Jackson, R. (1998). People-Wildlife Conflict Management in the Qomolangma Nature Preserve, Tibet. In W. Ning, D. Miller, L. Zhu, & J. Springer (Eds.), (pp. 40–46). Tibet's Biodiversity: Conservation and Management.. China: Tibet Forestry Department and World Wide Fund for Nature. China Forestry Publishing House.
Abstract: The primary objective of this paper is to report on people-wildlife conflicts arising from crop damage and livestock depredation in the Qomolangma Reserve, with special reference to the management of protected and endangered mammals.
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Kolosov A.M. (1975). Central Asia.
Abstract: It describes a mammal species composition in the mountain ecosystems of Central Asia Kopetdag, Hissaro-Alai and Pamir, Tien Shan, and Tarbagatai ridge. Data on distribution and population number is presented.
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Kolbintsev V.G. (1990). The role of the Aksu-Djabagly nature reserve in the vertebrate animals gene pool conservation (Vol. Part 3.).
Abstract: The Aksu-Djabagly nature reserve is a real guarantor for conservation of gene pool of five species Tien Shan bear, golden eagle, bearded vulture, Blue whistling thrush, and probably Central Asia stone marten. To strengthen the role of the nature reserve in the rare species conservation it is necessary to extend its area to a number of additional land plots belonging to forestries.
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Kataevsky V.N. (2002). Mammals of Sary Chelek nature reserve.
Abstract: The 30 species of mammals are presented in Sary Chelek nature reserve, Kyrgyzstan. Comparison of status of mammal's diversity in Soviet period and present time is made. Number decrease for some mammals is noted. Number of snow leopard in Sary Chelek is 2 individuals, Turkestan lynx 3, wolf 10, bear 20, badger 20, fox 25, jackal 25, wild boar 100 individuals. Snow leopard included in national Red data Book and Global Red List.
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Kataevsky V.N. (2002). Specific of fauna of mammals in Besh Aral nature reserve.
Abstract: Diversity of mammals in Besh Aral nature reserve, Kyrgyzstan is presented. Also analysis of the density of mammals in their habitats is given. Totally 31 mammals inhabited in nature reserve: 13 rodents, 11 carnivores, 3 ungulates, 2 hares, 1 insectivore and 1 bat. Number of snow leopard assessed as 8 individuals, Turkestan lynx 10, wild boar 100 and ibex 400 individuals. Snow leopard and Menzbier's marmot included in national Red data Book as well as in Global Red List.
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Kashkarov D.N. (1927). From lake Sary-Chelek to pass Air-Bel. Mammals.
Abstract: The author provides results of the expedition in the vicinity of lake Sary-Chelek, Kyrgyzstan. With reference to the local people he indicates the presence of irbis (Leopardus uncia), bear (Ursus leuconyx), dhole (Cyon alpinus) around Air-Bel. Livestock attracts the predators and every day shepherds find one sheep missing.
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Kashkarov D.N. (1923). Living conditions and living in various parts of the mountainous Turkestan. Central Asian snow leopard, irbis (Vol. Issue 2. The animals of mountainous Turkistan.).
Abstract: It describes fauna of the mountainous Turkestan. Irbis is met in Tien Shan, Pamir, Bukhara and Kopet-Dag. Apart from Turkistan, it lives in the Altai, Tibet and on northern slopes of the Himalayas. In Kopet-Dag, this species is met with another panther Caucasian leopard. It preys on ibex, wild sheep, roe deer, keklik (partridge), snow-cock and porcupine. It also attacks small livestock. Normally this species would never attack the man though hunters mentioned some cases that evidence otherwise.
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Kamelin R.V. (1990). The Hissar Nature reserve.
Abstract: It provides general information about the Hissar nature reserve (Uzbekistan), its physico-geographical features and description of flora and fauna. The following predator species inhabit the nature reserve: wolf, fox, Tien Shan brown bear (four five animals per 100 sq. km), ermine, weasel, stone marten, otter, badger, lynx (two animals per 100 sq. km) and snow leopard (about 10 animals). Wild boar and ibex are common species for the area (22 25 animals per 100 sq. km).
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Jalanka, H. H., & Roeken, B. (1990). The use of Medetomidine, Medetomidine-Ketamine combinations, and Atipamezole in nondomestic mammals: A review. Journal-of-Zoo-and-Wildlife-Medicine, 21(3), 259–282.
Abstract: The recent development of potent and specifica lphar-adrenoceptoar gonistsa nd antagonists has enhanced their use in nondomestic animal immobilization and reversal. Medetomidine, a new potent alphar-agonist, in combination with the dissociative anesthetic ketamine, has been used to immobilize a variety of nondomestic mammals. Medetomidine alone induces sedation in a dose-dependent way, and complete immobilization has been achieved with high doses in semidomesticated reindeer (Rangifer tarandus) and blue foxes (Alopex lagopus). Howbver, we feel that ketamine should be added to the immobilization mixture to ensure complete immobilization and operator safety. In ketamine combinations, medetomidine doses are usually 60-100 pg/kg. The required ketamine doses are remarkably low:0.8-1.6 mglkg in most ruminants,2.5-3.0 mgUgin felids,u rsids,a nd canids,a nd 5.G-8.0m glkgi n primates,w olverines(Gulog ulo),ando therm uitelids. Clinically, the resulting immobilization is characterized by a smooth onset, good to excellent myorelaxation, and areflexia at higher doses. Determinations of hematologic, serum biochemicil, arterial blood gas,a nd acid-bases tatusp arametersi ndicate that the immobilization is physiologically sound. We have had no fatalities attributable to the immobilization mixture ( I ,240 immobilizations). The alphar-adrenoceptora ntagonist,a tipamezole,i s highly efective in reversingt he immobilization induced by medetomidine, medetomidine-ketamine combinations, or xylazine. In ruminants, the medetomidine-ketamine-induced immobilization can be rapidly and persistently reversed by administering 100-l 50 1rg/kg of alipamezole i.v. and the rest s.c., adjusting the total atipamezole dose to an atipamezole: medetomidine ratio of approximately 4-5 (w/w). Becauseth e required ketamine doses are relatively high in carnivores, we prefer to use a lower atipamezole dose (totil atipamezoie: medetomidine ratio approximately 2-3 w/w) and to administer it i.m. or s.c. Using thii regimen, reversals are calm and animals show minimal “residual ketamine effect.” Because atipamezole is a competitive antagonist, its dose should be reduced if it is administered late in the immobilization period when a large part of medetomidine has been endogenously metabolized. Xylazine-induced immobilization is rapidly reversed by I mg of atipamezole for every 8-12 mg of xylazine used.
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Jackson, R. M., Ahlborn, G., Gurung, M., & Ale, S. (1996). Reducing livestock depredation losses in the Nepalese Himalaya. Proc.Vertebr.Pest Conf, 17, 241–247.
Abstract: The authors investigated livestock depredation patterns of snow leopards on the northern slopes of the Himalayans near the villages of Manang and Khangshar, Nepal. Information is discussed on the relationships among livestock loss, endangered species management, public relations/conservation issues, and cooperative efforts among institutions involved in the decision making process. A plan is devised for alleviating livestock loss and protecting endangered species in the area. pcp
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