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459 
Bioscience Journal  Original Article 

Biosci. J., Uberlândia, v. 35, n. 2, p. , Mar./Apr. 2019 
http://dx.doi.org/10.14393/BJ-v35n2a2019-41780 

Musa acuminata PSEUDOSTEM EXTRACT ON THE CONTROL OF Atta 
sexdens rubropilosa 

 
EXTRATO DE PSEUDOCAULE DE Musa acuminata NO CONTROLE DE Atta 

sexdens rubropilosa 
 

Thais Cibeli da SILVA
1
 ; Alcilene Batista de CAMARGO

1
; Laura Araújo SANCHES

2*
;  

Juliana GARLET
3
 

1. Engenheira Florestal, Universidade do Estado de Mato Grosso, Campus II - Av. Perimetral Rogério Silva, s/n-Jardim Flamboyant, 
Alta Floresta, Mato Grosso; 2. Engenheira Florestal, Mestranda em Biodiversidade e Agroecossistemas Amazônicos, Universidade do 

Estado de Mato Grosso, Campus II - Av. Perimetral Rogério Silva, s/n-Jardim Flamboyant, Alta Floresta, Mato Grosso; 
laura_araujo_@hotmail.com; 3. Professora, Dra. da Faculdade de Ciências Biológicas e Agrárias da Universidade do Estado de Mato 

Grosso, Campus II - Av. Perimetral Rogério Silva, s/n-Jardim Flamboyant, Alta Floresta, Mato Grosso. 
 

ABSTRACT: Currently, few active principles are authorized by the forest certification for the control 
of insect pests, with which it is necessary to develop new products, mainly aiming at lower environmental 
impact. The plants are able to develop substances called secondary metabolites, widely studied as an alternative 
form of pest control. Thus, the objective of this study was to evaluate the insecticidal potential of two Musa 
acuminata extracts, on the control of Atta sexdens rubropilosa. The extracts were obtained from the 
pseudostem of M. acuminata, which underwent drying and milling, producing two extracts: ethanolic (A1) and 
hydroethanolic rotaevaporate (A2) extract. For the analysis of the bioactivity of the extracts, a topical 
application of one milliliter of each extract on the ants was carried out, with the aid of spray, in the 
concentrations of: 2, 6, 10, 14, 18, and 20%, with distilled water (witness) applied to the test, analyzing the 
mortality and LC50, in different evaluation periods. At 24 hours the mortality of 90% at the concentration of 
20% for the A1 extract was observed. From the 10% concentration there was 100% mortality in this same 
period for the A2 extract, and at 48 hours the 2% concentration caused 100% mortality. In the LC50 analysis for 
24 hours values of 7.94 and 1.09% were obtained for ethanolic extract and rotavaporated ethanolic extract 
respectively. And the LC50 presented a decrease in values after 48 hours for the ethanolic extract presented 
value of 2.29%. Thus, it can be concluded that the A2 extract is the most efficient, since it allows the lower 
consumption of extract in the dilution for later application, due to the presence of insecticidal potential in low 
concentration. 

 
KEYWORKS: Solid waste. Secondary metabolite. Insecticide. Forest entomology. 

 
INTRODUCTION 

 
Cutting ants are American insects and 

scatter throughout Central and South America, 
except Chile. In Brazil there are 20 species and nine 
subspecies of Acromyrmex, ten species and three 
subspecies of Atta. Among the species that cause 
greater damages is the saúva lemon (Atta sexdens 
Forel) which has a wide distribution in the Brazilian 
territory. The habit of cutting leaves characterizes 
the leaf-cutting ants as the main plagues of forest 
and agricultural plantations, even destroying a 
culture totally or partially (HEBLING et al., 2000; 
DELABIE et al, 2011; OLIVEIRA et al., 2018).  

Currently in Brazil, the control of leaf 
cutting ants has been carried out with the application 
of formicidal baits, mainly based on Sulfluramide. 
However, the use of chemical control for insect-pest 
control in general has been questioned by the 
negative impacts it can cause to the environment. 

And in the forestry sector the forest certification 
required by some countries for export has further 
restricted the use of these chemicals. Few active 
principles are authorized by forest certification for 
pest control, and The FSC (Forest Stewardship 
Council) has restricted the use of the main active 
principles used to control forest pests in Brazil, 
including Fipronil, Deltrametrin, and Sulfluramide 
(JUNG et al., 2013). 

With the restriction and scarcity of 
insecticides registered, it is essential to develop and 
register new products for control. Since ancient 
times the properties present in plants used in 
medicine and against insects have been known 
(ARRAIS et al., 2014). Studies of pest control with 
plant-derived products were resumed in the early 
1960s, with a concern to protect the environment. 
Although studies have been resumed using plants, 
chemical insecticides have still been used to control 
ants, which can have negative effects on the 

Received: 14/04/18 
Accepted: 10/10/18 



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Biosci. J., Uberlândia, v. 35, n. 2, p. 459-466, Mar./Apr. 2019 

environment and on humans (SOUZA–SILVA et 
al., 2005). 

Plant insecticides are obtained from 
extractives, substances resulting from the secondary 
metabolism of plants that, according to chemical 
and ecological studies, play an important protective 
role in insects’ interactions with plants 
(VIGLIANCO et al., 2008), which can be obtained 
from various parts of the plant, such as the leaf, 
fruit, stem, or root, and its function is the defense of 
plant species against herbivorous insects 
(TAVARES; VENDRAMIM, 2005). 

The exploitation of bioactive secondary 
compounds present in the crude extract or essential 
oils of plants can be efficient in pest control. In this 
way, the pseudostem of banana (Musa acuminata) 
was selected for this study, in addition to a proposal 
of reuse of solid waste from fruit production. 
According to Souza et al. (2010) for each ton of 
industrialized banana, approximately three tons of 
pseudocaule and 480 kg of leaves are generated. 

The study of banana pseudostem extract (M. 
acuminata) aims beyond the use of the production 
residue, reducing the use of organosynthetic 
insecticides that contaminate and interfere with the 
environment, becoming a sustainable way to solve 
two different problems. The objective of the study 
was to evaluate the insecticidal potential of two 
extracts of Musa acuminata, for the control of Atta 
sexdens rubropilosa. 

The hypotheses tested in this study are: I) 
that the pseudostem of Musa acuminata has an 
insecticidal effect, due to work already done that 
verified the presence of secondary metabolites with 
insecticidal power; and, II) that the hydroethanolic 
rotaevaporate extract is more efficient than the 
ethanolic extract. 
 
MATERIAL AND METHODS 
 

The study was conducted in a laboratory at 
the State University of Mato Grosso, Alta Floresta 
Campus - MT, located between coordinates 9° 51' 
39.44” S and 56° 04' 7.38” W. The selected plant 
material (pseudostem) was obtained from the 
banana tree (M. acuminata) harvested in the rural 
area of Alta Floresta - MT, which was sectioned and 
cut in slices, dried in an oven with forced air 
circulation at 45 °C for 72 h, after drying, the 
material was crushed in a processor. 

To obtain the ethanolic extract (A1), 20 
grams of the dry and crushed material was used, and 
100 milliliters of ethanol (92.8%) was added, this 
solution was brought to the water bath for 15 
minutes at a temperature of 60 °C, often during this 

period, to facilitate the extraction of the substances 
present in the material. Subsequently, void filtration 
was carried out, the liquid obtained was filled into a 
clean bottle and stored in a cool, dry place protected 
from light. 

In order to obtain the crude hydroethanolic 
extract (A2) a new extract was produced, in which 
100g of dry and crushed material was conditioned 
and one liter of 70% alcohol. The solution was 
stored in a glass bottle for seven days and stirred 
periodically. The bottle was protected from light. 
Subsequently, the filtration was performed in fine 
tissue (voil), the liquid extract was rotated and 
lyophilized to obtain the extract A2. 

In the experiment, ten leaf-cutting ants were 
allocated, five soldiers and five workers along with 
a solid diet, in glass vials, sealed with voil, for air 
passage. To prepare the diet, three grams of 
dextrose, one grams of food agar, and 100 milliliters 
of distilled water were used as recommended by 
Jung et al. (2013). 

The components were mixed and 
microwaved for three minutes, the diet was packed 
into petri dishes and stored in a refrigerator until the 
time of bioassay implantation. The solidified diet 
was cut into cubes and placed in the glasses. During 
the evaluation period, the diet was renewed when 
necessary. 

To analyze the bioactivity of the extracts, a 
topical application of one milliliter of extract on the 
ants (contact) was carried out with the aid of a 
sprayer in the concentrations of 2, 6, 10, 14, 18, and 
20% and a witness (0%) of distilled water was 
applied. For each concentration, five replicates were 
arranged with ten ants each, comprising five 
workers and five soldiers, kept in an air-conditioned 
room. At 26 ± 2 °C, U. R. of 60 ± 10% and photo 
phase of 12 hours. The concentrations used were the 
same for both A1 and A2 extracts. 

The evaluations were carried out in a period 
of 72 hours, quantifying the number of dead ants (% 
of mortality), in the periods of 4, 24, 48, 56, and 72 
hours. This was the factorial experiment (2 x 7), 
with two ways of obtaining extracts, and seven 
different concentrations. The data were transformed 
into arcsen √x / 100, to meet the normality 
assumption and later submitted to an analysis of 
variance (Test F), the means being compared by the 
Tukey test (p <0.01), with the aid of Statistical 
Program Assistat version 7.7 beta (SILVA; 
AZEVEDO, 2016). The calculation of LC50 was 
performed. by means of the Probit curve. 
 
 
 



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RESULTS AND DISCUSSION 
 

The Table 1 shows the average percentages 
of mortality of A. sexdens rubropilosa at different 
exposure times and extract concentrations. 

 
 

 
Table 1. Mean percentage of mortality of A. sexdens rubropilosa by topical application of extracts of M. 

acuminata in different concentrations. 

h= hour; A1 = ethanolic extract; A2 = rotavaporated ethanolic extract; B1 = witness; B2 = 2%; B3 = 6%; B4 = 10%; B5 = 14%; B6 = 
18% and B7 = 20%.  Means followed by the same capital letter in the column, and lowercase in the row in each evaluation period, do 
not differ by Tukey test (p <0.01). 

 
 
As the interaction was not significant 

between the factors, the 56 and 72 hours evaluation 
times were analyzed separately, according to Table 
2. 

 
 

Table 2. Average percentage of mortality of A. sexdens rubropilosa by topical application of extracts of M. 
acuminata, in different concentrations in the periods of 56 and 72 hours of exposure. 

h= hour; A1 = ethanolic extract; A2 = rotavaporated ethanolic extract; B1 = witness; B2 = 2%; B3 = 6%; B4 = 10%; B5 = 14%; B6 = 
18% and B7 = 20%.  Means followed by the same capital letter in the column, and lowercase in the row in each evaluation period, do 
not differ by Tukey test (p <0.01). 

 

C% 
4h 24h 48h 

A1 A2 A1 A2 A1 A2 

B1 0 ±0,0 aC 2 ±0,72aC 28±7,42 aB 16 ±7,61 aB 64 ±5,25 aB 62±5,33aB 
B2 0±0,0 bC 36±8,38 aB 28 ±7,38 bB 78 ±5,18 aA 60±5,21 bB 100±0,0 aA 
B3 8 ±8,3bBC 48±6,28 aAB 32±6,32 bB 84 ±4,11 aA 64 ±5,23 bB 98 ±3,11 aAB 
B4 12±8,65 bBC 54 ±6,22aAB 60 ±5,25bAB 100±0,0 aA 76 ±4,22bAB 100±0,0 aA 
B5 0±0,0 bC 58±6,21 aAB 40±4,28 bB 100±0,0 aA 76 ±4,19bAB 100±0,0 aA 
B6 20±7,45 bAB 70±5,18 aA 58±5,31 bAB 100±0,0 aA 94 ±3,12 aA 100±0,0 aA 
B7 46±6,34 aA 60±6,19 aAB 90±3,18 aA 100±0,0 aA 100±0,0 aA 100±0,0 aA 
Cv (%) 37,10 28,17 18,11 
LC50(%) 22,5             6,02           7,94            1,09    2,29             1,09 

C% 
56 h 72h 

         A1 A2 A1 A2 

B1 72±5,21 a 78 ±4,2 b 82±6,17 a 82 ±4,11b 

B2 76±6,23 a 100±0,0 a 84 ±4,11a 100±0,0 a 

B3 68±5,26 a 98 ±3,02 a 86±4,13 a 98±3,02 a 

B4 80±4,22 a 100±0,0 a 88 ±4,14 a 100±0,0 a 

B5 80 ±4,19 a 100±0,0 a 88±4,12 a 100±0,0 a 

B6 94±3,12 a 100±0,0 a 96 ±3,02 a 100±0,0 a 

B7 100±0,0 a 100±0,0 a 100±0,0 a 100±0,0 a 

Cv (%) 25,33 8,25 21,67 7,29 

LC50 (%) 1,65 1,09 1,65 1,09 



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In the first four hours of the bioassay, there 
was a significant difference only for the 
concentration of 20% in the application of A1 
extract (Table 1). According to Lima Neto (2015), 
ethanolic extracts have lower contents of 
metabolites when compared to the rotated dry 
extract. Increasing the concentration increases the 
potential of efficiency in the application, 
corroborating with the one observed in this study for 
the extract A1 (Table 1). 

In the diluted A2 extract, there was a 
significant difference only in the concentration of 
18% after four hours of exposure. The relationship 
between extracts: A1 and A2 for the four-hour 
period showed a significant difference in practically 
all concentrations, except for 20%. 

For the evaluations at 24 hours in relation to 
the different concentrations analyzed, the A1 extract 
showed a significant difference for the concentration 
of 20%, where it caused a mortality of 90% of the 
individuals. Although authors such as Silva et al. 
(2008) and Lima Neto (2015) affirm the low content 
of bioactive, the extract A1 can be used, but in a 
higher concentration, as observed in this study. 
Carvalho et al. (2015) observed a mortality of 
99.2% of Aedes aegypti individuals in the 24-hour 
period, for aqueous extract of Croton tetradenius 
dried leaves obtained by maceration, a result similar 
to that was obtained for the A1 extract of Musa 
acuminata pseudostem. 

The A2 extract provided a significant 
difference in concentrations of 2 and 6% with 78 
and 84% mortality, respectively, in the 24-hour 
evaluation. From the 10% concentration, 100 
percent mortality was obtained at concentrations of 
10, 14, 18, and 20% (Table 1). It can be observed 
that in low concentrations the extract A2 already has 
insecticidal potential, as observed in the interaction 
between extracts, where all the concentrations 
differed, demonstrating the greater efficiency for the 
extract A2. 

According to Silva et al. (2008) extracts in 
the form of powder (rotaevaporated) have a higher 
concentration of bioactive compounds, elucidating 
the mortality of 100% of the individuals in this 
period. At 48 hours there was a significant 
difference for the A1 extract at the concentrations of 
18 and 20% with 94 and 100% of mortality, 
respectively, whereas for the A2 extract there was a 
significant difference only at the 2% concentration 
(Table 1).  

The results obtained for the 48 hours can be 
explained by the longer time of contact effect of the 
extracts in higher concentrations for extract A1 and 
in the smaller ones for extract A2, which, according 
to Lima Neto (2015), present a lower content of 
metabolites (bioactive) and may take longer to take 
effect. In the period of 48 hours there was a 
significant difference between extracts at 
concentrations of 2, 6, 10, and 14%. 

The readings in the 56 and 72 hours periods 
did not present a significant difference in mortality 
(Table 2), since in almost all treatments there was 
100% mortality of the individuals at 24 hours for the 
A2 extract. Rodrigues et al. (2014) also did not 
observe a significant difference in mortality of 
Aphis craccivora between 48 and 72 hours, for 
hexane extract of seeds of the species Annona 
muricata L. since in the bioassays, also presenting 
significant mortality at 24 hours. 

Therefore, the extract of Musa acuminata 
was efficient since other authors such as Souza et al. 
(2012) and Jung et al. (2013) obtained satisfactory 
results in a longer period of time. These authors 
tested different methods of obtaining extracts in a 
period of 20 days (Atta sexdens) and five days (Atta 
laevigata), respectively. Characterizing, in this 
study, the high efficiency, especially for the A2 
extract, since the topical application presented 
significant mortalities in the period of 24 hours of 
evaluation. 

Analyzing the LC50 (Table 1), it can be 
observed that the value found for the rotated 
vaporized hydroethanolic extract was lower when 
compared to alcohol in all the evaluation periods, 
stabilizing after 24 hours, when it was possible to 
observe high mortality in all concentrations. 
Another fact observed is the decrease in the value of 
LC50, with the increase in the period of exposure, 
observed for the two extracts evaluated. Araújo et 
al. (2008) analyzing the toxicity of hexane extracts 
of plants to the workers of Atta laevigata, also 
verified the decrease of the values of the LC50, with 
the increase of the periods of exposure, and the 
same pattern was observed by Souza et al. (2017) in 
Esenbeckia pumila extracts on Atta laevigata and 
Acromyrmex balzani. 

The mean survival time of the ants was 40.8 
hours after contact with the A1 extract, with 20% 
surviving individuals until the bioassay was 
terminated, probably due to the low bioactive 
content of the extract (Figure 1). 

 



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Figure 1. Survival curve of A. sexdens rubropilosa individuals, after contact with A1 extract, in the different 

periods and concentrations.  
 
According to Santos et al. (2013) the result 

obtained can be explained by the method and time 
of extraction of bioactive material studied. Extract 
A1 was already obtained, by means of infusion, 
after only 15 minutes, with this it can be understood 
that over a longer period or using another method, 
the use of the ethanolic extract would be more 
efficient. 

The ant survival analysis after contact with 
the diluted A2 extract showed that this was lower 
due to the bioactive content of the extract, as stated 
by Silva et al. (2008), which indicates that in this 
type of extract there are higher concentrations 
(Figure 2). In a study with rotavaporated extract 

diluted in distilled water from extracts of Derris 
amazonica Killip. (Timbó), Ipomoea carnea Jacq. 
(canudo), and Momordica charantia L. (São 
Caetano melon) Jesus et al. (2013) verified the 
control effectiveness of Bemisia tabaci (whitefly) 
nymphs from a concentration of 1,000 milligrams 
per liter, causing a mortality higher than 50% of the 
population, under the concentration of 3,000 
milligrams for liter, there were higher percentages 
of nymphal mortality. For the insecticidal activity of 
leaf extract of M. charantia L (São Caetano melon), 
however, when applied to 3,000 µg. ML-1, did not 
differ from those that caused higher mortality 
percentages.

 

 
Figure 2. Survival curve of A. sexdens rubropilosa individuals, after contact with extract A2 diluted in distilled 

water, as a function of the concentrations in the different periods. 
 
The average survival period of the ants was 

25.33 hours after contact with the diluted A2 
extract. Treatment at 2% concentration showed 
survival up to 24 hours. In the 6% treatment there 



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Biosci. J., Uberlândia, v. 35, n. 2, p. 459-466, Mar./Apr. 2019 

was survival of 2% until the end of the experiment. 
For the treatments 10, 14, 18, and 20% there was no 
survival in the period of 24 hours after topical 
application, evidencing its mortality after contact 
with the extract. 

Gomes et al. (2016) observed toxic effect by 
contact of extracts of leaves and branches of 
Zanthoxylum rhoifolium, bark of Simarouba amara, 
branches of Aspidosperma spruceanum, and leaves 
of Casearia arborea on Atta sexdens sexdens. 
According to these same authors the extracts of 
plants of the Rutaceae family have toxicity to A. 
sexdens sexdens and also to other insects and should 
be further studied. 

Thus, the hypotheses tested in this study 
were confirmed. The banana pseudocaule has an 
insecticidal effect on the results observed in this 
study, and the hydroethanolic rotaevaporate extract 
is more efficient than the ethanolic extract. 

Thus, this study presents the banana residue 
as an option for the control of leaf cutting ants, 
requiring further studies about the most efficient 
method of application, as well as the analysis of 
other parts of the plant, and other species cultivated 
in the country. 
 

CONCLUSIONS 

 
In the 24-hour period, 90% mortality was 

observed at the concentration of 20% for the A1 
extract.  

From the 10% concentration there was 
100% mortality in this same period for extract A2. 
In the LC50 analysis for 24 hours values of 7.94 and 
1.09% were obtained for ethanolic extract and 
rotavaporated ethanolic extract respectively. And 
the LC50 presented a decrease in values after 48 
hours for the ethanolic extract presented value of 
2.29%. 

The concentration of 2% of the A2 extract 
caused 100% mortality at 48 hours, a satisfactory 
result, which allows the lower consumption of 
material (extract) in the dilution for later 
application, due to the presence of insecticidal 
potential in low concentrations, characterizing the 
A2 extract as being the most efficient.  
 
ACKNOWLEDGEMENTS 
 

The authors thank the Professor Edith 
Eunice Arthur Petrica for the inspiration for this 
study. 

 

 
RESUMO: Atualmente, poucos princípios ativos são autorizados pela certificação florestal para o 

controle de insetos-praga, sendo necessário desenvolver novos produtos, principalmente visando menor 
impacto ambiental. As plantas são capazes de desenvolver substâncias chamadas metabólitos secundários, 
amplamente estudadas como uma forma alternativa de controle de pragas. Assim, o objetivo deste trabalho foi 
avaliar o potencial inseticida de dois extratos de Musa acuminata, no controle de Atta sexdens rubropilosa. Os 
extratos foram obtidos a partir do pseudocaule de M. acuminata, que foi submetido a secagem e moagem, 
produzindo dois extratos: etanólico (A1) e hidroalcoólico rotaevaporado (A2). Para a análise da bioatividade 
dos extratos, foi realizada uma aplicação tópica de um mililitro de cada extrato sobre as formigas, com o auxílio 
de spray, nas concentrações de: 2, 6, 10, 14, 18 e 20%, com água destilada (testemunha) aplicada ao teste, 
verificando-se a mortalidade e a CL50, em diferentes períodos de avaliação. Às 24 horas foi observada 
mortalidade de 90% na concentração de 20% para o extrato A1. A partir da concentração de 10% houve 100% 
de mortalidade nesse mesmo período para o extrato A2, e às 48 horas a concentração de 2% causou 100% de 
mortalidade. Na análise da LC50 para 24 horas obteve-se valores de 7,94 e 1,09% para o extrato etanólico e o 
extrato rotaevaporado respectivamente. E a CL50 apresentou diminuição nos valores apartir das 48 horas para o 
extrato etanólico apresentando valor de 2,29%. Assim, pode-se concluir que o extrato A2 é o mais eficiente, 
pois permite o menor consumo de extrato na diluição para posterior aplicação, devido à presença de potencial 
inseticida em baixa concentração. 

 
PALAVRAS-CHAVE: Resíduos sólidos. Metabólito secundário. Inseticida. Entomologia da floresta. 
 
 

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