Neonicotinoid insecticide systemicity in soybean plants and its effect on brown stink bugs

Basso, Claudir José; Kuss, Cassiano Carlos; Pias, Osmar Henrique de Castro; Muraro, Dionei Schmidt; Cutti, Luan

doi:10.1590/1983-40632016v4638908

ABSTRACT

During the application of pesticides on soybean fields, a vertical deposition gradient of the product can occur throughout the canopy, resulting in difficulties for controlling stink bugs that are in the middle and lower thirds of plants. This study aimed at evaluating the systemicity of thiamethoxam insecticide in different soybean phenological stages, using brown stink bugs as bioindicators of the pesticide efficacy. The study combined product application sites (lower, middle and upper third) and stink bugs infestation areas at five soybean phenological stages (R2, R3, R4, R5.2 and R6). For the R2 and R5.2 stages, plants presented acropetal translocation of the product, being the effect more evident in the R2 stage. For the R3, R4 and R6 stages, the product translocation was not sufficient for controlling the stink bugs. In all stages, for treatments with direct exposure (same infestation and spraying place), stink bugs were satisfactorily controlled.

KEY-WORDS:
Glycine max; Euchistus heros; thiamethoxam

RESUMO

Durante a aplicação de inseticidas, na cultura da soja, forma-se um gradiente vertical de deposição do produto ao longo do dossel, resultando em dificuldades no controle dos percevejos que se encontram nos terços médio e inferior das plantas. Objetivou-se avaliar a sistematicidade do inseticida tiametoxam em diferentes estágios da cultura da soja, utilizando-se o percevejo marrom como bioindicador da ação do inseticida. O estudo combinou locais de aplicação do produto (terço inferior, médio e superior) e de infestação dos percevejos, em cinco fases do estágio fenológico (R2, R3, R4, R5.2 e R6) da cultura da soja. Nos estágios R2 e R5.2, as plantas apresentaram translocação acropetal do produto, sendo o efeito mais pronunciado no estágio R2. Nos estágios R3, R4 e R6, não houve translocação suficiente do produto para o controle dos percevejos. Em todos os estágios, nos tratamentos com exposição direta (mesmo local de infestação e pulverização), houve controle satisfatório dos percevejos.

PALAVRAS-CHAVES:
Glycine max; Euchistus heros; tiametoxam

INTRODUCTION

The neotropical Euschistus heros (Heteroptera: Pentatomidae) is the most abundant stink bug species in Brazil (Sosa-Gómez et al. 2009SOSA-GÓMEZ, D. R. et al. Insecticide susceptibility of Euschistusheros (Heteroptera: Pentatomidae) in Brazil. Journal of Economic Entomology, Annapolis , v. 102, n. 3, p. 1209-1216, 2009.). Given its high potential for crop damage, high population density, difficulty of control and wide geographical distribution, this species is one of the main soybean [Glycine max (L.) Merrill] pests (Sosa-Gómez & Silva 2010SOSA-GÓMEZ, D. R.; SILVA, J. J. Neotropical brown stink bug (Euschistus heros) resistance to methamidophos in Paraná, Brazil. Pesquisa Agropecuária Brasileira, Brasília, DF, v. 45, n. 7, p. 767-769, 2010.).

Difficulty in controlling stink bugs is related, among other aspects, to the insect greater tolerance to insecticides, in relation to other species. Moreover, there are variations in susceptibility to the insecticide among populations, with some of them showing tolerance levels up to sixteen times higher, when compared to susceptible populations (Sosa-Gómez at al. 2001SOSA-GÓMEZ, D. R.; CORSO, I. C.; MORALES, L. Insecticide resistance to endosulfan: monocrotophos and metamidophos in the neotropical brown stink bug Euschistus heros (Fabr.). Neotropical Entomology, Londrina, v. 30, n. 2, p. 317-320, 2001. and 2009SOSA-GÓMEZ, D. R. et al. Insecticide susceptibility of Euschistusheros (Heteroptera: Pentatomidae) in Brazil. Journal of Economic Entomology, Annapolis , v. 102, n. 3, p. 1209-1216, 2009., Sosa-Gómez & Silva 2010SOSA-GÓMEZ, D. R.; SILVA, J. J. Neotropical brown stink bug (Euschistus heros) resistance to methamidophos in Paraná, Brazil. Pesquisa Agropecuária Brasileira, Brasília, DF, v. 45, n. 7, p. 767-769, 2010.). This tolerance has caused an increase in the use of neonicotinoid insecticides, which are among the most used globally (Girolami et al. 2009GIROLAMI, V. et al. Translocation of neonicotinoid insecticides from coated seeds to seedling guttation drops: a novel way of intoxication for bees. Journal of Economic Entomology, Annapolis, v. 102, n. 5, p. 1808-1815, 2009.) and are characterized as highly toxic to insects and by having low toxicity to other living organisms (Maienfisch et al. 2001MAIENFISCH, P. et al. Chemistry and biology of thiamethoxam: a second generation neonicotinoid. Pest Management Science, New York , v. 57, n. 1, p. 906-913, 2001.).

The systemicity of an insecticide can be understood as the ability of the product to be translocated to other plant tissues which have not received the product directly, at least not in sufficient amounts to be lethal to insects (Faria 2009FARIA, A. B. C. Revisão sobre alguns grupos de inseticidas utilizados no manejo integrado de pragas florestais. Ambiência, Guarapuava, v. 5, n. 2, p. 345-358, 2009., Reetz et al. 2011REETZ, J. E. et al. Neonicotinoid insecticides translocated in guttated droplets of seed-treated maize and wheat: a threat to honeybees? Apidologie, Amtsgericht Charlottenburg, v. 42, n. 6, p. 596-606, 2011.).

Neonicotinoids are described as systemic insecticides. However, in the literature, the movement of these insecticides through soybean crops has not been characterized yet, and it is unknown whether the translocated amounts are sufficient to control stink bugs.

The use of neonicotinoid insecticides in crops has been identified as one of the factors responsible for the decline in the populations of pollinating insects (Brittain & Potts 2011BRITTAIN, C.; POTTS, S. G. The potencial impacts of insecticides on the life-history traits of bees and the consequences for pollination. Basic and Applied Ecology, Jana, v. 12, n. 4, p. 321-331, 2011.). According to Blacquière et al. (2012)BLACQUIÈRE, T. et al. Neonicotinoids in bees: a review on concentration, side-effects and risk assessment. Ecotoxicology, Amtsgericht Charlottenburg, v. 21, n. 4, p. 973-992, 2012. , the systemic action of neonicotinoids makes this product to be translocated to all parts of the plant, eventually becoming infused within the plant nectar and pollen. It may have lethal or sublethal effects on pollinating insects (which are rarely detected), and thus influence both the physiology and behavior of bees, thereby undermining the social structure of the colony (Pham-Delègue et al. 2002PHAM-DELÈGUE, M. H. et al. Behavioral methods to assess the effects of pesticides on honey bees. Apidologie, Amtsgericht Charlottenburg, v. 33, n. 5, p. 425-432, 2002.).

Although the present study does not intend to investigate the environmental impact of neonicotinoids, the evaluation of the translocation of these products in soybean plants might indicate the degree at which beneficial insects such as bees may be exposed. This would contribute to neonicotinoid use strategies that minimize its impact on beneficial insects, such as those reported by Girolami et al. (2009)GIROLAMI, V. et al. Translocation of neonicotinoid insecticides from coated seeds to seedling guttation drops: a novel way of intoxication for bees. Journal of Economic Entomology, Annapolis, v. 102, n. 5, p. 1808-1815, 2009..

Under ideal climatic conditions for insecticides application, it is expected that the drops of the product will pass through the upper layer of leaves and be distributed throughout the canopy. There are factors such as physical barriers, weather conditions and application technology that can hinder the homogeneous distribution of the product (Ferreira & Oliveira 2008FERREIRA, M. C.; OLIVEIRA, J. R. G. di. Aplicação de fungicidas na cultura da soja com pulverizador costal pressurizado e manual elétrico com bico rotativo para volume baixo: parte 1: cobertura. In: SIMPÓSIO INTERNACIONAL DE TECNOLOGIA DE APLICAÇÃO DE AGROTÓXICOS, 4., 2008, Ribeirão Preto. Anais... Campinas: Instituto Agronômico, 2008.). The large leaf area of soybean makes it even more difficult to obtain uniformity in the product distribution throughout the plant canopy. This can result in low efficiency in the control of stink bugs, which are more prevalent in the middle and lower thirds of plants (Navarini 2008NAVARINI, L. Resposta de cultivares de soja ao controle químico de ferrugem asiática. 74 f. 2008. Dissertação (Mestrado em Produção Vegetal) - Universidade Federal de Santa Maria, Santa Maria, 2008.).

This study aimed at evaluating the thiamethoxam insecticide systemicity in different soybean phenological development stages, besides determining the insecticide effectiveness in controlling neotropical brown stink bugs.

MATERIAL AND METHODS

The systematic nature of thiamethoxam in soybean plants and its efficacy on the neotropical brown stink bug were studied at different phenological soybean stages (R2, R3, R4, R5.2 and R6). For each phenological stage, an isolated experiment was conducted. The treatments had different combinations of product application sites and stink bug infestation areas. In the experiments conducted at R2, R3, R4 and R5.2, plants were divided into two strata (lower and upper half), while, at R6, they were divided into three strata (lower, middle and upper third).

Experiments were carried out at 24 ºC, in a climate-controlled greenhouse, in Londrina, Paraná State, Brazil. Soybean plants were grown in containers with 5 L capacity, prepared with Hapludox soil collected at the 0.00-0.20 m depth layer, which was initially screened and homogenized. The soil pH correction with dolomitic limestone was applied thirty days before the experiment. Throughout the experiment, the soil was maintained with moisture near the field capacity. The BRS 1001 ipro soybean cultivar was used. Seeds were treated with inoculant (Brady rhizobium japonicum ; 6 mL kg^-1 of seeds) before seeding. On January 13 (2014), five seeds were placed in each pot. Fifteen days after seeding, germinated plants were thinned to only one seedling per container.

The thiamethoxam insecticide was prepared in suspension at a concentration of 0.235 g L^-1 of active ingredient. The Actara 250 WG commercial product was selected for this study because it contains thiamethoxam in isolation with no other insecticides. The thiamethoxam dose was calculated to be equivalent to the amount of this substance present in the dose of 250 mL ha^-1 of Engeo Pleno and from a spray volume of 150 L ha^-1. The suspension was sprayed with a manual sprayer until the runoff point of the spray mixture on the plant was reached. Specific plant strata were sprayed in accordance with each treatment. The plant parts that were not supposed to be sprayed were protected with plastic bags as was the soil. Soybean plants were infested with stink bugs immediately after the spray solution had dried.

The stink bugs used in the studies were collected at a Embrapa farm (23º11'0.6''S, 51º10'18.5''W). For the acclimatization of these insects, they were kept for seven days in screened cages, inside a greenhouse, and fed with soybean plants at the R5 stage (grain filling). During the experiments, the bugs were confined in each stratum of the plant with the use of a voile net. To avoid the kneading effect of leaves and branches, wire arches were used internally in the fabric to give structure and keep it rounded. The boundaries of the fabric layers were tied with a string to prevent insects from passing from one stratum to another.

For the experiments with the R2, R3, R4 and R5.2 stages, the experimental design was completely randomized, with six treatments: two application sites (upper and lower), two infested sites (upper and lower) and two control treatments with infestation in the two sites (upper and lower), but without insecticide application. Each treatment had ten replications and each plant was infested with four stink bugs per stratum. The evaluations were based on counting the number of living insects in each stratum and were performed daily until the seventh day after spraying. The number of living stink bugs was initially subjected to the W test (Shapiro & Wilk 1965), to confirm the normality hypothesis, and, as the data showed normal behavior, they were subjected to analysis of variance. When significant results were obtained, they were compared by the Tukey test at 1 %.

The design of the R6 stage experiment was completely randomized, with 12 treatments: three pesticide application sites (lower, middle and upper), three stink bugs infestation sites (lower, middle and upper) and three control treatments, with no insecticide, with three infestation sites (lower, middle and upper). All treatments had ten replications. Each plant was infested with five bugs per stratum. The evaluations were performed daily until the fourteenth day after spraying by counting the number of living insects. The number of living stink bugs was initially subjected to the W test (Shapiro & Wilk 1965), to confirm the normality hypothesis, and, as the data did not show normal behavior, they were analyzed by the non-parametric Kruskal-Wallis method (Campos 1979CAMPOS, H. de. Estatística experimental não-paramétrica. 3. ed. Piracicaba: USP, 1979.) and the treatment means compared by the chi-square test at 1 %.

RESULTS AND DISCUSSION

In all experiments, there was a low survival rate of bugs in the strata in which a direct spray was applied at the same site of stink bugs infestation (Tables 1 and 2). In the experiment conducted at the R5.2 stage, for treatments with direct exposure (same location of spraying and infestation of bugs), total mortality was achieved two days after spraying, indicating a fast acting toxic effect on the insects. This observation highlights the strong effect of direct contact and absorption of the thiamethoxam insecticide, as already shown by Sosa-Gómez et al. (2009)SOSA-GÓMEZ, D. R. et al. Insecticide susceptibility of Euschistusheros (Heteroptera: Pentatomidae) in Brazil. Journal of Economic Entomology, Annapolis , v. 102, n. 3, p. 1209-1216, 2009.. These authors tested insecticides with different actions on the stink bug control and observed that the best results were obtained with thiamethoxam.

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Table 1
Survival (average number of living bugs) of Euschistus heros, in response to the systemic effect of thiamethoxam applied in two different strata of soybean plants, at the R2, R3, R4 and R5.2 stages.

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Table 2
Survival (average number of living bugs) of Euschistus heros, in response to the systemic effect of thiamethoxam applied in three different strata of soybean plants, at the R6 stage (full grain).

The susceptibility of stink bugs to commercial products containing thiamethoxam is widely known (Sosa-Gómez et al. 2009SOSA-GÓMEZ, D. R. et al. Insecticide susceptibility of Euschistusheros (Heteroptera: Pentatomidae) in Brazil. Journal of Economic Entomology, Annapolis , v. 102, n. 3, p. 1209-1216, 2009., Fiorin et al. 2011FIORIN, R. A. et al. Método de aplicação de inseticida no controle de percevejo na cultura da soja. Semina: Ciência Agrárias, Londrina, v. 32, n. 1, p. 139-146, 2011.). The effect of these products is also known for other soybean pests species, such as Piezodorus guildinii (Westwood) (Heteroptera: Pentatomidae) and Nezara viridula (L.) (Heteroptera: Pentatomidae) (Ramiro et al. 2005RAMIRO, Z. A.; BATISTA FILHO, A.; CINTRA, E. R. R. Eficiência do inseticida Actara Mix 110 + 220 CE (thiamethoxam + cipermetrina) no controle de percevejos-pragas da soja. Arquivos do Instituto Biológico, São Paulo, v. 72, n. 2, p. 239-247, 2005., Farias et al. 2006FARIAS, J. R. et al. Eficiência de tiametoxam + lambda-cialotrina no controle do percevejo-verde-pequeno Piezodorus guildinii (Westwood. 1837) (Hemiptera: Pentatomidae) e seletividade para predadores na cultura da soja. Revista da FZVA, Uruguaiana, v. 13, n. 2, p. 10-19, 2006.).

In the experiments with the R2 and R5.2 stages, intermediate survival results were observed for treatments with the application of insecticide in the lower stratum and infestation in the upper stratum. For R2, only 25 % of the stink bugs survived seven days after spraying. In the R5.2 stage experiment, the survival result at seven days after spraying was 70 %, which shows that translocation is more efficient during the R2 stage. From this result it is possible to infer that there is a systemic acropetal effect (via xylem) of thiamethoxam. Cui et al. (2010)CUI, L. et al. Systemic action of novel neonicotinoid insecticide IPP-10 and its effect on the feeding behaviour of Rhopalosiphum padi on wheat. Pest Management Science, New York, v. 66, n. 7, p. 779-785, 2010. showed that this active substance has good mobility via xylem. Souza et al. 2006SOUZA , J. C. et al. Eficiência de thiamethoxan no controle do bicho-mineiro do cafeeiro: I - Influência da modalidade de aplicação. Coffe Science, Lavras, v. 1, n. 2, p. 143-149, 2006. observed that the greatest levels of the thiamethoxam insecticide in leaves were obtained 30 days after the application through irrigation water and can be found in the leaves up to 156 days of application, indicating a slow metabolism (degradation), as observed by Diez-Rodrigues et al. (2006)DIEZ-RODRÍGUEZ, G. I. et al. Resíduos de tiametoxam, aldicarbe e de seus metabólitos em folhas de cafeeiro e efeito no controle de Leucoptera coffeella (Guérin-Mèneville) (Lepidoptera: Lyonetiidae). Neotropical Entomology, Londrina, v. 35, n. 2, p. 257-263, 2006..

When the application of thiamethoxam was held in the upper stratum of the plant and the infestation at the lower stratum, in all soybean stages, the survival of stink bugs was high and did not differ from the results obtained in the control treatment (without insecticide). Thus, it was observed that the basipetal movement of thiamethoxam did not occur in a rate that would be sufficient to control the bugs. Cui et al. (2010)CUI, L. et al. Systemic action of novel neonicotinoid insecticide IPP-10 and its effect on the feeding behaviour of Rhopalosiphum padi on wheat. Pest Management Science, New York, v. 66, n. 7, p. 779-785, 2010. studied the systemicity of IPP-10, which is a neonicotinoid product recently released in the market for wheat, and they observed that the product was translocated via xylem and phloem, increasing the efficiency in controlling insects.

According to Briggs et al. (1982)BRIGGS, G. G.; BROMILOW, R. H.; EVANS, A. A. Relationships between lipophilicity and root uptake and translocation of non-ionised chemicals by barley. Pesticide Science, Tokyo, v. 13, n. 5, p. 495-504, 1982. and Hsu et al. (1990)HSU, F. C.; MARXMILLER, R. L; YANG, A. Y. S. Study of root uptake and xylem translocation of cinmethylin and related compounds in detopped soybean roots using a pressure chamber technique. Plant Physiology, Rockville, v. 93, n. 4, p.1573-1578, 1990. , the translocation of soybean pesticides was observed to occur mainly upward through the xylem, supporting the present study. Thiamethoxam is considered a polar substance and is therefore likely to translocate via xylem, with water and nutrients taken up by plants roots (Cui et al. 2010CUI, L. et al. Systemic action of novel neonicotinoid insecticide IPP-10 and its effect on the feeding behaviour of Rhopalosiphum padi on wheat. Pest Management Science, New York, v. 66, n. 7, p. 779-785, 2010.).

In the experiments conducted during the R3 and R4 stages, with indirect exposure treatments, there was no reduction in the survival rate of bugs, what indicates the absence of lethal doses through the translocation of thiamethoxam in plants. Considering the results of the experiments conducted at the R2 and R5.2 stages, it is evident that, in order to obtain a satisfactory control of this pest, it is important, besides a good coverage, spraying thiamethoxam preferably to the lower strata of the plants. Thus, this information highlights the importance of application technology regarding nozzles, pressure and environmental conditions. The biological efficiency of a spray depends not only on the proven efficiency of the product, but also on the technology used in its application.

In the experiment conducted at R6, the results obtained were similar to those at R3 and R4, with no evidence of systemic effects of thiamethoxam. In these plant development stages, treatments with indirect exposure did not have a significant reduction in the number of bugs, if compared to the control treatment (Table 2).

In the R6 stage, the mass of all vegetative structures of the plants (Ritchie et al. 1985RITCHIE, S. W. et al. How a soybean plant develops . Ames: Iowa State University of Science and Technology Cooperative Extension Service, 1985.), metabolic activity and water demand start to decrease (Souza et al. 2013SOUZA, G. M. et al. Soybean under water deficit: physiological and yield responses. In: BOARD, J. E. (Ed.). A comprehensive survey of international soybean research: genetics, physiology agronomy and nitrogen relationships. Rijeka: InTech, 2013. p. 273-298.). As the translocation of systemic pesticides occurs mainly through the xylem, following the water flow, these physiological changes may have contributed to reduce the systemic effects of thiamethoxam. In addition, it is possible that the conditions of the experiment (in a greenhouse) have accelerated the soybean maturation process, further reducing the water flow in those plants.

CONCLUSIONS

Plants at the R2 and R5.2 soybean phenological stages present acropetal translocation of the active substance thiametoxam, with a more evident effect during the R2 stage.
In the R3, R4 and R6 stages, the product translocation is not sufficient to control stink bugs in plant parts not directly exposed to thiametoxam.
At every stage, treatments with direct exposure had a satisfactory control of stink bugs, what indicates a good contact efficacy.

ACKNOWLEDGMENTS

The authors are thankful to the Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (Capes), for granting a Master's scholarship to the second author; Program of Graduate Studies in Agronomy, Agriculture and Environment of the Universidade Federal de Santa Maria, Campus Frederico Westphalen, and the laboratory teams of the Entomology Section of Embrapa Soja, for their support in conducting these studies; Dr. Samuel Roggia, for his support and assistance in the experiments; and Dr. Maria Cristina Neves de Oliveira, for helping us to interpret the statistical results.

REFERENCES

BLACQUIÈRE, T. et al. Neonicotinoids in bees: a review on concentration, side-effects and risk assessment. Ecotoxicology, Amtsgericht Charlottenburg, v. 21, n. 4, p. 973-992, 2012.
BRIGGS, G. G.; BROMILOW, R. H.; EVANS, A. A. Relationships between lipophilicity and root uptake and translocation of non-ionised chemicals by barley. Pesticide Science, Tokyo, v. 13, n. 5, p. 495-504, 1982.
BRITTAIN, C.; POTTS, S. G. The potencial impacts of insecticides on the life-history traits of bees and the consequences for pollination. Basic and Applied Ecology, Jana, v. 12, n. 4, p. 321-331, 2011.
CAMPOS, H. de. Estatística experimental não-paramétrica 3. ed. Piracicaba: USP, 1979.
CUI, L. et al. Systemic action of novel neonicotinoid insecticide IPP-10 and its effect on the feeding behaviour of Rhopalosiphum padi on wheat. Pest Management Science, New York, v. 66, n. 7, p. 779-785, 2010.
DIEZ-RODRÍGUEZ, G. I. et al. Resíduos de tiametoxam, aldicarbe e de seus metabólitos em folhas de cafeeiro e efeito no controle de Leucoptera coffeella (Guérin-Mèneville) (Lepidoptera: Lyonetiidae). Neotropical Entomology, Londrina, v. 35, n. 2, p. 257-263, 2006.
FARIA, A. B. C. Revisão sobre alguns grupos de inseticidas utilizados no manejo integrado de pragas florestais. Ambiência, Guarapuava, v. 5, n. 2, p. 345-358, 2009.
FARIAS, J. R. et al. Eficiência de tiametoxam + lambda-cialotrina no controle do percevejo-verde-pequeno Piezodorus guildinii (Westwood. 1837) (Hemiptera: Pentatomidae) e seletividade para predadores na cultura da soja. Revista da FZVA, Uruguaiana, v. 13, n. 2, p. 10-19, 2006.
FERREIRA, M. C.; OLIVEIRA, J. R. G. di. Aplicação de fungicidas na cultura da soja com pulverizador costal pressurizado e manual elétrico com bico rotativo para volume baixo: parte 1: cobertura. In: SIMPÓSIO INTERNACIONAL DE TECNOLOGIA DE APLICAÇÃO DE AGROTÓXICOS, 4., 2008, Ribeirão Preto. Anais... Campinas: Instituto Agronômico, 2008.
FIORIN, R. A. et al. Método de aplicação de inseticida no controle de percevejo na cultura da soja. Semina: Ciência Agrárias, Londrina, v. 32, n. 1, p. 139-146, 2011.
GIROLAMI, V. et al. Translocation of neonicotinoid insecticides from coated seeds to seedling guttation drops: a novel way of intoxication for bees. Journal of Economic Entomology, Annapolis, v. 102, n. 5, p. 1808-1815, 2009.
HSU, F. C.; MARXMILLER, R. L; YANG, A. Y. S. Study of root uptake and xylem translocation of cinmethylin and related compounds in detopped soybean roots using a pressure chamber technique. Plant Physiology, Rockville, v. 93, n. 4, p.1573-1578, 1990.
MAIENFISCH, P. et al. Chemistry and biology of thiamethoxam: a second generation neonicotinoid. Pest Management Science, New York , v. 57, n. 1, p. 906-913, 2001.
NAVARINI, L. Resposta de cultivares de soja ao controle químico de ferrugem asiática 74 f. 2008. Dissertação (Mestrado em Produção Vegetal) - Universidade Federal de Santa Maria, Santa Maria, 2008.
PHAM-DELÈGUE, M. H. et al. Behavioral methods to assess the effects of pesticides on honey bees. Apidologie, Amtsgericht Charlottenburg, v. 33, n. 5, p. 425-432, 2002.
RAMIRO, Z. A.; BATISTA FILHO, A.; CINTRA, E. R. R. Eficiência do inseticida Actara Mix 110 + 220 CE (thiamethoxam + cipermetrina) no controle de percevejos-pragas da soja. Arquivos do Instituto Biológico, São Paulo, v. 72, n. 2, p. 239-247, 2005.
REETZ, J. E. et al. Neonicotinoid insecticides translocated in guttated droplets of seed-treated maize and wheat: a threat to honeybees? Apidologie, Amtsgericht Charlottenburg, v. 42, n. 6, p. 596-606, 2011.
RITCHIE, S. W. et al. How a soybean plant develops . Ames: Iowa State University of Science and Technology Cooperative Extension Service, 1985.
SOSA-GÓMEZ, D. R. et al. Insecticide susceptibility of Euschistusheros (Heteroptera: Pentatomidae) in Brazil. Journal of Economic Entomology, Annapolis , v. 102, n. 3, p. 1209-1216, 2009.
SOSA-GÓMEZ, D. R.; CORSO, I. C.; MORALES, L. Insecticide resistance to endosulfan: monocrotophos and metamidophos in the neotropical brown stink bug Euschistus heros (Fabr.). Neotropical Entomology, Londrina, v. 30, n. 2, p. 317-320, 2001.
SOSA-GÓMEZ, D. R.; SILVA, J. J. Neotropical brown stink bug (Euschistus heros) resistance to methamidophos in Paraná, Brazil. Pesquisa Agropecuária Brasileira, Brasília, DF, v. 45, n. 7, p. 767-769, 2010.
SOUZA , J. C. et al. Eficiência de thiamethoxan no controle do bicho-mineiro do cafeeiro: I - Influência da modalidade de aplicação. Coffe Science, Lavras, v. 1, n. 2, p. 143-149, 2006.
SOUZA, G. M. et al. Soybean under water deficit: physiological and yield responses. In: BOARD, J. E. (Ed.). A comprehensive survey of international soybean research: genetics, physiology agronomy and nitrogen relationships. Rijeka: InTech, 2013. p. 273-298.

Publication Dates

Publication in this collection
Jan-Mar 2016

History

Received
Dec 2015
Accepted
Mar 2016

Este é um artigo publicado em acesso aberto sob uma licença Creative Commons

[1] BLACQUIÈRE, T. et al. Neonicotinoids in bees: a review on concentration, side-effects and risk assessment. Ecotoxicology, Amtsgericht Charlottenburg, v. 21, n. 4, p. 973-992, 2012.

[2] BRIGGS, G. G.; BROMILOW, R. H.; EVANS, A. A. Relationships between lipophilicity and root uptake and translocation of non-ionised chemicals by barley. Pesticide Science, Tokyo, v. 13, n. 5, p. 495-504, 1982.

[3] BRITTAIN, C.; POTTS, S. G. The potencial impacts of insecticides on the life-history traits of bees and the consequences for pollination. Basic and Applied Ecology, Jana, v. 12, n. 4, p. 321-331, 2011.

[4] CAMPOS, H. de. Estatística experimental não-paramétrica 3. ed. Piracicaba: USP, 1979.

[5] CUI, L. et al. Systemic action of novel neonicotinoid insecticide IPP-10 and its effect on the feeding behaviour of Rhopalosiphum padi on wheat. Pest Management Science, New York, v. 66, n. 7, p. 779-785, 2010.

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Treatments		Days after application¹ 1 Average number with the same letter in the column, within each stage, do not differ by the Tukey test at 1 %.
Strata insecticide application	Strata infestation	1	2	3	4	5	6	7
R2
Inferior	Inferior	0.1 c	0.0 c	0.0 c	0.0 c	0.0 d	0.0 c	0.0 b
Inferior	Superior	2.9 b	2.8 b	2.4 b	1.9 b	1.7 c	1.3 b	1.0 b
Superior	Inferior	3.9 a	3.8 ab	3.7 a	3.4 a	3.3 ab	2.6 ab	2.5 a
Superior	Superior	0.2 c	0.0 c	0.0 c	0.0 c	0.0 d	0.0 c	0.0 b
Without insecticide	Inferior	4.0 a	4.0 a	4.0 a	4.0 a	3.8 a	3.4 a	3.0 a
Without insecticide	Superior	4.0 a	3.8 ab	3.8 a	3.2 a	2.4 cb	2.4 ab	2.2 a
CV (%)²		21.6	21.54	23.3	23.3	23.6	28.6	29.9
R3
Inferior	Inferior	0.8 b	0.7 b	0.7 b	0.6 b	0.1 b	0.1 b	0.1b
Inferior	Superior	3.5 a	3.2 a	3.2 a	3.2 a	2.9 a	2.7 a	2.6 a
Superior	Inferior	3.9 a	3.6 a	3.6 a	3.3 a	3.1 a	2.9 a	2.7 a
Superior	Superior	1.1 b	0.6 b	0.6 b	0.6 b	0.5 b	0.4 b	0.3 b
Without insecticide	Inferior	4.0 a	4.0 a	4.0 a	4.0 a	3.8 a	3.6 a	3.0 a
Without insecticide	Superior	4.0 a	4.0 a	4.0 a	3.8 a	3.3 a	3.0 a	3.0 a
CV (%)²		23.8	26.5	26.5	28.3	26.2	28.5	28.8
R4
Inferior	Inferior	1.2 b	1.4 b	1.3 b	0.9 b	0.7 b	0.5 b	0.3 b
Inferior	Superior	4.0 a	4.0 a	3.9 a	3.9 a	3.7 a	3.5 a	3.3 a
Superior	Inferior	4.0 a	4.0 a	4.0 a	3.9 a	3.9 a	3.9 a	3.9 a
Superior	Superior	2.4 b	2.5 b	1.6 b	1.3 b	0.4 b	0.3 b	0.3 b
Without insecticide	Inferior	4.0 a	3.8 a	3.8 a	3.8 a	3.8 a	3.8 a	3.8 a
Without insecticide	Superior	4.0 a	4.0 a	4.0 a	4.0 a	4.0 a	4.0 a	4.0 a
CV (%)²		22.16	20.56	18.77	21.02	21.88	22.33	21.99
R5.2
Inferior	Inferior	0.6 b	0.0 c	0.0 c	0.0 c	0.0 c	0.0 c	0.0 c
Inferior	Superior	3.5 a	3.3 b	3.3 b	3.0 b	2.8 b	2.8 b	2.8 b
Superior	Inferior	3.9 a	3.8 a	3.8 a	3.8 a	3.8 a	3.8 a	3.8 a
Superior	Superior	0.2 b	0.0 c	0.0 c	0.0 c	0.0 c	0.0 c	0.0 c
Without insecticide	Inferior	3.8 a	3.8 a	3.8 a	3.8 a	3.8 a	3.8 a	3.8 a
Without insecticide	Superior	4.0 a	4.0 a	4.0 a	4.0 a	4.0 a	4.0 a	4.0 a
CV (%)²		24.6	16.4	16.4	18.5	17.7	17.7	17.7

Treatments		Days after application¹ 1 Average number with the same letter in the column, within each stage, do not differ by the Kruskal-Wallis test and the treatment means compared by the chi-square test at 1 %.
Strata of insecticide application	Strata of infestation	2	3	4	5	6	7	8	9	10	11	14
Inferior	Inferior	1.4 b	1.1 b	0.9 b	0.5 b	0.4 b	0.2 b	0.1 b	0.0 c	0.0 c	0.0 c	0.0 b
	Intermediate	4.9 a	4.8 a	4.8 a	4.8 a	4.6 a	4.5 a	4.5 a	4.2 b	4.2 b	4.2 b	4.1 a
	Superior	5.0 a	4.8 a	4.8 a	4.8 a	4.6 a	4.6 a	4.4 a	4.2 b	4.2 b	4.1 b	4.0 a
Intermediate	Inferior	4.9 a	4.9 a	4.8 a	4.8 a	4.7 a	4.7 a	4.5 a	4.4 b	4.4 b	4.2 b	3.6 a
	Intermediate	1.6 b	1.2 b	1.2 b	1.1 b	1.1 b	1.1 b	1.0 b	1.1 c	1.0 c	0.9 c	0.8 b
	Superior	4.8 a	4.7 a	4.6 a	4.6 a	4.6 a	4.5 a	4.2 a	4.2 b	3.9 b	3.9 b	3.8 a
Superior	Inferior	5.0 a	4.8 a	4.8 a	4.6 a	4.4 a	4.4 a	4.2 a	4.0 b	3.9 b	3.6 b	3.6 a
	Intermediate	4.8 a	4.8 a	4.9 a	4.9 a	4.9 a	4.9 a	4.9 a	4.9 a	4.9 a	4.8 a	4.6 a
	Superior	2.0 b	2.0 b	1.9 b	1.9 b	1.5 b	1.4 b	1.4 b	1.1 c	1.1 c	0.9 c	0.9 b
Without insecticide	Inferior	5.0 a	5.0 a	5.0 a	5.0 a	4.9 a	4.9 a	4.9 a	4.9 a	4.8 a	4.8 a	4.7 a
	Intermediate	4.9 a	4.8 a	4.8 a	4.7 a	4.5 a	4.5 a	4.5 a	4.5 b	4.4 b	4.4 b	4.2 a
	Superior	5.0 a	5.0 a	5.0 a	5.0 a	4.8 a	4.8 a	4.8 a	4.8 b	4.8 a	4.7 b	4.7 a
CV (%)		18.8	25.3	25.9	27.25	31.8	32.0	31.9	32.0	32.3	33.0	34.8

Brasil