Biology, Medicine, & Natural Product Chemistry ISSN: 2089-6514
Volume 3, Number 1, 2014 | Pages: 21-23 | DOI: 10.14421/biomedich.2014.31.21-23

Larvicidal Activity of the Mixture of Cashew Nut Shell Liquid (CNSL)
and Aqueous Extract of Sapindus rarak DC against Larvae of

Culex quinquefasciatus

Rahmi Safarina Fauziah1, Sudarsono1* and Budi Mulyaningsih2
1Pharmaceutical Biology Department, Faculty of Pharmacy; 2Parasitology Laboratory, Faculty of Medicine, UGM, Indonesia

Author correspondency*:
sudarsono@ugm.ac.id

Abstract

The aim of this study was to evaluate the larvicidal activity of Cashew Nut Shell Liquid (CNSL) against the Culex quinque fasciatus in
larval stage. The CNSL was diluted in water by addition of aqueous extract of Sapindus rarak DC to increase its solubility. Larvae were
exposed to varying concentrations of that mixture. The larvae mortality was observed after 24 h exposure. LC50 and LC90 value by
extrapolation were 20,52 ppm and 55,41 ppm respectively. CNSL were specified by characterizing its physico-chemical properties and
anacardic acid as marker compound by High Performance Chromatography (HPLC). The results were the mixture of Cashew Nut Shell
Liquid (CNSL) and Aquous extract of Sapindus rarak DC had larvicidal activity against Cx. Quinque-fasciatus and further investigations
were needed to identify the fatty acid derivative as active compound of CNSL which  responsible for larvicidal activity.

Keywords: larvicidal, larvae, Culex quinquefasciatus, Cashew Nut Shell Liquid, Sapindus rarak

Introduction

Culex quinquefasciatus is the most common mosquito
species found in Indonesia. There are the main cause of
the mosquito bites in the evenings and night. The main
factor supporting this species is probably due to poor
sanitation caused by human migration to urban areas.
Interest in the control of Cx.quinquefasciatus lies in the
fact that it acts as a vector of filarial disease as a serious
public health problem in Indonesia and many tropical
developing countries. Filariasis is an endemic, disabling,
and disfiguring disease. The filarial worm, Wuchereria
bancrofti responsible for human filariasis is carried by
Cx.quinquefasciatus which is a tropical pest and probably
the most abundant and ubiquitous house mosquito in
towns and cities, in the tropical countries.

One of the strategies of WHO in combating tropical
disease is to destroy their vectors or intermediate hosts.
Since no effective vaccine is available for filariasis, the
only effective approach of minimizing the incidence of
this disease is to eradicate and control mosquito vectors
mainly by application of organic insecticides to larval
habitats. Control of mosquito at this stage is efficient
because during the immature stages, mosquitoes are
immobile.

The use of natural products for controlling of insect
pests offers an economically viable and eco-friendly
approach, besides being harmless to beneficial insects
when adopted on a larger scale. Chemical pesticides have
been used for several decades in controlling pests and
vectors of various human diseases as they have a quick
knock down effect. However, their indiscriminate use
resulted in several problems such as resistance and
resurgence of pests, elimination of natural enemies, toxic
residues in food, water, air, and soil which affect human

health and disrupt the ecosystem, leading to the threat that
their continued use may further harm the environ-ment.

Anacardium occidentale L. (Anacardiaceae), a fruit
tree grown widely in tropical and sub-tropical areas is
cultivated in Indonesia for its cashew nuts. Tyman &
Morris in 1989 described the composition of CNSL
which found between the seed coat (pericarp) and the
nuts. It is not a triglyceride and contains a high portion of
phenolic compound, mainly are anacardic acid, cardol,
and cardanol. Recently, Lomonaco and Oliveira noted
insecticidal action of CNSL on larvae of Aedes aegypti
(Diptera: Culicidae). The three CNSL compo-nents
demonstrated good larvicidal activity against Ae. aegypti.

Despite the potential to be developed as larvicides,
phenolic compounds in the CNSL was toxic because it
induced dermatitis. In addition, application of CNSL as
larvicides in the medium of water is also cumbersome, so
it is necessary to add other materials intended to dilute it.
In this study, aqueous extract of Sapindus rarak DC was
added to increase the solubility of CNSL in water.

Materials and Methods

Plant materials

Cashew nuts were obtained from cashew trees
(A.occidentale) at Wonogiri, Central Java, Indonesia. The
fruits of Sapindus rarak DC were collected from the areas
of “Perhutani” located in Situbondo, East Java, Indonesia.
The plant material was identified by Mr.Joko Santosa and
Voucher specimen was deposit at Deprtment of
Pharmaceutical Biology   Faculty of Pharmacy, UGM.



22 Biology, Medicine, & Natural Product Chemistry 3 (1), 2014: 21-23

Oil Extraction of CNSL

The dried cashew nut shell (1,3 kg) were pressed by
hydraulic pressor to obtain Cashew Nut Shell Liquid
(CNSL).

Preparation of aquous extracts of S.rarak

The dried pericarp from S.rarak (10 g) were cut into small
pieces then extracted with 1000 mL of distilled water by
reflux process at 50°C for 30 minutes.  The concentration
of aqueous extract of S.rarak fruits was 1% b/v.

Reagents

N-Toluene (E.Merck), Ethyl acetate (E.Merck),   Acetic
acid glacial (E.Merck), Chloroform (Brataco), Methanol
(Brataco). Iodium P, Anisaldehyde-sulphuric acid LP,
Vanilin-sulphuric acid LP, ethanol 96% (Brataco), n-
hexane (Brataco), Hydrochloric acid (E.Merck). All other
chemicals used were analytical grade.

Larvicidal assay

The activity of the test materials were evaluated by the
World Health Organization recommended guidelines.

The larvicidal assay consisted of two steps. First was
the orientation to determine a certain concentration of
aqueous extract of S. rarak DC. (It was the biggest
concentration which is not found any died larvae). The
chosen concentration then was used for making the
mixture of CNSL and aquous extract of S. rarak DC. The
next step was dissolving CNSL in various amount so that
it was obtained 6 concentration series of the mixture for
used in the testing, which were 0; 8; 8,56;  9,16; 9,8; and
10,49 ppm.

Characterization of CNSL’s physico-chemical
properties

Physico-chemical properties of cashew nut shell oil was
characterized through the iodine number, esther number,
and acid number. Those properties were characterized by
Pusat Antar Universitas (PAU) - UGM.

HPLC analysis of CNSL constituents

The identity of anacardic acid was confirmed by HPLC.
The analysis was carried out using a Shimadzu SPD-
10VP chromatograph, UV-VIS detector, which utilized a
Lichochart RD-C18 analytical column. The mobile phase
consisted of methanol-acetic acid 4% (9:1v/v), which was
run in the isocratic mode phase (1 mL/min) at a UV
wavelength of 280 nm.

Determination of Foaming Index of S.rarak source

5 g of dried S.rarak fruits was dissolved in distilled water
and then heated 50oC for 5 minutes. 10 mL filtrate was
used for foaming test. Saponin test was performed by

agitation in 10 mL of the filtrate in a closed tube for 10
minutes. Incidence foam up interval of 10 minutes (stable
foam) showed a saponin.

Figure.1. Chromatogram of CSNL.

Figure.2. Chromatogram of Anacardic acid.

Results and Discussion

One of the marker constituent of CNSL, anacardic acid,
was detected in the sample of CNSL in relative
concentration of 2,58%. The HPLC chromatograms were
shown in fig.1 and fig.2.

Due to its bad solubility, CNSL was diluted in water
with S.rarak’s pericarp extract as a co-solvent, in
concentration which was determined by the orientation
test. Concentration of 400 ppm was selected as the
optimum concentration to dillute CNSL in water but it
had no effect to cause larval mortality. The mixture of
CNSL and S.rarak extract used in this study was visually
clear. There were also not detected visible oil particles or
any breaking phase.



Rahmi Safarina Fauziah, et al. – Larvicidal Activity of the Mixture of Cashew Nut Shell Liquid … 23

Table 1. Physico-chemical properties of CNSL used in this study.

Physico-chemical properties of CNSL Value

Iodium number (g iod/10 g CNSL) 6,3
Acid number (mg NaOH/g CNSL) 104,1
Saponification number 127,1
Esther number 45,9
Density (g/mL) 0,8232

It had no published data available of effect of CNSL
on immature stages of Culex mosquitoes. Effect of
different concentrations of CNSL solution on aquatic
stages of Cx.quinquefasciatus larvae in the laboratory
conditions was shown in Table 2.

There was significant decreasing mortality percentage
of the larvae by increasing CNSL concentration (table 2).
As shown in that Table, the biggest death rate was noticed
in exposure to 10,49 ppm concentration.

LC line equation obtained from probit analysis was y
= 3.01 x + 1.05, so that the calculation could be known
that LC50 and LC90 value were 20.52 ppm and 55.41 ppm,
respectively. This value was the result of extrapolation
and therefore could not guarantee that these results show
the actual value of LC50 and LC90.

Essential oils or plant extracts with LC50 values below
100 ppm can be considered potentially have larvicidal
activity. Our present observation reveals that
Cx.quenquefasciatus larvae were susceptible to 8 ppm to
10,49 ppm CNSL.

In Indonesia, population of Cx.quin-quefasciatus is
controlled by using of organophosphate insecticides, such
as temephos and Malathion. Temephos, which is also
known as “Abate” has been used in areas of water where
the Cx.quinquefasciatus mosquito breeds in order to
reduce the population of this disease-carrying insect.
Resistance to temephos by Cx.quinquefasciatus has been
reported in Brazilian and Malaysia. Temephos was very
lethal toward Cx.quinquefasciatus larvae with a
LC50=0,00088 ppm. CNSL consti-tuents were less active
than temephos, but could be important models for the
further development of new larvicides. It is necessary to
investigate the effectiveness of these mixture compounds
in a field setting and the toxicity toward other organisms,
for example by doing brine shrimp lethality test.

Conclusions

In the present work the mixture of CNSL in aquaeous
extract of S.rarak DC could be used as larvicide against.

Cx.quinquefasciatus. Given the continual search for
renewable and biodegradable sources of new medicinal
products, CNSL from cashew nut processing industries in
Indonesian agribusiness represents an opportunity to
increase the value of this by-product by developing green

larvicidal compounds to be used in filariasis control,
which is cheap, non-toxic, and biodegradable.

Table 2. Larvicidal activity of CNSL and S.rarak extract mixture
against Cx.quinque fasciatus larvae.

Acknowledgement

I would like to thanks to Faculty of Pharmacy and
Parasitology Laboratory UGM for the possibility for
doing experiment.

References

Cheng, S.S., Chang, H.T., Chang, S.T., Tsai, K.H. & Chen, W.J.,
2003, Bioactivity of selected plant essential oils against the
yellow fever mosquito Aedes aegypti larvae, Bioresearch
Technology, 89, 99-102.

Devine GJ, Furlong MJ. Insecticide use: Contexts and ecological
successions. Agric Hum Values 2007; 24: 281-306.

Evans, F.J. & Schmidt, R.J., 1980, Plants and Plant Products That
Induce Contact Dermatitis, Planta Medica, 38, 289-316.

Lima, J.B.P., Da-Cunha, M.P., Silva Júnior, R.C., Galardo, A.K.R.,
Soares, S.S., Braga, M.A., Ramos, R.P., Valle, D., 2003.
Resistance of Aedes aegypti to organophosphates in several
municipalities in the State of Rio de Janeiro and Espírito Santo,
Brazil. Am. J. Trop. Med. Hyg. 68, 329–333.

Lomonaco, D., Gilvandete, M.P.S., Yana, S.F., Angela, M.C.A.,
Selma, E.M., Mele, G., & Vasapollo, G., 2009, Study of
technical CNSL and its main components as new green
larvicides, Green Chemistry, 1, 31–33.

Oliveira, M.S.C., de Morais, S.M., Magalhaes, D.V., Batista, W.P.,
Vieira, G.P., & Craveiro, A.A., 2011, Antioxidant, larvicidal,
and antiacetylcholinesterase activities of cashew nut shell
liquid constituents, Acta Tropica, 117, 165-170.

Samuel T, Jayakumar M, William SJ. 2007, Culex mosquito: An
overview. In: William SJ. Defeating the public enemy, the
mosquito: A real challenge. Loyola Publications: Chennai, p.
95-116.

Shian, L.C., 2007, The Effect of Sublethal Concentration of Abate
on Aedes aegypti (Linnaeus) and Culex quinquefasciatus (Say),
Tesis, Universiti Sains Malaysia, Subang Jaya.

Tennyson, S., Ravindran, J.K. & Arivoli, S., 2012, Screening of
twenty five plant extracts for larvicidal activity against Culex
quinquefasciatus Say (Diptera: Culicidae), Asian Pacific
Journal of Tropical Biomedicine, S1130-S1134.

Tyman JHP, Morris LJ. Composition of cashew nut shell liquid. J
Chromatography 1989; 27: 287–8.

World Health Organization (WHO), 2005, Guidelines for
Laboratory and Field Testing of Mosquito Larvicides, Geneva.

CNSL
(ppm)

Number of larva died
(3 replications) Total

larvae
Mortality

(%)
1 2 3

0 1 1 0 75 2.67
8 2 4 4 75 13.33

8,56 5 3 3 75 14.67

9,16 7 3 3 75 17.33

9,8 6 9 0 75 20

10,49 8 5 3 75 21.33




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