Some Natural Plant Extracts Having Biocide Activities against the American Bollworm Helicoverpa armigera (Lepidoptera: Noctuidae)

Abstract

In the present research, the toxicity, antifeedant activity and biological effects of ethanolic leaves extract of four medicinal plants named Eucalyptus rostrata, Dodonea viscosa, Rhyza stricta and Cymbopogon schoenanthus were evaluated on 2nd, 3rd and 4th instar larvae of H. armigera under laboratory condition. The results showed that values of LC50 in mg of different plant extracts in mg/100ml of the larval diet can be arranged in an ascending order as follows: Dodonea 7.23 > Cymbopogon 12.59 > Rhazya 14.52 > Eucalyptus 29.42 mg/100ml diet (the least LC50 is more toxic than the higher one). All the tested extracts had antifeedant and starvation effects against the 2nd, 3rd, 4th instar larvae. D. viscose extract possesses the least antifeedant effect even of their higher toxicity. There was clear relation between the percent of starvation and antifeedant of the 2nd, 3rd and 4th larval instar. All extracts were nearly the same in their effect on the biotic potential; of the insect, and possess latent effect when tested against 2nd instar larvae, the value of LC 50 of the extract was added to the diet, extracts increased larval duration, deformation between pupae and adult stages, moths sterility, increased as decreasing in females egg production. Other effects were noticed, reduction in percentage of pupation and moths emergence. The plant extracts can be arranged ascending according to percentage of their sterility effects as follows: C. schoenanthus < E. rostrata < R. stricta < D. viscose. All extracts cause disruption on the biology and physiology of the insect, and all extract induced percentages of deformation between pupal and moth stages. The ethanolic extract of the plant leaves of the tested plans may be used for control H. armigera in combination with other methods in the integrated program in order to decrease the buildup of the resistance and protect the environment from chemical pollution.

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Sharaby, A. and Dhafar, Z. (2019) Some Natural Plant Extracts Having Biocide Activities against the American Bollworm Helicoverpa armigera (Lepidoptera: Noctuidae). Advances in Entomology, 7, 10-20. doi: 10.4236/ae.2019.71002.

1. Introduction

The American bollworm or tomato fruit worm Helicoverpa armigera (Hubn.) is highly polyphagus feeding on about 200 plant species, mainly annuals, developing on a wide range of food, fiber, oil and fodder crops as well as on many wild plants and perennial horticultural crops. It has long been recorded as a pest of many crops in the Kingdom of Saudi Arabia, like Tomato, Maize, Zucchini, Green pepper, Gourd, Muskmelon, Okra, Cassia, Potato, Bean, Chickpea, Sunflower, Red beet, Tobacco, Cowpea, and Turnip. It also attacks the cotton plantation in many parts of the world [1] [2] [3] , the larvae initially feed on leaves, later boring into flowers and, when flowers became bolls the small larvae break through the bolls fed on it, they move from boll to boll; the affected bolls fail to develop and the quality of the lint is severely spoilt. Slightly damaged bolls are also failed due to the invasion by rot microorganisms. In tomatoes, the larvae bore into immature, ripening and ripe fruit, preferring the latter, and cause rot. In maize, larvae bore into stems and can cause serious plant lodging [2]. Many problems have been encountered as a result of the extensive use of synthetic pesticides. Increasing problems concerning the application of such pesticides include pest resistance, residue, contamination of humans foods, mammalian toxicity and pollution of environments [4] [5]. Therefore, several insecticides occurring naturally in plants have been investigated as alternatives bioagents to the highly toxic synthetic chemical pesticides for pest control. Such natural products having pesticide activity are assumed to be environmentally more acceptable because of their low persistent nature and are less hazardous to humans [6] [7]. Bioactive compounds of plant origin are considered as ecologically safe alternative and the plant extracts with complex mixtures of compounds have been widely investigated for their insecticidal repellent, ovicidal, antifeedant and antioviposition properties [8]. There is an increasing interest in the role of the plant products in insect-plant interaction, particularly in host acceptance and rejection [9]. While plant chemicals may produce toxic effects when ingested by insects, antifeeding activity may determine the extent of insect herbivores. Several researches have recorded the entomotoxic properties of the plant extracts from different plant species [10] [11] [12]. The present research aimed to study the biological activity of four ethanolic leaves extract derived from medicinal plant named Eucalyptus rostrata, Dodonea viscose, Rhyza stricta and Cymbopogon schoenanthus in an effort to find out their biological activity against H. armigera as safe alternatives to chemical pesticides and their possible use in IPM programme for control, and protect the crops from infestation by H. armigera, also to delay the buildup of resistance strain.

2. Materials and Methods

2.1. Insect Breeding Larvae

Larvae and adults of H. armigera were collected from Berseem, Okra, and tomato field in KSA during summer season. The larvae were reared on a synthetic artificial diet mentioned by [13] under laboratory condition at 27˚C, at 10 h light: 14 h dark (LD10:14) photoperiod. Pupae were sexed and kept in separate plastic boxes until adult moth emergence. Adults were transferred to rearing jars allowed to mate and lay egg, and fed with 10% honey solution, black cloth strips were hanged inside the jars as a site for egg laying. The eggs were collected daily in other boxes. After hatching, neonate larvae were transferred to the artificial diet in order to feeding and complete their life cycle. 3rd instar larvae were kept individually in plastic vials to avoid cannibalism habit, different instars larvae were chosen from the rearing diet for different bioassay tests.

2.2. Plant Material and Extract Preparation

Plant leaves of E. rostrata and D. vescosa were collected from the garden in Dammam, R. stricta and C. schoenanthus were collected from the desert around AL-Dowami governorate in KSA. The plant were identified according the description of [14]. The extracts were prepared as follows; the collected leaves from each plant were dried in a shad at room temperature (27˚C ± 2˚C) for some days, the dried leaves were pulverized in fine powder with electric grinder and sieved. For extraction, the procedure of [15] was adopted at 27˚C ± 2˚C as follows, 250 g. from the dried fine powder of each plant leaves were soaked in 750 ml. Ethanol 80% as solvent for 3 - 4 days. The mixtures were stirred for one hour, the solution was filtered through What man filter paper No.4. The extract were concentrated by Rotary evaporator until solvent was completely evaporated to get the solidify crude ethanol extract. The obtained crude extracts were stored in sterilized dark bottles kept at 4˚C in refrigerator. Different concentration were prepared by dissolving a known weight of the extract in 2ml. of ethanol 80% with two drops of tween 80, then will mixed with 100ml. of the artificial diet that recorded by [13].

2.3. Bioassay Tests

Bioassay tests included, the toxic effect of ethanolic plant leaves of the four tested plants against the 2nd, 3rd and 4th instar larvae of H. armigera, antifeedant and starvation effects, and effect of the toxic concentration LC50 on some biological parameters of the insect.

2.3.1. Toxic Effect of the Plant Extract on the Larval Stage

With seven different concentrations of ethanolic extract (5, 10, 15, 20, 25, 30 and 40 mg extract/100ml. diet) were prepared of each of the tested plant. Diet was prepared with different serial concentrations of each extract. The prepared treated diet was cut into small pieces and placed in Petri dish. The diet prepared with the 2 ml. ethanol as a solvent with 2 drops of Tween 80 was used as positive control. One larva per Petri dish was released on the treated diet was left to fed for 7 days. Ten replicates were used each repeated five times for each concentration. Mortality counts were noted daily until 7 days. Moribund larvae were considered as dead.

Percent larval mortality = Number of deadlarvae Total number of treated larvae × 100

Percent mortality corrected according to Abbot's formula (Abbot, 1925),

Corrected mortality = % T % C 100 % C

T, % mortality in treatment―C, % mortality in control.

LC50, and LC95 calculated for 2nd, 3rd, 4th instar larvae according to [16] , and Probit regression (line Ldp-line) was used.

2.3.2. Antifeedant & Starvation Effect of Different Ethanolic Plant Extracts

Diet having LC50 value of extract of each plant was weighed and placed in Petri dishes for larval consumption. The diet prepared without extract was used as control. The tested instar larvae were starved for 8 h before the experiment. Starved larvae were released on treated and control diet in Petri dishes. Data was recorded after 24 h. Weight loss of diet due to water evaporation was quantified by establishing another control diet left without any larvae, then weighed at the end of the test. The percent diet consumed was calculated using feeding deterrence index (DI), [17]

Deterrent:CCA = ( C T C + T ) × 100

where, CAA is corrected antifeedant or deterrent activity; T is diet consumed in treatment and C is diet consumed in control.

Percent starvation: Larvae that fed on LC50 treated or untreated diet and also another left without any food were weighted after 48 h. from the beginning of the experiment. The test was run on newly molted 2nd instar in three replicates each contained 10 larvae. % Starvation calculated according [18].

Percent starvation = C E C S × 100

where E, is mean weight of treated larvae; C, is mean weigh of untreated larvae ; S is mean weight of larvae left for natural starvation.

2.3.3. Development and Survival of H. Armigera

For studying the effect of LC50 values of the ethanolic extract of the different tested plant, method of [19] was used, 100 of second instar larvae were chosen from the artificial diet left to fed for 48 h. on diet having LC50 value that recorded from the previous toxicity tests. Remained alive larvae were transferred on untreated diet to complete their development, for each test 100 larvae were used with 10 replicate. Different biological parameters were noticed like larval duration, larval weight, % pupation, pupal weight, pupal duration, % adult emergence, deformation between pupae & adults, sex ratio, egg production/female, egg hatchability and % sterility that recorded by [20].

All data were subjected to statistical analysis of variance (ANOVA) SPSS computer program.

3. Results and Discussion

Data obtained from the LdP line (Lethal Probit Regression Line) recorded the values of LC50 and LC95 of ethanolic extracts of the different plants against H. armigera 2nd instar larvae are summarized in (Table 1) all extracts induced toxic effect in variable values of LC50 as follows, D. viscosa 7.23 > C. schionanthus 12.29 > R. stricta 14.52 > E. rosyrata 29.42 mg/100ml (the least LC50 is more toxic than the higher one). Percentage of mortality was increased by increasing the extract concentration or the duration of feeding time.

The results agreed with that mentioned by [21] who found that D. viscosa extract at 5% concentration induced 75% death to Spodoptera littoralis 2nd instar larva fed for one day. The toxicity of D. viscosa because of the containment from sterols, viscosol, tannins, and high percentage of flavonoids, alkaloids saponins, coumarins and phenols [22] [23] [24] , recorded R. stricta extract had toxic effect on C. pipienes, LC50 reached 190 ppm. After 10 day post treatment, also alchoholic extract gave larval mortality within two day and LC50 was 251 ppm. R. stricta contained high percentage of alkaloids [25] [26] [27] , recorded that C. schoenanthus contained 11 terpines. [28] , found that 2% C. citratus oil leading to high toxicity of 3rd instar larvae of Spodoptera. exigua within 2 h. from treatment LC50 reached 0.215% after 24 h. We could conclude that variation in LC50 and the different extracts may be related to different larval ability to analyze the components of each extract.

There was a clear relation between the four tested extracts (Table 2). All extracts may be inhibited the gustatory chemoreceptors on the mouth parts of the larvae leading to lost its response for feeding, the stop food consumption effect on the digestive and hormonal system [29]. The higher antifeedant and starvation percentage induced by R. stricta extract attributed to their high content of alkaloids.

Table 1. LC50 & LC95 values in mg of plant extract/100ml diet on the 2nd instar larvae of H. armigera.

Table 2. Effect of plant extracts on percentage of starvation & antifeeding on different larval instars of H. armigera.

Data agreed with [30] recorded that highest level of alkaloids in methanolic and ethanolic extract of R. stricta leading to stop feeding of H. brunneipennis and A. ipsilon. Some alkaloids such as nicotin, strychnine, caffeine exhibited feeding of Dysdercus spp. [31] [32] [33] mentioned Melia extrac play as antifeedant on insects by their effect on juvenile hormone JH that reduced the insect growth and development and disrupted the metabolism. D. viscosa extract cleared the least antifeedant and starvation effect in spite of their higher toxicity, that was as result of consuming a large amount of the treated diet, it depends on the solvent used in the extraction process. [19] , found chloroform was the most suitable solvent for extraction the antifeedant material from D. viscosa plant leaves.

Effect on biological parameters: Data in Table 3 indicated that all tested extracts were nearly the same in their effect on the biotic potential and possess latent effect when the value of LC50 of the extract incorporated into the diet fed to 2nd instar larvae comparing with the control. The extracts of different plants increase the larval duration, percentage of deformed pupae and adults and the percentage of moth sterility. Other effects include decrease in the larval weight, reduced percentage of survivor larvae, pupation and moths emergence. Life cycle bioassay using the extracts revealed that it inhibited larval growth and delayed mean time to pupation; extremely potent inhibitor the larvae to reach the pupal stage. The pupae showed an intermediate form between larvae and pupae, Figure 1(b) and finally the pupae died. The pupae were minute in size Figure 1(a), with soft puparium and lost their body fluid. Appearance of deformed moths with twisted and shrinkage wings Figure 1(c), Figure 1(d), and intermediate form between pupae and moth were also observed.

The plant extracts can be arranged ascendingly according to the percentage of their sterility effects as follows: C. shoenanthus 6.62 < E. rostrata 39 < R. stricta 51.27 < D. viscose 68.8. It cleared that the plant extract cause disruption on the insect biology as a results of their effect on the insect hormone unbalance. The

Table 3. Biological aspects of H. armigera maintained on artificial diet treated with the concentration of LC50 values in mg. of different plant alcoholic extracts/100ml diet.

P < 0.05 Significant* P < 0.01 Highly Significant**.

Figure 1. Showing different morphological deformation occurred between pupal and adult stages of H. armigera treated with the different tested. extracts, (a) Minute pupa, T, compared with the untreated one C; (b) Pupae in intermediate form between papa and adult; (c) Deformed moth with twisted legs and minute antennae; (d) Deformed moth with twisted wings, and mouth parts with shrinkage abdomen.

differential inter-specific insect response to the extracts and its constituents could be attributed to compound structure-activity relationships and physiological-structural induced cellular changes resulting in poisoning of insects by blocking octopamine receptors [29] [34] [35] [36] suggested that the toxic effect may be attributed to a reversible competitive inhibition of acetylcholinesterase by site of the enzymes active center. It has been found that some plant that have insecticidal activity could be developed into product suitable for integrated pest management because they are selective to pests, have no or little harmful action against ecosystem. They act in many ways on various types of pests complex and may be applied to the plant in the same way as other agricultural chemicals [37] [38].

4. Conclusion

All extracts of the recorded plants induced different effects as toxicants and growth regulators; the most effective one was Dodonea LC50 value 7.23 mg/100ml on 2nd instar larvae followed by Cymbopogen 12.59 > Rhazya 14.52 > Eucalyptus 29.42 g/100ml diet (lees concentration gave more mortality). The diet that was treated with plan extract LC50 then ingested by the 2nd instar larvae induced latent biocidal activities as growth regulators, and percentage of moths sterilization occurred. Foregoing results may shed some light on the possibility of using the four tested plant extracts in field application as a mean for controlling H. armigera between other means of IPM programs.

Ethics Approval and Consent to Participate

Not applicable.

Consent for Publications

Not applicable.

Availability of Data and Materials

All dataset on which abstracted of the study have been drawn are presented in the main manuscript.

Funding

The experimental work is not financially supported by ant agency.

Authors Contributions

The corresponding author suggested the idea and designed the research, was supervisor, and wrote the manuscript, contributed to the writing and approved the manuscript.

The another co-author analyzed the data, preparation of tables and figures, contributed to the writing and approved the manuscript

Significant Statement

This study is very important for the clean environment free of the pollution of chemical insecticides, create new agents from local available plant materials safe, easy preparing, cheap, possible use in combination with other biological control method of IPM program, decrease build up resistance strains of the insect because of the extracts contained different constituents have different mode of actions on the insects.

Conflicts of Interest

The authors declare that they have no competing interests.

References

[1] Fakrudin, B., Kumar, V., Krishnareddy, K.B., Patil, B. and Kuruvinashetti, V. (2004) Morph Metric Differences between Pyrethroid Resistance and Susceptible Population of Cotton Bollworm, Helicoverpa armigera. Resistance of Pest Management News, 13, 18-19.
[2] Razmjou, J., Naseri, B. and Hemati, S.A. (2014) Comparative Performance of the Cotton Bollworm Helicoverpa armigera (Hubn.) (Lepidoptera: Noctuidae) on Various Host Plants. Journal of Pesticide Science, 87, 329-370.
[3] Hamza, A.F., EL-Orabi, M.A., Gharieb, O.H., EI-Saeady, A.A. and Hussein, A.E. (2016) Responase of Sitophilus granaries L. to Fumigant Toxicity of Some Plant Volatile Oils. Journal of Radiation Research and Applied Sciences, 9, 8-14.
https://doi.org/10.1016/j.jrras.2015.05.005
[4] Liu, N. and Yue, X. (2000) Insecticidal Resistance and Cross-Resistance in the House Fly (Diptera: Muscidae). Journal of Economic Entomology, 93, 1269-1275.
https://doi.org/10.1603/0022-0493-93.4.1269
[5] Namin, R.F., Naseri, B. and Razmjou, J. (2014) Nutritional Performance and Activity of Some Digestive Enzyme of the Cotton Bollworm, Helicoverpa armigera, in Response to Seven Tested Bean Cultivars. Journal of Insect Science, 14, 1-8.
https://doi.org/10.1673/031.014.93
[6] Elumalai, K., Krishnappa, K., Anandan, A., Govindarajan, M. and Mathivana, T. (2010) Antifeedant Activity of Medicinal Plant Essential Oils against Spodoptera litura (Lepidoptera: Noctuidae). International Journal of Recent Scientific Research, 2, 262-268.
[7] Arivoli, S. and Samuel, T. (2013) Antifeedant Activity, Developmental Indices and Morphogenetic Variations of Plant Extracts against Spodoptera littoralis (Fab) (Lepidoptera: Noctuidae). Journal of Entomology and Zoology Studies, 1, 87-96.
[8] Isman, M.B., Wan, A.J. and Passrieter, C. (2001) Insecticidal Activities of Essential Oils to Tobacco Cutworm. Spodoptera litura, Fitoterapia, 72, 65-68.
https://doi.org/10.1016/S0367-326X(00)00253-7
[9] Akhtar, Y. and Isman, M.B. (2004) Comparative Growth Inhibitory and Antifeedant Effect of Plant Extracts and pure Allelochemicals on Four Insect Species. Journal of Applied Entomology, 128, 32-38.
https://doi.org/10.1046/j.1439-0418.2003.00806.x
[10] Sadek, M.M. (1997) Antifeedant and Larvicidal Activity Effects of Eichornia crassipes Leaves on the Cotton Leafworm Spodoptera litteralis (Boisd.). Journal of Egypt German Society of Zoology, 24, 209-232.
[11] Sadek, M.M. (2003) Antifeedant and Toxic Activity of Adhatoda vasica Leaf Extract against Spodoptera littoralis (Lpidoptera: Noctuidae). Journal of Applied Entomology, 127, 396-404.
https://doi.org/10.1046/j.1439-0418.2003.00775.x
[12] Ulrichs, C.H., Mews, I., Adhikart, S., Bhattacharya, A. and Goswami, A. (2008) Antifeedant Activity and Toxicity of Leaf Extracts from Portesia coarctata Takeoka and Their Effects on the Physiology of Spodoptera littoralis (F.). Journal of Pest Science, 18, 79-84.
https://doi.org/10.1007/s10340-007-0187-4
[13] Sharaby, A. and AL-Dhafar, Z.M. (2018) Successful Laboratory Mass Production of the American Bollworm Helicoverpa armigera (Hubn.) on Artificial Diet. Merit Research Journal of Agricultural Science and Soil Sciences, 6, 7-12.
[14] Migahid, A.M. (1978) Flora of Saudi Arabia. Riyadh University, Riyadh.
[15] Abo-EL-Ghar, G.E.S., Khalil, K.F. and Eid, T.M. (1996) Some Biochemical Effects of Plant Extracts in the Black Cutworm Agrotis ipsilon (Hufn.) (Lepidoptera: Noctuidae). Journal of Applied Entomology, 120, 477-482.
https://doi.org/10.1111/j.1439-0418.1996.tb01638.x
[16] Finney, D.J. (1971) Probit Analysis. 3rd Edition, Cambridge University Press, London.
[17] Koul, O., Daniewski, W.M., Multani, J.S., Gumulka, M. and Singh, G. (2003) Antifeedant Effects of the Limonoidis from Entandrophragma candotei (Meliaceae) on the Gram Pod Borer, Helicoverpa armigera (Lepidoptera: Noctuidae). Journal of Agricultural and Food Chemistry, 51, 7271-7275.
https://doi.org/10.1021/jf0304223
[18] Mostafa, O.K. (1969) Studies on Antifeeding and Repellents to Economic Lepidoptera. M.Sc. Thesis, Faculty of Agriculture, Cairo University, Cairo.
[19] Abdel-Aziz, S.H. (1994) Food Chemical Components as an Ecological Limiting Factor for Population Growth of the Cotton Leafworm, Spodoptera littoralis (Boisd.). Ph.D. Thesis, Faculty of Agriculture, Ain Shams University, Cairo.
[20] Toppozada, A., Abdellah, S. and EL-Defrawi, M.E. (1966) Chemosterilization of Larvae and Adults of the Egyption Cotton Leafworm Prodenia litura by Apholate, Metepa and Tepa. Journal of Economic Entomology, 59, 1125-1128.
https://doi.org/10.1093/jee/59.5.1125
[21] Abdel-Aziz, S.H. and Sharaby, A. (1997) Some Biological Effects of White Mustard Oil, Brassica alba against the Cotton Leafworm Spodoptera littoralis (Boisd.). Anzeiger für Schädlingskunde, Pflanzenschutz, Umweltschutz, 70, 62-64.
[22] Penegelly, A. (1999) Dodonea viscose. Australian Journal of Medical Herbalism, 11, 11-14.
[23] Sachdev, K. and Kulshreshtha, D.K. (1984) Dodonic Acid, a New Diterpenoid from Dodonea viscose. Planta Medica, 5, 448.
https://doi.org/10.1055/s-2007-969764
[24] EI-Hag, E.A., Harraz, F.M., Zytoon, A. and Salama, A.K. (1996) Evaluation of Some Wild Herb Extracts for Control of Mosquitoes. (Diptera: Culicidae). Journal of King Saud University, Agricultural Sciences, 8, 135-145.
[25] Jewers, K., Pusey, D.F.G., Sharma, S.R. and Ahmad, Y. (1980) 13C (Carbon Isotope) NMR Spectral Analysis of Rhazin, Qyebrachamine and Rhazinilam (Isolated from Razya stricta, Medicinal Plants. Planta Medica: Journal of Medicinal Plant Research, 38, 359-362.
https://doi.org/10.1055/s-2008-1074890
[26] Al-Yahya, M.A., AL-Meshal, A., Moss, J.S., AL-Badre, A.A. and Mohamed, T. (1990) Saudi Plant Phytochemical and Biological Approach. KASCT No. 39, King Saud University Press, Riyadh.
[27] Dawidar, A.M., Emirly, S.T. and Abdel-Mogib, M. (1990) Ssquiterpenes from Cymbopogen schoenanthus L. Pharmazie, 45, 296-297.
[28] Sharaby, A. (1988) Anti-Insect Properties of Essential Oil of Lemon Grass, Cymbopogon citrates against the Lesser Cotton Leafworm Spodoptera exigua (Hubn.). Insect Science .and Its Application, 9, 77-80.
[29] Kostykovvsky. M., Rafaeli, A., Gileadi, C., Demchenko, N. and Shaaya, E. (2002) Activation of Octopaminergc Receptors by Essential Oil Constituents Isolated from Aromatic Plants: Possible Mode of Action Against Insect Pests. Pest Management Science, 58, 1101-1106.
[30] EL-Hag, E.A., EL-Nadi, A.H. and Zaitoon, A.A. (1999) Toxic and Growth Retarding Effects of Three Extracts on Culex pipiens Larvae (Diptera: Culicidae). Phytotherapy Research, 13, 388-392.
https://doi.org/10.1002/(SICI)1099-1573(199908/09)13:5<388::AID-PTR455>3.0.CO;2-U
[31] Wada, K. and Munakata, K. (1968) Naturally Occurring Insect Control Chemicals Isoboldine a Feeding Inhibitor and Concculolidine an Insecticide in Leaves of Cocculus trilobus D.C. Journal of Agricultural and Food Chemistry, 16, 471-474.
https://doi.org/10.1021/jf60157a034
[32] Redfern, R.E., Warthen, J.D., Mills, G.D. and Uebel, E.C. (1979) Molting Inhibitory Effects of Azardirachtin on Large Milkweed Bug. Science and Education Administration, No. 5, 1-5.
[33] Sieber, K.P. and Rembold, H. (1983) The Effect of Azardirachtin on the Endocrine Control of Moulting in Locusta migratoria. Journal of Insect Physiology, 29, 523-527.
https://doi.org/10.1016/0022-1910(83)90083-5
[34] Enan, E.E. (2004) Molecular and Pharmacological Analysis of an Octopamine Receptor from American Cockroach and Fruit Fly in Response to Plant Essential Oils. Archives of Insect Biochemistry and Physiology, 59, 161-171.
https://doi.org/10.1002/arch.20076
[35] Priestley, C.M., Burgess, I.F. and Williamson, E.M. (2006) Lethality of Essential Oil Constituents towards Human Louse, Pediculis humanus and Its Eggs. Fiterapia, 77, 303-309.
https://doi.org/10.1016/j.fitote.2006.04.005
[36] Ryan, M.F. and Pyrne, O. (1988) Plant Insect Convolution and Inhibition of Acetylcholinesterase. Journal of Chemical Ecology, 14, 1965-1975.
https://doi.org/10.1007/BF01013489
[37] Hedin, P.A., Hollingsworth, R.M., Masler, E.P., Miyamoto, J. and Thompson, D.G. (1997) Phytochemicals for Pest Control. ACS Symposium Series 658, American Chemical Society, Washington DC.
[38] Schmutterer, H. (1992) Control of Diamondback Moth by Application of Neem Extract. In: Talikar, N.S., Ed., Diamond Back Moth and Other Crucifer Pests, Proceedings of the 2nd International Workshop, Taipei, 325-332.

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