SERANGGA

Musca domestica Linnaeus is well-known as a pest that mechanically spreads diseases that are both medical and veterinary importance. Resistance has developed in the field as a result of the prolonged and improper application of insecticides to control the number of houseflies. The purpose of this study was to investigate the resistance status of poultry strain M. domestica larvae towards pyrethroid insecticides namely permethrin and deltamethrin, as well as organophosphate insecticides namely malathion and temephos. The third instar of susceptible poultry strains of M. domestica larvae was subjected to topical insecticide bioassay with concentrations ranging from 0.0005mg/L to 2000.0mg/L. The resistance ratio was calculated to categorize the level of resistance by dividing the LC₅₀ value of the poultry strain by the susceptible strain. The susceptibility status of the poultry strains, Sungai Lembu (SL) and Tapah Road (TR) towards pyrethroid and organophosphate revealed moderate to high resistance in comparison to the susceptible IMR strain (13.78-fold to 48.82-fold). Both strains were found to be resistant and possess multiple resistance and cross-resistance towards the tested insecticide. Understanding the resistance status of targeted pests is critical for effective, economically feasible, and environmentally sustainable pest management strategies in agriculture and beyond. It contributes to food security, environmental protection, and long-term pest control efficacy. Additionally, it is advisable to implement integrated pest management strategies and utilize synergists to enhance the effectiveness of both chemical-based insecticides and biopesticides.

Abbas, N. & Shad, S.A. 2015. Assessment of resistance risk to lambda-cyhalothrin and cross-resistance to four other insecticides in the house fly, Musca domestica L. (Diptera: Muscidae). Parasitology Research 114(7): 2629–2637.

Abbott, W. 1925. A method of computing the effectiveness of an insecticide. Journal of Economic Entomology 18: 265-267.

Abobakr, Y., Al-Hussein, F.I., Bayoumi, A.E., Alzabib, A.A. & Al-Sarar, A.S. 2022. Organophosphate insecticides resistance in field populations of house flies, Musca domestica L.: Levels of resistance and acetylcholinesterase activity. Insects 13(2): 192.

Axtell, R.C. 1986. Status and potential of biological control agents in livestock and poultry pest management systems. In. Patterson, R.S & Rutz, D.A. (eds.). Biological Control Of Muscoid Flies (Miscellaneous publications 61), pp. 1-9. College Park, MD: Entomological Society of America.

Bloomquist, J.R. & Miller, T.A. 1985. Carbofuran triggers flight motor output in pyrethroid-blocked reflex pathways of the house-fly. Pesticide Biochemistry Physiology 23: 247–255.

Bong, L.J. & Zairi, J. 2010. Temporal fluctuations of insecticides resistance in Musca domestica Linn (Diptera: Muscidae) in Malaysia. Tropical Biomedicine 27(2): 317–325.

Burgess, E.R., King, B. & Geden, C. 2020. Oral and topical insecticide response bioassays and associated statistical analyses used commonly in veterinary and medical entomology. Journal of Insect Science 20(6): 34-42.

Cao, M.X., Song, F.L., Zhao, T.Y., Dong, Y.D. & Sun, B.L. 2006. Survey of deltamethrin resistance in houseflies (Musca domestica) from urban garbage dumps in Northern China. Environmental Entomology 35: 1-9.

Cheah, W.K., Ng, K.S., Marzilawati, A.R. & Lum, L.C. 2014. A review of dengue research in Malaysia. The Medical Journal of Malaysia 69: 59-67.

Chong, N.L., Jahangir, K. & Jaal, Z. 2003. Chapter 8: Houseflies. In. Lee, C.Y., Zairi, J., Yap, H. H. & Chong, N.L. (eds.). Urban Pest Control a Malaysia Perspective. 2nd Edition, pp. 87-96. Penang: Mosquitoes Vector Control Research Unit, School of Biological Sciences, Universiti Sains Malysia, Malaysia.

Christopher J.G. 2012. Status of biopesticides for control of houseflies. Management of Houseflies. Journal Biopest 5: 1-11.

Department of Veterinary Services (DVS). 2022. Livestock Statistics 2021 to 2022. Malaysia: Department of Veterinary Malaysia. Ministry of Agriculture and Agro-Based Industry Malaysia. https://www.dvs.gov.my/dvs/resources/user_1/2022/BPSPV/Perangkaan%202021.2022/ Buku_Perangkaan_Ternakan_2021_2022_Keseluruhan.pdf [1 March 2024].

Department of Veterinary Services (DVS) 2019. Guideline of Waste Management in Poultry Farming. Malaysia: Department of Veterinary Malaysia. Ministry of Agriculture and Agro-Based Industry Malaysia.

https://www.dvs.gov.my/dvs/resources/user_1/2022/BPV/GP-Pengurusan-Sisa-Ayam.pdf [1 March 2024].

Essiedu, J.A., Adepoju, F. & Ivantsova, M. 2020. Benefits and limitations in using biopesticides. AIP Conference Proceedings 2313: 080002.

Eto, M. & Zweig, G. 2018. Organophosphorus Pesticides. 1st Edition. Boca Raton, USA: CRC Press.

Farooq, M. & Freed, S. 2016. Combined effects of Beauveria bassiana (Hypocreales: Clavicipitaceae) and insecticide mixtures on biological parameters of Musca domestica (Diptera: Muscidae). Pakistan Journal of Zoology 48: 1465-1476.

Helena, C.G., Larry, N.R., Curt, L. & Milan, K. 2015. The use of fly larvae for organic waste treatment. Waste Management 35: 68-80.

Kaufman, P.E., Scott, J.G. & Rutz, D.A. 2001. Monitoring insecticide resistance in house flies (Diptera: Muscidae) from New York dairies. Pest Management Science 57: 514- 521.

Khambay, B. & Jewes, P.J. 2004. Pyrethroid. In. Iatrou, K., Gill, S.S. & Gilbert, L.I. (eds.). Comprehensive Molecular Insect Science, pp. 1–29. Oxford: Pergamon Press Oxford.

Khamesipour, F., Lankarani, K.B., Honarvar, B. & Kwenti, T.E. 2018. A systematic review of human pathogens carried by the housefly (Musca domestica L.). BMC public health 18(1): 1049.

Khan, H.A.A. 2019, Characterization of permethrin resistance in a Musca domestica strain: Resistance development, cross-resistance potential and realized heritability. Pest Management Science 75: 2969-2974.

Ma, Z., Li, J., Zhang, Y., Shan, C. & Gao, X. 2017. Inheritance mode and mechanisms of resistance to imidacloprid in the house fly Musca domestica (Diptera: Muscidae) from China. PLoS One 11(12): 2-15.

Mahyar, K., Alireza, J.Z., Esmaeil, M. & Masih, R. 2023. Plant essential oils and their effectiveness against Musca domestica Linnaeus 1758 and its parasitoids. Serangga 28(1): 79-90.

Ong, S.Q., Ahmad, H., Jaal, Z. & Che, R.A. 2015. Comparative effectiveness of insecticides for use against the housefly (Diptera: Muscidae): Determination of resistance levels on a Malaysian poultry farm. Journal of Economics Entomology 109(1): 352–359.

Pathak, V.M., Verma, V.K., Rawat, B.S., Kaur, B., Babu, N., Sharma, A., Dewali, S., Yadav, M., Kumari, R., Singh, S., Mohapatra, A., Pandey, V., Rana, N. & Cunill, J.M. 2022. Current status of pesticide effects on environment, human health and it's eco-friendly management as bioremediation: A comprehensive review. Frontiers in Microbiology 13: 962619.

Rahim, J., Ahmad, A.H. & Maimusa, A.H. 2017. Effects of temephos resistance on life history traits of Aedes albopictus (Skuse) (Diptera: Culicidae), a vector of arboviruses. Revista Brasileira de Entomologia 61(4): 312-317.

Sawicki, R.M. 1987. Definition, Detection and Documentation of Insecticide Resistance. Combating Resistance to Xenobiotics. Chichester: Ellis Horwood.

Siriwattanarungsee, S., Sukontason, K., Olson, J. & Chailapakul, O. 2008. Efficacy of neem extract against the blowfly and housefly. Parasitology research 103: 535-44.

Tano, Z.J. 2011. Identity physical and chemical properties of pesticides, In. Stoytcheva, M. (ed.). Pesticides in the Modern World: Trends in Pesticides Analysis, pp. 1-18. Croatia: InTech.

Toto, N.A., Elhenawy, H.I., Eltaweil, A.S., El-Ashram, S., El-Samad, L.M., Moussian, B. & El Wakil, A. 2022. Musca domestica (Diptera: Muscidae) as a biological model for the assessment of magnetite nanoparticles toxicity. The Science of the total environment 806(4): 151483.

Trang, A. & Khandhar, P.B. 2023. Physiology, Acetylcholinesterase. St. Petersburg: StatPearls Publishing.

Wan, N.O, Nazni, W.A., Lee, H.L., Chen, C.D., Wan, N.W.M., Azahari, A.H. & Mohd, S.A. 2008. Detection of permethrin resistance in Aedes albopictus Skuse. Collected from Titiwangsa Zone, Kuala Lumpur, Malaysia. Proceeding of the 3rd ASEAN Congress of Tropical Medicine and Parasitology 3: 69-77.

Wang, J.N., Hou, J., Wu, Y.Y., Guo, S., Liu, Q. M., Li, T.Q. & Gong, Z.Y. 2019. Resistance of Housefly, Musca domestica L. (Diptera: Muscidae), to Five Insecticides in Zhejiang Province, China: The Situation in 2017. The Canadian Journal of Infectious Diseases and Medical Microbiology 2019(5): 1-10.

Wasi, A., Nazni, Hanlim, L., Sadiyah, I. & Azirun, M. 2003. Monthly prevalence of housefly, Musca domestica in lowlands and highlands and its association with chemical resistance. Tropical Biomedice 20: 65-76.

World Health Organization (WHO). 1986. Vector Control Series: The House fly Training and information Guide (Advance level). Lyngby, Denmark: World Health Organization Danish Pest Infection Laboratory.

World Health Organization (WHO). 1980. Status of Resistance in House Flies, Musca domestica. Document VBC/EC/80.7. Geneva, Switzerland: World Health Organization

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

https://apps.who.int/iris/bitstream/handle/10665/69101/WHO_CDS_WHOPES_ GCDPP_2005.13.pdf [1 March 2024].

Yap, H.H., Jahangir, K. & Zairi, J. 2000. Field efficacy of four insect repellent products against vector mosquitoes in a tropical environment. Journal of the American Mosquito Control Association 16(3): 241-244.