Combinations of Plant Essential Oil Based Terpene Compounds as Larvicidal and Adulticidal Agent against Aedes aegypti (Diptera: Culicidae)

Insecticidal plant-based compound(s)in combinations may show synergistic or antagonistic interactions against insect pest. Considering the rapid spread of the Aedes borne diseases and increasing resistance among Aedes population against conventional insecticides, twenty-eight combinations of plant essential oil-based terpene compounds were prepared and tested against larval and adult stages ofAedes aegypti. Initially five plant essential oils (EOs) were assessed for their larvicidal and adulticidal efficacy and two of their major compounds from each EO were identified from GC-MS results. Identified major compounds namely Diallyldisulfide, Diallyltrisulfide, Carvone, Limonene, Eugenol, Methyl Eugenol, Eucalyptol, Eudesmol and α-pinene were purchased and tested individually against A. aegypti. Binary combinations of these compounds were then prepared using sub-lethal doses, tested and their synergistic and antagonistic effects were determined. The best larvicidal compositions were obtained while Limonene was mixed with Diallyldisulfide and the best adulticidal composition was obtained while Carvone was mixed with Limonene. Commercially used synthetic larvicide “Temephos” and adulticide “Malathion” were tested individually and in binary combinations with the terpene compounds. The results revealed that the combination of Temephos and Diallyldisulfide and combination of Malathion and Eudesmol were the most effective combination. These effective combinations bear potential prospect to be used against Aedes aegypti.

Plant essential oils (EO) are secondary metabolites comprising different bioactive compounds and have been getting importance as alternative to synthetic insecticide. They are not only ecofriendly and user-friendly but being a mixture of different bioactive compounds, also offer less chance of resistance development 1 . With the accessibility of GC-MS technique, researchers explored the constituent compounds of different plant EOs and more than 3000 compounds from 17500 aromatic plants have been identified 2 most of which were tested for their insecticidal properties and reported to have insecticidal effects 3,4 . Some of the studies highlighted equal or higher toxicity of major constituent compound than its crude EO. But application of a single compound may again leave chance for resistance development like that of chemical insecticides 5,6 . Hence, emphasisis are now-a-days given to prepare mixtures of EO based compounds to enhance insecticidal effects as well as to reduce the probability of development of resistance by the targeted pest population. The individual active compound present in an EO may exhibit synergistic or antagonistic effects in combinations representing the overall activity of the EO and the fact is highlighted well in studies carried out by previous workers 7, 8 . In vector control programme also, EOs and their constituents are incorporated. Mosquitocidal activities of EOs were extensively studied upon Culex and Anopheles. Few studies also attempted to formulate effective insecticide by combining different botanicals with commercially used synthetic insecticide aiming to increase the overall toxicity as well as to minimize the side effects 9 . But study of such formulated compounds against Aedes aegypti is still scanty. Advancement of medical science with development of medication and vaccination help to handle some of the vector transmitted diseases.
Adulticidal activity of the eo. Except for the EO of Ocimum sanctum (Os), the rest four selected EO showed clear adulticidal effects with LC50 value lies between 23.37 ppm to 120.16 ppm at 24 h exposure period. The highest adulticidal efficacy was recorded for the EO of Callistemon linearis (Cl) with LC50 value of 23.37 ppm at 24 h post exposure period followed by Eucalyptus maculata (Em) with LC50 value of 101.91 ppm (Table 1). On the other hand, the LC50 value for the Os was not determined as maximum 53% percent mortality was recorded at the highest dose applied (Supplementary Fig. 3).

Analysis of effective EO components.
Based on NIST library database results, area percentage of GCchromatogram and MS spectral results,two major constituent compounds from each EO were identified and selected ( Table 2). For EO of As, the major compounds identified were Diallyldisulfide and Diallyltrisulfide, www.nature.com/scientificreports www.nature.com/scientificreports/ five combinations were found to have no larvicidal effect. Among the synergistic combinations, the combination between Diallyldisulfide and Temephos was found as the most effective with 100% observed mortality at 24 hours (Table 4). Again, mixture of Limonene with Diallyldisulfide, Eugenol with Temephos showed good potentiality with 98.3% observed larval mortality, (Table 5). Other 4 combinations i.e. Eudesmol plus Eucalyptol, Eudesmol plus Limonene, Eucalyptol plus αpinene, αpinene plus Temephos also showed remarkable larvicidal efficacy with more than 90% observed mortality against almost 60-75% expected mortality (Table 4). However, combination of Limonene with α-pinene or Eucalyptol showed antagonistic response. Similarly, mixtures of Temephos with Eugenol or Eucalyptol or Eudesmol or Diallyltrisulfide were found antagonistic. Again, combination between Diallyldisulfide and Diallyltrisulfide and combination of anyone of these compounds with Eudesmol or Eugenol were antagonistic in larvicidal action. Combinations of Eudesmol with Eugenol or α-pinene were also recorded antagonistic.
Acute adulticidal effects of binary mixtures. Among all the 28 binary mixtures tested for adulticidal activity, seven combinations were found to have synergistic actions, six with no effect while other fifteen were recorded with antagonistic effect. The mixture of Eudesmol plus Eucalyptol and Limonene plus Carvone were found more effective with 76% and 100% observed mortality respectively after 24 h than other synergistic combinations ( Table 5). Malathion was observed to show synergistic action in combination with all the compounds excepts with Limonene and Diallyltrisulfide. On the other hand, combination between Diallyldisulfide and Diallyltrisulfide and any one of them with Eucalyptol or Eudesmol or Carvone or Limonene were found antagonistic. Similarly combination of α-pinene with Eudesmol or Limonene, Eucalyptol with Carvone or Limonene, Limonene with Eudesmol or Malathion showed antagonistic larvicidal effects. For other six combinations, the expected and observed mortalities were not found to be significantly different ( Table 5).
Bioassay of effective combinations in large insect mass. Based on synergistic effects and sub-lethal doses, finally four combinations (Eudesmol plus Limonene, Eugenol plus Limonene, Diallyldisulfide plus Limonene and Diallyldisulfide plus Temephos) were selected and further tested for their larvicidal toxicity against large numbers of Aedes aegypti. The results showed 100% observed larval mortalities in response to binary combinations of Eugenol-Limonene, Diallyldisulfide-Limonene, Diallyldisulfide-Temephos against 76.48%, 72.16% and 63.4% expected larval mortalities respectively ( Table 6). The combination between Limonene and Eudesmol was comparatively less effective showing 88% observed larval mortality at 24 h exposure period (Table 6). So, in large scale application too, the selected four binary combinations showed synergistic larvicidal effect against A. aegypti (Table 6). www.nature.com/scientificreports www.nature.com/scientificreports/ For adulticidal bioassay, three synergistic combinations were selected to be applied against large numbers of adult A. aegypti. For selection of combinations to be tested against large insect mass, at first emphasis was given on the best two synergistic combinations of terpene compounds that was combination of Carvone plus Limonene and Eucalyptol plus Eudesmol. Secondly one best synergistic combination was selected from the pair of synthetic organophosphate Malathion with terpene compound. Here we consider the combination of  Table 3. Sub-lethal concentrations (LC50) of different terpene compounds against 4 th instar larvae and adults of Aedes aegypti.
www.nature.com/scientificreports www.nature.com/scientificreports/ Malathion plus Eudesmol as the best combination to be tested against large insect mass because of its maximum observed mortality and the very low LC50 values of the constituent candidates. Malathion showed synergistic action while combined with α-pinene, Diallydisulfide, Eucalyptol, Carvone and Eudesmol. But if we look at the LC50 values, the value for Eudesmol was the lowest (2.25 ppm). The calculated LC50 values for Malathion, α-pinene, Diallydisulfide, Eucalyptol, Carvone were 5.4, 716.55, 166.02, 17.6, 140.79 ppm respectively. These values indicated that the combination between Malathion and Eudesmol as the best combination from the dose point of view. The results revealed that the combination of Carvone plus Limonene and Eudesmol plus Malathion showed 100% observed mortality against 61% to 65% expected mortalities. Another combination, Eudesmol plus Eucalyptol showed 78.66% mortality against 60% expected mortality after 24 h exposure period. All the three selected combinations showed synergistic action in combination even in large-scale applications against adults of Aedes aegypti (Table 6).

Discussion
In the present investigation selected plant EOs of Mp, As, Os, Em and Cl showed promising lethal effects against larval and adult stages of Aedes aegypti. Larvicidal activity of EO of Mp was recorded highest with LC50 value of 0.42 ppm followed by EOs of As, Os and Em having LC50 value below 50 ppm at 24 h. These findings were in line with the previous studies carried on mosquitoes and another dipteran flies [10][11][12][13][14] . Although larvicidal potency of Cl was comparatively lower with LC50 value of 163.65 ppm at 24 h than other EOs, its adulticidal potential was found highest having LC50 value of 23.37 ppm at 24 h. EOs of Mp, As and Em also showed good adulticidal potential having LC50 value within the range of 100-120 ppm at 24 h exposure period but comparatively lower than their larvicidal efficiency. On the other hand, EO of Os showed negligible adulticidal effect even at the highest dose of treatment. Thus, the result reflects that the toxicity of the plant EOs may vary with respect to developmental stages of the mosquito 15 . It also depends on penetration rate of EO into the insect body, their interaction with specific target enzymes and detoxification ability of the mosquito at each developmental stage 16 . A good number of studies indicate that the major constituent compound(s) are responsible factor for bioactivity of an EO as it comprises the major fraction of the total compounds 3,12,17,18 . Therefore, we considered two major compounds from each EO. From GC-MS result Diallyldisulfide and Diallyltrisulfide were identified as the major compounds of EO of As which was in conformity with the previous reports [19][20][21] . Again, Carvone and Limonene were identified as the major compounds of EO of Mp although the previous report suggested menthol as one  www.nature.com/scientificreports www.nature.com/scientificreports/ of its major compound 22,23 . Constituent profile of the EO of Os revealed Eugenol and Methyl Eugenol as the major compounds showing similarity with the findings of earlier researchers 16,24 . Eucalyptol and Eudesmol were recorded as principal compounds present in Em leaf oil which was in line with the findings of some researchers 25,26 but contradicting the findings of Olalade et al. 27 . Dominance of Eucalyptol and αpinene was observed in EO of Callistemon linearis showing similarity with previous studies 28,29 . Whatever intraspecific variation for constituent composition and concentration of EO extracted from the same plant species from different places has been reported and also observed in the present study were influenced by geographical conditions where the plant grows, harvesting time, development stage or age of the plant and occurrence of chemotypes etc. 22,[30][31][32] . The identified major compounds were then purchased and tested for their larvicidal and adulticidal effects against Aedes aegypti. The result revealed that the larvicidal activity of Diallyldisulfide was equal to the activity of crude EO of As. But the activity of Diallyltrisulfide was higher than EO of As. These findings were similar to the findings of Kimbaris et al. 33 working on Culex pipines. However, these two compounds did not show good adulticidal   Table 6. Acute effects of Binary mixtures (1:1) of LC50 dose of selected terpene compounds against 4 th instar larvae and adults of Aedes aegypti and type of interaction after large scale application (n = 300 for larva and 150 for adult).
www.nature.com/scientificreports www.nature.com/scientificreports/ activity against the target mosquito which was in conformity with the findings of Plata-Rueda et al. 34 worked on Tenebrio molitor. EO of Os was found effective against larval stages of Aedes aegypti but not against adult stages. The larvicidal activity of major individual compound was found lesser than the activity of crude EO of Os. This implies the role of other compounds and their interactions in crude EO. Methyl Eugenol individually possessed negligible activity whereas Eugenol individually possessed moderate larvicidal activity. This finding one-way supported 35,36 and other way contradicted the findings of earlier investigators 37,38 . The difference in the functional group between Eugenol and Methyl Eugenol might make the differences of their toxicity against the same target insect 39 . Limonene was found to possess moderate larvicidal activity while the Carvone showed negligible effect. Similarly, comparatively lower toxicity of Limonene and higher toxicity of Carvone against adults supported the findings of some previous studies 40 and opposed others 41 . Possession of double bond both in endocyclic and exocyclic position might add advantage of these compounds as larvicidal agent 3,41 while as a ketone Carvone with unsaturated α and β carbon might show higher toxicity as adulticides 42 . However, individual performance of Limonene and Carvone were quite lower than the whole EO of Mp (Tables 1, 3). Among the terpene compounds tested, Eudesmol was found to possess highest effects both as larvicide and adulticide with LC50 value below 2.5 ppm and emerged as promising compound for Aedes control. Its performance was better than whole EO of Em though it was not in line with the finding of Cheng et al. 40 . Eudesmol, a sesquiterpene with two isoprene units are less volatile than oxygenated monoterpene like Eucalyptoland thus have a greater potential as insecticide. Eucalyptol by its own showed higher adulticidal than larvicidal activity and both supported and opposed by the findings of earlier workers 37,43,44 . The individual activity was almost at par with the activity of whole EO of Cl. Another bicyclic monoterpene, αpinene was found to possess lower adulticidal effect than larvicidal effect against Aedes aegypti which was opposite to the performance of whole EO of Cl. Overall insecticidal activity of a terpene compound is affected by its lipophilicity, volatility, branching of the carbon-atom, projection area, surface area, functional group and their position etc. 45,46 . The compounds may exert effects by disintegrating cell mass, blocking respiratory activity, interrupting nerve impulse transmissionetc 47 . The larvicidal activity of synthetic organophosphate-Temephos was found to have highest effect with LC50 value of 0.43 ppm, which was in accordance with the findings of Lek-Uthal 48 . The adulticidal activity of synthetic organophosphate -Malathion was recorded as 5.44 ppm. Although, both the organophosphates showed good response against the laboratory strain of Aedes aegypti, development of resistance by mosquitoes against these compounds have been reported from different parts of the globe 49 . However, no such reports of resistance development were found to documentagainst botanicals 50 . Therefore, botanicals are considered as potential alternative to chemical insecticide in vector control programme.
Out of 28 binary combinations (1:1) prepared from effective terpene compounds and terpene compound with Temephos to test for larvicidal action, nine combinations were found to have synergistic, 14 combinations with antagonistic and five combinations were found to have no effect. On the other hand, in case of adulticidal bioassay, seven combinations were found to have synergistic, 15 combinations antagonistic, while six combinations were recorded to have no effect. The reason for synergistic action of some combinations might be due to the interactions of candidate compounds on different vital pathways at a time or due to the serial inhibition of different key enzymes of a particular biological pathway 51 . Combinations of Limonene with Diallyldisulfide or Eudesmol or Eugenol were found synergistic both in small scale and large-scale application ( Table 6) while its combination with Eucalyptol or α-pinene was found to show antagonistic effect against larvae. On an average Limonene was found as a good synergist which might due to the presence of Methyl group, good cuticular penetration and different mode of actions 52,53 . It was reported earlier that Limonene could exert its toxic effect by penetrating through insect cuticle (contact toxicity) or targeting digestive system (anti-feeding) or acting on the respiratory systems (fumigant activity) 54 while phenylpropanoid like Eugenol might target metabolic enzymes 55 . Thus, compounds with the different mode of actions in combination might increase total lethal actions in mixtures. Eucalyptol with Diallyldisulfide or Eudesmol or α-pinene was found synergistic but rest of the combination with other compounds were either having no larvicidal effect or having antagonistic action. Earlier studies demonstrated inhibitory activity of Eucalyptol on AChE as well as octapamine and GABA receptors 56 . As cyclic monoterpenes, Eucalyptol, Eugenol, etc. might share the same mode of action like neurotoxic activity 57 thereby minimizing their combined effect by inhibiting each other. Again, the combination of the Temephos with Diallyldisulfide, α-pinene and Limonene were found synergistic that supported previous reports of synergism that occurred between plant product and synthetic organophosphate 58 .
The combination between Eudesmol and Eucalyptol was found synergistic against both larval and adult stages of Aedes aegypti which might be due to their different mode of action because of their dissimilar chemical structures. Eudesmol, which is a sesquiterpene might target respiratory system 59 while Eucalyptol, which is a monoterpene might affect acetylcholine esterase enzyme 60 . The combined effect of constituents on two or more target sites might boost total lethal actions of the combination. In case of adulticidal bioassay, Malathion was found to show synergism with Carvone or Eudesmol or Eucalyptol or Diallylldisulfide or α-pinene reflecting it as a good synergistic adulticidal candidate for combination with the entire terpene compounds except Limonene and Diallyltrisulfide. Similar finding of synergism of Malathion with plant extracts was reported by Thangam and Kathiresan 61 . This synergistic response might due to the combined toxic effects of Malathion and phytochemicals on detoxifying enzymes of insect body. Organophosphate like Malathion generally exerts their effect by inhibiting esterases, cytochrome P450 monooxygenase enzymes [62][63][64] . Therefore, combination of Malathion having these modes of action with terpene compounds having different mode of actions might enhance the total lethal effect against the mosquito.
On the other hand, antagonistic effect indicates that the selected compounds in a combination are less active than the individual effect of each compound. The reason for antagonism in some combinations might due to the alternation of behavior of one compound by the other compound by changing the rate of absorption, distribution, metabolism or excretion as has been suggested as possible mechanism of antagonism in combination www.nature.com/scientificreports www.nature.com/scientificreports/ of drug molecules by earlier researchers 65 . Again, the possible cause of antagonism might be due to the competition of constituent compounds for single receptor or target site due to similar mode of action. In some cases, non-competitive inhibition of target protein might also occur. In the present study the two organosulfur compounds namely Diallyldisulfide and Diallyltrisulfide showed antagonism possibly for the competition for the same target site. Again, these two sulfur compounds while combined with Eudesmol and α-pinene showed antagonistic and no effect. Eudesmol and α-pinene are cyclic in nature while Diallyldisulfide and Diallyltrisulfide are aliphatic in nature. Based on the chemical structure the total lethal activity supposed to enhance in combination of these compounds as their target sites are usually different 34,47 but experimentally we found antagonistic effect which might be due to some unknown biological interactions of these compounds in living system. Similarly, combination of eucalyptol with α-pinene resulted antagonistic response though the target site of action of these two compounds were reported differently by earlier researchers 47,60 . As both of the compounds are cyclic monoterpene, there may have certain common target site to which they might compete for binding and influenced overall toxicity of the combination pair in the study.
Considering LC50 values and observed mortalities, the two best synergistic combinations of terpene compounds viz.pair of Carvone plus Limonene and Eucalyptol plus Eudesmol and one best synergistic combination of the synthetic organophosphate Malathion with terpene compound i.e. Malathion plus Eudesmol were chosen for adulticidal bioassay to test against large insect mass to confirm whether these effective combinations would work against large number of individuals in comparatively larger exposure space. All these combinations showed synergistic response against large insect mass. Similar results were found for the best larvicidal synergistic combinations which were tested against large numbers of A. aegypti larvae. Therefore, it can be stated that the effective synergistic larvicidal and adulticidal combinations of plant based EO compounds are competent candidate against existing synthetic chemicals and can further be used to control Aedes aegypti population. Similarly, the effective combination of synthetic larvicide or adulticide with terpene compounds may further be used to reduce the dose of Temephos or Malathion to be applied against the mosquito. These synergistic combinations with potent efficacy may offer solution to check resistance evolution in Aedes mosquitoes in future.

Materials and Methodology establishment of Aedes aegypti colony. Eggs of Aedes aegypti was collected from Indian Council of Medical
Research-Regional Medical Research Centre, Dibrugarh and reared in the Department of Zoology, Gauhati University under controlled temperature (28 ± 1 °C) and humidity (85 ± 5%) following the methods described by Arivoli et al. 66 . After hatching, larvae were fed with larval food (powdered dog biscuit and yeast at a ratio of 3:1) while adults were fed on 10% glucose solution. From 3 rd day after emergence, the adult female mosquitoes were allowed to feed on blood of albino rat. Filter paper submerged in water kept in beaker was put inside the cage for egg laying. Bioassay of essential oils. Larvicidal assay. The standard WHO procedure 67 was used with slight modification to investigate the larvicidal toxicity. DMSO was used as emulsifying agent. Initially 100 and 1000 ppm concentration of each EO was tested exposing 20 larvae per replication. Based on the result, a series of concentration was applied and the mortality was recorded from 1 hour to 6 hours at one-hour time interval and at 24-hour, 48 hour and 72 hours after treatment. The sub-lethal (LC50) concentration was determined after 24, 48-and 72-hour of exposure period. Each concentration was assayed in triplicate along with one negative control (water only) and one positive control (DMSO treated water). If the pupation occurred and more than 10% larvae died in the control group then the test was repeated. If mortality occurred in the control groups between 5-10% then, then Abbot's correction formula 68 was used.

Collection of plant materials and eo extraction.
Adulticidal assay. The method described by Ramar et al. 69 was followed for adulticidal bioassay against Aedes aegypti, where acetone was used as a solvent. Initially, 100 and 1000 ppm concentration of each EO were tested against adult Aedes aegypti. 2 ml of each prepared solution was applied on Whatman no. 1 filter papers (size 12 × 15 cm 2 ) and allowed to evaporate acetone for 10 minutes. Filter paper treated with 2 ml of acetone alone was used as control. After evaporation of acetone, both the treated and the control filter paper were placed in cylindrical tubes (depth 10 cm). Ten numbers of 3-4 days old non-blood fed mosquitoes were transferred in each of the three replicas of each concentration. Based on the result of initial test, different concentrations of the selected oils were tested. Mortality was recorded at 1 hour, 2 hour, 3 hour, 4 hour, 5 hour, 6 hour, 24 hour, 48 hour and 72 hour respectively from the time of the mosquito released. LC50 value was calculated at 24 h, 48 h and 72 h of exposure period. If mortality exceeded 20% in the control batch, the whole test was repeated. Again, if mortality in the controls was above 5%, results with the treated samples were corrected using Abbott's formula 68 . Analysis of effective essential oil components. For analysis of the constituent compounds of the selected EO, Gas chromatography (Agilent 7890A) and mass spectrometry (Accu TOF GCv, Jeol) was performed. GC was equipped with a FID detector and a capillary column (HP5-MS). The carrier gas was helium at a flow rate of 1 ml/min. The GC programme was set for Allium sativum as 10: www.nature.com/scientificreports www.nature.com/scientificreports/ Identification of major terpene compounds of different EOs. Major compounds of each EO were identified based on their area percentage calculated from the GC-chromatogram and mass spectrometry results in reference to NIST standard database 70 .

Bioassays of individual major terpene compounds against A. aegypti. Two major compounds
from each EO were chosen from GC-MS result and purchased from Sigma-Aldrich having 98-99% purity for further bioassay. Larvicidal and adulticidal efficacy of these compounds against A. aegypti was tested following the methods described above. The most commonly used synthetic commercial larvicide Temephos (Sigma Aldrich) and adulticide Malathion (Sigma Aldrich) were assayed for comparing their efficacy with selected EO compounds following the same procedure.
Formulation of terpene compounds. Binary mixtures of selected terpene compounds and terpene compound plus commercial organophosphates (Temephos and Malathion) were prepared mixing LC50 dose of each candidate compound in 1:1 ratio. Prepared combinations were tested against both larval and adult stages of Aedes aegypti following the method described above. Each bioassay was performed in triplicate for each combination and three replicates for the individual compounds present in the respective combination. Mortalities of the target insect were recorded at 24 hours. Expected mortality of the binary mixtures was calculated based on following formula. The effects of each binary mixture were marked as synergistic, antagonistic and no effect based on their calculated χ 2 value following the method described by Pavela 52 . χ 2 value was calculated for each combination using following formula.
where, O m = Observed mortality of A. aegypti in response to binary mixtures. E = Expected mortality of A. aegypti in response to binary mixtures. The effect of a combination was designated as synergistic when the calculated χ 2 value was found greater than the table value at respective degrees of freedom at 95% confidence interval and if observed mortality was found greater than the expected mortality. Again, if the calculated χ 2 value for any combination was greater than the table value at definite degrees of freedom but observed mortality was found lower than the expected one, then that treatment was considered as antagonistic. While if in any combination, calculated χ 2 value found less than the table value at respective degrees of freedom then that combination was considered to have no effect.

Bioassay of effective combinations in large insect mass.
Based on the observed mortality in binary mixtures having synergistic action and the LC50 dose of each terpene compound present in the respective mixture, three to four potential synergistic combinations were selected to test for larvicidal and adulticidal activity against large number of insects (100 larvae and 50 adults) by following the method described above. Along with the mixtures, the individual compound present in the selected mixtures were also tested against same numbers of Aedes aegypti larvae and adults. The proportion of the combination was one part of LC50 dose of one candidate compound and one part of LC50 dose of another constituent compound. In adulticidal bioassay, selected compounds were dissolved in acetone solvent and applied in filter paper wrapped inside a cylindrical plastic vessel with 1300 cm 3 volume. The acetone was evaporated for 10 minutes before releasing adult insects. Again, in case of larvicidal bioassay, LC50 doses of the candidate compounds were first dissolved in equal amount of DMSO and then mixed in 1 liter of water kept in 1300 cm 3 plastic vessel and the larvae were released. statistical analysis. The mortality data recorded were subjected to probit analysis 71 for calculating LC 50 values using SPSS (version 16) and Minitab software.