ACKNOWLEDGMENTS

The authors would like to thank the Special Programs 
Division in the Superintendency for the Control of 
Endemic Disease (SUCEN) and the Synanthropic Fauna 
Identification and Research Laboratory in the Zoonoses 
Surveillance Division, City of Sao Paulo, for providing 
technical support to the field work. DPV is the recipient of 
a PhD fellowship from FAPESP (2012/19238-4).

REFERENCES

 1.  World Health Organization. Chagas disease in Latin America: 

an epidemiological update based on 2010 estimates. Wkly 

Epidemiol Rec. 2015;90:33-44.

 2.  Dias JC, Ramos Jr AN, Gontijo ED, Luquetti A, Shikanai-Yasuda 

MA, Coura JR, et al. II consenso brasileiro em doença de 

Chagas, 2015. Epidemiol Serv Saude. 2016;25 n. esp:7-86.

 3.  Moncayo A. Progress towards interruption of transmission of 

Chagas disease. Mem Inst Oswaldo Cruz. 1999;94 Suppl 1: 

401-4.

 4.  Dias JC, Amato-Neto V, Luna EJ. Mecanismos alternativos de 

transmissão do Trypanosoma cruzi no Brasil e sugestões para 

sua prevenção. Rev Soc Bras Med Trop. 2011;44:375-9. 

 5.  Oliveira JD, Alevi KC. Taxonomic status of Panstrongylus herreri 

Wygodzinsky, 1948 and the number of Chagas disease vectors. 

Rev Soc Bras Med Trop. 2017;50:434-5. 

 6.  Schofield CJ. Triatominae: biología y control. West Sussex: 

Eurocommunica; 1994.

 7.  Ribeiro AR, Oliveira RC, Ceretti Junior W, Lima L, Almeida 

LA, Nascimento JD, et al. Trypanosoma cruzi isolated from 

a triatomine found in one of the biggest metropolitan areas of 

Latin America. Rev Soc Bras Med Trop. 2016;49:183-9.

 8.  Medeiros-Sousa AR, Ceretti Junior W, Urbinatti PR, Carvalho GC, 

Paula MB, Fernandes A, et al. Mosquito fauna in municipal 

parks of Sao Paulo City, Brazil: a preliminary survey. J Am 

Mosq Control Assoc. 2013;29:275-9. 

 9.  Instituto Brasileiro de Geografia e Estatística. Estimativas de 

população. [cited 2018 May 24]. Available from: https://www.

ibge.gov.br/estatisticas-novoportal/sociais/populacao/9103-

estimativas-de-populacao.html?=&t=o-que-e

 10.  Myers N, Mittermeier RA, Mittermeier CG, Fonseca GA, Kent 

J. Biodiversity hotspots for conservation priorities. Nature. 

2000;403:853-8.

 11.  Forattini OP, Rabello EX, Castanho ML, Pattoli DG. Aspectos 

ecológicos da tripanossomose americana. I – Observações 

sôbre o Panstrongylus megistus e suas relações com focos 

naturais da infecção, em área urbana da cidade de São Paulo, 

Brasil. Rev Saude Pub. 1970;4:19-30. 

 12.  Dias JC. Southern Cone Initiative for the elimination of domestic 

populations of Triatoma infestans and the interruption of 

transfusional Chagas disease. Historical aspects, present 

situation and perspectives. Mem Inst Oswaldo Cruz. 2007; 

102 Suppl 1:11-8. 

 13.  Abad-Franch F, Diotaiuti L, Gurgel-Gonçalves R, Gürtler RE. 

Certifying the interruption of Chagas disease transmission 

by native vectors: cui bono? Mem Inst Oswaldo Cruz. 

2013;108:251-4.

 14. Leite OF, Alves MJ, Souza SS, Mayo RC, Andrade VR, Souza CE, 

et al. Triatoma infestans em área sob vigilância entomológica 

para doença de Chagas, Estado de São Paulo, Brasil. Rev Soc 

Bras Med Trop. 2001;34:437-43.

 15.  Wanderley DM, Silva RA, Carvalho ME, Barbosa GL. Doença 

de Chagas: a vigilância entomológica no Estado de São Paulo. 

Bol Epidemiol Paulista. 2007;4:8-12.

 16.  Rossi JC, Duarte EC, Gurgel-Gonçalves R. Factors associated with 

the occurrence of Triatoma sordida (Hemiptera: Reduviidae) 

in rural localities of Central-West Brazil. Mem Inst Oswaldo 

Cruz. 2015;110:192-200.

 17.  Lent H, Wygodzinsky P. Revision of the triatominae (Hemiptera: 

Reduviidae), and their significance as vectors of Chagas’ 

disease. Bull Am Mus Nat Hist. 1979;163:123-520

 18.  Gurgel-Gonçalves R, Ferreira JB, Rosa AF, Bar ME, Galvão C. 

Geometric morphometrics and ecological niche modelling 

for delimitation of near-sibling triatomine species. Med Vet 

Entomol. 2011;25:84-93.

 19.  Oscherov EB, Bar ME, Damborsky MP, Milano AM, Avalos 

G, Borda MA. Epidemiología de la enfermedad de Chagas, 

Departamento General Paz, Argentina. Rev Saude Publ. 

2003;37:59-64.

 20.  Silva RA, Barbosa GL, Rodrigues VL. Vigilância epidemiológica 

da doença de Chagas no estado de São Paulo no período de 

2010 a 2012. Epidemiol Serv Saude. 2014;23:259-67.

 21.  Macchiaverna NP, Gaspe MS, Enriquez GF, Tomassone L, Gürtler 

RE, Cardinal MV. Trypanosoma cruzi infection in Triatoma 

sordida before and after community-wide residual insecticide 

spraying in the Argentinean Chaco. Acta Trop. 2015;143:97-

102.

 22.  Leite GR, Santos CB, Falqueto A. Insecta, Hemiptera, Reduviidae, 

Panstrongylus geniculatus: geographic distribution map. Check 

List. 2007;3:147-52.

 23.  Valente VC, Valente SA, Noireau F, Carrasco HJ, Miles 

MA. Chagas disease in the Amazon Basin: association of 

Panstrongylus geniculatus (Hemiptera: Reduviidae) with 

domestic pigs. J Med Entomol. 1998;35:99-103.

 24.  Valente VC. Potential for domestication of Panstrongylus 

geniculatus (Latreille, 1811) (Liemiptera, Reduviidae, 

Triatominae) in the Municipality of Muaná, Marajó Island, 

State of Pará, Brazil. Mem Inst Oswaldo Cruz. 1999;94 Suppl 

1:399-400.

 25.  Miles MA, Souza AA, Póvoa M. Chagas’ disease in the Amazon 

Basin III. Ecotopes of ten triatomine bug species (Hemiptera, 

https://www.ibge.gov.br/estatisticas-novoportal/sociais/populacao/9103-estimativas-de-populacao.html
https://www.ibge.gov.br/estatisticas-novoportal/sociais/populacao/9103-estimativas-de-populacao.html
https://www.ibge.gov.br/estatisticas-novoportal/sociais/populacao/9103-estimativas-de-populacao.html


Ceretti-Junior et al.

Rev Inst Med Trop São Paulo. 2018;60:e33Page 6 of 6

Reduviidae) from the vicinity of Belém, Pará State, Brazil. J 

Med Entomol. 1981;18:266-78. 

 26.  Zeledon R. Vectores de la enfermedad de Chagas y sus 

características ecofisiológicas. Interciencia. 1983;8:384-95.

 27.  Serrano O, Mendoza F, Suárez B, Soto A. Seroepidemiología de 

la enfermedad de Chagas en dos localidades del municipio 

Costa de Oro, estado Aragua, Venezuela. Biomedica. 

2008;28:108-15.

 28.  Reyes-Lugo M, Rodriguez-Acosta A. Domiciliation of the 

sylvatic Chagas disease vector Panstrongylus geniculatus 

(Triatominae: Reduviidae) in Venezuela. Trans R Soc Trop 

Med Hyg. 2000;94:508.

 29.  Angulo VM, Esteban L, Luna KP. Eficacia en campo de un 

repelente a base de para-mentano-3,8-diol y aceite de limonaria 

contra Culicoides pachymerus (Diptera: Ceratopogonidae) en 

Colombia. Biomedica. 2012;32:277-85.

 30.  Naiff MF, Naiff RD, Barett TV. Vetores selváticos de doença 

de Chagas na área urbana de Manaus (AM): atividade de 

vôo nas estações secas e chuvosas. Rev Soc Bras Med Trop. 

1998;31:103-5.

 31.  Fé NF, Magalhães LK, Fé FA, Arakian SK, Monteiro WM, 

Barbosa MG. Ocorrência de triatomíneos em ambientes 

silvestres e domiciliares do município de Manaus, Estado do 

Amazonas. Rev Soc Bras Med Trop. 2009;42:642-6.

 32.  Maeda MH, Knox MB, Gurgel-Gonçalves R. Occurrence 

of synanthropic triatomines (Hemiptera: Reduviidae) in 

the Federal District of Brazil. Rev Soc Bras Med Trop. 

2012;45:71-6.

 33.  Cáceres AG, Troyes L, Gonzáles-Pérez A, Llontop E, Bonilla C, 

Murias E, et al. Enfermedad de Chagas en la región nororiental 

del Perú. I. Triatominos (Hemiptera, Reduviidae) presentes en 

Cajamarca y Amazonas. Rev Peru Med Exp Salud Publica. 

2002;19:17-23.

 34.  Torres V DB, Cabrera R. Geographical distribution and intra-

domiciliary capture of sylvatic triatomines in La Convención 

province, Cusco, Peru. Rev Inst Med Trop São Paulo. 

2010;52:157-60.

 35.  Depickère S, Durán P, López R, Chávez T. Presence of 

intradomicile colonies of the triatomine bug Panstrongylus 

rufotuberculatus in Muñecas, La Paz, Bolivia. Acta Trop. 

2011;117:97-100.

 36.  Depickère S, Duran P, Lopez R, Martinez E, Chavez T. After 

five years of chemical control: colonies of the triatomine 

Eratyrus mucronatus are still present in Bolivia. Acta Trop. 

2012;123:234-8.

 37.  Damborsky MP, Bar ME, Oscherov EB. Detección de triatominos 

(Hemiptera: Reduviidae) en ambientes domésticos y 

extradomésticos, Corrientes, Argentina. Cad Saude Publica. 

2001;17:843-9.

 38.  Wolff M, Castillo D. Evidencias de domesticación y aspectos 

biológicos de Panstrongylus geniculatus (Latreille, 1811) 

(Hemiptera: Reduviidae). Acta Entomol Chil. 2000;24:77-83. 

 39.  Noya-Alarcón O, Botto C, Cortez J, Ferrer E, Viettri M, Herrera L. 

Primer registro de Panstrongylus geniculatus (Latreille, 1811) 

en los municipios Alto Orinoco y Atures, estado Amazonas, 

Venezuela. Bol Malariol Salud Ambient. 2011;51:81-5.

 40.  Soto H, Tibaduiza T, Montilla M, Triana O, Suárez DC, Torres 

MT, et al. Investigación de vectores y reservorios en brote 

de Chagas agudo por posible transmisión oral en Aguachica, 

Cesar, Colombia. Cad Saude Publica 2014;30:746-56.

 41.  Noireau F, Abad-Franch F, Valente AS, Dias-Lima A, Lopes CM, 

Cunha V, et al. Trapping Triatominae in silvatic habitats. Mem 

Inst Oswaldo Cruz. 2002;97:61-3.

 42.  Obara MT, Ceretti Junior W, Urbinatti PR, Papa AR, Quintero LO, 

Barata JM. Sistema de armadilha modificada para captura de 

Triatomíneos (Hemiptera: Reduviidae) em diferentes ecótopos. 

Entomol Vect. 2002;9:583-90.

 43.  Alarcón de Noya B, Díaz-Bello Z, Colmenares C, Ruiz-Guevara 

R, Mauriello L, Zavala-Jaspe R, et al. Large urban outbreak 

of orally acquired acute Chagas disease at a school in Caracas, 

Venezuela. J Infec Dis. 2010;201:1308-15.

 44.  Rodrigues VL, Silva RA, Wanderley DM, Carvalho ME, 

Pauliquevis Junior CP. Detecção de triatomíneos da espécie 

Rhodnius neglectus em área urbana de municípios da região 

de Araçatuba. Bol Epidemiol Paulista. 2009;6:20-3.

 45.  Dias JV, Queiroz DR, Martins HR, Gorla DE, Pires HH, Diotaiuti 

L. Spatial distribution of triatomines in domiciles of an urban 

area of the Brazilian Southeast Region. Mem Inst Oswaldo 

Cruz. 2016;111:43-50.

 46.  Dias JP, Bastos C, Araújo E, Mascarenhas AV, Martins Netto E, 

Grassi F, et al. Acute Chagas disease outbreak associated with 

oral transmission. Rev Soc Bras Med Trop. 2008;41:296-300.


	ABSTRACT
	INTRODUCTION
	MATERIALS AND METHODS 
	RESULTS
	DISCUSSION
	CONFLICT OF INTERESTS 
	ACKNOWLEDGMENTS
	REFERENCES