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288 
Original Article 

Biosci. J., Uberlândia, v. 32, n. 2, p. 288-297, Mar./Apr. 2016 

CHEMICAL PESTICIDES AND VEGETAL EXTRACTS ON Sitophilus zeamais 
CONTROL IN STORED CORN GRAINS 

 
INSETICIDAS QUÍMICOS E EXTRATOS VEGETAIS NO CONTROLE DE 

Sitophilus zeamais EM GRÃOS DE MILHO ARMAZENADOS 
 

 

Marcella Karoline Cardoso VILARINHO
1
; Tonny José Araújo da SILVA

2
;  

Carlos CANEPPELE
3
; Adriano Ferreira ROZADO

4
 

1. Professora Mestre do curso de Agronomia, Universidade do Estado de Mato Grosso – UNEMAT, Cáceres, MT, Brasil. 
marcellakarolinecv@hotmail.com; 2. Professor Doutor do Programa de Pós Graduação em Engenharia Agrícola (ICAT/UFMT), 

Universidade Federal de Mato Grosso – UFMT, Rondonópolis, MT, Brasil; 3. Professor Doutor do Núcleo de Tecnologia em 
Armazenagem (NAT/UFMT) da Faculdade de Agronomia e Medicina Veterinária – UFMT, Cuiabá, MT, Brasil; 4. Professor, Doutor, 

ICAT - UFMT, Rondonópolis, MT, Brasil. 
 

ABSTRACT: Sitophilus species are major pests of stored grain and their control is achieved mainly with the 
use of chemical insecticides, but the indiscriminate use of these products is resulting in several undesirable factors to man 
and to the environment. Thus, the use of natural insecticides comes as an option to control the insects, while lessening 
risks to the environment. The study was conducted at the Institute of Agricultural Sciences and Technologies, 
Rondonópolis campus of the Federal University of Mato Grosso, in the period from March to September 2012. The 
experiment was conducted under three different storing conditions. Aqueous extracts were obtained by the addition of 
Allium sativum L, Azadirachta indica A. Juss. and Cymbopogon winterianum Jowitt vegetable powders in distilled water, 
at a ratio of 5 g per 100 ml, and the levels of chemical insecticides were of 0.04 and 0.15 ml/100 ml of water for 
deltamethrin and chlorpyrifos, respectively. Treatments were added to the corn grains, which were placed in a 2.5 L glass 
container, mixed by manual shaking and infested with 20 adults of unsexed Sitophilus zeamais. Grains were stored for 60 
days. At 30 and 60 days, the following items were analyzed: bugs count, water content in grains and electrical 
conductivity. The data were submitted to analysis of variance, and means were compared by Tukey test at 5% probability. 
At 30 days, the efficiency of chemical insecticides in the control of Sitophilus zeamais was observed in the three storage 
environments. Vegetal extracts were not effective in controlling insects. The larger number of insects increased the 
electrical conductivity and humidity values in the grains. 

 
KEYWORDS: Insect. Temperature. Humidity.  
 

INTRODUCTION 
 

Corn is a high economic and social 
expression agricultural product which is considered 
the culture that has the largest genetic 
characterization between arable species, and its raw 
material is used in human and animal feeding, as 
well as in industrial production of byproducts 
ranging from starch, oil and flour to animal feeds 
(GUIMARÃES, 2007). 

Being a culture of good adaptation to 
different ecosystems, Brazil is a country with high 
potential in the production of this grain, and in 
numbers the 2011/2012 harvest was estimated at 
165.92 million tons, 3.12 million more tons in 
relation to the previous year harvest. Of this amount, 
Mato Grosso state was responsible for the 
production of 40.223 million tons (Conab, 2012). 

Due to necessity to increase the productivity 
of this cereal, different technologies have been 
employed in the field with the aim of reducing 
losses in cultivation, and at this stage there is a need 

to focus on improvements in the collection and 
storage of the product processes, once that the grain 
has favorable characteristics for storing for a long 
period of time without any loss in quality. However, 
in order to obtain success during storage, proper 
cleaning, drying and grain storage practices are 
needed. Thus, it is important to be careful with 
factors that affect the grain during this stage, and 
among them, the largest loss-causing factors are: 
high temperature and humidity values at the time of 
storage, carbon dioxide and oxygen concentration in 
the interstitial air, grain characteristics, presence of 
microorganisms, insects and mites, and lack of 
structure in storage units. 

The preservation of this cereal quality is 
also greatly influenced by the presence of insects, 
particularly in tropical places, which have ideal 
characteristics for their development in grains 
(FARONI et al., 2005). Furthermore, storage pests 
have undergone adaptations to survive in different 
environments, what complicates their control. Pests 
cause losses in storage and generate weight loss, 

Received: 07/04/14 
Accepted: 20/01/16 



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increases in the respiratory activity of the grains and 
heating of the infestation site when consuming 
grains, resulting in the appearance of fungi, and thus 
resulting in higher losses of dry matter, depreciating 
grain quality. 

In Brazil, Sitophilus zeamais Mots., 1855 
(Coleoptera, Curculionidae) corn weevil has caused 
many quantitative and qualitative damage to corn 
culture, especially during storage (CANEPPELE et 
al., 2003;), and it stands out as the most important 
pest of stored grains in Brazil, and for having a high 
biotic potential and a large number of hosts, its 
control must be done effectively (CERUTI; 
LAZZARI, 2005). 

The maintenance of grains and seeds 
sanitary quality is made basically through the 
control of insect pests associated with stored grain, 
through the extensive use of chemicals. However, 
the indiscriminate use of this practice, coupled with 
the scarcity of products registered for this purpose, 
what hinders the rotation of chemical groups, has 
caused resistance in several insects’ species, 
presence of residues in food and poisoning of 
operators. 

These and other factors have been driven 
new research for less harmful alternatives to men 
and the environment, and among them there is the 
alternative control through plant origin insecticides, 
which has as main advantages the minimization of 
environmental problems, of residues in food, of 
harmful effects on beneficial organisms, of insect 
resistance to insecticides, and the reduction of 
human poisoning. 

Research with insecticide plants are carried 
out in order to find molecules with insecticides 
activities that may allow the synthesis of new 
products, and also in order to do the direct use of 

these plants in the control of insect pests. Even with 
the economic and conservation benefits of stored 
products offered by chemical insecticides against 
storage pests, the incorporation of sustainable use 
practices and the rational use of resources from 
biodiversity can become a difference that is capable 
of generating competitive advantages. 

Considering the economic importance of 
corn, its physiological characteristics and problems 
with stored grain pests, this study evaluated the 
insecticide effect of aqueous vegetal extracts and 
chemical insecticides commonly used to control 
grain pests stored in different storage conditions. 
 
MATERIAL AND METHODS 
 

The test to evaluate the insecticide potential 
of chemicals and plant extracts in different storage 
conditions was conducted at the Institute of 
Agricultural Sciences and Technologies, 
Rondonópolis campus of the Federal University of 
Mato Grosso, in the period from March to August 
2012. 

The treatments were conducted under three 
storage conditions, and to achieve the goal of this 
research, controlled chambers that are similar to an 
entomotron were made, which turned possible the 
implementation of the experiment under the desired 
conditions (Figure 1). The materials used in their 
construction were wooden boards, thermal 
insulation, temperature sensors and psychrometers. 
For the chamber construction, a structure containing 
three shelves with of 0.66 x 1.60 m dimensions and 
closed with doors made of wood and polystyrene 
plates was used, thereby forming insulation, in order 
to maintain the temperature and humidity of the 
controlled environments always constant. 

 

 
Figure 1. Schematic drawing of the storage chamber (Entomotron). (Illustration: Provided by the author). 
 



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The experiment consisted of three 
environments: AI- temperature and humidity; AII- 
humidity control; and AIII- humidity and 
temperature control. To control the temperature, a 
cooling and heating system was built, which were 
triggered automatically if the temperature exceeded 
certain determined extremes. 

Humidity control was accomplished through 
a recipient containing silica with forced air 
circulation. Within each environment a 
psychrometric set was installed, consisting of 
thermocouples sensors connected to a data logger, 
CR1000 model, which had the function of storing 
data and automating the heating, cooling and 
humidity control systems. The temperature 
maintained in AIII environment was of 25.1 °C, 
with a relative humidity of 70% (mean values), with 
the last variable also maintained in the AII 
environment. 

The insects used in the experiment were 
created at the postharvest laboratory of the Institute 
of Agricultural Sciences and Technologies, 
Rondonópolis campus of the Federal University of 
Mato Grosso. They were kept in glass recipients 
with 2.5L capacity, with the lid sealed with light 
type fabric (voile) and rubberized material (EVA) 
on the sides, thus avoiding insects leaving. Corn 
grains filling up to the middle of the recipient were 
used as substrate for the maintenance and creation 
of the insects. They were kept on shelves and in 
uncontrolled environmental conditions. 

Glasses maintenance was made throughout 
the experiment, where on an average of every 60 
days the adults of S. zeamais were transported to 
clean recipients with a new grain mass. The insects 
used for the experiment had an average age of 42 
days. 

Regarding the choice of chemicals used to 
S. zeamais control, it was opted for the use of 
deltamethrin, which is an active ingredient currently 
registered and used for the control of this insect. 
Taking the purpose of comparing another active 
ingredient, (Chlorpyrifos) was also used, which 
according to research has shown efficiency in the 
control of storage pests (SMIDERLE; CICERO, 
1998). The doses were of 0.04 and 0.15 ml/100 ml 
of water for deltamethrin and chlorpyrifos, 
respectively (ALFONSO et al., 2005). 

The extracts were obtained from neem 
(Azadirachta indica A. Juss) and citronella 
(Cymbopogon winterianum Jowitt.) leaves and from 
garlic cloves (Allium sativum L).  These plant 
species were chosen species due to scientific 
references of their use as insecticides. To prepare 
the extracts, the collected plant structures were dried 

in an oven with air circulation at 40 °C for 48 h, and 
only garlic cloves needed a longer dehydration 
period (72 h). 

After triturated, vegetable powders were 
stored separately in airtight recipients until its use. 
Aqueous extracts were obtained by the addition of 
the vegetable powders in distilled water at a ratio of 
5 g per 100 ml. 

Mixtures were maintained in sealed flasks 
for 24 h for the extraction of water soluble 
compounds, and after this period were filtered 
through fine fabric (voile), obtaining the 5% 
aqueous extracts (BRUNHEROTTO et al., 2010). 

 
Experiment installation:  

Initially, the grain mass was sieved on a 4 
mm mesh, for waste removal, and subsequently 
mixed in a 08 CFW 08 model homogenizer, for 
samples standardization. Twenty samples of 
approximately 50 g were taken to determine the 
water content of the grains by the oven method at 
103 ºC ± 1 ºC for 72 h, and it was found that the 
grain mass showed a 12% water content. 

Each experimental unit consisted of glass 
recipients with 2.5 L capacity, containing 1 kg of 
corn grains that were previously exposed to a 
temperature of -18 ° C for five days in a domestic 
freezer, in order to eliminate contaminant insects. 
Treatments applied in the experiment installation 
were distributed into the recipients and mixed by 
hand shaking up to their uniformization, with the 
excess being removed to prevent further 
concentration of the product in certain points. 

After the treatments application, each 
experimental unit was infested with 20 adults of 
unsexed Sitophilus zeamais. The experiment was 
conducted without insect reinfestation. The grains 
were stored for a period of 60 days. The variables 
were analyzed every thirty days from the 
experiment installation, totaling two evaluation 
periods (30 and 60 days). The choice of the amount 
of grains used for each experimental plot was made 
according to the need to withdraw samples for 
testing grains water content and electrical 
conductivity in each evaluation period. 

The experiment installed on June 8, 2012, 
was composed of six treatments, entered into three 
storage environments, with four repetitions, totaling 
72 plots. The two months prior to the beginning of 
the experiment (March to May 2012), were destined 
for the construction and automation of the storage 
chambers (entomotron). The variables analyzed 
were: 

Insect Count: In order to evaluate the 
products insecticide efficiency, live and dead insects 



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were separated with the aid of a sieve. After the first 
evaluation, living insects were returned to have their 
development observed in the next assessment. 

Water content in the grains: To determine 
the water content in grains, approximately 50g of 
corn grains were taken from each plot. The water 
content was determined in both evaluation periods, 
using the standard oven method at 103 ºC ± 1 ºC for 
72 hours, which was adopted by the Asae (1992) 
standard. This methodology was measured 
according to Karl Fischer titration, which is 
considered a basic reference standard (Grabe, 1987). 

Electrical conductivity: During the storage 
period, tests were conducted in four subsamples of 
50 grains for replicates of each treatment. Each 
subsample was weighed on a 0.01 g precision 
balance and placed in plastic cups of 180 ml, to 
which 75 ml of deionized water was added. The 
samples were kept at 25 °C in a climatic chamber 
(BOD) for 24 hours. After this period, the samples 
were shaken for homogenization of the exudates 
released into the water. The readings were made in 
an electrical conductivity meter mCA 150 model 
made by Ms Tecnopon, which was previously 
calibrated with a standard solution of sodium 
chloride with known conductivity value and an 
electrode of 1 µ S cm-1 constant. Before and after 
each determination, the electrode was repeatedly 

washed with deionized water. The value of the 
electrical conductivity read by the device was 
divided by the weight of its respective sample of 50 
grains in grams and the value expressed in µ S cm-1. 
g-1, as described by Vieira (1994). 

The experimental design was of subdivided 
plots in a factorial design with six treatments, three 
settings and four replications. Analysis of variance 
was performed for each period of evaluation of the 
variables, and means were compared by Tukey test 
at 5% probability, using the SISVAR statistical 
program (FERREIRA, 2012). 
 
RESULTS AND DISCUSSION 
 

The results show that in all settings the 
chlorpyrifos chemical insecticide showed significant 
efficiency in Sitophilus zeamais control, being 
100% effective in killing the insects in the first 
evaluation period (30 days) (Table 1). Due to the 
maximum mortality effect of chlorpyrifos in the first 
period, no statistical analyzes of this variable were 
made for all 60 days of evaluations because there 
was no living insects. These results agree with 
Afonso et al. (2005), who using the same dose of 
chlorpyrifos insecticide in Sitophilus zeamais 
observed the control of 100% of the insects after 96 
hours of contact with the insecticide. 

 
Table 1. Number of dead insects at 30 and 60 days after the start of treatments, in the three studied settings. (1) 

(1) Means followed by the same letter, lowercase in lines or uppercase in columns, do not differ by Tukey test at 5% probability. (2) I - 
Temperature and Relative Humidity: Setting; II - Temperature: Setting; Average humidity: 70%; III - Average Temperature: 25.1 ° C; 
Average humidity: 70%. Mean values throughout the storage period. 

 
Data of this study also revealed the 

statistical equality of deltamethrin treatment in the 
setting I, after thirty days of storage where there was 
no humidity and temperature control, and in the 

Insecticides Settings
 (2)

 

 30 days 60 days 

 I II III I II III 

Garlic 6.0 aB 5.5 aC 4.2 aC 6.2 aAB 5.7 aA 9.0 aB 

Citronella 7.7 aB 4.5 aC 8.2 aBC 4.2 bAB 7.5 bA 27.5 aA 

Chlorpyrifos 20.0 aA 20.0 aA 20.0 aA - - - - - - 

 Deltamethrin 15.2 aA 11.0 abB 10.5 bB 1.0 aB 4.7 aA 5.7 aB 

Neem 6.5 aB 4.5 aC 6.5 aBC 15.2 aA 10.0 aA 15.7 aAB 

Control 4.5 aB 3.5 aC 4.5 aC 4.0 aAB 7.5 aA 11.2 aB 



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setting II, after 60 days of storage with humidity 
control in an average of 70% and ambient 
temperature, which was efficient in insects killing 
like chlorpyrifos. Pereira et al. (2003), working with 
barley stored grains, also verified deltamethrin 
efficacy in Sitophilus oryzae mortality until the 
thirtieth day of storage, although Lahóz (2008) had 
not seen the expected efficiency in the control of 
Sitophilus zeamais in stored corn from the 
beginning of assessments. Treatments based on 
vegetal extracts have not statistically differed among 
them and the control in the first evaluation period, 
with lower efficiency in control compared to 
chemical insecticides. In the second evaluation 
period, no statistical differences between the vegetal 
extracts and the control were observed, where the 
largest numbers of dead insects were observed in the 
neem on setting I and in garlic, neem and control on 
setting II.  

Considering the number of live insects, the 
best treatment, i.e., the one that left fewer offspring 

after chlorpyrifos, was deltamethrin at 30 days in 
the setting II and at 60 days in all settings (Table 2). 
Analyzing these results, it was found that all 
treatments had birth rates from the second 
evaluation period, showing statistical equality 
between vegetal extracts treatments and the control, 
where the highest incidence of live insects were 
observed in garlic treatments on settings I and III, 
and neem and citronella on settings I and II, 
respectively, strengthening the hypothesis that the 
mortality of insects in the last period has been from 
natural causes. 

It can also be inferred that the absence of 
insecticidal activity of vegetal extracts may be due 
to low concentration and the extraction method used 
in the study. Unlike the results found in this study, 
Coitinho et al. (2006), using Neem essential oil, had 
the lowest incidence of insects between the 
employed treatments, and this may have occurred 
because authors worked with higher doses 
(50ml/20g) than those used in this study. 

 
Table 2. Number of living insects at 30 and 60 days after the start of treatments, in the three studied settings. (1) 

Insecticides                                                  Settings
 (2)

 

 30 days 60 days 

 I II III I II III 

Garlic 14.0 aB 14.5 aC 15.7 aC 491.5 aB 442.7 aAB 536.0 aB 

Citronella 12.2 aB 15.5 aC 11.7 aBC 351.0 aAB 595.7 aB 452.0 aAB 

Chlorpyrifos   0.0 aA   0.0 aA   0.0 aA - - - - - - 

Deltamethrin   4.7 aA   9.0 abB   9.5 bB   84.0 aA   83.7 aA   75.5 aA 

Neem 13.5 aB 15.7 aC 13.5 aBC 568.0 aB 355.5 aAB 394.0 aAB 

Control 15.5 aB 16.5 aC 15.5 aC 425.2 aAB 365.2 aAB 377.0 aAB 

(1) Means followed by the same letter, lowercase in lines or uppercase in columns, do not differ by Tukey test at 5% probability. (2) I - 
Temperature and Relative Humidity: Setting; II - Temperature: Setting; Average humidity: 70%; III - Average Temperature: 25.1 ° C; 
Average humidity: 70%. Mean values throughout the storage period. 
 

In addition, the setting temperature may 
have been of great influence on the further 
development of these insects, because according to 
Caneppele et al. (2010), the optimum temperature 
for S. zeamais development is between 28 °C, 
although its development also occurs between 15 
and 34 ° C, thus being consistent with the 
temperature values of the study settings, which 
range from 24.6 to 27.6 ° C from the first to the last 

evaluation period. Another way to explain that 
natural insecticides have not presented efficiency 
may be related to the method of extracts extraction, 
thus agreeing with Tavares and Vendramim (2005), 
which have also found no insecticidal effect of 
aqueous vegetal extracts in relation to S. zeamais 
adults. According to Tavares (2006), compounds 
with insecticidal activity present in some plants 
cannot be extracted in high polarity solvents, which 



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is the opposite when these are of medium or low 
polarity (chloroform and hexane). 

For water content in the grains in different 
treatments, it was observed that at 30 and 60 days, 
in general, there was no difference between settings 
or between treatments, except for deltamethrin in 

setting III at 30 days, which showed high grain 
humidity content (18.6%) (Table 3). It is noted that 
from the first to the last assessment period there was 
a decrease in the water content of the grains in the 
treatments with deltamethrin and chlorpyrifos. 

 
Table 3. Humidity (%) at 30 and 60 days after the start of treatment, in the three settings.(1) 

Insecticides Settings 
(2) 

 

 30 days 60 days 

 I II III I II III 

Garlic 15.6  aA 14.9 aA 15.6 aA 15.1 aAB 14.9 aAB 14.5 aA 

Citronella 17.3 abAB 16.3 aA 18.1 bB  16.3 aB 16.2 aAB 17.4 aB  

Chlorpyrifos 17.9 aB 19.0 aB 18.3 aB 14.8 aAB 16.6 bB 15.0 abA 

Deltamethrin 16.8  bAB 15.0 aA 18.6 cB 14.0  aA 14.0 aA 16.0 bAB 

Neem 16.8 abAB 15.8 aA 18.1 bB 16.1 abAB 15.1 aAB 17.6 bB 

Control 16.4 aAB 15.2 aA 15.9 aA 15.4 aAB 14.6 aAB 16.0 aAB 

(1) Means followed by the same letter, lowercase in lines or uppercase in columns, do not differ by Tukey test at 5% probability. (2) I - 
Temperature and Relative Humidity: Setting; II - Temperature: Setting; Average humidity: 70%; III - Average Temperature: 25.1 ° C; 
Average humidity: 70%. Mean values throughout the storage period. 
 

From the initial period until the end, settings 
humidity was of around 75.8; 73.9 and 72.6%, and 
temperature was of 24.4; 25.0 and 24.7 °C on 
settings I, II and III, respectively. These data are in 
agreement with those of Alves et al. (2008), who 
studied the influence of S. zeamais in the respiratory 
rate of corn grains during a storage period of 150 
days and observed a decrease in humidity, with an 
increase in the temperature and the storage period, 
and with Faroni et al. (2005), who also observed a 
decrease in the water content of corn grains in 
temperatures above 25 °C. In the two above-
mentioned papers, the authors agree that the 
reduction of grain moisture is caused by the high 
temperatures of the environment in which the grains 
are stored. 

Considering the lowest grain moisture 
content at 60 days for the deltamethrin treatment, 
when compared to the control content (Table 3) and 
when related to the lowest values of live insects 
(Table 2), it can be inferred that the low grain 
moisture may have been a positive factor for the 
efficiency of deltamethrin, confirming what has 
been described by Samson et al. (1988), who 

reported that insecticides are more stable when in 
contact with grains with lower humidity content. 
Lahóz (2008) had also observed this effect when 
working with insecticides in S. zeamais control and 
added that the low grain moisture decreases 
oviposition of insects. 

Another factor that may have influenced the 
low water content in the grains was the amount of 
live insects in the treatments with chemical 
insecticides, as it is observed in Table 2 that 
chlorpyrifos and deltamethrin were the treatments 
that had the lowest index numbers of insects alive. 
According to Alves et al. (2008), increases in the 
moisture content are caused by increases in the 
population growth rate of pest insects, which 
produces water through their metabolism, 
contributing to the increase in the water content in 
grains. As population growth was reduced in these 
treatments, the respiratory rate of the insects was not 
high, so the effect on the moisture content was also 
reduced. 

This effect of insects on the grain moisture 
can be confirmed by the observation of vegetal 
extracts treatments and the control, which had a 



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high rate of population growth from the second 
evaluation period, as well as high water content in 
grains. This information is confirmed by Silva et al. 
(2003) and Antunes et al. (2011), who observed that 
an increase in humidity of wheat and corn grains as 
S. zeamais population increased, further reinforcing 
the hypothesis that insects have influence on the 
increase in grain moisture content. 

In the first period, the moisture values that 
were high may have suffered interference from the 
environment and the initial period of storage, 
tending to the hygroscopic equilibrium of plots with 
settings. On this occasion, air relative humidity 
(75.7, 67.2 and 69.4% on average) and temperature 
values (average of 24.6, 25.2 and 24.8 °C) on 
settings I , II, and III, respectively, led to an increase 
in the equilibrium moisture content of these grains 
because as they are living bodies with a porous 
internal structure and with low thermal conductivity, 
which gives them a hygroscopicity characteristic, 
they are able to maintain constant heat and moisture 
changes to the environment through intergranular 
spaces in grains mass (MULTON, 1980). 

Regarding grains quality, the electric 
conductivity test have shown good indicators of cell 
membrane integrity, since the higher the amounts of 
exudates ions into the grains, less intact will be the 
membranes, what reflects in the further deterioration 
of the grains (GOULART et al., 2007), and to have 
significant influence on the electrical conductivity 
tests, the water content of the grains should be 
adjusted to a range of between 10 and 17% 
(VIEIRA et al., 2002), which were values found in 
most treatments (Table 3). 

It was observed that lowest values of 
electrical conductivity in the first evaluation period 
(30 days) occurred on setting I for the control, garlic 
and deltamethrin treatments, with deltamethrin 
being also statistically equal on setting II (Table 4). 
For the second evaluation period statistical equality 
was observed for garlic treatment, which showed 
lower values of electrical conductivity on settings I 
and III, followed by chlorpyrifos and deltamethrin 
on setting I. 

 
Table 4. Electrical conductivity of grains at 30 and 60 days after the start of the treatment in the three studied 

settings. (1) 

Insecticides Settings
 (2)

 

 30 days 60 days 

 I II III I II III 

Garlic 38.5 aA 41.6 aAB 39.0 aA 60.7 aA   78.9 aAB   68.7 aA 

Citronella 60.0 aB 61.2 aC 79.9 aBC 92.9 aB 124.1 bC 118.6 bC 

Chlorpyrifos 43.4 aAB 53.3 abBC 67.6 bBC 57.5 aA 91.8 bB   87.7 bAB 

Deltamethrin 40.5 aA 34.0 aA 68.3 bBC 55.1 aA   55.7 aA   98.6 bABC 

Neem 47.8 aAB 40.4 aAB 74.5 bC 96.5 abB   82.2 aAB 116.0 bBC 

Control 37.4 aA 37.6 aAB 54.0 bAB 67.1 aAB   83.0 aAB   91.2 aABC 

(1) Means followed by the same letter, lowercase in lines or uppercase in columns, do not differ by Tukey test at 5% probability. (2) I - 
Temperature and Relative Humidity: Setting; II - Temperature: Setting; Average humidity: 70%; III - Average Temperature: 25.1 ° C; 
Average humidity: 70%. Mean values throughout the storage period. 
 

It was noted that the increase of electrical 
conductivity was independent of the number of live 
insects (Table 2), including the possibility that 
natural insecticides have no insecticidal effect, but 
may have acted as repellents, as the integrity of the 
grains was maintained. 

It was also noticed an increase in electrical 
conductivity values according to the storage period, 
which are results similar to those obtained by 
Alencar et al. (2008), who studied the quality of 
soybean in function of storage conditions and 
observed for a period of 180 days higher values of 



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electric conductivity as the storage periods 
increased. The authors therefore inferred that higher 
levels of water contribute to the deterioration of the 
grains due to the denaturing of the cellular 
membrane. 
 
CONCLUSIONS 
 

Chlorpyrifos chemical insecticide offers 
100% efficiency to control Sitophilus spp. Adults in 
all analyzed settings after 30 days of storage. 

 Deltamethrin had low Sitophilus zeamais 
control in the first assessment period, showing its 
efficiency in the subsequent period (60 days). 

Plant insecticides offer low efficiency in the 
control of Sitophilus zeamais. 

 An increase in electrical conductivity and 
water content in the grains was observed according 
to the insects population growth. 
 
ACKNOWLEDGEMENTS 
 

To Coordenação de Aperfeiçoamento de 
Pessoal de Nível Superior for granting the master’s 
scholarship. 

 
 
RESUMO: O objetivo desse trabalho foi estudar o efeito inseticida de extratos vegetais aquosos e inseticidas 

químicos sob condições de armazenamento. O experimento foi realizado sob três condições de armazenamento. Os 
extratos aquosos foram obtidos pela adição dos pós vegetais de  Allium sativum L, Azadirachta indica A. Juss. e 
Cymbopogon winterianum Jowitt. em água destilada na proporção de 5g por 100 ml, e as dosagens dos inseticidas 
químicos foram de 0,04 e 0,15 ml/100 ml de água para Deltametrina e Clorpirifós respectivamente. Os tratamentos foram 
adicionados aos grãos de milho acondicionados em recipientes de vidro de 2,5 L, misturados por agitação manual, e 
infestados com 20 adultos de Sitophilus zeamais não sexados. Os grãos ficaram armazenados durante 60 dias. Analisou-se 
aos 30 e 60 dias: contagem de insetos, teor de água nos grãos e condutividade elétrica. Os dados foram submetidos à 
analise de variância, e as médias comparadas pelo teste de Tukey a 5 % de probabilidade. Aos 30 dias, observa-se 
eficiência dos inseticidas químicos no controle de Sitophilus zeamais nos três ambientes de armazenamento. Os extratos 
vegetais não são eficientes no controle dos insetos. O maior número de insetos elevam os valores de condutividade elétrica 
e umidade nos grãos.  

 
PALAVRAS-CHAVE: Inseto. Temperatura. Umidade.  
 
 

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