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PLOS Neglected Tropical Diseases 2011

Population Vulnerability and Disability in Kenya's Tsetse Fly Habitats

DOI: 10.1371/journal.pntd.0000957

Sue C. Grady ,Joseph P. Messina,Paul F. McCord

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Abstract:

Background Human African Trypanosomiasis (HAT), also referred to as sleeping sickness, and African Animal Trypanosomaisis (AAT), known as nagana, are highly prevalent parasitic vector-borne diseases in sub-Saharan Africa. Humans acquire trypanosomiasis following the bite of a tsetse fly infected with the protozoa Trypanosoma brucei (T.b.) spp. –i.e., T.b. gambiense in West and Central Africa and T.b. rhodesiense in East and Southern Africa. Over the last decade HAT diagnostic capacity to estimate HAT prevalence has improved in active case-finding areas but enhanced passive surveillance programs are still lacking in much of rural sub-Saharan Africa. Methodology/Principal Findings This retrospective-cross-sectional study examined the use of national census data (1999) to estimate population vulnerability and disability in Kenya's 7 tsetse belts to assess the potential of HAT-acquired infection in those areas. A multilevel study design estimated the likelihood of disability in individuals, nested within households, nested within tsetse fly habitats of varying levels of poverty. Residents and recent migrants of working age were studied. Tsetse fly's impact on disability was conceptualised via two exposure pathways: directly from the bite of a pathogenic tsetse fly resulting in HAT infection or indirectly, as the potential for AAT takes land out of agricultural production and diseased livestock leads to livestock morbidity and mortality, contributing to nutritional deficiencies and poverty. Tsetse belts that were significantly associated with increased disability prevalence were identified and the direct and indirect exposure pathways were evaluated. Conclusions/Significance Incorporating reports on disability from the national census is a promising surveillance tool that may enhance future HAT surveillance programs in sub-Saharan Africa. The combined burdens of HAT and AAT and the opportunity costs of agricultural production in AAT areas are likely contributors to disability within tsetse-infested areas. Future research will assess changes in the spatial relationships between high tsetse infestation and human disability following the release of the Kenya 2009 census at the local level.

References

[1]	Pollock JN (1982) Training manual for tsetse control personnel, Vol 2: Ecology and behaviour of tsetse. Rome: Food and Agriculture Organization of the United Nations.
[2]	World Health Organization African Trypanosomiasis Fact Sheet No. 259. Revised August 2006. [http://www.who.int/mediacentre/factsheet？s/fs259/en/print.html].
[3]	World Health Organization Control of Human African Trypanosomiasis: A strategy for the African region. August 22–26, 2005. [http://www.who.int/trypanosomiasis_afric？an/resources/afro_tryps_strategy.pdf].
[4]	World Health OrganizationWeekly Epidemiological Record 24 February 2006; 81: 69–80.
[5]	Kuzmin IV, Niezgoda M, Franka R, Agwanda B, Markotter W, et al. (2010) Human African Trypanosomiasis in areas without surveillance. Emerging Infectious Diseases 16(2): 354–256. doi: 10.3201/eid1602.090967
[6]	Ouma J (2010) Personal communication on October 19 and 20, 2010.
[7]	Mattioli RC, Feldmann U, Hendrickx Wint W, Jannin J, Slingenbergh J (2004) Tsetse and trypanosomiasis intervention policies supporting sustainable animal-agricultural development. Food, Agriculture and Environment 2(2): 310–314.
[8]	Oluwafemi R (2009) The impact of African animal trypanosomosis and tsetse fly on the livelihood and well-being of cattle and their owners in the BICOT study area of Nigeria. The Internet Journal of Veterinary Medicine 5(2). doi: 10.5580/2397
[9]	Swallow BM (2000) Impacts of trypanosomiasis on African agriculture. Rome: Food and Agriculture Organization of the United Nations.
[10]	Hursey BS, Slingenbergh J (1995) The tsetse fly and its effects on agriculture in sub-Saharan Africa. World Animal Review 84-85: 67–73.
[11]	Budd LT (1999) DFID-Funded Tsetse and Trypanosomiasis Research and Development since 1980. Volume 2-Economic Analysis. United Kingdom: Department of International Development.
[12]	Delgado C, Rosegrant M, Steinfeld H, Ehui S, Courbois C (1999) Livestock to 2020: The Next Food Revolution. Washington, DC: IFPRI.
[13]	World Health Organization Communicable diseases and severe food shortage situations. August 25, 2005. Geneva, Switzerland. [http://www.who.int/diseasecontrol_emerge？ncies/guidelines/Severe_food_shortages.p？df].
[14]	Hide G (1999) History of sleeping sickness in East Africa. Clinical Microbiology Reviews 12(1): 112–125.
[15]	Courtin F, Jamonneau V, Duvallet G, Garcia A, Coulibaly B, et al. (2008) Sleeping Sickness in West Africa (1906-2006): Changes in spatial repartition and lessons from the past. Tropical Medicine and International Health 13(3): 334–344. doi: 10.1111/j.1365-3156.2008.02007.x
[16]	Minnesota Population Center. Integrated Public Use Microdata Series-International. Minneapolis: University of Minnesota, 2009. Retrieved from [https://international.ipums.org/internat？ional] on July 1, 2010.
[17]	Bourn D, Reid R, Rogers D, Snow B, Wint W (2001) Envrionmental Change and the Autonomous Control of Tsetse and Trypanosomosis in Sub-Saharan Africa. Oxford: Environmental Research Group Oxford Limited.
[18]	Rutto JJ, Karuga JW (2009) Temporal and Spatial Epidemology of Sleeping Sicness and Use of Geographical Information System (GIS) in Kenya. Journal of Vector Borne Diseases 46(1): 18–25.
[19]	World Health Organization Report of a WHO informal consultation on sustainable control of human African trypanosomiasis. May 1–3, 2007. Geneva, Switzerland. [http://whqlibdoc.who.int/hq/2007/WHO_CDS？_NTD_IDM_2007.6_eng.pdf].
[20]	International Livestock Research Institute (ILRI); 2009 [http://www.ilri.org/].
[21]	Environmental Systems Research Institute (ESRI); 2009 [http://www.esri.com/].
[22]	Central Bureau of Statistics in Kenya; 1997 doi: 10.1016/s0140-6736(10)60148-1
[23]	Statistical Analysis Software, Inc.; 2009 [http://www.sas.com/].
[24]	Scientific Software International, Inc.; 2009 [http://www.ssicentral.com/].
[25]	Raudenbush SW, Bryk AS (2002) Hierarchical Linear Models Applications and Data Analysis Methods. London: Sage Publications.
[26]	Otim CP, Ocaido M, Okuna NM, Erume J, Ssekitto C, et al. (2004) Disease and Vector Constraints Affection Cattle Production in Pastoral Communities of Ssembabule District, Uganda. Livestock Research for Rural Development 16(5).
[27]	Ford-Berrang L, Odiit M, Maiso F, Waltner-Toews D, McDermott J (2010) Sleeping Sickness in Uganda: revisiting current and historical distributions. African Health Science 6(4): 223–231.
[28]	Kennedy PG (2008) Diagnosing central nervous system trypanosomiasis: two stage or not to stage? Transactions Royal Society Tropical Medicine and Hygiene 102: 306–307. doi: 10.1016/j.trstmh.2007.11.011
[29]	Tiberti N, Hainard A, Lejon V, Robin X, Mumba Ngoyi D, et al. (2010) Discovery and verification of osteopontin and beta-2-microglobulin as promising markers for staging human African trypanosomiasis. Molecular Cell Proteomics Aug 19. [Epub ahead of print]. doi: 10.1074/mcp.m110.001008
[30]	Radwanska M (2010) Emerging trends in the diagnosis of Human African Trypanosomiasis. Parasitology 1-10: doi:10.1017/S03118210000211.
[31]	World Health Organization (2010) African trypanosomiasis Fact Sheet No. 259 [http://www.who.int/mediacentre/factsheet？s/fs259/en/].
[32]	Pepin J, Milord F (2009) African trypanosomiasis and drug-induced encephalopathy: risk factors and pathogenesis. Transactions Royal Society Tropical Medicine and Hygiene 85: 222–224. doi: 10.1016/0035-9203(91)90032-t
[33]	Barrett MP (2010) Potential new drugs for human African trypanosomiasis: some progress at last. Current Opinion in Infectous Diseases Sept 14 [Epub ahead of print].
[34]	Lutje V, Seixas J, Kennedy A (2010) Chemotherapy for second-stage Human African Trypanosomiasis. Cochrane Database of Systematic Reviews Aug 4;8: CD006201. doi: 10.1002/14651858.cd006201.pub2
[35]	Finelle P (1983) African animal trypanosomiasis. World Animal Review 37(7–10).
[36]	FAO, AGAL Livestock Sector Brief. March 2005. Rome, Italy.
[37]	Kristjanson P, Krishna A, Radeny M, Nindo W (2004) Pathways out of poverty in Western Kenya and the role of livestock. Rome: Food and Agriculture Organization of the United Nations.
[38]	DeVisser M, Messina J, Moore N, Lusch D, Maitima J (2010) A dynamic species distribution model of Glossina subgenus Morsitans: The identification of tsetse reservoirs and refugia. Ecosphere 1(1): art6. doi:10.1890/ES10-00006.1.
[39]	Okwi PO, Ndeng G, Kristjason P, Arunga M, Notenbaert A, et al. (2007) Spatial determinants of poverty in rural Kenya. Proceedings of the National Academy of Sciences of the United States of America 104(43): 1: 6769–16774. doi: 10.1073/pnas.0611107104

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