Background Pastoralists in low-income countries usually live in close proximity to their animals and thus represent an important repository of information about livestock disease. Since wild and domestic animals often mix freely whilst grazing, pastoralists are also able to observe first-hand the diseases that are present in wildlife and as such are key informants in disease outbreaks in sylvatic animals. We report here the findings of the first study of the knowledge and role of Masai pastoralists in mange in wildlife and livestock in Masai Mara, Kenya. Methodology/Principal Findings In this paper we describe the knowledge of mange accrued by 56 Masai pastoralists in Kenya and how they respond to it in both wildlife and livestock. In total, 52 (93%) pastoralists had a clear idea of the clinical appearance of mange, 13 (23%) understood its aetiology and 37 (66%) knew that mites were the causal agent. Thirty-nine (69%) believed that mange cross-infection between domestic and wild animals occurs, while 48 (85%) had observed mange in domestic animals including sheep (77%), goats (57%), dogs (24%) and cattle (14%). The pastoralists had also observed wild animals infected with mange, above all lions (19%), gazelles (14%), cheetahs (12%) and wildebeests (2%). In 68% of cases Masai pastoralists treat mange infection or apply control measures, most commonly via the topical use of acaricides (29%) and/or the reporting of the outbreak to the veterinary authorities (21%). In the period 2007–2011, Kenya Wildlife Service received 24 warnings of 59 wild animals with mange-like lesions from the Masai Mara pastoralist community. The reported species were cheetah, lion, wild dog, Thomson’s gazelle and wildebeest. Conclusion Masai pastoralists have good knowledge of mange epidemiology and treatment. Their observations and the treatments they apply are valuable in the control of this disease in both wild and domestic animals.
References
[1]
Muller GH, Kirk RW, Scott DW (1989) Small animal dermatology, 4th Edition. W.B. Saunders Company, Philadelphia, Pennsylvania, 1,007 pp.
[2]
Kahn CM, Line S, Allen DG, Anderson DP, Jeffcoh LB, et al. (2005) Acariasis mite infestation. In the Merck Veterinary Manual. 9th Edition. Published by Merck and Co Inc. Whitehouse Station, New Jersey U.S.A. Pages 742–749.
[3]
Bornstein S, M?rner T, Samuel WM (2001) Sarcoptes scabiei and sarcoptic mange. In: Samuel WM, Pybus MJ, Kocan AA (Eds) Parasitic diseases of wild mammals, 2PndP edn. Iowa State University Press, Ames. ISBN 0-8138-2978- X, 107–119.
[4]
Alasaad S, Walton S, Rossi L, Bornstein S, Abu-Madi M, et al. (2011) Sarcoptes-World Molecular Network (Sarcoptes-WMN): integrating research on scabies. Int J Infect Dis 15: 294–297.
[5]
Walton SF, Holt DC, Currie BJ, Kemp DJ (2004) Scabies: New future for a neglected disease. Adv Parasitol 57: 309–376.
[6]
Heukelbach J, Feldmeier H (2006) Scabies. Lancet 367: 1767–1774.
[7]
Obasanjo OO, Wu P, Conlon M, Karanfil LV, Pryor P, Moler G, et al. (2001) An outbreak of scabies in a teaching hospital: lessons learned. Infection Control and Hospital Epidemiology 22: 13–18.
[8]
Dagleish MP, Ali Q, Powell RK, Butz D, Woodford MH (2007) Fatal Sarcoptes scabiei infection of blue sheep (Pseudois nayaur) in Pakistan. Journal of Wildlife Diseases 43: 512–517.
[9]
Alasaad S, Schuster RK, Gakuya F, Theneyan H, Jowers MJ, et al. (2012) Applicability of molecular markers to determine parasitic infection origins in the animal trade: A case study from Sarcoptes mites in wildebeest. Forensic Sci Med Pathol 8: 280–284.
[10]
Pence DB. Ueckermann E (2002) Sarcoptic mange in wildlife. Revue Scientifique Et Technique 21: 385–398.
[11]
Soulsbury CD, Iossa G, Baker PJ, Cole NC, Funk SM, et al. (2007) The impact of sarcoptic mange Sarcoptes scabiei on the British fox Vulpes vulpes population. Mammal Rev 37: 278–296.
[12]
Curie BJ, Harumal P, McKinnon M, Walton SF (2004) First documentation of in vivo and in vitro ivermectin resistance in Sarcoptes scabiei. Clin Inf Dis 39: 8–12.
[13]
Bradberry SM, Cage SA, Proudfoot AT, Vale JA (2005) Poisoning due to pyrethroids. Toxicology Review 24: 93–106.
[14]
Sanderson H, Laird B, Pope L, Brain R, Wilson C, et al. (2007) Assessment of the environmental fate and effects of ivermectin in aquatic mesocosms. Aquatic Toxicology 85: 229–240.
[15]
Serrano E, Cross PC, Beneria M, Ficapal A, Curia J, et al. (2011) Decreasing prevalence of brucellosis in red deer via efforts to control disease in livestock. Epidemiology and Infection 139: 1626–1630.
[16]
Polley L (2005) Navigating parasite webs and parasite flow: Emerging and re-emerging parasitic zoonoses of wildlife origin. International Journal for Parasitology 35: 1279–1294.
[17]
Zahler M, Essig A, Gothe R, Rinder H (1999) Molecular analyses suggest monospecificity of the genus Sarcoptes (Acari: Sarcoptidae). International Journal for Parasitology 29: 759–766.
[18]
Walton SF, Currie BJ, Kemp DJ (1997) A DNA fingerprinting system for the ectoparasite Sarcoptes scabiei. Molecular and Biochemical Parasitology 85: 187–196.
[19]
Walton SF, Choy JL, Bonson A, Valle A, McBroom J, et al. (1999) Genetically distinct dog-derived and human-derived Sarcoptes scabiei in scabies-endemic communities in northern Australia. Am J Trop Med Hyg 61: 542–547.
[20]
Walton SF, Dougall A, Pizzutto S, Holt D, Taplin D, et al. (2004) Genetic epidemiology of Sarcoptes scabiei (Acari: Sarcoptidae) in northern Australia. International Journal for Parasitology 34: 839–849.
[21]
Alasaad S, Soglia D, Sarasa M, Soriguer RC, Pérez JM, et al. (2008) Skin-scale genetic structure of Sarcoptes scabiei populations from individual hosts: empirical evidence from Iberian ibex-derived mites. Parasitol Res 104: 101–105.
[22]
Alasaad S, Soglia D, Spalenza V, Maione S, Soriguer RC, et al. (2009) Is ITS-2 rDNA suitable marker for genetic characterization of Sarcoptes mites from different wild animals in different geographic areas? Vet Parasitol 159: 181–185.
[23]
Rasero R, Rossi L, Maione S, Sacchi P, Rambozzi L, et al. (2010) Host taxon-derived Sarcoptes mites in European wildlife animals, revealed by microsatellite markers. Biological Conservation 143: 1269–1277.
[24]
Alasaad S, Oleaga A, Casais R, Rossi L, Molinar-Min A, et al. (2011) Temporal stability in the genetic structure of Sarcoptes scabiei under the host-taxon law: empirical evidences from wildlife-derived Sarcoptes mite in Asturias, Spain. Parasit Vectors 4: 151.
[25]
Arlian LG (1989) Biology, host relations, and epidemiology of Sarcoptes scabiei. Annu Rev Entomol 34: 139–161.
[26]
Gakuya F, Rossi L, Ombui J, Maingi N, Muchemi G, et al. (2011) The curse of the prey: Sarcoptes mite molecular analysis reveals potential prey-to-predator parasitic infestation in wild animals from Masai Mara, Kenya. Parasit Vectors 4: 193.
[27]
Ngoru B, Mulama M (2002) Cheetah (Acinonyx jubatus) population status, problem and possible mitigation measures in Maasai Mara National Reserve and adjacent Group Ranches. Cheetah Conservation Project in Mara. A report to Kenya Wildlife Service, Nairobi, Kenya.
[28]
Mwanzia JM, Kock R, Wambua J, Kock N, Jarret O (1995) An outbreak of Sarcoptic Mange in the free-living cheetah (Acinonyx jubatus) in the Mara region of Kenya. In: Proceedings of American Association of Zoo Veterinarians and American Association of Wildlife Veterinarians Joint Conference, Omaha; Pages 105–112.
[29]
Gakuya F, Ombui J, Maingi N, Muchemi G, Ogara W, et al. (2012) Sarcoptic mange and cheetah conservation in Masai Mara (Kenya): Epidemiological study in a wildlife/livestock system. Parasitology [doi:10.1017/S0031182012000935].
[30]
Alasaad S, Rossi L, Soriguer RC, Rambozzi L, Soglia D, et al. (2009) Sarcoptes mite from collection to DNA extraction: the lost realm of the neglected parasite. Parasitol Res 104: 723–732.
[31]
Fain A (1968) étude de la variabilité de Sarcoptes scabiei avec une revisiondes Sarcoptidae. Acta zoologica et pathologica Antverpiensia 47: 1–196.
[32]
Sanders A, Froggatt P, Wall R, Smith KE (2000) Life-cycle stage morphology of Psoroptes mange mites. Medical and Veterinary Entomology 14: 131–141.
[33]
Mugera GM, Bwangamoi O, Wandera JG (1979) Diseases caused by Ectoparasites I. In: Disease of cattle in Tropical Africa. Kenya Literature Bureau Nairobi; Pages 296–304.
[34]
Blood DC, Radostitis OM (1989) In:Veterinary Medicine. A Textbook of the Diseases of Cattle, Sheep, Pigs, Goats and Horses. 7th Edition. Printed by the University printing House Oxford. Pages 1094–1099.
[35]
León-Vizcaíno L, Cubero MJ, González-Capitel E, Simón MA, Pérez L, et al. (2002) Experimental ivermectin treatment of sarcoptic mange and establishment of a mange-free population of Spanish ibex. J Wildl Dis 37: 775–785.
[36]
Heukelbach J, Winter B, Wilcke T, Muehlen M, Albrecht S, et al. (2004) Selective mass treatment with ivermectin to control intestinal helminthiases and parasitic skin diseases in a severely affected population. Bull World Health Organ 82: 563–571.
[37]
Munang’andu HM, Siamudaala VM, Matandiko W, Munyeme M, Chembensofu M, et al. (2020) Sarcoptes mite epidemiology and treatment in African buffalo (Syncerus caffer) calves captured for translocation from the Kafue game management area to game ranches. BMC Vet Res 6: 29.
[38]
Alasaad S, Ndeereh D, Rossi L, Bornstein S, Permunian R, et al. (2011) The opportunistic Sarcoptes scabiei: A new episode from giraffe in the drought-suffering Kenya. Vet Parasitol doi.org/10.1016/j.vetpar.2011.10.039.
