Resistance Status of House Flies (Diptera: Muscidae) from Southeastern Nebraska Beef Cattle Feedlots to Selected Insecticides

Marçon, Paula; Thomas, Gustave D.; Siegfried, Blair D.; Campbell, John B.; Skoda, S.

doi:10.1603/0022-0493-96.3.1016

Cited by 23 publications

(9 citation statements)

References 13 publications

(2 reference statements)

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“…Management of M. domestica in the urban environment has usually been directed to target the adult stage by using insecticides as a major control measure. However, the usefulness of insecticidal control is becoming more costly mainly due to the development of insecticide resistance . Among insecticides, permethrin (a pyrethroid) has been one of the best insecticides for the management of dipteran flies; however, over‐reliance has led to the development of resistance against permethrin.…”

Section: Introductionmentioning

confidence: 99%

Characterization of permethrin resistance in a Musca domestica strain: resistance development, cross‐resistance potential and realized heritability

Khan

2019

Pest Management Science

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BACKGROUND: Permethrin (a pyrethroid) has been recommended for the management of a number of insect pests, including Musca domestica. Recently, resistance to permethrin has been reported from the Punjab province, Pakistan, which necessitates the need to manage the resistance problem. For this reason, a field strain of M. domestica was selected with permethrin for ten consecutive generations (G1-G10) to determine the risk assessment, the rapidity with which permethrin resistance can develop, and the presence or absence of the cross-resistance phenomenon. RESULTS:The results revealed that permethrin resistance increased very quickly in response to selection experiments. The resistance ratio (RR) value increased by 16.04-to 605.92-fold and the LD 50 value increased by 100.22 to 3787.08 ng fly −1 after selection experiments. Moreover, the increase in LD 50 value remained stable when the selected strain (Perm-SEL) was cultured in the absence of permethrin for the next five generations (G11-G15). The results revealed the possibility of minor cross-resistance in the Perm-SEL strain with -cyfluthrin and deltamethrin, and lack of cross-resistance with imidacloprid and spinosad. The realized heritability (h 2 ) value for the Perm-SEL strain was 0.23. Assuming a mean slope value of 1.27 and an h 2 value of 0.23, then ten to four generations would be estimated for a 10-fold increase in the LD 50 values at 50-90% selection intensity, respectively. CONCLUSION:The results of present study revealed high risk for permethrin resistance development under continuous selection pressure. Permethrin resistance developed very quickly under laboratory conditions, which might reflect the likelihood of resistance evolution in field conditions if permethrin selection pressure holds for a long time.

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Section: Introductionmentioning

confidence: 99%

Characterization of permethrin resistance in a Musca domestica strain: resistance development, cross‐resistance potential and realized heritability

Khan

2019

Pest Management Science

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“…They can annoy animals and people, cause complaints from neighbours, and lead to production losses and animal welfare problems (Campbell & Berry, 1989; Catangui et al , 1997; Cook et al , 1999; Campbell et al , 2001). Flies can transmit pathogens (Greenberg, 1971; De Jesus et al , 2004; Graczyk et al , 2005) and the management of large populations may require the application of insecticides, with potential for environmental pollution, health and safety‐related issues and the development of insecticide resistance in target populations (Cilek & Greene, 1994; Kocisova et al , 2002; Marçon et al , 2003; Mullens et al , 2010; Pitzer et al , 2010).…”

Section: Introductionmentioning

confidence: 99%

Nuisance flies on Australian cattle feedlots: immature populations

Hogsette

Urech²,

Green³

et al. 2011

Medical Vet Entomology

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Species composition, seasonality and distribution of immature fly populations on a southern Queensland feedlot during 2001-2003 were determined. Similar data were collected on feedlots in central New South Wales and central Queensland. The fly species recovered in the highest numbers were Musca domestica L. (Diptera: Muscidae), Stomoxys calcitrans L. (Diptera: Muscidae) and Physiphora clausa Macquart (Diptera: Ulidiidae). Houseflies were the dominant species at all feedlots. Houseflies preferred the warmer months from October to June, but stable flies preferred the cooler months and peaked in spring (September-November) and autumn (March-May). Larval abundance ratings recorded in the feedlot and numbers of larvae extracted in the laboratory from corresponding samples followed similar trends. Larvae of M. domestica were most abundant in the hospital and induction area and least abundant in horse stables and yards. Pupae of M. domestica were abundant in the hospital and induction area and drains, but least abundant in horse stables and yards. Larvae of S. calcitrans were most abundant in drains and least abundant in horse stables and yards. Pupae of S. calcitrans were most numerous in drains and least numerous in old cattle pens. Feedlot design and management had little effect on fly reduction.

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“…With hygiene at minimum provision, immediate fly control was imposed by spraying 76% dichlorvos, and LD90 of adult housefly was 3.5-3.9 times higher than the flies from control sites. As in the United States, in a study tested against nine insecticides, the fly strains showed high resistances in tetrachlorvinphos, permethrin and cyfluthrin [31], while in southeastern Nebraska, houseflies are shown to be moderately resistant to permethrin yet extremely resistant to stirofos and methoxychlor [32]. Deltamethrin-resistant flies were discovered in urban garbage dump of cities of Beijing, Tianjin and Zhangjiakou [33].…”

Section: Domestica Response Towards Insecticidementioning

confidence: 99%

Defence against Oxidative Stress and Insecticides inMusca domestica

Hao¹,

Hamzah²,

Alias³

2020

Trends in Integrated Insect Pest Management

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This review is looking at the way Musca domestica defends itself against harmful molecules. One of the most notable enemies is against oxidative stress. Over the years there were reports that indicated the development of resistance on range of pesticides that are used against the flies. Researches have demonstrated that there are several functional protein molecules which contribute directly or indirectly as a response to oxidative stress and resistance against insecticides. As currently, the whole genome sequencing of the organisms has enabled future study to be conducted in evaluating the behaviour of the targeted protein/enzyme in response to oxidative stress and intake of insecticides in the flies.

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Resistance Status of House Flies (Diptera: Muscidae) from Southeastern Nebraska Beef Cattle Feedlots to Selected Insecticides

Cited by 23 publications

References 13 publications

Characterization of permethrin resistance in a Musca domestica strain: resistance development, cross‐resistance potential and realized heritability

Characterization of permethrin resistance in a Musca domestica strain: resistance development, cross‐resistance potential and realized heritability

Nuisance flies on Australian cattle feedlots: immature populations

Defence against Oxidative Stress and Insecticides inMusca domestica

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