【 摘 要 】

Background

Tick and tsetse-borne diseases (TTBDs) constrain livestock production in tropical and subtropical regions of the world. Of this community of endemic diseases, East coast fever (T.parva) is the most important tick-borne disease (TBD) accounting for 70% of all losses due to TBDS in this region where control efforts target either tsetse or TBDs and seldom both. In those instances where simultaneous pyrethroid insecticide TTBD control is implemented, collateral benefits of tsetse control on TBD control have not been quantified. In the interest of guiding future TTBD control efforts, the effect of restricting pyrethroid insecticides to the legs, belly and ears (RAP) of cattle for tsetse and trypanosomiasis control on T.parva prevalence in crop-livestock production systems in Tororo district, south-eastern Uganda was determined.

Methods

We randomly allocated 16 villages to diminazene diaceturate (DA) and 3 graded RAP (25%, 50% and 75% of village herd sprayed respectively) treatment regimens. All cattle were ear-tagged, treated with diminazene diaceturate (DA) and those in regimens 2-4 received monthly graded RAP. Blood samples taken fourteen days post DA treatment and once three monthly were analysed by molecular techniques for T.parva.

Results

In total, 8,975 samples from 3,084 animals were analysed. Prevalence of T.parva varied between 1-3% in different treatment regimens. RAP regimens were associated with slightly lower average risk of infection compared to DA. However, the confidence interval was broad and the result was not statistically significant. There was no evidence of a dose response relationship between graded RAP and T.parva prevalence. These findings are discussed herein with regard to endemic stability development to different TBDs.

Conclusions

We found only a slight effect of RAP on T.parva infection. Since sample size determination was based on trypanosomes incidence, the study was underpowered given the low T.parva prevalence. While the findings need to be confirmed in future studies, the observed slight reduction in the risk of infection with T.parva might not compromise endemic stability.

【 授权许可】

   
2014 Muhanguzi et al.; licensee BioMed Central Ltd.

【 预 览 】

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【 图 表 】

【 参考文献 】

• [1]Jongejan F, Uilenberg G: The global importance of ticks. Parasitology 2004, 129(Suppl):S3-14.
• [2]Swallow BM: Impacts of trypanosomiasis on African agriculture. Rome: FAO; 1999.
• [3]Uilenberg G: International collaborative research: significance of tick-borne hemoparasitic diseases to world animal health. Vet Parasitol 1995, 57(1–3):19-41.
• [4]Kivaria FM: Estimated direct economic costs associated with tick-borne diseases on cattle in Tanzania. Trop Anim Health Prod 2006, 38(4):291-299.
• [5]Tosas AO: Theileria Parva: Inter- and Intra-Species Interactions in the Community of Endemic Pathogens of African Cattle. Edinburgh: The University of Edinburgh; 2006.
• [6]Perry BD, Young AS: The past and future roles of epidemiology and economics in the control of tick-borne diseases of livestock in Africa: the case of theileriosis. Prev Vet Med 1995, 25(2):107-120.
• [7]Purnell R: East Coast fever: some recent research in East Africa. Adv Parasitol 1977, 15:83-132.
• [8]Deem SL, Perry BD, Katende JM, McDermott JJ, Mahan SM, Maloo SH, Morzaria SP, Musoke AJ, Rowlands GJ: Variations in prevalence rates of tick-borne diseases in Zebu cattle by agroecological zone: implications for East Coast fever immunization. Prev Vet Med 1993, 16(3):171-187.
• [9]Fevre EM, Wissmann BV, Welburn SC, Lutumba P: The burden of human African trypanosomiasis. PLoS Negl Trop Dis 2008, 2(12):e333.
• [10]Minjauw B, McLeod A: Tick-borne diseases and poverty. The impact of ticks and tick- borne diseases on the livelihood of small-scale and marginal livestock owners in India and eastern and southern Africa. Research report, DFID Animal Health Programme. UK: Centre for Tropical Veterinary Medicine, University of Edinburgh; 2003.
• [11]Perry B, Sones K: Poverty reduction through animal health. Science 2007, 315(5810):333-334.
• [12]Kabayo JP: Aiming to eliminate tsetse from Africa. Trends Parasitol 2002, 18(11):473-475.
• [13]Torr S, Eisler M, Coleman P, Morton J, Machila N: Integrated control of ticks and tsetse. A report for the DFID Advisory and Support Services Contracts 2002.
• [14]de Haan C, Umali DL: Public and private sector roles in the supply of veterinary services. In Public and Private Roles in Agricultural Development, Proceedings of 12th Agricultural Sector symposium. Washington DC: The World Bank; 1992:125-137.
• [15]Holden S: The economics of the delivery of veterinary services. Rev Sci Tech 1999, 18(2):425-439.
• [16]Eisler MC, Torr SJ, Coleman PG, Machila N, Morton JF: Integrated control of vector-borne diseases of livestock – pyrethroids: panacea or poison? Trends Parasitol 2003, 19(8):341-345.
• [17]Torr SJ, Maudlin I, Vale GA: Less is more: restricted application of insecticide to cattle to improve the cost and efficacy of tsetse control. Med Vet Entomol 2007, 21(1):53-64.
• [18]Bardosh K, Waiswa C, Welburn SC: Conflict of interest: use of pyrethroids and amidines against tsetse and ticks in zoonotic sleeping sickness endemic areas of Uganda. Parasit Vectors 2013, 6:204. BioMed Central Full Text
• [19]Okello A, Welburn S, Kabasa JD, Waiswa C, Rannaleet A, Mitchell M, Semakula L: Stamp Out Sleeping Sickness (SOS): An Innovative One Health Approach to Neglected Zoonotic Disease in Uganda. In Ecohealth. NEW YORK, NY 10013 USA: 233 SPRING ST; 2011:S72-S72.
• [20]Kabasa JD: Public-private partnership works to stamp out sleeping sickness in Uganda. Trends Parasitol 2007, 23(5):191-192.
• [21]Bauer B, Kabore I, Liebisch A, Meyer F, Petrich-Bauer J: Simultaneous control of ticks and tsetse flies in Satiri, Burkina Faso, by the use of flumethrin pour on for cattle. Trop Med Parasitol 1992, 43(1):41-46.
• [22]Selby R, Bardosh K, Picozzi K, Waiswa C, Welburn SC: Cattle movements and trypanosomes: restocking efforts and the spread of Trypanosoma brucei rhodesiense sleeping sickness in post-conflict Uganda. Parasit Vectors 2013, 6(1):281. BioMed Central Full Text
• [23]Norval RAI, Perry BD, Young AS: The epidemiology of theileriosis in Africa. London: Academic Press; 1992.
• [24]Coleman PG, Perry BD, Woolhouse ME: Endemic stability–a veterinary idea applied to human public health. Lancet 2001, 357(9264):1284-1286.
• [25]Magona JW, Greiner M, Mehlitz D: Impact of tsetse control on the age-specific prevalence of trypanosomosis in village cattle in southeast Uganda. Trop Anim Health Prod 2000, 32(2):87-98.
• [26]Okiria R, Okuna NM, Magona JW, Mayende JS: Sustainability of tsetse control by subsequent treatment of 10% of a previously treated Ugandan cattle population with 1% w/v deltamethrin. Trop Anim Health Prod 2002, 34(2):105-114.
• [27]Okello-Onen J, Tukahirwa EM, Perry BD, Rowlands GJ, Nagda SN, Musisi G, Bode E, Heinonen R, Mwayi W, Opuda-Asibo J: The impact of tick control on the productivity of indigenous cattle under ranch conditions in Uganda. Trop Anim Health Prod 2003, 35(3):237-247.
• [28]Muhanguzi D, Picozzi K, Hatendorf J, Thrusfield M, Welburn SC, Kabasa JD, Waiswa C: Prevalence and spatial distribution of Theileria parva in cattle under crop-livestock farming systems in Tororo District, Eastern Uganda. Parasit Vectors 2014, 7:91. BioMed Central Full Text
• [29]Picozzi K, Tilley A, Fèvre E, Coleman P, Magona J, Odiit M, Eisler M, Welburn S: The diagnosis of trypanosome infections: applications of novel technology for reducing disease risk. Afr J Biotechnol 2002, 1(2):39-45.
• [30]Ahmed HA, MacLeod ET, Hide G, Welburn SC, Picozzi K: The best practice for preparation of samples from FTA(R)cards for diagnosis of blood borne infections using African trypanosomes as a model system. Parasit Vectors 2011, 4:68. BioMed Central Full Text
• [31]Becker S, Franco JR, Simarro PP, Stich A, Abel PM, Steverding D: Real-time PCR for detection of Trypanosoma brucei in human blood samples. Diagn Microbiol Infect Dis 2004, 50(3):193-199.
• [32]Skilton RA, Bishop RP, Katende JM, Mwaura S, Morzaria SP: The persistence of Theileria parva infection in cattle immunized using two stocks which differ in their ability to induce a carrier state: analysis using a novel blood spot PCR assay. Parasitology 2002, 124(Pt 3):265-276.
• [33]Konnai S, Imamura S, Nakajima C, Witola WH, Yamada S, Simuunza M, Nambota A, Yasuda J, Ohashi K, Onuma M: Acquisition and transmission of Theileria parva by vector tick, Rhipicephalus appendiculatus. Acta Trop 2006, 99(1):34-41.
• [34]Ocaido M, Otim C, Okuna N, Erume J, Ssekitto C, Wafula R, Kakaire D, Walubengo J, Monrad J: Socio-economic and livestock disease survey of agro-pastoral communities in Serere County, Soroti District, Uganda. Livest Res Rural Dev 2005, 7:Art. #93.
• [35]Murray M, Gray A: The current situation on animal trypanosomiasis in Africa. Prev Vet Med 1984, 2(1):23-30.
• [36]Hursey B, Slingenbergh J: The tsetse fly and its effects on agriculture in sub-Saharan Africa. World Anim Rev 1995, 2:67-73.
• [37]Machila N, Emongor R, Shaw AP, Welburn SC, McDermott J, Maudlin I, Eisler MC: A community education intervention to improve bovine trypanosomiasis knowledge and appropriate use of trypanocidal drugs on smallholder farms in Kenya. Agr Syst 2007, 94(2):261-272.
• [38]Magona JW, Walubengo J, Olaho-Mukani W, Jonsson NN, Welburn SW, Eisler MC: Spatial variation of tick abundance and seroconversion rates of indigenous cattle to Anaplasma marginale, Babesia bigemina and Theileria parva infections in Uganda. Exp Appl Acarol 2011, 55(2):203-213.
• [39]Staroverov SA, Sidorkin VA, Fomin AS, Shchyogolev SY, Dykman LA: Biodynamic parameters of micellar diminazene in sheep erythrocytes and blood plasma. J Vet Sci 2011, 12(4):303-307.
• [40]Magona JW, Walubengo J, Olaho-Mukani W, Jonsson NN, Welburn SC, Eisler MC: Clinical features associated with seroconversion to Anaplasma marginale, Babesia bigemina and Theileria parva infections in African cattle under natural tick challenge. Vet Parasitol 2008, 155(3–4):273-280.
• [41]Bohning D, Greiner M: Prevalence estimation under heterogeneity in the example of bovine trypanosomosis in Uganda. Prev Vet Med 1998, 36(1):11-23.
• [42]Bourn D, Grant I, Shaw A, Torr S: Cheap and safe tsetse control for livestock production and mixed farming in Africa. Aspect Appl Biol 2005, 75:81.
• [43]Vale G, Mutika G, Lovemore D: Insecticide-treated cattle for controlling tsetse flies (Diptera: Glossinidae): some questions answered, many posed. Bull Entomol Res 1999, 89(06):569-578.
• [44]Brownlow AC: Evaluation of a novel method for controlling bovine trypanosomiasis; a longtudinal study in south-eastern Uganda. Edinburgh, UK: The University of Ednburgh; 2007.
• [45]Vale GA, Grant IF: Modelled impact of insecticide-contaminated dung on the abundance and distribution of dung fauna. Bull Entomol Res 2002, 92(3):251-263.
• [46]Vale GA, Grant IF, Dewhurst CF, Aigreau D: Biological and chemical assays of pyrethroids in cattle dung. Bull Entomol Res 2004, 94(3):273-282.
• [47]Norval RA, Lawrence JA, Young AS, Perry BD, Dolan TT, Scott J: Theileria parva: influence of vector, parasite and host relationships on the epidemiology of theileriosis in southern Africa. Parasitology 1991, 102 Pt 3:347-356.
• [48]Mahoney DF, Ross DR: Epizootiological factors in the control of bovine babesiosis. Aust Vet J 1972, 48(5):292-298.
• [49]Mettam R, Carmichael J: Turning sickness, a protozoan encephalitis of cattle in Uganda. Its relationship with East Coast fever. Parasitology 1936, 28(02):254-283.
• [50]Bruce D, Hamerton A, Bateman H, Mackie F: Amakebe: a disease of calves in Uganda. Proceedings of the Royal Society of London Series B, Containing Papers of a Biological Character 1910, 82(555):256-272.