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ENVIRONMENTAL FACTORS AND THEIR EFFECTS ON HOUSE FLY (MUSCA DOMESTICA L.) ECOLOGY AND SUPPRESSIONLoy, Vance Albert, 1930- January 1972 (has links)
No description available.
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Housefly control with dry baits formulated from organic phosphorus insecticides and sugarBerndt, Wayne Leslie. January 1955 (has links)
Call number: LD2668 .T4 1955 B49 / Master of Science
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Biology of a population of houseflies, Musca domestica L., on a geographically isolated ranch following two as compared to three years of dieldrin sprayingsGray, Thomas Merrill. January 1957 (has links)
Call number: LD2668 .T4 1957 G73 / Master of Science
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Experimental induction of resistance to an acylurea insect growth regulatorCodrea, Mary Elizabeth 01 January 1982 (has links)
A laboratory colony of a multi-insecticide susceptible strain of the housefly, Musca domestica was challenged with continuous larval selection pressure equivalent to the initial LC 60 level for 8 generations with the insect growth regulator WL 86303 (1-(3,5-dichloro-4)4-nitrophenoxy- phenyl)-3 -(2)chlorobenzoyl)- urea). A more than twofold increase in resistance was observed at the F8 generation. No cross-tolerance to the related compound, diflubenzuron (DIMILIN (R)) (1-(4-chlorophenyl)-3- (2,6-difluorobenzoyl)-urea) was observed after 8 generations. WL 86303 was significantly less toxic to houseflies than diflubenzuron. No significant difference was noted between the toxicity of WL 86303 to an unpressured wild housefly strain, and to the unselected multi-susceptible strain. A larval-rearing bioassay technique for measuring the toxicity levels of juvenile developmental disruptors is described.
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Effect of electrostatic fields on insects: the housefly and cabbage looperRidout, Robert Angell January 1974 (has links)
Effects of electrostatic fields on insects were studied using cabbage loopers, Trichoplusia ni (Hubner) and houseflies, Musca domestica L. Two series of tests were conducted; one to determine the electrostatic field effect on the locational preference and the other to determine the field effect on wingbeat.
Among the field gradients examined (250, 500, 750, 1000, 1250, 1500 v/crn), those with 750 v/cm and up had significant influence on the locational preference of houseflies at the five percent significance level. With a choice between two regions, having no field and with field at an e.f.i. of 750 v/cm, houseflies preferred to be in the field. For gradients above 750 v/cm the houseflies preferred the region with no field.
Electrostatic fields with gradients 500, 750, 1000, 1250, and 1500 v/cm had significant effect on the wingbeat frequency of male cabbage loopers and no effect on females. The change in wingbeat among males was found to increase linearly with increasing e.f.i. Removal of part or full antenna did not effect the response of loopers to electrostatic fields. / Master of Science
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Biological control of the common house fly Musca domestica L. in horse stables, using Bacillus thuringiensis serovar israelensis and Beauveria bassiana.Martins, Cheralyn. 30 October 2014 (has links)
House flies (Musca domestica L.) are common pests affecting horses and their owners. Control of house flies in stable yards is currently based on the use of pesticides. However, the development of resistance by these flies to most pesticide groups has motivated horse owners to seek alternative methods of fly control. An entomopathogenic fungus, Beauveria bassiana (Bb) and an entomopathogenic bacterium, Bacillus thuringiensis var. israelensis (Bti) are two biological agents known to have activity against house flies. The broad objective of this study was to evaluate the effect of these two biological control agents on house flies in an equine environment.
Using a structured questionnaire, presented in Chapter 2, thirty horse owners in KwaZulu-Natal were asked about the nuisance value of house flies, their current control measures, the potential market for biocontrol agents against house flies, and each owner’s perception of biocontrol methods. The horse owners were using three methods of house fly control namely, physical, chemical and biological. Most horse owners (97%) wanted access to effective biocontrol agents for control of house flies. Most horse owners (80%) stabled their horses at night, some or all of the time. The resultant manure piles in the stable yard were considered to be the primary cause of house fly problems. About 64% of the horse owners were dissatisfied with the currently available methods of controlling house flies in this situation. Chapter 3 covers two observational trials in which varying doses of Bacillus thuringiensis var. israelensis (Bti) were fed to horses, in order to identify a baseline dosage to give to horses in order to adequately control house fly populations growing in horse manure. The bacterium Bti, grown on wheat bran, was fed to six miniature horses at doses of 0, 0.125, 0.25, 0.5, 0.75, and 1.0 g per meal in Trial 3a, and at 0, 0.5, 1, 2, 4 and 8 g per meal in Trial 3b. Faeces were collected three times a week for 11 weeks and placed in incubation trays to allow the number of emerging adult house flies and closed pupae to be counted. In Trial 3a, there was a significant reduction in the number of closed pupae with an increase in Bti in the feed. The regression equation suggests that there will be 3.1 times as many closed pupae in the faeces when horses are fed 1 g of Bti in their feed, than when horses are fed no Bti. This dosage is the minimum baseline dosage for future trials.
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Using manure from horses dosed in Trials 3a and 3b, the survival of the bacterium through the gut of horses was evaluated using a standard isolation technique. The growth of Bt colonies on the manure after the Bt isolation technique showed that some of the bacterial cells survived transition through the digestive tract of the horse. This study was qualitative in nature and did not attempt to quantify the level of Bti spore survival. These two observations suggest that Bacillus thuringiensis var. israelensis has the potential to be used as a biocontrol agent, applied via horse feed, for the control of house flies in stable yards. Future clinical trials, with appropriate replication, should be conducted using 1 g Bti/meal as the lowest test dosage.
The objective of Chapter 4 was to determine whether spraying Bti or Bb on to horse manure is effective in the control of house flies. Over a six week period, two spraying trials were conducted in which increasing doses of Bb and Bti were sprayed on to 500 g samples of horse manure. Counts of house fly pupae and adults were taken. The doses of Bb and Bti tested were 0, 1, 2, 4 g in Trial 4a, and 0, 4, 8 and 12 g in Trial 4b. The research reported in Chapter 4 was characterized by the unexpectedly high levels of biological variation in egg, larvae and pupae numbers that were found in samples of horse manure, taken from the same skip two days apart. The statistical design of the two trials conducted was inadequate to cope with the high level of variation about treatment means for fly and larval counts. However, despite the lack of significant differences between treatment means, there is observational evidence that suggests that both Bb and Bti do have an effect on house fly survival. A simplified statistical model, which compared the number of hatched house flies on untreated manure, with the number on manure treated with any level of Bb (1 to 4 g /250 ml water), found a significant reduction in the number of hatched flies on treated manure. There was no significant corresponding reduction in the number of closed pupae, which suggests that Bb acts primarily before the larva pupates. The optimal dose of Bb and Bti to be sprayed on to manure could not be determined because of the high variation about treatment means. It is suggested that, in future trials similar dosages for Bb could be tested, but that higher dosages of Bti (starting at 2 g/250 ml water) should be used. Trial periods should be extended and replication increased dramatically to reduce variation about treatment means. Transformation of data before analysis may also be necessary to equalize variation about treatment means. / M.Sc.Agric. University of KwaZulu-Natal, Pietermaritzburg 2013.
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Biological control of the common house fly (Musa domestica L.) using Bacillus thuringiensis (Ishiwata) berliner var. Israelensis and Beauveria bassiana (Bals.) vullemin in caged poultry facilities.Mwamburi, Lizzy A. January 2008 (has links)
The entomopathogenic fungus Beauveria bassiana and the bacterium Bacillus thuringiensis var. israelensis (Bti) have been widely studied for their role in biocontrol against many arthropods and extensively exploited for insect pest control. The purpose of this study was to evaluate the effect of four B. bassiana and two Bti formulations and their respective combinations, for the biological control of the common house fly, Musca domestica L., a major pest in poultry facilities. In vitro screening was undertaken to select the best B. bassiana isolates from 34 B. bassiana isolates and two Paecilomyces isolates. All the isolates of B. bassiana were found to be effective against adult house flies, but were marginally effective in controlling fly larvae. The Paecilomyces isolates were non-pathogenic towards both adult house flies and larvae. The best four isolates R444, 7320, 7569 and 7771 caused >90% mortality within 2d and were subjected to dose-mortality bioassays. Microscopic studies using light and scanning electron microscopy indicated the different durations of the lifecycle of B. bassiana development on the house fly. High temperature was found to delay conidial germination. Spore germination and mycelial growth were also inhibited by high adjuvant concentrations. Laboratory baseline bioassay data established, a dose-time response relationship using a waterdispersible granules (WDG) Bti formulation that demonstrated that the susceptibility of M. domestica larvae to a given concentration of Bti increased as the duration of exposure increased. In the laboratory studies, the LC50 and LC90 values of Bti for the larvae ranged between 65 - 77.4 and 185.1 - 225.9?g ml-1, respectively. LT50 and LT90 values were 5.5 and 10.3d respectively. In the field, a concentration of 10g Bti kg-1 (bran formulation) of feed resulted in 90% reduction of larvae for 4wk post-treatment. A higher concentration (2g L-1) of Bti in spray (WDG) applications was not significantly more effective than the lower concentration of 1g L-1. Thus, adding Bti to chicken feed has potential for the management and control of house flies in cagedpoultry facilities. The impact of oral feed applications of a bran formulation of Bti and a commercial chemical larvicide, Larvadex®, were compared with respect to their efficacy on the control of house fly 3 larval populations in poultry manure. The sublethal effects were manifested in terms of decreasing emergence of adult house flies. Although Larvadex® reduced larval density and caused significant reductions in emergence of adult house flies, it generally exhibited weaker lethal effects than Bti. The reduction levels achieved as a result of feeding 250mg Bti kg-1 at 5wk were similar to those achieved as a result of feeding twice the amount of Larvadex® at 4wk to the layers. From both an efficiency and economic perspective, comparisons to assess the impact of combining different concentrations of the two Bti formulations were carried out to evaluate their success in controlling house fly larvae and adults in poultry houses. The percentage mortality of larvae accomplished as a result of using a combination of 250mg kg-1 Bti in feed and 2g L-1 spray applications was equivalent to that obtained as a result of combining 500mg kg-1 Bti in feed and 1g L-1 spray application. The cost-benefit analysis (expressed in terms of mortality of larvae) indicated that the most effective combination for control of house fly larvae and fly emergence was the 500mg kg-1 in feed and 2g L-1 spray application combination that resulted in 67% larval mortality and 74% inhibition of adult house fly emergence. This study presents commercial users with possible combinations of applications of the two Bti formulations. Comparisons of larval mortalities and house fly emergence resulting from the Bti - B. bassiana treatments with those from Larvadex® - B. bassiana treatments, showed better control levels compared to any of the individual agents alone. The Bti treatments were more effective at controlling larval populations and inhibiting the emergence of house flies than Larvadex®, even when Larvadex® was applied together with B. bassiana. The effects of the Bti - B. bassiana and the Larvadex® - B. bassiana interactions were additive. These trials suggest that the efficacy of Bti in the control of house fly larvae may be improved with frequent applications of B. bassiana. / Thesis (Ph.D.)-University of KwaZulu-Natal, Pietermaritzburg, 2008.
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