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Part III - Human–Bear Coexistence

Published online by Cambridge University Press:  16 November 2020

Vincenzo Penteriani
Affiliation:
Spanish Council of Scientific Research (CSIC)
Mario Melletti
Affiliation:
WPSG (Wild Pig Specialist Group) IUCN SSC
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Bears of the World
Ecology, Conservation and Management
, pp. 213 - 272
Publisher: Cambridge University Press
Print publication year: 2020

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References

References

Ahmad, S., Hameed, S., Ali, H., et al. (2016). Carnivores’ diversity and conflicts with humans in Musk Deer National Park, Azad Jammu and Kashmir, Pakistan. European Journal of Wildlife Research 62: 565576.Google Scholar
Ali, A., Waseem, M., Teng, M., et al. (2018). Human–Asiatic black bear (Ursus thibetanus) interactions in the Kaghan Valley, Pakistan. Ethology Ecology & Evolution 30: 399415.Google Scholar
Ambarlı, H. (2016). Rural and urban students’ perceptions of and attitudes toward brown bears in Turkey. Anthrozoös 29: 489502.Google Scholar
Ambarlı, H. & Bilgin, C.C. (2008). Human-brown bear conflicts in Artvin, north-eastern Turkey: encounters, damage, and attitudes. Ursus 19: 146153.Google Scholar
Artelle, K. A., Anderson, S. C., Reynolds, J. D., et al. (2016). Ecology of conflict: marine food supply affects human–wildlife interactions on land. Scientific Reports 6: 25936.CrossRefGoogle ScholarPubMed
Bargali, H. S., Akhtar, N. & Chauhan, N. P. S. (2005). Characteristics of sloth bear attacks and human casualties in North Bilaspur forest division, Chhattisgarh, India. Ursus 16: 263267.Google Scholar
Bartoń, K. A., Zwijacz-Kozica, T., Zięba, F., Sergiel, A. & Selva, N. (2019). Bears without borders: long-distance movement in human-dominated landscapes. Global Ecology and Conservation 17: p.e00541.CrossRefGoogle Scholar
Baruch-Mordo, S., Breck, S. W., Wilson, K. R. & Theobald, D. M. (2008). Spatiotemporal distribution of black bear–human conflicts in Colorado, USA. Journal of Wildlife Management 72: 18531862.Google Scholar
Bautista, C., Naves, J., Revilla, E., et al. (2017). Patterns and correlates of claims for brown bear damage on a continental scale. Journal of Applied Ecology 54: 282292.Google Scholar
Beckmann, J. P. & Berger, J. (2003). Rapid ecological and behavioural changes in carnivores: the responses of black bears (Ursus americanus) to altered food. Journal of Zoology 261: 207212.CrossRefGoogle Scholar
Bejder, L., Samuels, A., Whitehead, H., Finn, H. & Allen, S. (2009). Impact assessment research: use and misuse of habituation, sensitisation and tolerance in describing wildlife responses to anthropogenic stimuli. Marine Ecology – Progress Series 395: 177185.CrossRefGoogle Scholar
Belant, J. L., Simek, S. L. & West, B. C. (2011). Managing human–black bear conflicts. Human–Wildlife Conflicts Monograph 1: 177.Google Scholar
Borbón-García, A., Reyes, A., Vives-Flórez, M. & Caballero, S. (2017). Captivity shapes the gut microbiota of Andean bears: insights into health surveillance. Frontiers in Microbiology 8: 112.CrossRefGoogle ScholarPubMed
Botetzagias, I. & Kotilda, E. (2018). Bear management in Greece as a ‘problem orientation’ policy issue: a Q-methodology approach. Aegean Journal of Environmental Sciences 3: 136.Google Scholar
Breck, S. W., Williams, C. L., Beckmann, J. P., et al. (2008). Using genetic relatedness to investigate the development of conflict behavior in black bears. Journal of Mammalogy 89: 428434.Google Scholar
Breck, S. W., Lance, N. & Seher, V. (2009). Selective foraging for anthropogenic resources by black bears: minivans in Yosemite National Park. Journal of Mammalogy 90: 10411044.Google Scholar
Bulte, E. H. & Rondeau, D. (2005). Why compensating wildlife damages may be bad for conservation. Journal of Wildlife Management 69: 1419.Google Scholar
Can, Ö. E., Cruze, N. D., Garshelis, D. L., Beecham, J. J. & Macdonald, D. W. (2014). Resolving human–bear conflict: a global survey of countries, experts and key factors. Conservation Letters 7: 501513.Google Scholar
Charoo, S. A., Sharma, L. K. & Sathyakumar, S. (2011). Asiatic black bear–human interactions around Dachigam National Park, Kashmir, India. Ursus 22: 106113.CrossRefGoogle Scholar
Chauhan, N. P. S. (2003). Human casualties and livestock depredation by black and brown bears in the Indian Himalaya, 1989–98. Ursus 14: 8487.Google Scholar
Clark, J. D., Dobey, S., Masters, D. V., et al. (2005). American black bears and bee yard depredation at Okefenokee Swamp, Georgia. Ursus 16: 234244.Google Scholar
Coleman, T. H., Schwartz, C. C., Gunther, K. A. & Creel, S. (2013). Grizzly bear and human interaction in Yellowstone National Park: an evaluation of bear management areas. The Journal of Wildlife Management 77: 13111320.CrossRefGoogle Scholar
Costello, C. M., Jones, D. E., Inman, R. M., et al. (2003). Relationship of variable mast production to American black bear reproductive parameters in New Mexico. Ursus 14: 116.Google Scholar
Cozzi, G., Chynoweth, M., Kusak, J., et al. (2016). Anthropogenic food resources foster the coexistence of distinct life history strategies: year-round sedentary and migratory brown bears. Journal of Zoology 300: 142150.CrossRefGoogle Scholar
Creachbaum, M. S., Johnson, C. & Schmidt, R. H. (1998). Living on the edge: a process for redesigning campgrounds in grizzly bear habitat. Landscape Urban Plan 42: 269286.Google Scholar
Debata, S., Swain, K. K., Sahu, H. K. & Palei, H. S. (2017). Human–sloth bear conflict in a human-dominated landscape of northern Odisha, India. Ursus 27: 9098.Google Scholar
DeMaster, D. P. & Stirling, I. (1981). Ursus maritimus. Mammalian Species 145: 17.CrossRefGoogle Scholar
Ditmer, M. A., Burk, T. E. & Garshelis, D. L. (2015). Do innate food preferences and learning affect crop raiding by American black bears? Ursus 26: 4052.Google Scholar
Dutta, T., Sharma, S., Maldonado, J. E., Panwar, H. S. & Seidensticker, J. (2015). Genetic variation, structure, and gene flow in a sloth bear (Melursus ursinus) meta-population in the Satpura-Maikal landscape of Central India. PLoS ONE 10: 79.CrossRefGoogle Scholar
Dyck, M. G. (2006). Characteristics of polar bears killed in defense of life and property in Nunavut, Canada, 1970–2000. Ursus 17: 5262.Google Scholar
Elfström, M., Davey, M. L., Zedrosser, A., et al. (2014a). Do Scandinavian brown bears approach settlements to obtain high-quality food? Biological Conservation 178: 128135.Google Scholar
Elfström, M., Zedrosser, A., Jerina, K., et al. (2014b). Does despotic behavior or food search explain the occurrence of problem brown bears in Europe? Journal of Wildlife Management 78: 881893.Google Scholar
Elfström, M., Zedrosser, A., Stoen, O. G. & Swenson, J. E. (2014c). Ultimate and proximate mechanisms underlying the occurrence of bears close to human settlements: review and management implications. Mammal Review 44: 518.Google Scholar
Espinosa, S. & Jacobson, S. K. (2012). Human–wildlife conflict and environmental education: evaluating a community program to protect the andean bear in Ecuador. Journal of Environmental Education 43: 5565.CrossRefGoogle Scholar
Fredriksson, G. (2005). Human–sun bear conflicts in East Kalimantan, Indonesian Borneo. Ursus 16: 130137.CrossRefGoogle Scholar
Fredriksson, G. (2012). Effects of El Nino and large-scale forest fires on the ecology and conservation of Malayan sun bears (Helarctos malayanus) in East Kalimantan, Indonesian Borneo. PhD doctoral thesis, University of Amsterdam.Google Scholar
Garcia, K. C., Joshi, H. M. & Dharaiya, N. (2016). Assessment of human–sloth bear conflicts in North Gujarat, India. Ursus 27: 510.Google Scholar
Garshelis, D. L. (2009). Family Ursidae. In: Wilson, D. E. & Mittermeier, R. A. (Eds.), Handbook of the mammals of the world. Vol. 1. Carnivores (pp. 448497). Barcelona: Lynx Edicions.Google Scholar
Garshelis, D. L., Baruch-Mordo, S., Bryant, A., Gunther, K. A. & Jerina, K. (2017). Is diversionary feeding an effective tool for reducing human–bear conflicts? Case studies from North America and Europe. Ursus 28: 3155.Google Scholar
Ghadirian, T., Qashqaei, A. T., Soofi, M., Abolghasemi, H. & Ghoddousi, A. (2017). Diet of Asiatic black bear in its westernmost distribution range, southern Iran. Ursus 28: 1519.Google Scholar
Gillin, C. M., Hammond, F. M. & Peterson, C. G. (1994). Evaluation of an aversive conditioning technique used on female grizzly bears in the Yellowstone ecosystem. International Conference on Bear Research and Management 9: 503512.Google Scholar
Gniadek, S. J. & Kendall, K. C. (1998). A summary of bear management in Glacier National Park, Montana, 1960–1994. Ursus 10: 155159.Google Scholar
Goldstein, I. (1991). Spectacled bear predation and feeding behavior on livestock in Venezuela. Studies on Neotropical Fauna and Environment 26: 231235.Google Scholar
Groff, C., Dalpiaz, D., Frapporti, C., Rizzoli, R. & Zanghellini, P. (2010). 2009 Bear report of the Forestry and Wildlife Department of the Autonomous Province of Trento. Trento: Autonomous Province of Trento.Google Scholar
Guharajan, R., Abram, N. K., Magguna, M. A., et al. (2017). Does the vulnerable sun bear Helarctos malayanus damage crops and threaten people in oil palm plantations? Oryx 134: 635646.Google Scholar
Gunther, K. A. & Hoekstra, H. E. (1998). Bear-inflicted human injuries in Yellowstone National Park, 1970–1994. Ursus 10: 377384.Google Scholar
Gunther, K. A., Haroldson, M. A., Frey, K., et al. (2004). Grizzly bear–human conflicts in the Greater Yellowstone ecosystem, 1992–2000. Ursus 15: 1022.Google Scholar
Hedman, D. (2009). Manitoba Conservation, Thompson, Canada. Summary of the third international bear–people conflicts workshop in Canmore, Alberta (November 15–18), and oral presentation.Google Scholar
Herrero, S. (1994). The Canadian National Parks and grizzly bear ecosystems: the need for interagency management. International Conference on Bear Research and Management 9: 721.Google Scholar
Herrero, S., Smith, T., Debruyn, T. D., Gunther, K. & Matt, C. A. (2005). From the field: brown bear habituation to people – safety, risks, and benefits. Wildlife Society Bulletin 33: 362373.Google Scholar
Honda, T. (2013). Late spring frosts induce human–Asiatic black bear conflicts. Mammal Study 38: 287292.CrossRefGoogle Scholar
Hopkins, J. B. I., Koch, P. L., Ferguson, J. M. & Kalinowski, S. T. (2014). The changing anthropogenic diets of American black bears over the past century in Yosemite National Park. Frontiers in Ecology and the Environment 12: 107114.Google Scholar
Huang, C., Li, X.-Y., Shi, L.-J. & Jiang, X.-L. (2018). Patterns of human–wildlife conflict and compensation practices around Daxueshan Nature Reserve, China. Zoological Research 39: 406412.Google Scholar
Immelmann, K. & Beer, C. (1989). A dictionary of ethology. Cambridge, MA: Harvard University Press.Google Scholar
Jampel, C. (2016). Cattle-based livelihoods, changes in the taskscape, and human–bear conflict in the Ecuadorian Andes. Geoforum 69: 8493.Google Scholar
Jamtsho, Y. & Wangchuk, S. (2016). Assessing patterns of human–Asiatic black bear interaction in and around Wangchuck Centennial National Park, Bhutan. Global Ecology and Conservation 8: 183189.Google Scholar
Johnson, H. E., Lewis, D. L., Verzuh, T. L., et al. (2018). Human development and climate affect hibernation in a large carnivore with implications for human–carnivore conflicts. Journal of Applied Ecology 55: 663672.Google Scholar
Jonker, S. A., Parehurst, J. A., Field, R. & Fuller, T. K. (1998). Black bear depredation on agricultural commodities in Massachusetts. Wildlife Society Bulletin 26: 318324.Google Scholar
Jorgenson, J. P. & Sandoval, A. S. (2005). Andean bear management needs and interactions with humans in Colombia. Ursus 16: 108116.Google Scholar
Kaczensky, P. (1999). Large carnivore depredation on livestock in Europe. Ursus 11: 5972.Google Scholar
Karamanlidis, A. A., Sanopoulos, A., Georgiadis, L. & Zedrosser, A. (2011). Structural and economic aspects of human–bear conflicts in Greece. Ursus 22: 141151.Google Scholar
Kavčič, I., Adamič, M., Kaczensky, P., Krofel, M. & Jerina, K. (2013). Supplemental feeding with carrion is not reducing brown bear depredations on sheep in Slovenia. Ursus 24: 111119.Google Scholar
Kimball, B. A., Nolte, D. L., Engeman, R. M., Johnston, J. J. & Stermitz, F. R. (1998). Chemically mediated foraging preference of black bears (Ursus americanus). Journal of Mammalogy 79: 448456.Google Scholar
Kishimoto, R. (2009). Status of the 2006 drastic rise of Asiatic black bear (Ursus thibetanus) intrusions into residential areas in Nagano Prefecture. In: Oi, T., Ohnishi, N., Koizumi, T. & Okochi, I. (Eds.), Biology of bear intrusions. Proceedings of the International Workshop “The Mechanism of the Intrusion of Bears into Residential Areas,” November 21–22, 2008, Kyoto, Japan (pp. 3539). Ibaraki: Forestry and Forest Products Research Institute.Google Scholar
Kobashikawa, S. & Koike, S. (2016). Spatiotemporal factors affecting bark stripping of conifer trees by Asiatic black bears (Ursus thibetanus) in Japan. Forest Ecology and Management 380: 100106.CrossRefGoogle Scholar
Krofel, M. & Jerina, K. (2012). Review of human–bear conflicts: causes and possible solutions. Professional Journal of Forestry 70: 235253.Google Scholar
Krofel, M., Špacapan, M. & Jerina, K. (2017). Winter sleep with room service: denning behaviour of brown bears with access to anthropogenic food. Journal of Zoology 302: 814Google Scholar
Laguna, A. (2018). Manual de prevención y atención de ataques por Oso Andino (Tremarctos ornatus) al ganado en Ecuador. Quito: Big Mammals Conservation.Google Scholar
Laufenberg, J. S., Johnson, H. E., Doherty, P. F. & Breck, S. W. (2018). Compounding effects of human development and a natural food shortage on a black bear population along a human development–wildland interface. Biological Conservation 224: 188198.Google Scholar
Leigh, J. & Chamberlain, M. J. (2008). Effects of aversive conditioning on behavior of nuisance Louisiana black bears. Human–Wildlife Conflicts 2: 175182.Google Scholar
Li, X., Buzzard, P., Chen, Y. & Jiang, X. (2013). Patterns of livestock predation by carnivores: human–wildlife conflict in Northwest Yunnan, China. Environmental Management 52: 13341340.Google Scholar
Linnell, J. D. C., Aanes, R., Swenson, J. E., Odden, J. & Smith, M. E. (1997). Translocation of carnivores as a method for managing problem animals: a review. Biodiversity and Conservation 6: 12451257.Google Scholar
Linnell, J. D. C., Lescureux, N., Majic, A., Von Arx, M. & Salvatori, V. (2013). Results from a stakeholder workshop on large carnivores in Brussels (pp. 168). Brussels: European Commission.Google Scholar
Lira Torres, I., Carrera Treviño, R. & Martínez García, L.F. (2015). Primer registro de oso negro Ursus americanus (Carnivora: Ursidae) en un bosque tropical subperennifolio en la reserva de la biosfera “El Cielo”, Tamaulipas, México. Therya 6: 653660.CrossRefGoogle Scholar
Liu, F., McShea, W. J., Garshelis, D. L., et al. (2011). Human–wildlife conflicts influence attitudes but not necessarily behaviors: factors driving the poaching of bears in China. Biological Conservation 144: 538547.Google Scholar
Lowery, D. R., Morse, W. C. & Steury, T. D. (2012). Biological and social investigation of human–black bear conflicts in the panhandle of Florida. Human Dimensions of Wildlife 17: 193206.CrossRefGoogle Scholar
Madden, F. & McQuinn, B. (2014). Conservation’s blind spot: the case for conflict transformation in wildlife conservation. Biological Conservation 178: 97106.Google Scholar
Madison, J. S. (2008). Yosemite National Park: the continuous evolution of human–black bear conflict management. Human–Wildlife Conflicts 2: 160167.Google Scholar
Majić Skrbinšek, A. & Krofel, M. (2015). Defining, preventing, and reacting to problem bear behaviour in Europe (pp. 156). Brussels: European Commission.Google Scholar
Mattson, D. J., Blanchard, B. M. & Knight, R. R. (1992). Yellowstone grizzly bear mortality, human habituation, and whitebark pine seed crops. Journal of Wildlife Management 56: 432442.Google Scholar
Mazur, R. L. (2010). Does aversive conditioning reduce human–black bear conflict? The Journal of Wildlife Management 74: 4854.CrossRefGoogle Scholar
Mazur, R. & Seher, V. (2008). Socially learned foraging behaviour in wild black bears, Ursus americanus. Animal Behaviour 75: 15031508.Google Scholar
McCullough, D. R. (1982). Behavior, bears, and humans. Wildlife Society Bulletin 10: 2733.Google Scholar
McKinley, B. K., Belant, J. L. & Etter, D. R. (2014). American black bear–apiary conflicts in Michigan. Human–Wildlife Interactions 8: 228234.Google Scholar
McLellan, B. N. (2005). Sexually selected infanticide in grizzly bears: the effects of hunting on cub survival. Ursus 16: 141156.Google Scholar
Meagher, M. & Phillips, J. R. (1983). Restoration of natural populations of grizzly and black bears in Yellowstone National Park. International Association of Bear Research and Management 5: 152158.Google Scholar
Merkle, J. A., Robinson, H. S., Krausman, P. R. & Alaback, P. (2013). Food availability and foraging near human developments by black bears. Journal of Mammalogy 94: 378385.Google Scholar
Miller, S. D. & Tutterrow, V. L. (1999). Characteristics of nonsport mortalities to brown and black bears and human injuries from bears in Alaska. Ursus 11: 239252.Google Scholar
Mir, Z. R., Noor, A., Habib, B. & Veeraswami, G. G. (2015). Attitudes of local people toward wildlife conservation: a case study from the Kashmir Valley. Mountain Research and Development 35: 392400.Google Scholar
Molinari, P., Krofel, M., Bragalanti, N., et al. (2016). Comparison of the occurrence of human–bear conflicts between northern Dinaric Mountains and south-eastern Alps. Carnivore Damage Prevention News 12: 917.Google Scholar
Morehouse, A. T. & Boyce, M. S. (2017). Evaluation of intercept feeding to reduce livestock depredation by grizzly bears. Ursus 28: 6680.Google Scholar
Morehouse, A. T., Graves, T. A., Mikle, N. & Boyce, M. S. (2016). Nature vs. nurture: evidence for social learning of conflict behaviour in grizzly bears. PLoS ONE 11: e0165425.Google Scholar
Mueller, C., Herrero, S. & Gibeau, M. L. (2004). Distribution of subadult grizzly bears in relation to human development in the Bow River Watershed, Alberta. Ursus 15: 3547.Google Scholar
Narita, R., Mano, T., Yokoyama, R. & Takayanagi, A. (2011). Variation in maize consumption by brown bears (Ursus arctos) in two coastal areas of Hokkaido, Japan. Mammal Study 36: 3339.CrossRefGoogle Scholar
Naves, J., Ordiz, A., Fernández-Gil, A., et al. (2018) Patterns of brown bear damages on apiaries and management recommendations in the Cantabrian Mountains, Spain. PLoS ONE 13: e0206733.Google Scholar
Normua, F., Higashi, S., Ambu, L. & Mohamed, M. (2004). Notes on oil palm plantation use and seasonal spatial relationships of sun bears in Sabah, Malaysia. Ursus 15: 227231.Google Scholar
Northrup, J. M., Stenhouse, G. B. & Boyce, M. S. (2012). Agricultural lands as ecological traps for grizzly bears. Animal Conservation 15: 369377.Google Scholar
Obbard, M. E., Howe, E. J., Wall, L. L., et al. (2014). Relationships among food availability, harvest, and human–bear conflict at landscape scales in Ontario, Canada. Ursus 25: 98110.Google Scholar
Oka, T., Miura, S., Masaki, T., et al. (2004). Relationship between changes in beechnut production and Asiatic black bears in northern Japan. Journal of Wildlife Management 68: 979986.Google Scholar
Penteriani, V., López-Bao, J. V., Bettega, C., et al. (2017). Consequences of brown bear viewing tourism: a review. Biological Conservation 206: 169180.Google Scholar
Penteriani, V., Delgado, M. D. M., Krofel, M., et al. (2018a). Evolutionary and ecological traps for brown bears Ursus arctos in human-modified landscapes. Mammal Review 48: 180193.Google Scholar
Penteriani, V., Huber, D., Jerina, K., et al. (2018b). Trans-boundary and trans-regional management of a large carnivore: managing brown bears across national and regional borders in Europe. In: Hovardas, T. (Ed.), Large carnivore conservation and management: Human dimensions and governance. Oxford, UK: Routledge, Taylor & Francis Group.Google Scholar
Penteriani, V., Zarzo-Arias, A., Novo-Fernández, A., Bombieri, G. & López-Sánchez, C. A. (2019). Responses of an endangered brown bear population to climate change based on predictable food resource and shelter alterations. Global Change Biology 25: 11331151.Google Scholar
Proctor, M. F., Kasworm, W. F., Annis, K. M., et al. (2018). Conservation of threatened Canada–USA trans-border grizzly bears linked to comprehensive conflict reduction. Human–Wildlife Interactions 12: 348372.Google Scholar
Rajpurohit, K. S. & Krausman, P. R. (2000). Human–sloth bear conflicts in Madhya Pradesh, India. Wildlife Society Bulletin 28: 393399.Google Scholar
Ralf, R. (1995). History of bear–human conflict management in Jasper National Park: 1907–1995. Jasper: Jasper National Park.Google Scholar
Ravenelle, J. & Nyhus, P. J. (2017). Global patterns and trends in human–wildlife conflict compensation. Conservation Biology 31: 12471256.Google Scholar
Saito, M., Yamauchi, K. & Aoi, T. (2008). Individual identification of Asiatic black bears using extracted DNA from damaged crops. Ursus 19: 162167.Google Scholar
Sangay, T. & Vernes, K. (2008). Human–wildlife conflict in the Kingdom of Bhutan: patterns of livestock predation by large mammalian carnivores. Biological Conservation 141: 12721282.Google Scholar
Sato, Y., Mano, T. & Takatsuki, S. (2005). Stomach contents of brown bears Ursus arctos in Hokkaido, Japan. Wildlife Biology 11: 133144.Google Scholar
Schirokauer, D. W. & Boyd, H. M. (1998). Bear–human conflict management in Denali National Park and Preserve, 1982–94. Ursus 10: 395403.Google Scholar
Schwartz, C. C., Swenson, J. E. & Miller, S. D. (2005). Large carnivores, moose, and humans: a changing paradigm of predator management in the 21st century. Alces 39: 4163.Google Scholar
Schwartz, C. C., Haroldson, M. A., White, G. C., et al. (2006). Temporal, spatial, and environmental influences on the demographics of grizzly bears in the Greater Yellowstone Ecosystem. Wildlife Monographs 161: 168.Google Scholar
Scotson, L., Vannachomchan, K. & Sharp, T. (2014). More valuable dead than deterred? Crop-raiding bears in Lao PDR. Wildlife Society Bulletin 38: 783790.Google Scholar
Sethy, J. & Chauhan, N. S. (2013). Human–sun bears conflict in Mizoram, North East India: impact and conservation management. International Journal of Conservation Science 4: 317328.Google Scholar
Shivik, J. A., Ruid, D., Willging, R. C. & Mock, K. E. (2011). Are the same bears repeatedly translocated from corn crops in Wisconsin? Ursus 20: 114119.CrossRefGoogle Scholar
Sowka, P. (2009). Techniques and refuse management options for residential areas, campgrounds, and group-use area. In: Living with Black Bears, Grizzly Bears and Lions Project. 3. Swan Valley, MT: Living with Wildlife Foundation, & Montana Fish, Wildlife and Parks.Google Scholar
Stenhouse, G. B., Lee, L. J. & Poole, K. G. (1988). Some characteristics of polar bear killed during conflicts with humans in the Northwest Territories, 1976–86. Arctic 41: 275278.Google Scholar
Stewart, W. B., Witmer, G. W. & Koehler, G. M. (1999). Black bear damage to forest stands in western Washington. Western Journal of Applied Forestry 14: 128131.Google Scholar
Steyaert, S. M. J. G., Kindberg, J., Swenson, J. E. & Zedrosser, A. (2013). Male reproductive strategy explains spatiotemporal segregation in brown bears. Journal of Animal Ecology 82: 836845.Google Scholar
Steyaert, S. M., Kindberg, J., Jerina, K., et al. (2014). Behavioral correlates of supplementary feeding of wildlife: can general conclusions be drawn? Basic and Applied Ecology 15: 669676.Google Scholar
Steyaert, S. M. J. G., Leclerc, M., Pelletier, F., et al. (2016). Human shields mediate sexual conflict in a top predator. Proceedings of the Royal Society B 283: 20160906.CrossRefGoogle Scholar
Swenson, J. E. & Andrén, H. (2005). A tale of two countries: large depredation and compensation schemes in Sweden and Norway. In: Woodroffe, R., Thirgood, S. & Rabinowitz, A. (Eds.), People and wildlife, conflict or coexistence? (pp. 323339). Cambridge, UK: Cambridge University Press.Google Scholar
Swenson, J. E., Sandegren, F., Soderberg, A., et al. (1997). Infanticide caused by hunting of male bears. Nature 386: 450451.Google Scholar
Swenson, J. E., Dahle, B. & Sandegren, F. (2001). Intraspecific predation in Scandinavian brown bears older than cubs-of-the-year. Ursus 12: 8192.Google Scholar
Tavss, E. A. (2005). Correlation of reduction in nuisance black bear complaints with implementation of a nonviolent program and a hunt. In; New Jersey public hearing on the comprehensive black bear management policy. Rutgers, NJ: State University of New Jersey.Google Scholar
Taylor, J. D. & Phillips, P. (2019). Black bears. Wildlife Damage Management Series. U.S. Department of Agriculture Animal and Plant Health Inspection Service: Wildlife Services.Google Scholar
Towns, L., Derocher, A. E., Stirling, I., Lunn, N. J. & Hedman, D. (2009). Spatial and temporal patterns of problem polar bears in Churchill, Manitoba. Polar Biology 32: 15291537.Google Scholar
Treves, A. & Karanth, K. U. (2003). Human–carnivore conflict and perspectives on carnivore management worldwide. Conservation Biology 17: 14911499.Google Scholar
Treves, A., Kapp, K. J. & Macfarland, D. M. (2010). American black bear nuisance complaints and hunter take. Ursus 21: 3042.Google Scholar
van Eeden, L. M., Eklund, A., Miller, J. R., et al. (2018). Carnivore conservation needs evidence-based livestock protection. PLoS Biology 16: e2005577.Google Scholar
Widman, M. & Elofsson, K. (2018). Costs of livestock depredation by large carnivores in Sweden 2001 to 2013. Ecological Economics 143: 188198.Google Scholar
Wielgus, R. B. & Bunnell, F. L. (1994). Sexual segregation and female grizzly bear avoidance of males. Journal of Wildlife Management 58: 405413.Google Scholar
Wilder, J. M., DeBruyn, T. D., Smith, T. S. & Southwould, A. (2007). Systematic collection of bear–human interaction information for Alaska’s national parks. Ursus 18: 209216.Google Scholar
Wilson, R. R., Regehr, E. V., Martin, M. St., et al. (2017). Relative influences of climate change and human activity on the onshore distribution of polar bears. Biological Conservation 214: 288294.Google Scholar
Wilson, S. M. (2007). Community-supported conservation of grizzly bears on private agricultural lands. Final close-out report for conservation innovation grant. Portland, OR: US Department of Agriculture – Natural Resources Conservation Service.Google Scholar
Wilson, S. M. (2016). A guidebook to human–carnivore conflict: Strategies and tips for effective communication and collaboration with communities (pp. 167). Ljubljana, Slovenia: Slovenia Forest Service – LIFE DINALP BEAR Project.Google Scholar
Wilson, S. M., Madel, M. J., Mattson, D. J., Graham, J. M. & Merrill, T. (2006). Landscape conditions predisposing grizzly bears to conflicts on private agricultural lands in the western USA. Biological Conservation 130: 4759.Google Scholar
Wilson, S. M., Neudecker, G. A. & Jonkel, J. J. (2013). Human–grizzly bear coexistence in the Blackfoot River watershed, Montana: getting ahead of the conflict curve. In: Clark, S. & Rutherford, M. (Eds.), Large carnivore conservation: Integrating science and policy in the North American West (pp. 117214). Chicago, IL: University of Chicago Press.Google Scholar
Wong, W. M., Leader-Williams, N. & Linkie, M. (2015). Managing human–sun bear conflict in Sumatran agroforest systems. Human Ecology 43: 255266.Google Scholar
Wynn-Grant, R., Ginsberg, J. R., Lackey, C. W., Sterling, E. J. & Beckmann, J. P. (2018). Risky business: modeling mortality risk near the urban-wildland interface for a large carnivore. Global Ecology and Conservation 16: e00443.Google Scholar
Yamazaki, K., Koike, S., Kozakai, C., et al. (2009). Behavioral study of free ranging Japanese black bears I. Does food abundance affect the habitat use of bears? In: Oi, T., Ohnishi, N., Koizumi, T. & Okochi, I. (Eds.), Biology of bear intrusions. Proceedings of the International Workshop “The Mechanism of the Intrusion of Bears into Residential Areas,” November 21–22, 2008, Kyoto, Japan (pp. 6063). Ibaraki: Forestry and Forest Products Research Institute.Google Scholar
Zack, C. S., Milne, B. T. & Dunn, W. C. (2003). Southern oscillation index as an indicator of encounters between humans and black bears in New Mexico. Wildlife Society Bulletin 31: 517520.Google Scholar
Zapata-Ríos, G. & Branch, L. C. (2018). Mammalian carnivore occupancy is inversely related to presence of domestic dogs in the high Andes of Ecuador. PLoS ONE 13: p.e0192346.CrossRefGoogle ScholarPubMed
Zedrosser, A., Steyaert, S. M. J. G., Gossow, H. & Swenson, J. E. (2011). Brown bear conservation and the ghost of persecution past. Biological Conservation 144: 21632170.Google Scholar
Ziegltrum, G. J. & Nolte, D. L. (2001). Black bear forest damage in Washington state, USA: economic, ecological, social aspects. Ursus 12: 169172.Google Scholar
Zukowski, B. & Ormsby, A. (2016). Andean bear livestock depredation and community perceptions in Northern Ecuador. Human Dimensions of Wildlife 21: 111126.Google Scholar
Zyśk-Gorczyńska, E., Jakubiec, Z., Wertz, B. & Wuczyński, A. (2016). Long-term study of damage to trees by brown bears Ursus arctos in Poland: increasing trends with insignificant effects on forest management. Forest Ecology and Management 366: 5364.Google Scholar

References

Artelle, K. A., Reynolds, J. D., Treves, A., et al. (2018). Hallmarks of science missing from North American wildlife management. Science Advances 4(3): eaao0167.Google Scholar
Balint, P. J., Stewart, R. E., Desai, A. & Walters, L. C. (2011). Wicked environmental problems: Managing uncertainty and conflict. Washington, DC: Island Press.Google Scholar
Baruch-Mordo, S., Breck, S. W., Wilson, K. R. & Broderick, J. (2011). the carrot or the stick? Evaluation of education and enforcement as management tools for human–wildlife conflicts. PLoS ONE 6(1): e15681.Google Scholar
Boroditsky, L. (2010, July 24). Lost in translation. The Wall Street Journal.Google Scholar
Boroditsky, L. (2011). How language shapes thought. Scientific American, 4.Google Scholar
Brownstein, M. (2019). Implicit bias. Available from https://plato.stanford.edu/entries/implicit-bias/ (accessed March 9, 2019).Google Scholar
Busjeet, G. (2013). Planning, monitoring, and evaluation: Methods and tools for poverty and inequality reduction programs. Washington, DC: World Bank. Retrieved from https://openknowledge.worldbank.org/handle/10986/16449Google Scholar
Can, Ö. E. & Macdonald, D. W. (2017). To protect everything, please click here: does a revolution in data collection guarantee one in conservation? Animal Conservation, 20(1): 12.Google Scholar
Can, Ö. E. & Macdonald, D. W. (2018). Looking under the bonnet of conservation conflicts: can neuroscience help? Biodiversity and Conservation 27(8): 20872091.Google Scholar
Can, Ö. E., Lise, Y. & Kandemir, İ. (2007). Bees and bears: a review of beekeeper-bear conflict in Black Sea Region, Turkey and recommendations for conflict resolution. American Bee Journal, July: 630–636.Google Scholar
Can, Ö. E., D’Cruze, N., Garshelis, D. L., Beecham, J. & Macdonald, D. W. (2014). Resolving human–bear conflict: a global survey of countries, experts, and key factors. Conservation Letters 7(6): 501513.Google Scholar
Chandran, R. (2015, March 9). It’s broke, so fix it: humanitarian response in crisis. Available from https://cpr.unu.edu/its-broke-so-fix-it-humanitarian-response-in-crisis.html (accessed April 5, 2015).Google Scholar
Cohn, J. P. (2002). Environmental conflict resolution. BioScience 52(5): 400404.Google Scholar
Eagleman, D. (2016). The brain: The story of you. Edinburgh: Canongate.Google Scholar
Editors. (1957). Approaches to the study of social conflict: introduction by the editors. Conflict Resolution 1(2): 105110.Google Scholar
Elm, E. C. & Diener, M. K. (2007). The language of war in biomedical journals. The Lancet 369: 1.Google Scholar
Federal Aviation Administration. (2000). FAA system safety handbook. Retrieved from www.faa.gov/regulations_policies/handbooks_manuals/aviation/risk_management/ss_handbook/Google Scholar
Ginges, J., Atran, S., Medin, D. & Shikaki, K. (2007). Sacred bounds on rational resolution of violent political conflict. Proceedings of the National Academy of Sciences 104(18): 73577360.Google Scholar
Gippoliti, S., Brito, D., Cerfolli, F., et al. (2018). Europe as a model for large carnivores conservation: is the glass half empty or half full? Journal for Nature Conservation 41: 7378.Google Scholar
Gore, M. L., Knuth, B. A., Curtis, P. D. & Shanahan, J. E. (2006). Education programs for reducing American black bear–human conflict: indicators of success? Ursus, 17(1): 7580.Google Scholar
Gore, M. L., Knuth, B. A., Scherer, C. W. & Curtis, P. D. (2008). Evaluating a conservation investment designed to reduce human–wildlife conflict: evaluating conservation investment. Conservation Letters 1(3): 136145.CrossRefGoogle Scholar
Gretzinger, J., Molak, M., Reiter, E., et al. (2019). Large-scale mitogenomic analysis of the phylogeography of the Late Pleistocene cave bear. Scientific Reports 9(1). doi:10.1038/s41598-019-47073-zGoogle Scholar
Hardin, G. (1968). The tragedy of the commons. Science 162(3859): 12431248.Google Scholar
Herrero, S., Higgins, A., Cardoza, J. E., Hajduk, L. I. & Smith, T. S. (2011). Fatal attacks by American black bear on people: 1900–2009. The Journal of Wildlife Management 75(3): 596603.Google Scholar
Hristienko, H. & McDonald, J. E. (2007). Going into the 21st century: a perspective on trends and controversies in the management of the American black bear. Ursus 18(1): 7288.Google Scholar
Institute of Medicine. (2009). On being a scientist: A guide to responsible conduct in research, 3rd edition. Washington, DC: National Academies Press.Google Scholar
IUCN SSC BSG. (2019). Principles of human–bear conflict reduction. IUCN SSC Bear Specialist Group.Google Scholar
Knowlton, L. W. & Phillips, C. C. (2009). The logic model guidebook: Better strategies for great results. Thousand Oaks, CA: SAGE.Google Scholar
Larson, B. M. (2005). The war of the roses: demilitarizing invasion biology. Frontiers in Ecology and the Environment 3(9): 495500.Google Scholar
Lise, Y. (2011). Doğa Konuşmaları Yaban Hayat. Yesil Atlas, 8.Google Scholar
Marsh, H. (2014). Do no harm: Tales of life, death and brain surgery. London: Weidenfeld & Nicolson.Google Scholar
Matt, C. (2012). 4th International Human–Bear Conflicts Workshop Summary. Available from www.bearbiology.org/wp-content/uploads/2019/08/4th-human-bear-conflict-workshop-summary.pdfGoogle Scholar
OED. (2015). Conflict. Oxford English Dictionary. Oxford, UK: Oxford University Press. Retrieved from www.oed.com/view/Entry/38898?result=1&rskey=uilnn5&Google Scholar
O’Sullivan, N. J., Teasdale, M. D., Mattiangeli, V., et al. (2016). A whole mitochondria analysis of the Tyrolean Iceman’s leather provides insights into the animal sources of Copper Age clothing. Scientific Reports 6(1). doi:10.1038/srep31279Google Scholar
Paquet, P. C. & Darimont, C. T. (2010). Wildlife conservation and animal welfare: two sides of the same coin. Animal Welfare 19(2): 177190.Google Scholar
Paulus, M. P., Potterat, E. G., Taylor, M. K., et al. (2009). A neuroscience approach to optimizing brain resources for human performance in extreme environments. Neuroscience & Biobehavioral Reviews 33(7): 10801088.Google Scholar
Peterson, M. N., Birckhead, J. L., Leong, K., Peterson, M. J. & Peterson, T. R. (2010). Rearticulating the myth of human–wildlife conflict. Conservation Letters 3(2): 7482.Google Scholar
Peterson, M. N., Peterson, M. J., Peterson, T. R. & Leong, K. (2013). Why transforming biodiversity conservation conflict is essential and how to begin. Pacific Conservation Biology 19(2): 94.Google Scholar
Peyton, B. (1994). Conservation in the developing world: ideas on how to proceed. Bears: Their Biology and Management 9: 115.Google Scholar
Pooley, S., Barua, M., Beinart, W., et al. (2017). An interdisciplinary review of current and future approaches to improving human–predator relations: improving human–predator relations. Conservation Biology 31(3): 513523.Google Scholar
Presnall, C. C. (1943). Wildlife conservation as affected by American Indian and Caucasian concepts. Journal of Mammalogy 24(4): 458464.Google Scholar
Ramsbotham, O., Woodhouse, T. & Miall, H. (2011). Contemporary conflict resolution, 3rd edition. Bristol: Polity.Google Scholar
Ratnayeke, S., Van Manen, F. T., Pieris, R. & Pragash, V. S. J. (2014). Challenges of large carnivore conservation: sloth bear attacks in Sri Lanka. Human Ecology 42: 467479. doi:10.1007/s10745-014-9643-yGoogle Scholar
Reddy, S. M. W., Montambault, J., Masuda, Y. J., et al. (2017). Advancing conservation by understanding and influencing human behavior: human behavior and nature. Conservation Letters 10(2): 248256.Google Scholar
Redpath, S. M., Young, J., Evely, A., et al. (2013). Understanding and managing conservation conflicts. Trends in Ecology & Evolution 28(2): 100109.Google Scholar
Redpath, S. M., Bhatia, S. & Young, J. (2015). Tilting at wildlife: reconsidering human–wildlife conflict. Oryx 49(2): 222225.Google Scholar
Rittel, H. W. J. & Webber, M. M. (1973). Dilemmas in a general theory of planning. Policy Sciences 4(2): 155169.Google Scholar
Rogers, E. M. (1995). Diffusion of innovations, 4th edition. New York, NY: Free Press.Google Scholar
Sandermoen, K. (2019). Management consulting (is not) for dummies. Alosen, Switzerland: Sandermoen Publishing.Google Scholar
Shenhav, A. & Greene, J. D. (2014). Integrative moral judgment: dissociating the roles of the amygdala and ventromedial prefrontal cortex. Journal of Neuroscience 34(13): 47414749.Google Scholar
Spencer, R. D., Beausoleil, R. A. & Martorello, D. A. (2007). How agencies respond to human–black bear conflicts: a survey of wildlife agencies in North America. Ursus 18(2): 217229.Google Scholar
Swaisgood, R. R. (2007). Current status and future directions of applied behavioral research for animal welfare and conservation. Applied Animal Behaviour Science 102(3–4): 139162.Google Scholar
Tetlock, P. (2003). Thinking the unthinkable: sacred values and taboo cognitions. Trends in Cognitive Sciences 7: 320324.Google Scholar
Treves, A. & Bruskotter, J. (2014). Tolerance for predatory wildlife. Science 344(6183): 476477.Google Scholar
Treves, A., Wallace, R. B., Naughton-Treves, L. & Morales, A. (2006). Co-managing human–wildlife conflicts: a review. Human Dimensions of Wildlife 11(6): 383396.Google Scholar
UNDP. (2009). Handbook on planning, monitoring and evaluating for development results. New York, NY: United Nations Development Programme.Google Scholar
United Nations. (2004). World population to 2300 (No. ST/ESA/SER.A/236). New York, NY: United Nations.Google Scholar
Wilson, S. M. (2016). A guidebook to human–carnivore conflict: Strategies and tips for effective communication and collaboration with communities. Ljubljana, Slovenia: Slovenia Forest Service – LIFE DINALP BEAR project.Google Scholar
W. K. Kellogg Foundation. (2004). W.K. Kellogg Foundation 2004.pdf. Michigan, USA: W.K. Kellogg Foundation.Google Scholar
WSPA. (2009). Principles of human–bear conflict management. Istanbul: World Society for the Protection of Animals.Google Scholar
Zedrosser, A. (2019). The major challenges facing bears. International Bear News 28(2): 2.Google Scholar

References

Acharya, K. P., Paudel, P. K., Neupane, P. R. & Köhl, M. (2016). Human–wildlife conflicts in Nepal: patterns of human fatalities and injuries caused by large mammals. PLoS ONE 11: 118.Google Scholar
Akhtar, N. (2006). Human–sloth bear conflict: a threat to sloth bear conservation. International Bear News 15: 1517.Google Scholar
Akiyama, G., Kuwahara, H., Asahi, R., Tosa, R. & Yokota, H. (2017). Prompt procedures have a great impact on the consequences of Asiatic black bear mauling. Journal of Nippon Medical School 84: 294300.Google Scholar
Ali, A., Waseem, M., Teng, M., et al. (2018). Human–Asiatic black bear (Ursus thibetanus) interactions in the Kaghan Valley, Pakistan. Ethology Ecology and Evolution 30: 399415.Google Scholar
Anderson, K. (1957). Man-eaters and jungle killers. London: George Allen and Unwin Ltd.Google Scholar
Arimoto, I., Okamura, H., Koike, S., Yamazaki, K. & Kaji, K. (2014). Behavior and habitat of Asiatic black bear (Ursus thibetanus) inhabiting near settlements. Honyuruikagaku 54: 1931.Google Scholar
Bargali, H. S., Akhtar, N. & Chauhan, N. P. S. (2005). Characteristics of sloth bear attacks and human casualties in North Bilaspur Forest Division, Chhattisgarh, India. Ursus 16: 263267.CrossRefGoogle Scholar
Bombieri, G., Delgado, M. del M., Russo, L. F., et al. (2018a). Patterns of wild carnivore attacks on humans in urban areas. Scientific Reports 8: 17728.Google Scholar
Bombieri, G., Nanni, V., Delgado, M. del M., et al. (2018b). Content analysis of media reports on predator attacks on humans: toward an understanding of human risk perception and predator acceptance. BioScience 68: 577584.Google Scholar
Bombieri, G., Naves, J., Penteriani, V., et al. (2019). Brown bear attacks on humans: a worldwide perspective. Scientific Reports 9: 8573. https://doi.org/10.1038/s41598-019-44341-wGoogle Scholar
Brower, C. (1942). Fifty years below zero: A lifetime of adventure in the Far North. New York, NY: Dodd, Mead and Company.Google Scholar
Burton, R. G. (1856). A book of man eaters (first edition 1931). Delhi: Mittal Publications.Google Scholar
Chapron, G., Kaczensky, P., Linnell, J.D.C., et al. (2014). Recovery of large carnivores in Europe’s modern human-dominated landscapes. Science 346: 15171519.Google Scholar
Charoo, S. A., Sharma, L. K. & Sathyakumar, S. (2011). Asiatic black bear–human interactions around Dachigam National Park, Kashmir, India. Ursus 22: 106113.CrossRefGoogle Scholar
Clark, D. (2003). Polar bear–human interactions in Canadian national parks, 1986–2000. Ursus 14: 6571.Google Scholar
Conover, M.R. (2008). Why are so many people attacked by predators? Human–Wildlife Interactions 2: 139140.Google Scholar
Debata, S., Swain, K. K., Sahu, H. K. & Palei, H. S. (2017). Human–sloth bear conflict in a human-dominated landscape of northern Odisha, India. Ursus 27: 9098.Google Scholar
Dhamorikar, A. H., Mehta, P., Bargali, H. & Gore, K. (2017). Characteristics of human–sloth bear (Melursus ursinus) encounters and the resulting human casualties in the Kanha–Pench corridor, Madhya Pradesh, India. PLoS ONE 12: 118.Google Scholar
Dharaiya, N., Bargali, H. S. & Sharp, T. (2016). Melursus ursinus. The IUCN Red List of Threatened Species 2016: e.T13143A45033815 (WWW document). http://dx.doi.org/10.2305/IUCN.UK.2016-3.RLTS.T13143A45033815.enGoogle Scholar
Fenton, L. L. (1909). Tiger attacking a bear. Bombay Natural History Society 979.Google Scholar
Fleck, S. & Herrero, S. (1988). Polar bear–human conflicts. Contract report for Parks Canada and GNWT, contract 502/85/23.Google Scholar
Garcia, K. C., Joshi, H. M. & Dharaiya, N. (2016). Assessment of human–sloth bear conflicts in North Gujarat, India. Ursus 27: 510.Google Scholar
Garrote, P. J., Delgado, M. del M., López-Bao, J. V., et al. (2017). Individual attributes and party affect large carnivore attacks on humans. European Journal of Wildlife Research 63: 80.Google Scholar
Herrero, S. (1972). Aspects of evolution and adaptation in American black bears (Ursus americanus Pallas) and brown and grizzly bears (U. arctos Linné.) of North America. Bears: Their Biology and Management 2: 221.Google Scholar
Herrero, S. (2018). Bear attacks: Their causes and avoidance, 3rd edition. New York, NY: Lyons & Burford.Google Scholar
Herrero, S. & Higgins, A. (2003). Human injuries inflicted by bears in Alberta: 1960–98. Ursus (Knoxville) 14: 4454.Google Scholar
Herrero, S., Higgins, A., Cardoza, J. E., Hajduk, L. I. & Smith, T. S. (2011). Fatal attacks by American black bear on people: 1900–2009. Journal of Wildlife Management 75: 596603.Google Scholar
Hwang, M. H. & Garshelis, DL . (2007). Activity patterns of Asiatic black bears (Ursus thibetanus) in the Central Mountains of Taiwan. Journal of Zoology 271: 203209.Google Scholar
Jamtsho, Y. & Wangchuk, S. (2016). Assessing patterns of human–Asiatic black bear interaction in and around Wangchuck Centennial National Park, Bhutan. Global Ecology and Conservation 8: 183189.Google Scholar
Jangid, K. A. & Sharma, K. R. (2018). How locals characterize the causes of sloth bear attacks in Jawai, Rajasthan. International Bear News 27: 1112.Google Scholar
Japan Bear Network. (2006). Understanding Asian bears to secure their future. Ibaraki: Japan Bear Network.Google Scholar
Japan Bear Network. (2011). Report on statistics of the bear caused human injuries (in Japanese). Ibaraki: Japan Bear Network.Google Scholar
Kozakai, C., Yamazaki, K., Nemoto, Y., et al. (2011). Effect of mast production on home range use of Japanese black bears. Journal of Wildlife Management 75: 867875.Google Scholar
Kurt, F. & Jayasuriya, A. (1968). Notes on a dead bear. Loris 11: 182183.Google Scholar
Lal Moten, T., Bhat, T. A., Gulzar, A., Mir, A. & Mir, F. (2017). Causalities of human wildlife conflict in Kashmir valley, India; a neglected form of trauma: our 10 year study. International Journal of Research in Medical Sciences 55: 18981902.Google Scholar
Laurie, A. & Seidensticker, J. (1977). Behavioural ecology of the sloth bear (Melursus ursinus). Journal of Zoology 182: 187204.Google Scholar
Littledale, H. (1889). Bears being eaten by tigers. Journal of Bombay Natural History Society 4: 316.Google Scholar
Mardaraj, P. C. (2015). Identifying key issues for the conservation of sloth bear (Melursus ursinus) in Rajnilgiri, Odisha, Eastern India. The Rufford Foundation, United Kingdom.Google Scholar
Mardaraj, P. & Dutta, S.K. (2011). Human–sloth bear conflict in Balasore Forest Division, Eastern India. Saarbrücken, Germany: LAP Lambert Academic Publishing GmbH & Co. KG.Google Scholar
Moen, G. K., Støen, O. G., Sahlén, V. & Swenson, J. E. (2012). Behaviour of solitary adult Scandinavian brown bears (Ursus arctos) when approached by humans on foot. PLoS ONE 7: e31699.Google Scholar
Nabi, D. G., Tak, S. R., Kangoo, K. A. & Halwai, M. A. (2009a). Comparison of injury pattern in victims of bear (Ursus thibetanus) and leopard (Panthera pardus) attacks. A study from a tertiary care center in Kashmir. European Journal of Trauma and Emergency Surgery 35: 153158.Google Scholar
Nabi, D. G., Tak, S. R., Kangoo, K. A. & Halwai, M. A. (2009b). Increasing incidence of injuries and fatalities inflicted by wild animals in Kashmir. Injury 40: 8789.Google Scholar
National Park Service. (2019). Bear facts (WWW document). Available from www.nps.gov/yose/planyourvisit/bearfacts.htmGoogle Scholar
Nellemann, C., Støen, O. G., Kindberg, J., et al. (2007). Terrain use by an expanding brown bear population in relation to age, recreational resorts and human settlements. Biological Conservation 138: 157165.Google Scholar
Ordiz, A., Støen, O. G., Delibes, M. & Swenson, J. E. (2011). Predators or prey? Spatio-temporal discrimination of human-derived risk by brown bears. Oecologia 166: 5967.Google Scholar
Oshima, T., Ohtani, M. & Mimasaka, S. (2018). Injury patterns of fatal bear attacks in Japan: a description of seven cases. Forensic Science International 286: e14e19.Google Scholar
Penteriani, V., Delgado, M. del M., Pinchera, F., et al. (2016). Human behaviour can trigger large carnivore attacks in developed countries. Scientific Reports 6: 20552.Google Scholar
Penteriani, V., Bombieri, G., Fedriani, J. M., et al. (2017). Humans as prey: coping with large carnivore attacks using a predator–prey interaction perspective. Human–Wildlife Interactions 11: 192207.Google Scholar
Rajpurohit, K. S. & Krausman, P. R. (2000). Human–sloth bear conflicts in Madhya Pradesh, India. Wildlife Society Bulletin 28: 393399.Google Scholar
Ramachandran, A. (2009, November 11). Frozen with fear: stranded teen v polar bears. The Sydney Morning Herald (WWW document). Available from www.smh.com.au/world/frozen-with-fear-stranded-teen-v--polar-bears-20091111-i9fs.htmlGoogle Scholar
Rasool, A., Wani, A. H., Darzi, M. A., et al. (2010). Incidence and pattern of bear maul injuries in Kashmir. Injury 41: 116119.Google Scholar
Ratnayeke, S., Van Manen, F. T., Pieris, R. & Pragash, V. S. J. (2014). Challenges of large carnivore conservation: sloth bear attacks in Sri Lanka. Human Ecology 42: 467479.Google Scholar
Røskaft, E., Händel, B., Bjerke, T. & Kaltenborn, B. P. (2007). Human attitudes towards large carnivores in Norway. Wildlife Biology 13: 172185.Google Scholar
Sethy, J. & Chauhan, N.S. (2013). Human–sun bears conflict in Mizoram, North East India: impact and conservation management. International Journal of Conservation Science 4: 317328.Google Scholar
Sethy, J. & Chauhan, N. S. (2016). Status and distribution of Malayan sun bear in Namdapha Tiger Reserve, Arunachal Pradesh, India. International Journal of Conservation Science 7: 533552.Google Scholar
Shah, A., Mir, B., Ahmad, I., et al. (2010). Pattern of bear maul maxillofacial injuries in Kashmir. National Journal of Maxillofacial Surgery 1: 96.Google Scholar
Sharp, T. & Sonone, S. D. (2011). Sloth bear attacks: causes and consequences. International Bear Newsletter 20: 1417.Google Scholar
Sharp, T. R., Swaminathan, S., Arun, A. S., et al. (2017). Sloth bear attack behavior and a behavioral approach to safety. Final report to International Association for Bear Research and Management.Google Scholar
Silwal, T., Kolejka, J., Bhatta, B. P., et al. (2017). When, where and whom: assessing wildlife attacks on people in Chitwan National Park, Nepal. Oryx 51: 370377.Google Scholar
Singh, N., Sonone, S., Rot, J. & Dharaiya, N. A. (2017). An unusual attractant spurs sloth bear break-ins in Maharashtra, India 26: 20–21.Google Scholar
Smith, T. S. & Herrero, S. (2018). Human–bear conflict in Alaska: 1880–2015. Wildlife Society Bulletin 42: 254263.Google Scholar
Smith, T. S., Herrero, S., Debruyn, T. D. & Wilder, J. M. (2008). Efficacy of bear deterrent spray in Alaska. Journal of Wildlife Management 72: 640645.Google Scholar
Smith, T. S., Herrero, S., Layton, C. S., Larsen, R. T. & Johnson, K. R. (2012). Efficacy of firearms for bear deterrence in Alaska. Journal of Wildlife Management 76: 10211027.Google Scholar
Støen, O. G., Ordiz, A., Sahlén, V., et al. (2018). Brown bear (Ursus arctos) attacks resulting in human casualties in Scandinavia 1977–2016; management implications and recommendations. PLoS ONE 13: e0196876.Google Scholar
Swenson, J. E. (1999). Does hunting affect the behavior of brown bears in Eurasia? Ursus 11: 157162.Google Scholar
Tak, S. R., Nabi, D. G., Halwai, M. A. & Mir, B. A. (2009). Injuries from bear (Ursus thibetanus) attacks in Kashmir. Turkish Journal of Trauma & Emergency Surgery 15: 130134.Google Scholar
Wikipedia. (2019). Willem Barentsz (WWW socument). Available from https://en.wikipedia.org/wiki/Willem_BarentszGoogle Scholar
Wilder, J. M., Vongraven, D., Atwood, T., et al. (2017). Polar bear attacks on humans: implications of a changing climate. Wildlife Society Bulletin 41: 537547.Google Scholar
Wilson, E. O. (1984). Biophilia. Cambridge, MA: Harvard University Press.Google Scholar
Windler, A. (2014). Views towards the sun bear and frames on the human–sun bear conflict of local people in West Sumatra, Indonesia. Wageningen: Forest and Nature Conservation, Wageningen University & Research.Google Scholar
Yamazaki, K. (2004). Recent bear–human conflicts in Japan. International Bear News 13: 1617.Google Scholar
Yamazaki, K. (2010). Ursus thibetanus. In: Ohdachi, S. D., Ishibashi, Y., Iwasa, M. A., Fukui, D. & Saitoh, T. (Eds.), The wild mammals of Japan (pp. 243245). Kyoto: Shoukado Book Seller.Google Scholar
Yamazaki, K. (2017). Consecutive fatal attacks by Asiatic black bear on humans in Northern Japan. International Bear News 26: 1617.Google Scholar
Yamazaki, K. & Sato, Y. (2014). Country-wide range mapping of Asiatic black bears reveals increasing range in Japan. International Bear News 23: 1819.Google Scholar
Yamazaki, K., Furubayashi, K., Kasai, S., et al. (2008). A preliminary evaluation of activity-sensing GPS collars for estimating daily activity patterns of Japanese black bears. Ursus 19: 154161.Google Scholar

References

Abrams, P. A. (1995). Implications of dynamically variable traits for identifying, classifying, and measuring direct and indirect effects in ecological communities. The American Naturalist 146: 112134.Google Scholar
Allendorf, F. W. & Hard, J. J. (2009). Human-induced evolution caused by unnatural selection through harvest of wild animals. Proceedings of the National Academy of Sciences USA 106: 99879994.Google Scholar
Altendorf, K. B., Laundré, J. W., González, C. A. L. & Brown, J. S. (2001). Assessing effects of predation risk on foraging behavior of mule deer. Journal of Mammalogy 82: 430439.Google Scholar
Apps, C. D., Bruce, N., John, G. & Michael, F. (2004). Estimating grizzly bear distribution and abundance relative to habitat and human influence. Journal of Wildlife Management 68: 138152.Google Scholar
Armfield, J. M. (2006). Cognitive vulnerability: a model of the ethology of fear. Clinical Psychology Review 26: 746768.Google Scholar
Armfield, J. M. (2007). Understanding animal fears: a comparison of the cognitive vulnerability and harm-looming models. BMC Psychiatry 7: 68. doi:10.1186/1471-244X-7-68.Google Scholar
Basille, M., Herfindal, I., Santin-Janin, H., et al. (2009). What shapes Eurasian lynx distribution in human dominated landscapes: selecting prey or avoiding people? Ecography 32: 683691.Google Scholar
Beale, C. M. & Monaghan, P. (2004). Human disturbance: people as predation-free predators? Journal of Applied Ecology 41: 335343.Google Scholar
Bischof, R., Fujita, R., Zedrosser, A., Söderberg, A. & Swenson, J. E. (2008). Hunting patterns, ban on baiting, and harvest demographics of brown bears in Sweden. The Journal of Wildlife Management 72: 7988.Google Scholar
Blumstein, D. T. (2016). Habituation and sensitization: new thoughts about old ideas. Animal Behaviour 120: 255262.Google Scholar
Bojarska, K. & Selva, N.(2012). Spatial patterns in brown bear Ursus arctos diet: the role of geographical and environmental factors. Mammal Review 42: 120143.Google Scholar
Bombieri, G., Nanni, V., Delgado, M. M., et al. (2018). Content analysis of media reports on predator attacks on humans: toward an understanding of human risk perception and predator acceptance. BioScience 68: 577584.Google Scholar
Bombieri, G., Naves, J., Penteriani, V., et al. (2019). Brown bear attacks on humans: a worldwide perspective. Scientific Reports 9: 8573. doi.org/10.1038/s41598-019-44341-wGoogle Scholar
Chapron, G., Kaczensky, P., Linnell, J. D. C., et al. (2014). Successful recovery of large carnivores in Europe’s human-dominated landscapes. Science 346: 15171519.Google Scholar
Coltman, D. W., O’Donoghue, P., Jorgenson, J. T., et al. (2003). Undesirable evolutionary consequences of trophy hunting. Nature 426: 655658.Google Scholar
Cotovelea, A., Ionescu, O., Şofletea, N., et al. (2015). Testing the influence of habituation on genetic structure of brown bear (Ursus arctos). Annals of Forest Research 58: 8190.Google Scholar
Cristescu, B., Stenhouse, G. B. & Boyce, M. S. (2013). Perception of human-derived risk influences choice at top of the food chain. PLoS ONE 8: e82738.Google Scholar
Cristescu, B., Stenhouse, G. B. & Boyce, M. S. (2016). Large omnivore movements in response to surface mining and mine reclamation. Scientific Reports 6: 19177.Google Scholar
Darimot, C. T., Carlson, S. M., Kinnison, M. T., et al. (2009). Human predators outpace other agents of trait changes in the wild. Proceedings of the National Academy of Sciences USA 106: 952954.Google Scholar
Elfström, M. & Swenson, J. E. (2009). Effects of sex and age on den site use by Scandinavian brown bears. Ursus 20: 8593. 10.2192/09gr005.1Google Scholar
Elfström, M., Swenson, J. E. & Ball, J. P. (2008). Selection of denning habitats by Scandinavian brown bears Ursus arctos. Wildlife Biology 14(2): 176187.Google Scholar
Elfström, M., Davey, M. L., Zedrosser, A., et al. (2014a). Do Scandinavian brown bears approach settlements to obtain high-quality food? Biological Conservation 178: 128135.Google Scholar
Elfström, M., Zedrosser, A., Støen, O.-G. & Swenson, J. E. (2014b). Ultimate and proximate mechanisms underlying the occurrence of bears close to human settlements: review and management implications. Mammal Review 44: 518.Google Scholar
Elfström, M., Zedrosser, A., Jerina, K., et al. (2014c). Does despotic behavior or food search explain the occurrence of problem brown bears in Europe? Journal of Wildlife Management 78: 881893.Google Scholar
Festa-Bianchet, M. (2003). Exploitative wildlife management as a selective pressure for life-history evolution of large mammals. In: Apollonio, M. & Festa-Bianchet, M. (Eds.), Animal behavior and wildlife conservation (pp. 191207). Washington, DC: Island Press.Google Scholar
Haemig, P. D. (1992). Competition between ants and birds in a Swedish forest. Oikos 65: 479483.Google Scholar
Haemig, P. D. (1994). Effect of ants on the foraging of birds in spruce trees. Oecologia 97: 3540.Google Scholar
Herrero, S. (1985). Bear attacks. Their causes and avoidance. New York, NY: Lyons Press.Google Scholar
Herrero, S., Smith, T., DeBruyn, T. D., Gunther, K. & Matt, C. A. (2005). Brown bear habituation to people – safety, risks, and benefits. Wildlife Society Bulletin 33: 362373.Google Scholar
Hertel, A. G., Zedrosser, A., Mysterud, A., et al. (2016). Temporal effects of hunting on foraging behavior of an apex predator: do bears forgo foraging when risk is high? Oecologia 182: 10191029.Google Scholar
Hoekstra, J. M., Boucher, T. M., Ricketts, T. H. & Roberts, C. (2005). Confronting a biome crisis: global disparities of habitat loss and protection. Ecology Letters 8: 2329.Google Scholar
Jacobs, M., Vaske, J. J., Dubois, S. & Fehres, P. (2014). More than fear: role of emotions in acceptability of lethal control of wolves. European Journal of Wildlife Research 60: 589598.Google Scholar
Johansson, M. & Karlsson, J. (2011). Subjective experience of fear and the cognitive interpretation of large carnivores. Human Dimensions of Wildlife 16: 1529.Google Scholar
Johansson, M., Ferreira, I., Støen, O.-G., Frank, J. & Flykt, A. (2016). Targeting human fear of large carnivores – many ideas but few known effects. Biological Conservation 20: 261269.Google Scholar
Johansson, M., Flykt, A., Frank, J. & Støen, O.-G. (2019). Controlled exposure reduces fear of brown bears. Human Dimensions of Wildlife 24: 363379. DOI:10.1080/10871209.2019.1616238.Google Scholar
Johnson, H. E., Breck, S. W., Baruch-Mordo, S., et al. (2015). Shifting perceptions of risk and reward: dynamic selection for human development by black bears in the western United States. Biological Conservation 187: 164172.Google Scholar
Kaczensky, P. (1997) Large carnivore depredation on livestock in Europe. Ursus 11: 5972.Google Scholar
Kaczensky, P., Huber, D., Knauer, F., et al. (2006). Activity patterns of brown bears (Ursus arctos) in Slovenia and Croatia. Journal of Zoology 269: 474485.Google Scholar
Kavcic, I., Adamic, M., Kaczensky, P., Krofel, M. & Jerina, K. (2013). Supplemental feeding with carrion is not reducing brown bear depredations on sheep in Slovenia. Ursus 24: 111119.Google Scholar
Kilpelainen, J., Finér, L., Neuvonen, S., et al. (2009). Does the mutualism between wood ants (Formica rufa group) and Cinara aphids affect Norway spruce growth? Forest Ecology and Management 257: 238243.Google Scholar
Knopff, A. A., Knopff, K. H., Boyce, M. S. & St Clair, C. C. (2014). Flexible habitat selection by cougars in response to anthropogenic development. Biological Conservation 178: 136145.Google Scholar
Kopatz, A, Eiken, H. G., Aspi, J., et al. (2014). Admixture and gene flow from Russia in the recovering northern European brown bear (Ursus arctos). PLoS ONE 9: e97558.Google Scholar
Laundré, J. W., Hernández, L. & Altendorf, K. B. (2001). Wolves, elk, and bison: reestablishing the “landscape of fear” in Yellowstone National Park, U.S.A. Canadian Journal of Zoology 79: 14011409.Google Scholar
Lima, S. L. (1998). Nonlethal effects in the ecology of predator–prey interactions. BioScience 48: 2534.Google Scholar
Linnell, J. D. C., Swenson, J. & Andersen, R. (2001). Predators and people: conservation of large carnivores is possible at high human densities if management policy is favourable. Animal Conservation 4: 345350.Google Scholar
Lodberg-Holm, H. K., Wathne Gelink, H., Hertel, A. G., et al. (2019). Hunting creates a landscape of fear that influences foraging tactics of brown bears. Basic and Applied Ecology 35: 1827.Google Scholar
Mace, R. D., Waller, J. S., Manley, T. L., Lyon, L. J. & Zuuring, H. (1996). Relationships among grizzly bears, roads and habitat in the Swan Mountains, Montana. The Journal of Applied Ecology 33: 1395.Google Scholar
Machutchon, A. G., Himmer, S., Davis, H. & Gallagher, M. (1998). Temporal and spatial activity patterns among coastal bear populations. Ursus 10: 539546.Google Scholar
Manfredo, M. J. (2008). Who cares about wildlife? Social science concepts for exploring human wildlife relationships and conservation issues. New York, NY: Springer.Google Scholar
Martin, J., Basille, M., Van Moorter, B., et al. (2010). Coping with human disturbance: spatial and temporal tactics of the brown bear (Ursus arctos). Canadian Journal of Zoology 88: 875883.Google Scholar
McLellan, B. N. & Shackleton, D. M. (1989). Immediate reactions of grizzly bears to human activities. Wildlife Society Bulletin 17: 269274.Google Scholar
Moen, G. K. (2018). Human-mediated effects on brown bear behavior and potential cascading effects. PhD thesis, Faculty of Environmental Sciences and Natural Resource Management, Norwegian University of Life Sciences, Ås, Norway.Google Scholar
Moen, G. K., Støen, O.-G., Sahlén, V. & Swenson, J. E. (2012). Behaviour of solitary adult Scandinavian brown bears (Ursus arctos) when approached by humans on foot. PLoS ONE 7: e31699.Google Scholar
Moen, G., Ordiz, A., Kindberg, J., et al. (2019). Behavioral reactions of brown bears to approaching humans in Fennoscandia. Écoscience 26: 2333. DOI: 10.1080/11956860.2018.1513387Google Scholar
Mueller, C., Herrero, S. & Gibeau, M. L. (2004). Distribution of subadult grizzly bears in relation to human development in the Bow River Watershed, Alberta. Ursus 15: 3547.Google Scholar
Mysterud, A. (2011). Selective harvesting of large mammals: how often does it result in directional selection? Journal of Applied Ecology 48: 827834.Google Scholar
Nellemann, C., Støen, O.-G., Kindberg, J., et al. (2007). Terrain use by an expanding brown bear population in relation to age, recreational resorts and human settlements. Biological Conservation 138: 157165.Google Scholar
Nielsen, S. E., Munro, R. H. M., Bainbridge, E. L., Stenhouse, G. B. & Boyce, M. S. (2004). Grizzly bears and forestry: II. Distribution of grizzly bear foods in clearcuts of west-central Alberta, Canada. Forest Ecology and Management 199: 6782.Google Scholar
Olson, T. L., Squibb, R. C. & Gilbert, B. K. (1998). Brown bear diurnal activity and human use: a comparison of two salmon streams. Ursus 10: 547555.Google Scholar
Ordiz, A., Støen, O.-G., Delibes, M. & Swenson, J. E. (2011). Predators or prey? Spatio-temporal discrimination of human-derived risk by brown bears. Oecologia 166: 5967.Google Scholar
Ordiz, A., Støen, O.-G., Sæbø, S., et al. (2012). Do bears know they are being hunted? Biological Conservation 152: 2128.Google Scholar
Ordiz, A., Støen, O.-G., Sæbø, S., et al. (2013). Lasting behavioural responses of brown bears to experimental encounters with humans. Journal of Applied Ecology 50: 306314.Google Scholar
Ordiz, A., Kindberg, J., Sæbø, S., Swenson, J. E. & Støen, O.-G. (2014). Brown bear circadian behavior reveals human environmental encroachment. Biological Conservation 173: 19.Google Scholar
Ordiz, A., Støen, O.-G., Delibes, M. & Swenson, J. E. (2017). Staying cool or staying safe in a human-dominated landscape: which is more relevant for brown bears? Oecologia 185: 191194.Google Scholar
Ordiz, A., Moen, G. K., Sæbo, S., et al. (2019). Habituation, sensitization, or consistent behavioral responses? Brown bear responses after repeated approaches by humans on foot. Biological Conservation 232: 228237.Google Scholar
Penteriani, V., Delgado, M. del M., Pinchera, F., et al. (2016). Human behaviour can trigger large carnivore attacks in developed countries. Scientific Reports 6: 20552.Google Scholar
Penteriani, V., López-Bao, J. V., Bettega, C., et al. (2017). Consequences of brown bear viewing tourism: a review. Biological Conservation 206: 169180.Google Scholar
Penteriani, V., Delgado, M. del M., Krofel, M., et al. (2018). Evolutionary and ecological traps for brown bears Ursus arctos in human-modified landscapes. Mammal Review 48: 180193.Google Scholar
Petram, W., Knauer, F. & Kaczensky, P. (2004). Human influence on the choice of winter dens by European brown bears in Slovenia. Biological Conservation 119: 129136.Google Scholar
Proaktor, G., Coulson, T. & Milner-Gulland, E. J. (2007). Evolutionary responses to harvesting in ungulates. Journal of Animal Ecology 76: 669678.Google Scholar
Proctor, M., McLellan, B., Boulanger, J., et al. (2010). Ecological investigations of grizzly bears in Canada using DNA from hair, 1995–2005: a review of methods and progress. Ursus 21: 169188.Google Scholar
Pulliainen, E. (1983). Behaviour of an expanding population of the brown bear (Ursus arctos) in northern Europe. Zeitschrift für Säugetierkunde 48: 290297.Google Scholar
Rode, K. D., Farley, S. D. & Robbins, C. T. (2006). Behavioral responses of brown bears mediate nutritional effects of experimentally introduced tourism. Biological Conservation 133: 7080.Google Scholar
Roth, H. U. (1983). Diel activity of a remnant population of European brown bears. International Conference on Bear Research and Management 5: 223229.Google Scholar
Røskaft, E., Bjerke, T., Kaltenborn, B., Linnell, J. D. C. & Andersen, R. (2003). Patterns of self-reported fear towards large carnivores among the Norwegian public. Evolution and Human Behavior 24: 184198.Google Scholar
Sahlén, E., Støen, O.-G. & Swenson, J. E. (2011). Brown bear den site concealment in relation to human activity in Sweden. Ursus 22(2): 152158.Google Scholar
Sahlén, V., Ordiz, A., Swenson, J. E. & Støen, O.-G. (2015a). Behavioural differences between single Scandinavian brown bears (Ursus arctos) and females with dependent young when experimentally approached by humans. PLoS ONE 10: e0121576.Google Scholar
Sahlén, V., Friebe, A., Sæbø, S., Swenson, J. E. & Støen, O.-G. (2015b). Den entry behavior in Scandinavian brown bears: implications for preventing human injuries. Journal of Wildlife Management 79(2): 274287.Google Scholar
Selva, N., Teitelbaum, C. S., Sergiel, A., et al. (2017). Supplementary ungulate feeding affects movement behavior of brown bears. Basic and Applied Ecology 24: 6876.Google Scholar
Sorensen, A. A., Stenhouse, G. B., Bourbonnais, M. L. & Nelson, T. A. (2015). Effects of habitat quality and anthropogenic disturbance on grizzly bear (Ursus arctos horribilis) home-range fidelity. Canadian Journal of Zoology 93: 857865.Google Scholar
Steyaert, S. M. J. G., Zedrosser, A., Elfström, M., et al. (2016). Ecological implications from spatial patterns in human-caused brown bear mortality. Wildlife Biology 22: 144152.Google Scholar
Stockan, J. & Robinson, E. J. H. (2016). Wood ant ecology and conservation. Cambridge, UK: Cambridge University Press.Google Scholar
Støen, O.-G., Ordiz, A., Evans, A. L., et al. (2015). Physiological evidence for a human-induced landscape of fear in brown bears (Ursus arctos). Physiology and Behavior 152: 244248.Google Scholar
Støen, O.-G., Ordiz, A., Sahlén, V., et al. (2018). Brown bear (Ursus arctos) attacks resulting in human casualties in Scandinavia 1977–2016; management implications and recommendations. PLoS ONE 13(5): e0196876. https://doi.org/10.1371/journal.pone.0196876.Google Scholar
Suring, L., Barber, K., Schwartz, C., et al. (1998). Analysis of cumulative effects on brown bears on the Kenai Peninsula, southcentral Alaska. Ursus 10: 107117.Google Scholar
Swenson, J. E., Wabakken, P., Sandegren, F., et al. (1995). The near extinction and recovery of brown bears in Scandinavia in relation to the bear management policies of Norway and Sweden. Wildlife Biology 1: 1125.Google Scholar
Swenson, J. E., Sandegren, F., Brunberg, S. & Wabakken, P. (1997). Winter den abandonment by brown bears Ursus arctos: causes and consequences. Wildlife Biology 3: 3538.Google Scholar
Swenson, J. E., Sandegren, F., Söderberg, A., et al. (1999). Interactions between brown bears and humans in Scandinavia. Biosphere Conservation 2: 19.Google Scholar
Swenson, J. E., Gerstl, N., Dahle, B. & Zedrosser, A. (2000). Action plan for the conservation of the brown bear in Europe (Ursus arctos). Strasbourg Cedex: Council of Europe Nature and Environment.Google Scholar
Swenson, J. E., Schneider, M., Zedrosser, A., et al. (2017). Challenges of managing a European brown bear population; lessons from Sweden, 1943–2013. Wildlife Biology 2017(4): wlb.00251.Google Scholar
Sæther, B. E., Engen, S., Swenson, J. E., Bakke, Ø. & Sandegren, F. (1998). Assessing the viability of Scandinavian brown bear, Ursus arctos, populations: the effects of uncertain parameter estimates. Oikos 83: 403416.Google Scholar
Thompson, R. F. (2009). Neurobiology of learning and memory habituation: a history. Neurobiology of Learning and Memory 92: 127134.Google Scholar
Van de Walle, J., Pigeon, G., Zedrosser, A., Swenson, J. E. & Pelletier, F. (2018). Hunting regulation favors slow life histories in a large carnivore. Nature Communications 9: 1100.Google Scholar
Wheat, R. E. & Wilmers, C. C. (2016). Habituation reverses fear-based ecological effects in brown bears (Ursus arctos). Ecosphere 7: 111.Google Scholar
Woodroffe, R. (2000). Predators and people: using human densities to interpret declines of large carnivores. Animal Conservation 3: 165173.Google Scholar
Woodroffe, R. & Ginsberg, J. R. (1998). Edge effects and the extinction of populations inside protected areas. Science 280: 21262128.Google Scholar
Zarzo-Arias, A., Delgado, M., Ordiz, A., et al. (2018). Brown bear behaviour in human-modified landscapes: the case of the endangered Cantabrian population, NW Spain. Global Ecology and Conservation 16: e00499.Google Scholar
Zedrosser, A., Steyaert, S. M. J. G., Gossow, H. & Swenson, J. E. (2011). Brown bear conservation and the ghost of persecution past. Biological Conservation 144: 21632170.Google Scholar

References

Balbontín, J., Penteriani, V. & Ferrer, M. (2005). Humans act against the natural process of breeder selection: a modern sickness for animal populations? Biodiversity and Conservation 14: 179186.Google Scholar
Benazzo, A., Trucchi, E., Cahill, J. A., et al. (2017). Survival and divergence in a small group: the extraordinary genomic history of the endangered Apennine brown bear stragglers. Proceedings of the National Academy of Sciences 114: E9589E0597.Google Scholar
Bischof, R., Swenson, J. E., Yoccoz, N. G., Mysterud, A. & Gimenez, O. (2009). The magnitude and selectivity of natural and multiple anthropogenic mortality causes in hunted brown bears. Journal of Animal Ecology 78: 656665.Google Scholar
Bonnet Lebrun, A.-S., Karamanlidis, A. A., De Gabriel Hernando, M., Renner, I. & Gimenez, O. (2020). Identifying priority conservation areas for recovering large carnivores using citizen science data. Animal Conservation 23: 8393.Google Scholar
Carter, N. H. & Linnell, J. D. C. (2016). Co-adaptation is key to coexisting with large carnivores. Trends in Ecology and Evolution 31: 575578.Google Scholar
Chapron, G., Kaczensky, P., Linnell, J. D. C., et al. (2014). Recovery of large carnivores in Europe’s modern human-dominated landscapes. Science 346: 15171519.Google Scholar
Ciucci, P. & Boitani, L. (2008). The Apennine brown bear: a critical review of its status and conservation problems. Ursus 19: 130145.Google Scholar
Ciucci,