1. WHO (2022) World Malaria Report 2021. World Health Organization. Geneva, Swit¬zerland. Available at: https://www.who.int/teams/global-malaria-programme/reports/world-malaria-report-2022.
2. Azari-Hamidian S, Norouzi B, Har¬bach RE (2019) A detailed review of the mosqui-toes (Diptera: Culicidae) of Iran and their medical and veterinary importance. Acta Tropica. 194: 106–122.
3. Sedaghat MM, Sanei-Dehkordi AR, Abai M, Khanavi M, Mohtarami F, Abadi YS (2011) Larvicidal activity of essential oils of Apiaceae plants against malaria vector, Anopheles stephensi. Iran J Ar-thropod Borne Dis. 5(2): 51–59.
4. Hemingway J (2014) The role of vector control in stopping the transmission of malar¬ia: threats and opportunities. Philos Trans R Soc Lond B Biol Sci. 369(1645): 20130431.
5. WHO (2018) Global report on insecticide resistance in malaria vectors: 2010–2016. World Health Organiza¬tion. Geneva, Swit¬zer¬land. Available at: https://apps.who.int/iris/handle/10665/272533.
6. Bekele D (2018) Review on insecticidal and repellent activity of plant products for malaria mosquito control. Biomed Res Rev. 2(2): 1–7.
7. Tahghighi A, Ravasan NM, Djadid ND, Alipour H, Ahmadvand R, Karimian F, Yousefinejad S (2019) GC–MS analysis and anti–mosquito ac¬tivities of Juni-perus virgini¬ana essential oil against Anopheles stephen¬si (Diptera: Cu-licidae). Asian Pac J Trop Bi¬omed. 9(4): 168–175.
8. Krishnappa K, Dhanasekaran S, Elumalai K (2012) Larvicidal, ovicidal and pupi¬cidal activities of Gliricidia sepium (Jacq.) (Legu¬minosae) against the ma¬larial vec-tor, Anophe¬les stephensi Liston (Cu-licidae: Diptera). Asian Pac J Trop Bio-med. 5(8): 598–604.
9. Khanavi M, Najafi B, Sada SN (2017) Chem¬i¬cal constitute and larvicidal activ-ity of fractions of Ajuga chamaecis-tustomen¬tella plant against malaria vec-tor Anoph¬eles ste¬phensi. J Arthropod Borne Dis. 11(1): 116–123.
10. Vatandoost H, Rustaie A, Talaeian Z, Abai MR, Moradkhani F, Vazirian M, Hadjiakhoon¬di A, Shams-Ardekani MR, Khanavi M (2018) Larvicidal activity of Bu¬nium persicum essential oil and ex-tract against malaria vector, Anopheles stephensi. J Arthropod Borne Dis. 12(1): 85–93.
11. Lame Y, Nukenine EN, Simon Pierre DY, Elijah AE, Esimone CO (2015) Labora-tory evaluations of the fractions efficacy of An¬nona senegalensis (Annonaceae) leaf extract on immature stage develop-ment of malarial and filarial mosquito vectors. J Arthropod Borne Dis. 9(2): 226–237.
12. Ghosh A, Chowdhury N, Chandra G (2012) Plant extracts as potential mos-quito larvi¬cides. Indian J Med Res. 135(5): 581–598.
13. Mosaddegh M, Naghibi F (2005) Islamic Republic of Iran. In: Bodeker G, Ong CK, Grundy C, Burford G, Shein K (Eds): WHO Global Atlas of Tradition-al, Com¬plementary and Alternative Medicine, World Health Or¬ganization, center for health develop¬ment, Kobe, Japan, pp. 159–164.
14. Jurjani E (1976) Zakhire Kharazmshahi. Bonyade Farhang-e Iran Publisher, Iran.
15. Aghili A (2009) Makhzan ul-Advia. Rah- e Kamak, Iran.
16. Mozaffarian V (2007) A Dictionary of Ira-nian Plant Names. 5th ed. Frhang Moaser Publisher, Iran.
17. Khani A, Heydarian M (2014) Fumigant and repellent properties of sesquiter-pene-rich essential oil from Teucrium po-lium subsp. capitatum (L.). Asian Pac J Trop Med. 7(12): 956–961.
18. Yadav NP, Rai VK, Mishra N, Sinha P, Bawankule DU, Pal A (2014) A novel ap¬proach for development and charac-terization of effective mosquito repellent cream formu¬lation containing citronella oil. Biomed Res Int. 2014: 786084.
19. Klun JA, Debboun M (2000) A new mod-ule for quantitative evaluation of repel-lent efficacy using human subjects. J Med Ento¬mol. 37(1): 177–181.
20. WHO (2005) Guidelines for laboratory and field testing of mosquito larvicides. World Health Organiza¬tion. WHO/CDS/ WHOPES/GCDPP/13. Ge¬neva, Swit-zerland. Available at: https://apps.who.int/iris/handle/10665/69101
21. Yohana R, Chisulumi PS, Kidima W, Tahghighi A, Maleki-Ravasan N, Kwe¬ka EJ (2022) Anti-mosquito properties of Pelargo¬nium roseum (Geraniaceae) and Juniperus virginiana (Cupressaceae) es-sential oils against dominant malaria vec-tors in Africa. Malar J. 2(1): 1-15.
22. Dehghankar M, Maleki-Ravasan N, Tahghighi A, Karimian F, Karami M (2021) Bioactivities of rose-scented ge-ranium nanoemulsions against the larvae of Anopheles stephensi and their gut bac¬teria. Plos one. 16(2): e0246470.
23. CDC (2013) CDC releases final West Nile virus national surveillance data for 2012. Cen¬ters for Disease Control and Preven-tion. Colo¬rado, United States. Available at: https://www.cdc.gov/westnile/resources/pdfs/wnvguidelines.pdf
24. Keziah EA, Nukenine EN, Danga SPY, Younoussa L, Esimone CO (2015) Creams formulated with Ocimum gratis-simum L. and Lantana camara L. crude extracts and frac¬tions as mosquito repel-lents against Aedes aegypti L.(Diptera: Culicidae). J Insect Sci. 15(1): 45.
25. WHO (2004) WHO specifications and eval¬uations for public health pesticides, Icar¬idin. World Health Organization. Geneva, Switzerland. Available at: https://extranet.who.int/pqweb/sites/default/files/vcp-documents/WHOVC-SP_Icaridin_2004.pdf
26. Popović A, Šućur J, Orčić D, Štrbac P (2013) Effects of essential oil formula-tions on the adult insect Tribolium cas-taneum (Herbst) (Col., Tenebrionidae). J Cent Eur Agric. 14(2): 181–193.
27. Tahghighi A, Ghafari S, Ghanavati S,
Kazemi SHM (2022) Repellency of aer-ial parts of Teucrium polium L. essential oil for¬mulation against Anopheles ste-phensi. Int J Trop Insect Sci. 42(5): 3541–3550
28. Sutthanont N, Choochote W, Tuetun B, Junkum A, Jitpakdi A, Chaithong U, Doungrat Riyong D, Pitasawat B (2010) Chemical composition and larvicidal ac-tivity of edible plant-derived essential oils against the pyrethroid-susceptible and-re¬sistant strains of Aedes aegypti (Diptera: Culicidae). J Vector Ecol. 35: 106–115.
29. Vivekanandhan P, Venkatesan R, Ramkumar G, Karthi S, Senthil-Nathan S, Shiva¬kumar MS (2018) Comparative analysis of major mosquito vectors re-sponse to seed-derived essential oil and seed pod-derived ex¬tract from Acacia nilotica. Int J Enviro Res Public Health. 15(2): 388.
30. Ranchitha B, Umavathi S, Thangam Y, Revathi S (2016) Chemical Constituents and larvicidal Efficacy of Melia azeda-rach L. leaf extract against dengue vec-tor Aedes aegypti L (Diptera: Culicidae). Int J Innov Res Sci Eng Technol. 15: 3060–3070.
31. Prabhavathi O, Yuvarajan R, Natarajan D (2016) Mosquitocidal properties of Oci-mum canum Sims (Lamiaceae) leaf ex-tracts against dengue vector Aedes ae-gypti L. (Diptera: Cu¬licidae). J ento¬mol acarol res. 48: 345–354.
32. Liang DW, Zhang T, Fang HH, He J (2008) Phthalates biodegradation in the envi¬ronment. Appl Microbiol Biotech-nol. 80 (2): 183–198.
33. Ramamurthy V, Krishnaveni S (2014) Larvi¬cidal efficacy of leaf extracts of Heli¬otropium Indicum and Mukia maderaspat¬ana against the dengue fever mosquito vector Ae¬des aegypti. J Ento-mol Zool Stud. 2: 40–45.
34. Babu SM, Tharan B, Dhanasekaran S, Thushimenan S, Kovendan K, Alagar-ma¬lai J (2016) Chemical compositions, antifeedant and larvicidal activity of Pongamia pinnata (L.) against polypha-gous field Pest, Spodop¬tera litura. Int J Zool Invest. 2: 48–57.
35. Karthik S, Suriyaprabha R, Vinoth M, Srither S, Manivasakan P, Rajendran V, Vali¬yaveettil S (2017) Larvicidal, super hydro¬phobic and antibacterial properties of herbal nanoparticles from Acalypha indica for bio¬medical applications. RSC Adv. 7(66): 41763–41770.
36. Zhao F, Wang P, Lucardi RD, Su Z, Li S (2020) Natural sources and bioactivities of 2,4-di-tert-butylphenol and its ana-logs. Tox¬ins. 12(1): 35.
37. Chen Y, Dai G (2015) Acaricidal, repel-lent, and oviposition-deterrent activities of 2, 4-di-tert-butylphenol and ethyl ole-ate against the carmine spider mite Tetranychus cin¬nabarinus. J Pest Sci. 88: 645–655.
38. Saleem M (2009) Lupeol, a novel anti-inflammatory and anti-cancer dietary triter¬pene. Cancer lett. 285: 109–115.
39. Duan D, Bu C, Cheng J, Wang Y, Shi G (2011) Isolation and identification of acari¬cidal compounds in Inula japonica (Asterace¬ae). J Econ Entomol. 104: 375–378.
40. Díaz M, Díaz CE, Álvarez RG, González A, Castillo L, González-Coloma A, Seoane G, Rossini C (2015) Differential anti-insect ac¬tivity of natural products isolated from Dodo¬naea viscosa Jacq. (Sapindaceae). J Plant Prot Res. 55: 172–178.
41. de Almeida Alves TM, Nagem TJ, de Carvalho LH, Krettli AU, Zani CL (1997) Antiplasmodial triterpene from Vernonia bra¬siliana. Planta med. 63(6): 554–555.
42. Srinivasan T, Srivastava G, Pathak A, Ba-tra
S, Raj K, Singh K, Puri SK, Kundu B (2002) Solid-phase synthesis and bio-evalua¬tion of lupeol-based libraries as antimalarial agents. Bioorg Med Chem Lett. 12(20): 2803–2806.
43. Ajaiyeoba EO, Ashidi JS, Okpako LC, Hough¬ton PJ, Wright CW (2008) An-tiplas¬modial compounds from Cassia si-amea stem bark extract. Phytother Res. 22(2): 254–255.
44. Spindola KCVW, Simas NK, dos Santos CE, da Silva AG, Romão W, Vanini G, da Silva SRC, Borges GR, de Souza FG (2016) Dendranthema grandiflorum, a hybrid orna¬mental plant, is a source of larvicidal com¬pounds against Aedes ae-gypti larvae. Rev bras farmacogn. 26(3): 342–346.
45. Chandrasekaran R, Seetharaman P, Krish-nan M, Gnanasekar S, Sivaperumal S (2018) Carica papaya (Papaya) latex: a new para¬digm to combat against dengue and filariasis vectors Aedes aegypti and Culex quinquefas¬ciatus (Diptera: Cu-licidae). 3 Biotech. 8(2): 83.