DOI: 10.13102/sociobiology.v64i3.1070Sociobiology 64(3): 256-260 (September, 2017)

Open access journal: http://periodicos.uefs.br/ojs/index.php/sociobiology
ISSN: 0361-6525

Effects of Diafenthiuron in Toxic Baits on Colonies of Leaf-cutting ants (Hymenoptera: 
Formicidae)

Introduction

The leaf-cutting ants are considered important pest 
insects in agricultural and forestry crops by causing economic 
damage in areas of the Neotropical region, mainly in Brazil 
(Reis et al., 2010). The main challenge in controlling leaf-
cutting ants is the search for insecticides which are less 
harmful to agricultural ecosystems, but still effective when 
formulated as toxic granular baits (Forti et al., 2007).

Some insecticides have already been tested for control 
of leaf-cutting ants, such as chlorpyriphos (Forti et al., 2003), 
diflubenzuron and dechlorane (Nagamoto et al., 2007), but 
without success in manufacturing and marketing them as 
formicide baits. However, diafenthiuron (C23H32N2OS) is 
presented as a promising formicide; its activity against other 
groups of insects and mites is very well known (Ishaaya et al., 

Abstract 
Dianfenthiuron is a pre-insecticide that can be activated by photolysis, and may be a 
promising formicide. This study evaluated the effect of diafenthiuron after photolysis 
in colonies of Atta sexdens rubropilosa Forel, 1908. The experiment was conducted 
in a completely randomized design with five treatments and five replications: control 
(no active ingredient), sulfluramid (standard formicide), diafenthiuron (no exposure 
to UV), diafenthiuron (2h exposure to UV) and diafenthiuron (6h exposure to UV). 
Toxic baits were applied at a rate of 0.5 g per colony, and we observed the transport 
and incorporation of the baits into the colonies. A grading scale was used (0 to 4) to 
measure the cutting of Acalypha L. (Euphorbiaceae) leaves by workers at 2, 7, 14 and 21 
days after application (DAA) and we also measured the garden mass (fungus + adult + 
brood) at 21 DAA in order to check for growth of the fungus culture. Total loading and 
incorporation occurred one hour after application of the baits. Colonies that received 
sulfluramid did not transport leaves at 2 DAA. Workers that received baits with D2h 
showed an average of 20% transport and 55% incorporation of leaves at 21 DAA. The 
grading scale indicated that treatments D2h and D6h had the lowest averages, 0.80 and 
2.00, respectively. The treatments D2h and D6h reduced cutting of leaves and fungus 
garden mass, but did not kill the colonies of A. sexdens rubropilosa.

Sociobiology
An international journal on social insects

MS Barbosa1, LC Forti2, RT Fujihara3, CG Raetano2

Article History

Edited by
Evandro N. Silva, UEFS, Brazil
Received                     16 May 2016
Initial acceptance       08 January 2017
Final acceptance    07 May 2017
Publication date        17 October 2017

Keywords 
Atta, chemical control, ultraviolet light, 
carbodiimide.

Corresponding author
Marcílio Souza Barbosa
Laboratório de Entomologia e Acarologia
Universidade Federal de Alagoas
Campus de Arapiraca, P.O. Box 61
CEP 57309-005 - Arapiraca-AL, Brasil.
E-Mail: agromss@hotmail.com

2007). Moreover, as it affects cellular respiration (Dekeyser, 
2005), its mechanism of action in insects is similar to that of 
sulfluramid, which is the main active ingredient in toxic baits.

Diafenthiuron is a pre-insecticide that, after photolysis, 
is converted into carbodiimide, becoming a potent insecticide 
(Ruder & Kayser, 1993). This physical-chemical characteristic 
can be manipulated in the laboratory. In this context, the present 
study evaluated the effect of diafenthiuron after photolysis, 
when supplied in formulation of toxic bait to colonies of Atta 
sexdens rubropilosa Forel, 1908.

Material and Methods

Study site

In 2012, young colonies (8 months old) from the 
Laboratory of Social Pest Insects, FCA/UNESP, Botucatu, São 

1 - Universidade Federal de Alagoas (UFAL), Arapiraca-AL, Brazil
2 - Faculdade de Ciências Agronômicas (FCA/UNESP), Botucatu-SP, Brazil
3 - Universidade Federal de São Carlos (CCA/UFSCar), Araras-SP, Brazil

RESEARCH ARTICLE - ANTS



Sociobiology 64(3): 256-260 (September, 2017) 257

Paulo, Brazil, were maintained under controlled temperature 
and humidity (24°C ± 2 and 70 ± 5%) in plastic containers 
with a capacity of 395 mL volume for the fungus chamber and 
250 mL for the waste and foraging chambers.

At the fungus chamber, a 1.0 cm plaster layer was 
placed at the base (maintenance of humidity). Colonies were 
given leaves of Acalypha L. (Euphorbiaceae) as vegetable 
substrate, which were offered in a natural state or dehydrated, 
according to humidity conditions.

Preparation and application of treatments

The baits applied to the colonies of A. sexdens 
rubropilosa had the following treatments: Ctl - control (no 
active ingredient); Sul - sulfluramid (standard formicide - 
0.3% of the active ingredient - Mirex-S®); Dne - diafenthiuron 
(no exposure to ultraviolet light); D2h - diafenthiuron [2h 
exposure to ultraviolet light (UV)] and; D6h - diafenthiuron 
[6h exposure to ultraviolet light (UV)]. The use of sulfluramid 
as formicide is already known (Zanetti et al., 2003; Nagamoto 
et al., 2004), and so it was used as a standard comparative to 
diafenthiuron.

Treatments with diafenthiuron contained the following 
ingredients: vegetable soybean oil (Soya®) (5%), dehydrated 
citrus pulp (94%), active ingredient (1%) and distilled water. 
The treatments D2h and D6h were mixed with a solution of 
acetone + distilled water (3:1) and then exposed to ultraviolet 
light with a peak wavelength of 253nm (TUV-30W T8, 
Philips Electronics Brasil®) (adapted and modified from Keum 
et al., 2002) during the predetermined periods (2h and 6h). 
Afterwards, they remained in the absence of light for 24 
hours for the decomposition into bioactive forms (mainly 
carbodiimide).

We applied 0.5g baits/colony, the equivalent of 22 
pellets of 0.5 cm in length each. The baits were offered in 
the foraging chamber only once, when it was observed the 
transport and the incorporation to the colony. 

Evaluations and data analysis

A grading scale was used [(grading - cutting % - leaf 
cutting area cm2): 0-0-0.00; 1-25-17.38; 2-50-34.76; 3-75-
52.14; 4-100-69.52] to evaluate the cutting of leaves of 
Acalypha by workers after the treatment with baits at 2, 7, 14 
and 21 days after application (DAA).

This scale was designed based on the average sampling 
of Acalypha leaves supplied daily (1 whole leaf of average size 
for each colony) after analysis of leaf area by the equipment 
LI-COR® BIOSCIENCES (LI-3100C AREA METER). The 
mass of the garden (fungus + adult + brood) was also measured 
at 21 DAA, to check for growth of the fungus culture.

The experiment was conducted in a completely 
randomized design with five treatments (bait) and five 
replications, each plot was represented by a colony. To assess 

the cutting of Acalypha leaves (grading scale), it was used 
a factorial arrangement (5x4), where the first factor was the 
group of treatments with baits, and the second, the days after 
application of baits (DAA), comparing the means by Tukey’s 
test (P <0.05).

Data of transport and incorporation of the leaves were 
evaluated in percentage. Differences in the growth of the 
fungus culture (mass) were tested by analysis of variance with 
comparison of means of treatments with baits by Tukey’s test 
(P <0.05). The assumption of normality was tested by Shapiro-
Wilk test (P <0.05). The statistical analysis was performed in 
the Sisvar 5.3 software (Ferreira, 2011).

Results and Discussion

Total transport and incorporation of baits were observed 
in all treatments, one hour after application. Although young, 
the colonies exhibited significant foraging activity throughout 
the rearing period. However, at 2 DAA, the workers that 
received sulfluramid no longer transported leaves (Fig 1-A) 
and showed visible symptoms of poisoning, such as slow 
motion, stretched and paralyzed hind legs (Nagamoto et al., 
2007), reducing or even stopping the execution of the task.

At 7 DAA, only the colonies that received the treatment 
Ctl continued to transport leaves in a way similar to that 
observed before the beginning of the experiment. The treatments 
D2h and D6h have already demonstrated reduced transport of 
leaves (Fig 1-A). In the treatment Ctl, 100% of the transported 
leaves were incorporated, and the percentages were higher 
than 90% in Dne and D6h. On the other hand, at 7 DAA, there 
was no incorporation in Sul, due to the mortality of workers 
and in D2h, the average incorporation of leaves was reduced 
by 55% at 21 DAA (Fig 1-B).

The grading scale for the cutting of leaves of Acalypha 
by foragers (F = 115.94; P = 0.0001) (Table 1) assigned 
the highest score to the treatment Ctl, and then to Dne. The 
treatments D2h and D6h reached intermediate scores because 
the workers made the cut, but carried few fragments to the 
fungus chamber. On the other hand, sulfluramid prevented 
the cutting of leaves by the workers, yielding a score of zero 
(no cutting). This score refers to the disruption of the activity, 
because ants stop performing it after contact with the bait 
containing this active ingredient.

However, the average of the grading scale was obtained 
regardless of the period of observation of the cutting behavior, 
because the worker can reduce, maintain or increase this 
activity when under the effect of active ingredients. Thus, the 
evaluation of cutting of leaves was based on the significant 
interaction between treatments (bait) and DAA (F = 3.39; P 
= 0.0005) breaking down the treatments within each day and 
using the grading scale in the period from 7 to 21 DAA (Table 
1). Thus, Ctl colonies maintained an average of about 4.00 in 
all periods analyzed. In Dne, the cutting of leaves decreased 
over time (3.00) and D2h showed a marked decrease (0.80).



MS Barbosa, LC Forti, RT Fujihara, CG Raetano – Effects of Diafenthiuron on Leaf-cutting ants258

To assess the general development of the colony, we 
analyzed the growth based on the mass of the fungus chamber 
= queen, workers and brood (F = 25.75, P = 0.0001) (Table 2). 
At 21 DAA, the mass of A. sexdens rubropilosa was higher 
in Ctl due to lack of active ingredient, followed by Dne, D2h 
and D6h. There was no assessment in Sul, given the total 
mortality of the colony.

Aspects of poisoning of workers (symptoms), presence 
of dead ants, growth of contaminant yeast (mainly Escovopsis 
Muchovej & Della Lucia, Ascomycetes) and survival of the 
colony at the end of the study are shown in Table 3. The effect 
of baits in the colonies of A. sexdens rubropilosa was only 
detected when baits contained the active ingredient sulfluramid.

This result was remarkable in this treatment for all 
the variables cited, however, the baits applied with Dne, D2h 
and D6h caused symptoms of poisoning, reduced mobility 
(slowness) during the first DAA, but somehow ants managed 
to regain mobility without affecting survival of the colony, 
only changing the natural state of development. A general 
analysis of diafenthiuron efficiency as formicide leads to 
some questions before assessing its actual effect on colonies 
of A. sexdens rubropilosa:

The bait was attractive? When preparing a formicide, 
the attractiveness can directly affect the efficiency, because it 
is essential to encourage the contact and ingestion with the active 
ingredient, thus allowing the contamination by the insecticide. 

However, the transport by the workers was 100% one hour after 
application of baits, proving the attractiveness of citrus pulp, 
which has been already recognized (Brugger et al., 2008).

Were the colonies in constant foraging? Another problem 
is the activity of the colonies prior to experimentation (rearing 
stage), because according to Delabie et al. (2000), it is important 
to make sure that nests used in experiments of attractiveness are 
active. These should have good transport of leaves and large 
size workers (head width greater than 2 mm). Although some of 
these steps are determined for experimentation in the field, they 
must also be taken in the laboratory (Nagamoto et al., 2004), 
since they can mask the efficiency of promising insecticides.

Was there a simple rejection (selection) of the leaves of 
Acalypha after application of baits? In Figure 1-A, treatments 
with diafenthiuron reduced the transport of leaves, reaching 
only 20% with D2h. In this case, it would hardly be possible, 
because from the beginning of rearing it has been offered, cut 
and transported the same plant material, preventing confusion 
in the selection due to the conditioning of foragers workers 
and scouts to remain with this odor, making it a characteristic 
sign of the substrate, as mentioned by Brugger et al. (2008).

Once clarified these questions they may be disregarded, 
because all colonies transported the baits efficiently and did 
not discharge them in the waste chamber, or in the foraging 
chamber, in observations held 24 hours after application.

What is the mechanism of action of diafenthiuron? 
Sulfluramid is a chemical compound that acts directly on 
the mitochondria by inhibiting the ATP synthesis (adenosine 
triphosphate). The de-ethylated metabolite of sulfluramid is 
produced by the metabolism of cytochrome P450, a potent 
electron uncoupler of the mitochondrial respiratory chain, 
interrupting the production of energy. This disruption and 
subsequent loss of ATP results in inactivity, paralysis and 
death of the insect exposed to sulfluramid (Heong et al., 
2011). Diafenthiuron also has a mechanism of action similar 
to sulfluramid in insects and mites (Ruder & Kayser, 1993), 
which could be enhanced when subjected to UV, as it is a pre-
insecticide, which needs to turn into a secondary metabolite, 
such as the carbodiimide, to become a potent insecticide 
(Kayser & Eilinger, 2001; Dekeyser, 2005).

Table 1. Grading scale (0 to 4) for the cutting of Acalypha sp. leaves by Atta sexdens rubropilosa workers after the treatment 
with baits at 2, 7, 14 and 21 DAA (days after application).

Treatment
DAA

2 7 14 21
Ctl 3.80 ± 0.20 cA 3.80 ± 0.20 dA 3.60 ± 0.24 dA 4.00 ± 0.00 cA
Sul 0.00 ± 0.00 aA 0.00 ± 0.00 aA 0.00 ± 0.00 aA 0.00 ± 0.00 aA
Dne 3.80 ± 0.20 cA 3.40 ± 0.40 cdA 3.40 ± 0.24 cdA 3.00 ± 0.00 bcA
D2h 3.80 ± 0.20 cC 2.40 ± 0.60 bcB 1.60 ± 0.24 bAB 0.80 ± 0.37 aA
D6h 2.04 ± 0.24 bA 2.00 ± 0.32 bA 2.20 ± 0.37 bcA 2.00 ± 0.32 bA

Means, within a column/row, followed by different small/capital letters are different by Tukey test (P<0,05). Treatments: Ctl (control); Sul 
(sulfluramid); Dne (diafenthiuron no exposure to ultraviolet light), D2h (diafenthiuron with 2h exposure to ultraviolet light); D6h (diafenthiuron 
with 6h exposure to ultraviolet light). D6h (diafenthiuron with 6h exposure to ultraviolet light). DAA: days after application.

Treatment Fungus garden + adults + offspring (g)
Ctl 30.38 ± 1.46 c
Dne 26.00 ± 1.22 b
D2h 22.85 ± 0.24 b
D6h 17.35 ± 0.97 a
Coefficient of 
variation (%)

10,00

Means followed by different letters are significantly different by Tukey 
test (P<0,05). Treatments: Ctl (control); Dne (diafenthiuron no exposure 
to ultraviolet light), D2h (diafenthiuron with 2h exposure to ultraviolet 
light); D6h (diafenthiuron with 6h exposure to ultraviolet light).

Table 2. Mass of the fungus of Atta sexdens rubropilosa colonies 21 
DAA (days after application).



Sociobiology 64(3): 256-260 (September, 2017) 259

Diafenthiuron was initially developed to control pests, 
such as mites, white flies and aphids (Kayser & Eilinger, 
2001). Given the low toxicity to some species of insects, it 
has been reported as a promising insecticide when applied 
at recommended doses, and with potential to be used in 
Integrated Pest Management (IPM), as it is not harmful to 
beneficial insects, especially the biological control agents of 
insect pests (Preetha et al., 2009).

Among these, stands out the predator of aphids 
Chrysoperla carnea (Stephens, 1836) (Neuroptera: Chrysopidae), 
beetles of the family Coccinellidae and Trichogramma spp. 
(Hymenoptera: Trichogrammatidae) wasps. For C. carnea, for 
instance, the application of a high dose of diafenthiuron (3.2 
g.L-1) caused 53% of adult mortality, and a low dose (0.8 g.L-1), 
only 3%, showing low effect on this species, as the increase in 

diafenthiuron by up to four times only increased by 50% the 
adult mortality (Preetha et al., 2009).

In leaf-cutting ants, the low toxicity of diafenthiuron, 
when ingested, can be explained by two ways: (i) due to the 
possibility of low dose application to the treated colonies, 
which reduces the effect of the compound, and (ii) due to 
the resistance of workers to the insecticide, which may 
have presented mechanisms of detoxification in relation to 
diafenthiuron or its secondary metabolite, although it had 
affected the execution of activities by workers.

At last, treatments containing D2h and D6h reduced 
the cutting of leaves and fungus garden mass, but did not kill 
the colonies of A. sexdens rubropilosa. Bueno (2013) also 
studied the toxicity of active ingredients (diafenthiuron and 
tolfenpyrad) in A. sexdens rubropilosa workers and the results 
showed significant reduction in the survival of workers when 
compared with controls of each ingredient, particularly when 
they were dissolved in soybean oil. However, baits containing 
the active ingredients were not effective in controlling colonies 
of A. sexdens rubropilosa. Diafenthiuron did not kill the colonies 
of A. sexdens rubropilosa on the doses studied, however it 
should be tested in other dosages of ultraviolet light and in 
different formulations or in consortium with other chemicals 
compounds before being totally discarded as formicide.

After photolysis by UV, diafenthiuron interfered with 
the cutting and transport of leaves to the colony, but was not 
efficient against young colonies of A. sexdens rubropilosa. 
The colonies of leaf-cutting ants that received toxic baits with 
diafenthiuron (6h exposure to UV) developed less mass of the 
fungus 21 days after application.

Acknowledgments

The first author would like to thank Coordenadoria de 
Aperfeiçoamento de Pessoal de Nível Superior (CAPES) for 
a granted scholarship.

References

Brugger, M. S., Fernandes, M. A. C., Hallack, N. M. R. 
& Lopes, J. F. S. (2008). Avaliação dos efeitos tóxicos de 
extrato hexânico de Azadirachta indica (A. Juss) em colônias 
de Acromyrmex rugosus (Smith, 1858) (Formicidae, Attini). 
Revista Brasileira de Zoociências, 10: 233-238.

Bueno, F. C. Seleção de ingredientes ativos para o 
desenvolvimento de iscas tóxicas para o controle de 
formigas-cortadeiras (Hymenoptera: Formicidae). 2013. 
Tese (Doutorado em Ciências Biológicas) – Botucatu-SP, 
Universidade Estadual Paulista, 75p.

Dekeyser, M. A. (2005). Acaricide mode of action. Pest 
Management Science, 61: 103-110. doi: 10.1002/ps.994

Delabie, J.H.C., Della Lucia, T. & Pastre, L. (2000). 
Protocolo de experimentação para avaliar a atratividade 

Fig 1. Transport of Acalypha leaves (A) and substrate incorporation 
(B) by A. sexdens rubropilosa workers after application of baits. 
Treatments: Ctl (control); Sul (sulfluramid); Dne (diafenthiuron no 
exposure to ultraviolet light), D2h (diafenthiuron with 2h exposure to 
ultraviolet light); D6h (diafenthiuron with 6h exposure to ultraviolet 
light). DAA (days after application).

Treatment

State of colonies

Intoxication Dead ants
Contaminant 

fungus
Dead 

colonies
Ctl DNO NM DNO DNO
Sul 1 DAA TM 3 DAA 5 DAA
Dne OFDAA NM DNO DNO
D2h OFDAA NM DNO DNO
D6h OFDAA NM DNO DNO

Treatments: Ctl (control); Sul (sulfluramid); Dne (diafenthiuron no exposure 
to ultraviolet light), D2h (diafenthiuron with 2h exposure to ultraviolet light); 
D6h (diafenthiuron with 6h exposure to ultraviolet light). DNO: do not oc-
curred. DAA: days after application. OFDAA: occurred in the first days after 
application. NM: natural mortality. TM: total mortality.

Table 3. General state of Atta sexdens rubropilosa colonies after 
application of baits. 



MS Barbosa, LC Forti, RT Fujihara, CG Raetano – Effects of Diafenthiuron on Leaf-cutting ants260

de novas formulações de iscas granuladas utilizadas no 
controle das formigas cortadeiras Acromyrmex spp. e Atta spp. 
(Hymenoptera: Formicidae: Myrmicinae: Attini) no campo. 
Anais da Sociedade Entomológica do Brasil, 29: 843-848. 
doi: 10.1590/S0301-80592000000400029

Ferreira, D.F. (2011). Sisvar: um sistema computacional de 
análise estatística. Ciência e Agrotecnologia, 35: 1039-1042. 
doi: 10.1590/S1413-70542011000600001

Forti, L.C., Nagamoto, N.S., Ramos, V.M., Andrade, A.P.P., 
Lopes, J.F.S., Camargo, R.S., Moreira, A.A. & Boaretto, M.A.C. 
(2003). Eficiencia de sulfluramida, fipronil y clorpirifoscomo 
sebos en el control de Atta capiguara Gonçalves (Hymenoptera: 
Formicidae). Pasturas Tropicales, 25: 28-35. 

Forti, L.C., Pretto, D.R., Nagamoto, N.S., Padovani, C.R., 
Camargo, R.S. & Andrade, A.P.P. (2007). Dispersal of the 
delayed action insecticide sulfluramid in colonies of the 
leaf-cutting ant Atta sexdens rubropilosa (Hymenoptera: 
Formicidae). Sociobiology, 50: 1149-1163.

Heong, K.L., Tan, K.H., Garcia, C.P.F., Fabellar, L.T. & Lu, 
Z. (2011). Research methods in toxicology and insecticide 
resistance monitoring of rice planthoppers. Los Baños 
(Philippines): International Rice Research Institute, 101p. 

Ishaaya, I., Barazani, A., Kontsedalov, S. & Horowitz, A.R. 
(2007). Insecticides with novel modes of action: mechanism, 
selectivity and cross-resistance. Entomological Research, 37: 
148-152. doi: 10.1111/j.1748-5967.2007.00104.x

Kayser, H. & Eilinger, P. (2001). Metabolism of diafenthiuron 
by microsomal oxidation: procide activation and inactivation 
as mechanisms contributing to selectivity. Pest Management 
Science, 57: 975-980. doi: 10.1002/ps.360

Keum, Y-S., Kim, J.H., Kim, Y.W., Kim, K. & Li, Q.X. 
(2002). Photodegradation of diafenthiuron in water. Pest 
Management Science, 58: 496-502. doi: 10.1002/ps.483

Nagamoto, N.S., Forti, L.C. & Raetano, C.G. (2007). Evaluation 
of the adequacy of diflubenzuron and dechlorane in toxic 
baits for leaf-cutting ants (Hymenoptera: Formicidae) based 
on formicidal activity. Journal of Pest Science, 80: 9-13. doi: 
10.1007/s10340-006-0143-8

Nagamoto, N.S., Forti, L.C., Andrade, A.P.P., Boaretto, 
M.A.C. & Wilcken, C.F. (2004). Method for the evaluation 
of insecticidal activity over time in Atta sexdens rubropilosa 
workers (Hymenoptera: Formicidae). Sociobiology, 44: 413-431.

Preetha, G., Stanley, J., Manoharan, T., Chandrasekaran, S. & 
Kutallam, S. (2009). Toxicity of imidacloprid and diafenthiuron 
to Chrysoperla carnea (Stephens) (Neuroptera: Chrysopidae) 
in the laboratory conditions. Journal of Plant Protection 
Research, 49: 290-296. doi: 10.2478/v10045-009-0047-8.

Reis, M.A., Zanetti, R., Scolforo, J.R.S. & Ferreira, M.Z. 
(2010). Amostragem de formigas-cortadeiras (Hymenoptera: 
Formicidae) em eucaliptais pelos métodos de transectos em 
faixa e em linha. Revista Árvore, 34: 1101-1108. doi: 10.1590/
S0100-67622010000600016

Ruder, F.J. & Kayser, H. (1993). The carbodiimide product 
of diafenthiuron inhibts mitochondria in vivo. Pesticide 
Biochemistry and Physiology, 46: 96-106. doi: 10.1006/
pest.1993.1041

Zanetti, R., Zanuncio, J.C., Souza-Silva, A. & Abreu, 
L.G. (2003). Eficiência de isca formicida aplicada sobre o 
monte de terra solta de ninhos de Atta sexdens rubropilosa 
(Hymenoptera: Formicidae). Revista Árvore, 27: 410-407. 
doi: 10.1590/S0100-67622003000300019