ABSTRACT
Infections caused by arboviruses that have mostly impacted the Brazilian morbidity and mortality are caused by the same vector, Aedes aegypti. Preventive actions related to the vector are the most effective strategies in the prevention and control of these diseases. This study aimed to associate the knowledge on the vector that transmits dengue, Zika and chikungunya with the sociodemographic and behavioral preventive practices towards Aedes aegypti in the municipality of Tangara da Serra, Mato Grosso State, in the Brazilian Legal Amazon. A probabilistic urban population sampling was obtained by clusters: census sectors and households. The sample size calculation considered 10% of loss and a 1.5 design effect. This is a cross-sectional research carried out through a household survey in February and March 2018. There were 583 participants. The study variables were knowledge on the vector, sociodemographic characteristics and preventive practices related to the vector. The statistical analysis was based on a bivariate analysis and Poisson multiple regressions. Inadequate or insufficient knowledge on the vector Aedes aegypti remained associated with education in the categories illiterate (p<0.001) and 8 years of study or less (p<0.001), in addition to not adopting practices of capping and cleaning the water tank (p=0.002) and not using insecticides at home (p=0.007). It is concluded that there is a need for health communication actions that consider characteristics the population, especially the level of education and previous knowledge on the vector, allowing a dialogical approach and enabling the community participation in preventive practices and control of the vector Aedes aegypti .
Aedes aegypti; Dengue fever; Zika virus; Chikungunya virus; Health Knowledge, Attitudes, Practice
INTRODUCTION
The epidemics caused by arbovirus infections are a concern in public health, not only in Brazil, where DENV, CHIKV and ZIKV viruses have a large circulation, but also in the Americas and in the world, due to their capacity of dissemination, adaptation and universal susceptibility, besides their ability to cause severe cases and complications that can be neurological, articular and hemorrhagic1 . According to the Brazilian Epidemiological Bulletin, until the Epidemiological Week 50 of 2020, 979,764 probable cases of dengue were reported in Brazil, and the Midwest region presented with the highest incidence of 1,200 cases/100,000 inhabitants. In the same period 80,914 probable cases of chikungunya were reported in the country, and in relation to Zika, until the Epidemiological Week 49 of 2020, 7,119 probable cases were reported2 .
Aedes ( Stegomyia ) aegypti and Aedes ( Stegomyia ) albopictus have a wide geographic distribution and are vectors of viruses that cause diseases such as dengue, Zika, chikungunya and yellow fever3 , despite the similarities between them, climate conditions, domiciliation, dispersion, feeding and reproduction are differences that determine the dynamics of transmission4 . Brazilian studies show levels of infestation of Aedes albopictus much lower than those found for Aedes aegypti 3 , 5 . These factors define Aedes aegypti as the main species responsible for the transmission of these infections in Brazil. Disorderly growth of cities, absence of adequate basic sanitation conditions, and large variations in weather patterns are factors that favor the proliferation of Aedes aegypti in all regions of Brazil6 . In Mato Grosso State, distribution and abundance of vector populations are influenced by the environmental complexity and the geographic confluence of Pantanal, Cerrado and Amazon biomes7 .
Preventive measures for vector control are carried out according to the guidelines of the National Dengue Control Program (NCPD) launched in 2002 by the Brazilian Ministry of Health8 , and several technologies have been developed as complementary strategies in an attempt to reduce mosquito infestation and the incidence of arbovirus infections, such as innovations in biological and genetic modification of mosquito vectors and replacement of interventions to promote resistance to viral infections, targeting different Aedes aegypti stages9 . Among these strategies are information campaigns and health education activities, whose content have focused on the similarity between the symptoms of dengue, Zika and chikungunya, and the fight against Aedes aegypti 10 , often leading to the understanding that preventing the disease means adopting behaviors to avoid contact with the mosquito11 . However, a fragmentation of actions has been perceived with an emphasis on seasonal periods, requiring a reflection on the implementation of permanent educational actions that would permeate integral strategies, appropriate to the social realities and that could foster a collective construction of popular knowledge.
For the planning and implementation of health communication strategies that have the potential to contribute to the construction of popular knowledge, support preventive behaviors and community participation, it is essential to know how people think and act in relation to the control of the vector that transmits arbovirus infections12 . Thus, this study aimed to associate the knowledge on the vector that transmits dengue, Zika and chikungunya with the sociodemographic and preventive behavioral characteristics related to Aedes aegypti in the municipality of Tangara da Serra, Mato Grosso State, in the Brazilian Legal Amazon.
MATERIALS AND METHODS
This is a cross-sectional study performed through a household survey, conducted in the period of February and March 2018, in the urban region of the municipality of Tangara da Serra, located in Mato Grosso State, in the Legal Amazon.
The municipality of Tangara da Serra has a territorial area13 of 11,636,976 km2, is located in the Southwest region of Mato Grosso State, about 250 km from Cuiaba, the State capital. The estimated population for 2018 was 101,764 inhabitants. Among the total population of Tangara da Serra, 91% resides in the urban area, representing 25,581 of permanent private households14 . The climate of the region is tropical humid and megathermal (Aw), acording the classification proposed by Koppen, and characterized by rains in summer, drought in winter and high temperatures15 .
A probabilistic sampling was investigated, comprising the urban population by conglomerates, in two stages: primary sampling units, 34 census sectors, defined by the Brazilian Institute of Economics and Statistics (IBGE) for the 2010 Demographic Census, and secondary units composed of 660 households, proportionally drawn according to the size of each sector ( Figure 1 ). The sample size calculation considered the adopted standard error adopted of 0.025 for a sample of 400 individuals, adding to this number 10% of losses and 1.5 of design effect. Then, one resident per household, aged 18 years or older was invited to participate in the study, and the interview was carried out after the signature of the Informed Consent Term. For closed households, three visits were made at different times, on different days before replacing them by another home, which was done by drawing lots. Thus, from the total of 660 individuals randomly chosen, 583 constituted the final sample of this study due to losses caused by rejection and absence.
Map of census sectors and selected census sectors in the municipality of Tangara da Serra, Mato Grosso State, 2018.
Data collection was composed of the application of a questionnaire with the following sections: 1) sociodemographic characteristics; 2) knowledge on the vector that transmits dengue, Zika, and chikungunya; 3) information on water supply; and 4) preventive practices for the control of arbovirus infections. These data were double entered into the EpiInfo version 7.2.2.6 database (Centers for Disease Control and Prevention, Atlanta, GA, USA).
Studies on knowledge use different ways to assign value to variables. In this study, knowledge on the vector was considered as adequate or inadequate/ insufficient, according to the guidelines established by the Brazilian Ministry of Health (MS), according to three criteria: reproduction (asked if they had ever seen a mosquito larva); morphology (asked if they had ever seen the specific mosquito, the transmitter), habits (times when Aedes aegypti mosquitoes usually feed and usually bite). Knowledge was considered adequate when there were 2 or 3 affirmative and/or correct answers about these criteria. The dependent variable was the knowledge on the vector Aedes aegypti (inadequate/insufficient and adequate knowledge on the vector). The independent variables were: gender (male, female), age group (18-39, 40-59 and ≥ 60 years), education (illiterate, ≤ 8 years of study, > 8 years of study), auto-declared skin color (non-white, white), if the voluntary lives with a spouse/partner (yes, no), availability of water through the general municipality network (not applicable, alternate days, daily), water storage in a water tank (yes, no), water used for drinking (untreated at home, treated at home, industrialized). Regarding the variables related to preventive practices, they were categorized as yes or no.
For data analysis, the SPSS software (Statistical Package for the Social Sciences, version 20.0, SPSS Inc., Chicago, IL, USA) was used. Bivariate and multiple analyses were performed. In the bivariate analysis, the crude prevalence ratios (cPR) with their respective 95% confidence intervals (95%CI) were estimated, and the independent variables that kept a p value lower than 20% (p<0.20) were selected for the multiple analysis, adjusted by the Poisson multiple regression model with robust variance, considering a significance level of 5% (p<0.05) for variables that remained associated with knowledge on the vector Aedes aegypti .
This study was approved by the Research Ethics Committee of Porto Alegre Clinical Hospital, Federal University of Rio Grande do Sul, Rio Grande do Sul State, Brazil, under the process Nº 2.068.222.
RESULTS
From the total of 583 participants, 68.1% were female, and 46.3% were between 18 and 39 years old; regarding the level of education, 58.5% had more than eight years of schooling, the non-white skin color was self-declared by 65.2% of the individuals and 61.9% lived with a spouse or partner. Regarding information on water supply, 87% reported daily availability of water from the general municipality network, 95% had the habit of storing water in water tanks, and 41.7% used drinking water treated at home ( Table 1 ).
Knowledge on the vector that transmits dengue, Zika and chikungunya was considered adequate for 52.7% of participants. The association between inadequate or insufficient knowledge and sociodemographic characteristics were found in the age group greater than or equal to 60 years old (p=0.017), among illiterate individuals (p=0.002) and among those with 8 years or less of study (p<0.001). As for water supply, inadequate or insufficient knowledge was associated with storing water in a water tank (p=0.044) and using untreated drinking water at home (p=0.023), while adequate knowledge on the vector was associated with receiving mains water every other day (p=0.002) ( Table 2 ).
Regarding preventive practices, inadequate or insufficient knowledge on the vector was associated with the lack of coverage or cleaning of water reservoirs (p=0.001) and not using insecticides at home (p<0.001) ( Table 3 ).
After the Poisson model analysis with robust variance, inadequate or insufficient knowledge on the vector that transmits dengue, Zika, and chikungunya remained associated with education in the illiterate (p<0.001) and 8 years or less of study (p<0.001) categories, in addition to not performing the capping and cleaning of the water tank (p=0.002) and not using insecticides at home (p=0.007), while adequate knowledge on the vector remained associated with receiving water from the general network supply every other day (p=0.017) ( Table 4 ). The other variables lost significance after the statistical modeling.
DISCUSSION
Regarding the reproduction, morphology and habits of the vector that transmits dengue, Zika and chikungunya, a little more than half of the studied population had sufficient knowledge, an inferior result in comparison with those described in a Mexican study, in which knowledge on the breeding sites of mosquitoes was described by 95.5% of participants16 . In a survey of an urban community in Northeastern Brazil, participants reported knowing that not all types of mosquitoes transmit infections11 , a fact evidenced in this survey, as people from Mato Grosso identified the larva and the transmitting mosquito in some occasions, differentiating it from other types of mosquitoes. Besides the identification of the vector, 21% of the individuals gave an adequate response according to the Ministry of Health, that is, they informed that the blood repast of the vector occurs in the morning and early evening, similar to the study in El Salvador, in which 40.9% of respondents provided adequate information16 , whereas in another survey, in Northeastern Brazil, 71% reported knowing the diurnal habits of the mosquito11 .
Knowledge on the vector can be established through the meaning and relevance of information individuals have access to17 , and in this sense, the understanding of the vector found in this study may be related to the actions of the endemic disease control agents (ECA) and community health agents (CHA), as well as the campaigns to disseminate information in the media, which have as their main theme, the characteristics and morphology of the vector, the presence of larvae in containers with standing water and diurnal habits of the mosquito, showing appropriation of the contents disseminated11 , 16 . To face endemic diseases in Brazil, one of the strategies is the integration of ECAs actions, with the activities of CHAs in the Family Health Strategy teams (FHS), and among these actions, orientation to residents on possible breeding sites of the vector and signs and symptoms of arboviruses18 , plays a strategic role in the prevention and control of these diseases19 .
An association was found between inadequate or insufficient knowledge on the vector of these arbovirus infections and the educational level of the interviewees, suggesting that individuals with lower educational levels have less information on the vector. A study with health professionals and the general population found that the length of studies may have positively influenced a higher level of knowledge20 and in Nepal, an association was found between the educational level of the participants and better prevention attitudes towards dengue21 . Therefore, the level of education can be considered a determining factor of knowledge, as well as of attitudes and preventive practices, especially when it comes to actions with participation of the community for the vector control, suggesting that a higher level of education is related to the empowerment of the population in these activities22 . In view of these results, it is necessary to consider that, for health educational activities, people with fewer years of education may need a different approach, supplying their information needs, so that prevention actions can occur.
In this survey carried out in Mato Grosso State, an association was found between having adequate knowledge on the vector and the availability of the municipality general network supply in the household every other day. Some studies such as one from the Northeastern Brazil, suggested that the availability of water is a determinant for the maintenance of the mosquito life cycle23 , showing a correlation between dengue cases and water /sewage treatment rates24 . Therefore, water supply/ sewage treatment is an important indicator in the control of Aedes aegypti . The water supply is a factor that influences the ecology of the vector, and has been identified as a key factor in the transmission of arbovirus infections, because in places in which the water supply is irregular, with lack or intermittence of water supply, storage through the use of inadequate reservoirs is frequent, creating an ideal environmental condition for the increment of breeding sites, favoring reproduction and survival of the vector25 .
The residents of the municipality of Tangara da Serra experienced a water crisis in the year 2016, prior to the collection period of this study, having been decreed a situation of emergency caused by drought, resulting in irregular and insufficient distribution of rainfall26 , 27 , an important factor that may have influenced the responses to the need for rationing and care of water reservoirs, highlighting the need of considering the community characteristics and previous knowledge when planning educational activities for disease prevention. Still on the availability of water, the study suggests that the government should ensure substantial investments in measures such as environmental sanitation and environmental and health education on a continuous basis, which can contribute for the elimination of breeding sites, larvae and mosquitoes, as well as the selection of socio-environmental indicators can assist in the analysis of the Building Infestation Index, acting as a subsidy in the implementation of public policies for prevention and control of Aedes aegypti 28 .
Not performing the capping and cleaning of water tanks was associated with inadequate or insufficient knowledge on the vector, which may suggest that not knowing how the mosquito reproduction takes place is related to the lack of preventive actions, especially in households that need to store water for consumption in temporary reservoirs due to intermittent supply. Similar results were found in a study conducted in the Northeast region of Brazil, in which water care practices were associated with knowledge on dengue, suggesting that it is possible that having sufficient knowledge may influence the preventive practices such as cleaning and sealing water reservoirs11 .
Inadequate knowledge on the vector was also statistically associated with the non-use of insecticides or spatial repellents at home. The application of these insecticides is efficient in containing the adult form of the mosquito, and is a practice used and seen by many individuals as the solution to the problem of arbovirus infections, but this belief has led to the misuse of products and environmental contamination25 . In addition to the resistance of Aedes aegypti to conventional insecticides that has already been observed in Brazilian studies29 , 30 , space repellents have the function of avoiding human contact with the vector, are of low molecular weight and produce a mosquito-free area, protecting people from bites, but are not yet fully recognized as an effective component of vector control strategies, but may be an option to be considered in situations of high infestation31 . Furthermore, control measures based on the identification and elimination of breeding sites of vectors in the larval stage are the most efficient, making the research and development of less polluting or less toxic alternatives urgent32 , resulting in their dissemination and access to the population.
To improve the knowledge on the vector that transmits dengue, Zika and chikungunya, and the preventive practices against the mosquito, it is believed that communication and health education interventions are necessary, aiming to produce sense in the population on the guidelines proposed by the government and the scientific community, focusing on innovative and important information for the effective participation of the community in the control of mosquito infestation and to promote and reinforce the importance of domestic preventive, simpler and more effective, as much as less harmful practices, such as the rational use of repellents and insecticides16 , emphasizing to the population in a clear and accessible way, and in adequate language, how these actions, if properly conducted, can bring benefits to their quality of life33 .
Knowledge is one of the factors influencing the performance of preventive practices for arboviruses34 , and a dialogic approach of educational strategies is necessary, despite efforts to control the Aedes aegypti vector, if dengue outbreaks and the emergence of other arboviruses, such as chikungunya and Zika occur. In addition, to face problems related to the proliferation of Aedes aegypti , it is essential to improve water supply services, sewage systems and housing conditions35 .
Among the limitations of this study is the fact has a cross-sectional design, and the answers on knowledge and practices were self-reported. Selection bias may also have occurred, as only individuals who were present in the household at the time of the interview were invited to participate in the survey. Another limitation for this type of study is related to the subjectivity of knowledge, recognizing the importance of knowledge that communities have, however, considering for the purpose of analysis, knowledge as the information to which the population had access to, coming from mass communication campaigns and/or health education actions.
CONCLUSION
The positive association with inadequate or insufficient knowledge on the vector that transmits dengue, Zika and chikungunya found in this study suggests that individuals with lower levels of education have less knowledge, confirming the need for improved communication and health educational actions that would meet the demands of each population, considering an accessible language and prior knowledge.
Adequate knowledge on the vector was associated with intermittent water supply for consumption, leading to the need of water storage in reservoirs; thus, this finding is relevant. Furthermore, regarding the water reservoirs, the inadequate or insufficient knowledge was associated with the lack of cleaning and sealing of storage reservoirs, showing the need for more information on the vector, its characteristics of reproduction, and the proper care towards water reservoirs.
Similar studies, which analyze the relationship between knowledge and preventive practices adopted by a population, are important for planning of public policies as well as efficient communication actions conducted according to the community characteristics, providing a dialogical approach that would encourage the participation of all citizens. Based on the results found here, a future study is suggested to verify the association between the knowledge and preventive practices on arbovirus infections and the occurrence of these diseases.
ACKNOWLEDGMENTS
We thank the Municipal Health Secretariat of Tangara da Serra and the Epidemiological Surveillance team for the logistics. The Tangara da Serra press for its support in publicizing the project to the community. To Nursing students at the University of Mato Grosso State for data collection.
REFERENCES
- 1 Donalisio MR, Freitas AR, Zuben AP. Arboviruses emerging in Brazil: challenges for clinic and implications for public health. Rev Saude Publica. 2017;51:30.
-
2 Brasil. Ministério da Saúde. Secretaria de Vigilância em Saúde. Monitoramento dos casos de arboviroses urbanas transmitidas pelo Aedes aegypti (dengue, chikungunya e Zika), semanas epidemiológicas 1 a 50, 2020. Bol Epidemiol. 2020;51:1-33. [cited 2021 Jul 21]. Available from: https://www.gov.br/saude/pt-br/media/pdf/2020/dezembro/28/boletim_epidemiologico_svs_51.pdf
» https://www.gov.br/saude/pt-br/media/pdf/2020/dezembro/28/boletim_epidemiologico_svs_51.pdf - 3 Fonseca Júnior DP, Serpa LL, Barbosa GL, Pereira M, Holcmam MM, Voltolini JC, et al. Vectors of arboviruses in the state of São Paulo: 30 years of Aedes aegypti and Aedes albopictus. Rev Saude Publica. 2019;53:84.
- 4 Zara AL, Santos SM, Fernandes-Oliveira ES, Carvalho RG, Coelho GE. Estratégias de controle do Aedes aegypti: uma revisão. Epidemiol Serv Saude. 2016;25:391-404.
- 5 Glasser CM, Arduino MB, Barbosa GL, Ciaravolo RM, Domingos MF, Oliveira CD, et al. Comportamento de formas imaturas de Aedes aegypti, no litoral do Estado de São Paulo. Rev Soc Bras Med Trop. 2011;44:349-55.
- 6 Teixeira MG, Siqueira Jr. JB, Ferreira GL, Bricks L, Joint G. Epidemiological trends of dengue disease in Brazil (2000-2010): a systematic literature search and analysis. PLoS Negl Trop Dis. 2013;7:e2520.
- 7 Cruz LC, Guimarães AG, Souza EM, Ferreira RS, Gomes RS, Slhessarenko RD, et al. Influence of climatic variables on the Aedes aegypti and Culex quinquefasciatus populations in Mato Grosso, Brazil. Rev Soc Bras Med Trop. 2020;53: e20190185.
-
8 Brasil. Ministério da Saúde. Fundação Nacional de Saúde. Programa Nacional de Controle da Dengue (PNCD): instituído em 24 de julho de 2002. Brasília: Ministério da Saúde; 2002. [cited 2021 Jul 21]. Available from: http://bvsms.saude.gov.br/bvs/publicacoes/pncd_2002.pdf
» http://bvsms.saude.gov.br/bvs/publicacoes/pncd_2002.pdf -
9 Pan American Health Organization. Evaluation of innovative strategies for Aedes aegypti control: challenges for their introduction and impact assessment. Washington, D.C.: PAHO; 2019. [cited 2021 Jul 21]. Available from: https://iris.paho.org/bitstream/handle/10665.2/51375/9789275120965_eng.pdf?sequence=1&isAllowed=y
» https://iris.paho.org/bitstream/handle/10665.2/51375/9789275120965_eng.pdf?sequence=1&isAllowed=y - 10 Albarado AJ, Prado EJ, Mendonça AV. Um, dois, três – gravando: as campanhas audiovisuais do Ministério da Saúde sobre dengue, chikungunya e Zika de 2014 a 2017. Reccis Rev Eletron Comun Inf Inov Saude. 2019;13:75-86.
- 11 Santos SL, Cabral AC, Augusto LG. Conhecimento, atitude e prática sobre dengue, seu vetor e ações de controle em uma comunidade urbana do Nordeste. Cien Saude Coletiva. 2011;16 Suppl 1:1319-30.
- 12 Souza VM, Hoffmann JL, Freitas MM, Brant JL, Araújo WN. Avaliação do conhecimento, atitudes e práticas sobre dengue no Município de Pedro Canário, Estado do Espírito Santo, Brasil, 2009: um perfil ainda atual. Rev Pan-Amaz Saude. 2012;3:37-43.
-
13 Instituto Brasileiro de Geografia e Estatística. Tangará da Serra. [cited 2021 Jul 21]. Available from: https://biblioteca.ibge.gov.br/biblioteca-catalogo.html?id=32996&view=detalhes
» https://biblioteca.ibge.gov.br/biblioteca-catalogo.html?id=32996&view=detalhes -
14 Instituto Brasileiro de Geografia e Estatística. Brasil/MatoGrosso/Tangará da Serra. [cited 2021 Jul 21]. Available from: https://cidades.ibge.gov.br/brasil/mt/tangara-da-serra/panorama
» https://cidades.ibge.gov.br/brasil/mt/tangara-da-serra/panorama - 15 Dallacort R, Moreira PS, Inoue MH, Silva DJ, Carvalho IF, Santos C. Wind speed and direction characterization in Tangará da Serra, Mato Grosso state, Brazil. Rev Bras Metereol. 2010;25:359-64.
- 16 Mejía R, Ribó A, Quinteros E, López A, Villegas P, Vela XF, et al. Knowledge attitude and practices related on prevention of mosquito borne diseases and sanitation conditions in a Salvadoran urban community. Occup Dis Environ Med. 2016;4:83-102.
- 17 Ribeiro DE, Souza IG, Souza AP. O conceito de informação e conhecimento sob a ótica dos docentes do curso de biblioteconomia UFCA. Folha Rosto. 2015;1:16-9.
- 18 Pereira GA, Pícoli RP, Cazola LH. Integration of endemic disease control workers in the Family Health Strategy, Campo Grande, Mato Grosso do Sul, Brazil, 2017. Epidemiol Serv Saude. 2021;30:e2019500.
- 19 Evangelista JG, Flisch TM, Valente PA, Pimenta DN. Agentes de combate às endemias: construção de identidades profissionais no controle da dengue. Trab Educ Saude. 2019;17:e0017303.
- 20 Menchaca-Armenta I, Ocampo-Torres M, Hernández-Gómez A, Zamora-Cerritos K. Risk perception and level of knowledge of diseases transmitted by Aedes aegypti. Rev Inst Med Trop Sao Paulo. 2018;60:e10.
- 21 Dhimal M, Aryal KK, Dhimal ML, Gautam I, Singh SP, Bhusal CL, et al. Knowledge, attitude and practice regarding dengue fever among the healthy population of highland and lowland communities in Central Nepal. PLoS One. 2014;9:e102028.
- 22 Diaz-Quijano FA, Martínez-Vega RA, Rodriguez-Morales AJ, Rojas-Calero RA, Luna-González ML, Díaz-Quijano RG. Association between the level of education and knowledge, attitudes and practices regarding dengue in the Caribbean region of Colombia. BMC Public Health. 2018;18:143.
- 23 Valle D, Pimenta DN, Cunha RV, organizadores. Dengue: teorias e práticas. Rio de Janeiro: Editora Fiocruz; 2015.
- 24 Silva JC, Machado CJ. Associations between dengue and socio-environmental variables in capitals of the Brazilian Northeast by cluster analysis. Ambiente Soc. 2018;21:e01332
-
25 Sardão T. Dengue e Zika: ABES alerta sobre a importância do saneamento básico no combate às doenças. [cited 2021 Jul 21]. Available from: http://abes-dn.org.br/?p=923#:~:text=combate%20%C3%A0s%20doen%C3%A7as-,Dengue%20e%20zika%3A%20ABES%20alerta
» http://abes-dn.org.br/?p=923#:~:text=combate%20%C3%A0s%20doen%C3%A7as-,Dengue%20e%20zika%3A%20ABES%20alerta -
26 Mato Grosso. Governo Estadual. Decreto nº 767, de 16 de dezembro de 2016. Homologa Decreto de situação de emergência do Município de Tangará da Serra/MT. Diário Oficial do Estado, 16 dez. 2016. p.8. [cited 2021 Jul 21]. Available from: sesp.mt.gov.br/documents/4713378/12145074/diario_oficial_2016-12-16_pag_8++--18.pdf
» sesp.mt.gov.br/documents/4713378/12145074/diario_oficial_2016-12-16_pag_8++--18.pdf - 27 Melo MT, Queiroz TM, Vinaga L, Ferreira JR, Marchetto M. Variabilidade das classes de água e Índice de Estado Trófico do riacho Queima Pé. Rev Eng Agric. 2019;27:68-79.
- 28 Feitosa FR, Sobral IS, Jesus EN. Indicadores socioambientais como subsídio à prevenção e controle da Dengue. Rev Eletronica Gest Educ Tecnol Ambient. 2015;19:351-68.
- 29 Prophiro JS, Silva OS, Luna JE, Piccoli CF, Kanis LA, Silva MA. Aedes aegypti and Aedes albopictus (Diptera: Culicidae): coexistence and susceptibility to temephos, in municipalities with occurrence of dengue and differentiated characteristics of urbanization. Rev Soc Bras Med Trop. 2011;44:300-5.
- 30 Gambarra WP, Martins WF, Lucena Filho ML, Albuquerque IM, Apolinário OK, Beserra EB. Spatial distribution and esterase activity in populations of Aedes (Stegomyia) aegypti (Linnaeus) (Diptera: Culicidae) resistant to temephos. Rev Soc Bras Med Trop. 2013;46:178-84.
- 31 Estrada JL, Moscoso KE, Salas IF, Achee NL, Grieco JP. Spatial repellency and other effects of transfluthrin and linalool on Aedes aegypti and Aedes albopictus. J Vector Ecol. 2019;44:89-93.
- 32 Guilhermino JF, Guerreiro AT, Almeida FS, Grillo ZD. A ciência no uso de produtos naturais para controle do vetor do vírus Zika (ZIKV). Rev Fitos. 2016;10:8-12.
- 33 Ouédraogo S, Benmarhnia T, Bonnet E, Somé PA, Barro AS, Kafando Y, et al. Evaluation of effectiveness of a community-based intervention for control of dengue virus vector, Ouagadougou, Burkina Faso. Emerg Infect Dis. 2018;24:1859-67.
- 34 Wong LP, Shakir SM, Atefi N, AbuBakar S. Factors affecting dengue prevention practices: nationwide survey of the Malaysian public. PLoS One. 2015;10:e0122890.
-
35 Dias BC. Melhoramento dos serviços de água e saneamento é a resposta ao Zika vírus, diz Léo Heller. [cited 2021 Jul 21]. Available from: https://www.abrasco.org.br/site/noticias/ecologia-e-meio-ambiente/zika_saneamento_leo_heller/16639/
» https://www.abrasco.org.br/site/noticias/ecologia-e-meio-ambiente/zika_saneamento_leo_heller/16639/
Publication Dates
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Publication in this collection
16 Aug 2021 -
Date of issue
2021
History
-
Received
1 Apr 2021 -
Accepted
20 July 2021