Your search keyword '"Francesca Cagnacci"' showing total 8 results

1. Access to human-mobility data is essential for building a sustainable future

Author

Ruth Y. Oliver, Melissa Chapman, Diego Ellis-Soto, Vanessa Brum-Bastos, Francesca Cagnacci, Jed Long, Matthias-Claudio Loretto, Robert Patchett, and Christian Rutz

Subjects

Environmental sciences, GE1-350, Ecology, QH540-549.5

Abstract

Mobile devices, and other tracking technologies, generate detailed data on the movements and behavior of billions of people worldwide. At present, these data are predominantly used to pursue corporate interests. We argue that improving access to human-mobility data is essential for addressing urgent conservation and sustainability goals. Close collaboration between industry and the research community has the potential to generate substantive environmental and societal benefits.

Published

2024

2. Making the best of a hard job: A response to Nakashima (2022)

Author

Giacomo Santini, Milo Abolaffio, Federico Ossi, Barbara Franzetti, Francesca Cagnacci, and Stefano Focardi

Subjects

Ecology, QH540-549.5

Published

2022

3. Population assessment without individual identification using camera-traps: A comparison of four methods

Author

Giacomo Santini, Milo Abolaffio, Federico Ossi, Barbara Franzetti, Francesca Cagnacci, and Stefano Focardi

Subjects

Camera traps, Abundance estimation, Time-to-event, REST, Population monitoring, Association model, Ecology, QH540-549.5

Abstract

The use of camera traps to estimate population size when animals are not individually recognizable is gaining traction in the ecological literature, because of its applicability in population conservation and management.We estimated population size of synthetic animals with four camera trap sampling-based statistical models that do not rely on individual recognition. Using a realistic model of animal movement to generate synthetic data, we compared the random encounter model, the random encounter and staying time model, the association model and the time-to-event-model and we investigated the impact of violation of assumptions on the population size estimates.While under ideal conditions these models provide reliable population estimates, when synthetic animal movements were characterised by differences in speed (due to diverse behaviours such as locomotion, grazing and resting) none of the model provided both unbiased and precise density estimates. The random encounter model and the time-to-event-model provided precise results but tended to overestimate population size, while the random encounter and staying time model was less precise and tended to underestimate population size. Lastly, the association model was unable to provide precise results. We found that each tested model was very sensitive to the method used to estimate the range of the field-of-view of camera traps. Density estimates from both random encounter model and time-to-event-model were also very sensitive to biases in the estimate of animals’ speed. We provide guidelines on how to use these statistical models to get population size estimates that could be useful to wildlife managers and practitioners.

Published

2022

4. Animal movements occurring during COVID-19 lockdown were predicted by connectivity models

Author

Andrea Corradini, Wibke Peters, Luca Pedrotti, Mark Hebblewhite, Natalia Bragalanti, Clara Tattoni, Marco Ciolli, and Francesca Cagnacci

Subjects

Ursus arctos, Anthropause, Human mobility, Connectivity, Wildlife road crossing, Anthropogenic disturbance, Ecology, QH540-549.5

Abstract

Recent events related to the measures taken to control the spread of the Coronavirus (SARS-CoV-2) reduced human mobility (i.e. anthropause), potentially opening connectivity opportunities for wildlife populations. In the Italian Alps, brown bears have recovered after reintroduction within a complex anthropogenic matrix, but failed to establish a metapopulation due to reduced connectivity and human disturbance (i.e. infrastructure, land use, and human mobility). Previous work from Peters et al. (2015, Biol. Cons. 186, 123–133) predicted the main corridors and suitable hot spots for road network crossing for this population across all major roads and settlement zones, to link most suitable habitats. Bears used the identified hot spots for road network crossing over the years, but major barriers such as main motor roads were not overcome, possibly due to functional anthropogenic disturbance, specifically human mobility. By analyzing 404 bear occurrences reported to local authorities (as bear-related complaints) collected between 2016 and 2020 (March 9th - May 18th), hence including the COVID-19 related lockdown, we tested the effect of human presence on brown bears' use of space and hot spots for road network crossing. Animals occupied human-dominated spaces and approached hot spots for crossing at a higher rate during the lockdown than in previous years, suggesting that connectivity temporarily increased with reduced human mobility for this population. As a result of their increased use of hot spots, bears expanded their use of suitable areas beyond the population core area. Movement of animals across structural barriers such as roads and human settlements may therefore occur in absence of active disturbance. We also showed the value of predictive models to identify hot spots for animal barrier crossing, the knowledge of which is critical when implementing management solutions to enhance connectivity. Understanding the factors that influence immigration and emigration across metapopulations of large mammals, particularly carnivores that may compete indirectly with humans for space or directly as super-predators, is critical to ensure the long-term viability of conservation efforts for their persistence. We argue that dynamic factors such as human mobility may play a larger role than previously recognized.

Published

2021

5. Parasites and wildlife in a changing world: The vector-host- pathogen interaction as a learning case

Author

Annapaola Rizzoli, Valentina Tagliapietra, Francesca Cagnacci, Giovanni Marini, Daniele Arnoldi, Fausta Rosso, and Roberto Rosà

Subjects

Zoology, QL1-991

Abstract

In the Anthropocene context, changes in climate, land use and biodiversity are considered among the most important anthropogenic factors affecting parasites-host interaction and wildlife zoonotic diseases emergence. Transmission of vector borne pathogens are particularly sensitive to these changes due to the complexity of their cycle, where the transmission of a microparasite depends on the interaction between its vector, usually a macroparasite, and its reservoir host, in many cases represented by a wildlife vertebrate. The scope of this paper focuses on the effect of some major, fast-occurring anthropogenic changes on the vectorial capacity for tick and mosquito borne pathogens. Specifically, we review and present the latest advances regarding two emerging vector-borne viruses in Europe: Tick-borne encephalitis virus (TBEV) and West Nile virus (WNV). In both cases, variation in vector to host ratio is critical in determining the intensity of pathogen transmission and consequently infection hazard for humans. Forecasting vector-borne disease hazard under the global change scenarios is particularly challenging, requiring long term studies based on a multidisciplinary approach in a One-Health framework. Keywords: Anthropocene, Vector-borne diseases, Tick-borne encephalitis, West nile virus, Vectorial capacity, Vector to host ratio

Published

2019

6. Global COVID-19 lockdown highlights humans as both threats and custodians of the environment

Author

Francesca Cagnacci, Anastasios Bounas, Víctor Vázquez, Volen Arkumarev, Margarita Roa, Christopher J. Henderson, Neil Hammerschlag, Marc J. S. Hensel, Ian MacGregor-Fors, Catherine Hobaiter, Elijah Panipakoochoo, Gonzalo Mucientes, Million Tesfaye, Camilo E. Sánchez-Sarria, Dallas D'Silva, Grant Garner, Cloé Pourchier, Erin E. Posthumus, Zuania Colón-Piñeiro, Theresa M. Crimmins, Charlie Huveneers, Victor China, William D. Halliday, Avi Bar-Massada, Breyl X. K. Ng, Jennifer D. Reilly, Brendan J. Godley, Thibaud Gruber, Natalia Ocampo-Peñuela, Mitchell J. Rider, Lori Anne Barnett, Vladimir Dobrev, Nicholas D. Higgs, Christopher J. Patrick, Angélica Hernández-Palma, Kenneth B.H. Er, Rebecca A. Hutchinson, Harel Baz, Pia Anderwald, Marc Shellard, Camilo M. Botero, Sang Don Lee, Megan E. Hanna, Christopher D. Stallings, Yehezkel Buba, Pamela Carzon, Aroha Miller, David R. Barclay, Steffen Oppel, Juan Sebastian Ulloa, Víctor M. Eguíluz, Justin R. Perrault, Thomas A. Schlacher, Lisandro Benedetti-Cecchi, Victoria Saravia-Mullin, Nuno Queiroz, Fabio Bulleri, Zehava Sigal, Robert J. Orth, Jonas Hentati-Sundberg, Tomas J. Bird, Ron Chen, Jarod Lyon, Mengistu Wondafrash, Laurent Chauvaud, Gabriel Barros Gonçalves de Souza, Sarah J. L. Severino, Clive R. McMahon, Christian Requena-Mesa, Eulogio H. Soto, Amir Ayali, Jesse S. Lewis, Mark J. Costello, Miguel A. Furtado, Jessica P. Diaz-Orozco, Eleanor A. Weideman, Kyle Maclean, Frédéric LeTourneux, Lorenzo Sileci, Clementine Seguine, Sarah Abarro, Mackenzie B. Woods, David March, Qiang Yang, Katja Baerenfaller, Catherine M. Foley, Sharon Davidzon, David W. Sims, Ku'ulei S. Rodgers, Cheryl A. Frederick, Andrew G. Jeffs, Ohad Hatzofe, Yigael Ben Ari, Shmulik Yedvab, Cyril Piou, Gregory D. LeClair, Juan C. Franco Morales, Matthew G. Henderson, Cristian A. Cruz-Rodríguez, Ron Efrat, Tabi Karkom, Thomas A. Okey, Tudor Racoviceanu, Enrico Lunghi, Alazar Ruffo, Mohlamatsane M. Mokhatla, Ofer Yaakov, Stephanie M. Martin, Dobromir Dobrev, Matthew K. Pine, Dinusha R.M. Jayathilake, Antonia T. Cooper, Andrea Corradini, Eva Cacabelos, Yunior R. Velázquez, Amber Dearden, Iacopo Bertocci, Tal Gavriel, Sarah E. Hirsch, Elzbieta Kret, Meaghan E. Faletti, Matthew W. H. Chatfield, Lucy C. Woodall, Mary E. Clinton, Gal Badihi, Ilia Baskin, Carina Terry, Christopher G. Lowe, Joseph S. Curtis, Brandy S. Biggar, Nicole Esteban, Ellen G. Denny, Margot L. Hessing-Lewis, David Elustondo, Jeffrey Haight, Donna Gibbs, Robert L. Thomson, Maxim Larrivée, Matthew D. Adams, Camrin D. Braun, Mark G. Meekan, Brendan Connors, Avi Berkovitch, Jessica Schultz, Sigal Balshine, Lauren McWhinnie, Hanspeter Loetscher, Vicent Calatayud, Simon R. Thorrold, Christian Rutz, Nataliya A. Milchakova, Martin K.S. Smith, Stephanie K. Archer, Richard K. Dewey, Raoul Manenti, Kristina Boerder, Alon Penn, Ogen Licht, Susana Rodríguez-Buriticá, Zhu Liu, Rotem Sade, Michael B. Schrimpf, Nicola Koper, Rick D. Stuart-Smith, Austin J. Gallagher, Clayton T. Lamb, Reilly Rodriguez, Luca Pedrotti, Arjun Amar, Amanda E. Bates, Solomon Mengistu, Thierry Grandmont, Guojun He, Oliver N. Shipley, Sara N. Schaffer, Jorge P. Rodríguez, Cecilia Martin, Robin Hale, Simon A. Morley, Eyal Miller, Catherine Alexandra Gagnon, Sarah E. Dudas, Hyomin Park, Sally Hofmeyr, Paulson G. Des Brisay, Matthias-Claudio Loretto, Assaf Zvuloni, Elena Maggi, Jasmine A. Ballantyne, Susan J. Cunningham, Malcolm C.K. Soh, Elizabeth M. P. Madin, Sonja Wipf, David S. Hik, Stoyan C. Nikolov, Cameron J. Baker, Ben L. Gilby, Felipe A. Estela, Chiara Ravaglioli, Christophe Guinet, Alyssa Rosemartin, Lauren Dares, Gilles Gauthier, Michelle García-Arroyo, Luca Rindi, Oded Berger-Tal, Brendan D. Shea, Lucy Zipf, Michael S. Diamond, Shengjie Lai, Giann K. Aguirre-Samboní, Jennifer M. Jackson, Peter G. Ryan, Emily J. Southall, Kyle D. Kittelberger, Fabio C. De Leo, Jonathan Belmaker, Olof Olsson, Steven J. Cooke, Yuhang Pan, Rylan J. Command, Vincent Z. Kuuire, Kevin Wong, Reut Vardi, Xiangliang Zhang, Cristian Mihai Adamescu, Craig A. Radford, Enrique Arbeláez-Cortés, Andrew Graham, Joël Bêty, Charles Palmer, Yuval Zukerman, Miyako H. Warrington, Michael J. Schram, Amit Dolev, Orlando Acevedo-Charry, Claudio A. Quesada-Rodriguez, Kara R. Wall, Nikita Sergeenko, Celene B. Milanes, Jaein Choi, Paula Moraga, Jeff Switzer, Yenifer Herrera-Varón, Jonathan D. Midwood, Manor Gury, Amanda Weltman, Emiliano Mori, Thomas M. Clarke, Mai Lazarus, Jeffrey R. Parmelee, Petra Sumasgutner, Patrick T. Rex, Ziv Birman, Rodrigo Solis, Jennifer Chapman, Alejandro Bernal-Ibáñez, Vinay Udyawer, Itai Namir, David Ocampo, Justin A. Del Bel Belluz, Egide Kalisa, Reny P. Devassy, Pierre Legagneux, Jorge Ramírez-González, Jessleena Suri, Shelby R. Hoover, Michelle E. Taylor, Carlos M. Duarte, Ana F. L. Sobral, Graham J. Edgar, Francesc Peters, Philina A. English, Francis Juanes, Lisa C. Lacko, Marta Coll, Gentile Francesco Ficetola, Nicolas Moity, Emily Weigel, Nathan R. Geraldi, Jill L. Brooks, Philippe Archambault, Nicholas A. W. Brown, Julia Wakeling, Tanya Otero, Matt Rothendler, Shira Salingré, Laura Borden, Richard B. Primack, Veronica Nanni, Miqkayla Stofberg, Guy Lavian, Jacob W. Brownscombe, Samuel Bakari, Jonathan A. Peake, Andrew D. Olds, Paris V. Stefanoudis, Patricia S. Albano, Alexandre Alonso-Fernández, Seth G. Cherry, Juan Fernández-Gracia, Çağan H. Şekercioğlu, Shahar Malamud, Eric Clua, Jeannette Bedard, Dugald Thomson, Josip Kusak, Uri Roll, Louise Wilson, Craig E. Franklin, Roanna Y. T. Pang, Jose Manuel Ochoa-Quintero, Lina María Sánchez-Clavijo, Julien Bonnel, Sorin Cheval, Christine M. Boston, Mark A. Hindell, R. L. Marsh, Ruthy Yahel, Samuel Wiesmann, Frédéric Dulude de-Broin, Adrian H.B. Loo, Ross G. Dwyer, Takahiro Shimada, M. Ortega, Laura P. Kroesen, Ignacio Gestoso, Bibiana Gómez-Valencia, Valeria Vergara, Takanao Tanaka, Fiona Francis, Benjamin P. Y.-H. Lee, Delphine Mathias, Steven Mihaly, Kathleen L. Prudic, Alessia Scuderi, Dana Haggarty, Kent P. McFarland, Katharine L. Gerst, Paul B. Day, Vikram Aditya, Graeme C. Hays, Cerren Richards, Jeffrey A. Seminoff, Robert Harcourt, Matthew P. Stefanak, European Commission, Agencia Estatal de Investigación (España), Ministerio de Economía y Competitividad (España), Ministerio de Ciencia e Innovación (España), Department of Ocean Sciences [Newfoudland, Canada] (Memorial University of Newfoundland), Memorial University of Newfoundland (Memorial University of Newfoundland)-Department of Biology, Memorial University of Newfoundland, Gordon and Betty Moore Foundation, National Geographic Society, University of St Andrews. School of Biology, University of St Andrews. Centre for Biological Diversity, University of St Andrews. Centre for Social Learning & Cognitive Evolution, and Group, PAN-Environment Working

Subjects

0106 biological sciences, QH301 Biology, Politique sanitaire, Biodiversity, GF Human ecology. Anthropogeography, 01 natural sciences, 3rd-NDAS, Matematikk og Naturvitenskap: 400::Zoologiske og botaniske fag: 480::Zoogeografi: 486 [VDP], RA0421, RA0421 Public health. Hygiene. Preventive Medicine, Pandemic, Enforcement, GE, pandémie, évaluation de l'impact social, COVID-19, lockdown, human activity, wildlife, environmental treats, GF, Global monitoring, S50 - Santé humaine, Nature Conservation, Restoration, [SDE]Environmental Sciences, Conservation de la nature, P01 - Conservation de la nature et ressources foncières, Samfunnsvitenskap: 200::Samfunnsgeografi: 290 [VDP], GE Environmental Sciences, Coronavirus disease 2019 (COVID-19), Wildlife, 010603 evolutionary biology, Surveillance de l’environnement, Article, QH301, Matematikk og Naturvitenskap: 400::Zoologiske og botaniske fag: 480::Etologi: 485 [VDP], Dual role, SDG 3 - Good Health and Well-being, Settore BIO/07 - ECOLOGIA, Matematikk og Naturvitenskap: 400::Zoologiske og botaniske fag: 480::Økologi: 488 [VDP], 14. Life underwater, Environmental planning, Ecology, Evolution, Behavior and Systematics, Nature and Landscape Conservation, Custodians, 010604 marine biology & hydrobiology, Impact sur l'environnement, Évaluation de l'impact, 15. Life on land, Protection de l'environnement, 13. Climate action, Business, Gestion de l'environnement

Abstract

18 pages, 5 figures, supplementary data https://doi.org/10.1016/j.biocon.2021.109175.-- The data supporting the findings of this study are available in the Supplementary Materials (Appendix 3–5, Table A3-A5). Raw datasets (where available) and results summary tables for each analysis of human mobility and empirical datasets are deposited in a github repository: https://github.com/rjcommand/PAN-Environment, The global lockdown to mitigate COVID-19 pandemic health risks has altered human interactions with nature. Here, we report immediate impacts of changes in human activities on wildlife and environmental threats during the early lockdown months of 2020, based on 877 qualitative reports and 332 quantitative assessments from 89 different studies. Hundreds of reports of unusual species observations from around the world suggest that animals quickly responded to the reductions in human presence. However, negative effects of lockdown on conservation also emerged, as confinement resulted in some park officials being unable to perform conservation, restoration and enforcement tasks, resulting in local increases in illegal activities such as hunting. Overall, there is a complex mixture of positive and negative effects of the pandemic lockdown on nature, all of which have the potential to lead to cascading responses which in turn impact wildlife and nature conservation. While the net effect of the lockdown will need to be assessed over years as data becomes available and persistent effects emerge, immediate responses were detected across the world. Thus initial qualitative and quantitative data arising from this serendipitous global quasi-experimental perturbation highlights the dual role that humans play in threatening and protecting species and ecosystems. Pathways to favorably tilt this delicate balance include reducing impacts and increasing conservation effectiveness, The Canada Research Chairs program provided funding for the core writing team. Field research funding was provided by A.G. Leventis Foundation; Agence Nationale de la Recherche, [grant number ANR-18-32–0010CE-01 (JCJC PEPPER)]; Agencia Estatal de Investigaci; Agência Regional para o Desenvolvimento da Investigação Tecnologia e Inovação (ARDITI), [grant number M1420-09-5369-FSE-000002]; Alan Peterson; ArcticNet; Arkadaşlar; Army Corp of Engineers; Artificial Reef Program; Australia's Integrated Marine Observing System (IMOS), National Collaborative; Research Infrastructure Strategy (NCRIS), University of Tasmania; Australian Institute of Marine Science; Australian Research Council, [grant number LP140100222]; Bai Xian Asia Institute; Batubay Özkan; BC Hydro Fish and Wildlife Compensation Program; Ben-Gurion University of the Negev; Bertarelli Foundation; Bertarelli Programme in Marine Science; Bilge Bahar; Bill and Melinda Gates Foundation; Biology Society of South Australia; Boston University; Burak Över; California State Assembly member Patrick O'Donnell; California State University Council on Ocean Affairs, Science & Technology; California State University Long Beach; Canada Foundation for Innovation (Major Science Initiative Fund and funding to Oceans Network Canada), [grant number MSI 30199 for ONC]; Cape Eleuthera Foundation; Centre National d'Etudes Spatiales; Centre National de la Recherche Scientifique; Charles Darwin Foundation, [grant number 2398]; Colombian Institute for the Development of Science and Technology (COLCIENCIAS), [grant number 811–2018]; Colombian Ministry of Environment and Sustainable Development, [grant number 0041–2020]; Columbia Basin Trust; Commission for Environmental Cooperation; Cornell Lab of Ornithology; Cultural practices and environmental certification of beaches, Universidad de la Costa, Colombia, [grant number INV.1106–01–002-15, 2020–21]; Department of Conservation New Zealand; Direction de l'Environnement de Polynésie Française; Disney Conservation Fund; DSI-NRF Centre of; Excellence at the FitzPatrick Institute of African Ornithology; Ecology Project International; Emin Özgür; Environment and Climate Change Canada; European Community: RTD programme - Species Support to Policies; European Community's Seventh Framework Programme; European Union; European Union's Horizon 2020 research and innovation programme, Marie Skłodowska-Curie, [grant number 798091, 794938]; Faruk Eczacıbaşı; Faruk Yalçın Zoo; Field research funding was provided by King Abdullah University of Science and Technology; Fish and Wildlife Compensation Program; Fisheries and Oceans Canada; Florida Fish and Wildlife Conservation Commission, [grant numbers FWC-12164, FWC-14026, FWC-19050]; Fondo Europeo de Desarrollo Regional; Fonds québécois de la recherche nature et technologies; Foundation Segré; Fundação para a Ciência e a Tecnologia (FCT Portugal); Galapagos National Park Directorate research, [grant number PC-41-20]; Gordon and Betty Moore Foundation, [grant number GBMF9881 and GBMF 8072]; Government of Tristan da Cunha; Habitat; Conservation Trust Foundation; Holsworth Wildlife Research Endowment; Institute of Biology of the Southern Seas, Sevastopol, Russia; Instituto de Investigación de Recursos Biológicos Alexander von Humboldt; Instituto Nacional de Pesquisas Espaciais (INPE), Brazil; Israeli Academy of Science's Adams Fellowship; King Family Trust; Labex, CORAIL, France; Liber Ero Fellowship; LIFE (European Union), [grant number LIFE16 NAT/BG/000874]; María de Maeztu Program for Units of Excellence in R&D; Ministry of Science and Innovation, FEDER, SPASIMM,; Spain, [grant number FIS2016–80067-P (AEI/FEDER, UE)]; MOE-Korea, [grant number 2020002990006]; Mohamed bin Zayed Species Conservation Fund; Montreal Space for Life; National Aeronautics and Space Administration (NASA) Earth and Space Science Fellowship Program; National Geographic Society, [grant numbers NGS-82515R-20]; National Natural Science Fund of China; National Oceanic and Atmospheric Administration; National Parks Board, Singapore; National Science and Technology Major Project of China; National Science Foundation, [grant number DEB-1832016]; Natural Environment Research Council of the UK; Natural Sciences and Engineering Research Council of Canada (NSERC), Alliance COVID-19 grant program, [grant numbers ALLRP 550721–20, RGPIN-2014-06229 (year: 2014), RGPIN-2016-05772 (year: 2016)]; Neiser Foundation; Nekton Foundation; Network of Centre of Excellence of Canada: ArcticNet; North Family Foundation; Ocean Tracking Network; Ömer Külahçıoğlu; Oregon State University; Parks Canada Agency (Lake Louise, Yoho, and Kootenay Field Unit); Pew Charitable Trusts; Porsim Kanaf partnership; President's International Fellowship Initiative for postdoctoral researchers Chinese Academy of Sciences, [grant number 2019 PB0143]; Red Sea Research Center; Regional Government of the Azores, [grant number M3.1a/F/025/2015]; Regione Toscana; Rotary Club of Rhinebeck; Save our Seas Foundation; Science & Technology (CSU COAST); Science City Davos, Naturforschende Gesellschaft Davos; Seha İşmen; Sentinelle Nord program from the Canada First Research Excellence Fund; Servizio Foreste e Fauna (Provincia Autonoma di Trento); Sigrid Rausing Trust; Simon Fraser University; Sitka Foundation; Sivil Toplum Geliştirme Merkezi Derneği; South African National Parks (SANParks); South Australian Department for Environment and Water; Southern California Tuna Club (SCTC); Spanish Ministry for the Ecological Transition and the Demographic Challenge; Spanish Ministry of Economy and Competitiveness; Spanish Ministry of Science and Innovation; State of California; Sternlicht Family Foundation; Suna Reyent; Sunshine Coast Regional Council; Tarea Vida, CEMZOC, Universidad de Oriente, Cuba, [grant number 10523, 2020]; Teck Coal; The Hamilton Waterfront Trust; The Ian Potter Foundation, Coastwest, Western Australian State NRM; The Red Sea Development Company; The Wanderlust Fund; The Whitley Fund; Trans-Anatolian Natural Gas Pipeline; Tula Foundation (Hakai Institute); University of Arizona; University of Pisa; US Fish and Wildlife Service; US Geological Survey; Valencian Regional Government; Vermont Center for Ecostudies; Victorian Fisheries Authority; VMRC Fishing License Fund; and Wildlife Warriors Worldwide, With funding from the Spanish government through the ‘Severo Ochoa Centre of Excellence’ accreditation (CEX2019-000928-S

Published

2021

7. Effects of cumulated outdoor activity on wildlife habitat use

Author

Luca Pedrotti, Francesco Rovero, Marco Ciolli, E. Emiel van Loon, Clara Tattoni, Francesca Cagnacci, Andrea Corradini, Gioele Passoni, Matthias Randles, Valentina Oberosler, and Theoretical and Computational Ecology (IBED, FNWI)

Subjects

0106 biological sciences, Disturbance (geology), Population, Metapopulation, 010603 evolutionary biology, 01 natural sciences, Bio-logging, COI, Habitat selection, Human-wildlife conflict, Strava, Ursus arctos, Settore BIO/07 - ECOLOGIA, education, Ecology, Evolution, Behavior and Systematics, Nature and Landscape Conservation, Ecological niche, education.field_of_study, Land use, Human–wildlife conflict, Ecology, 010604 marine biology & hydrobiology, Land-use planning, Geography, Habitat

Abstract

Humans profoundly affect animal distributions by directly competing for space, not only transforming, but actively using their habitat. Anthropogenic disturbance is usually measured via structural proxies such as infrastructure and land use that overlook the impact of human presence, or functional disturbance. In this study, we propose a methodology unifying two paradigms, human mobility and animal movement, to fill this gap. We developed a novel spatially-explicit index of anthropic disturbance, the Cumulative Outdoor activity Index (COI), and validated it with ground truth observations derived from camera trapping (r = +0.63, p < 0.001). Building on previous work from Peters et al. (2015, Biol. Cons. 186, 123–133) on a Critically Endangered brown bear population in the Alps, we used Resource Selection Analysis to assess the influence of different forms of anthropogenic disturbance on the relative probability of habitat selection. The intensity of COI provided an effective measure of functional anthropogenic disturbance, and it outperformed all alternative and commonly-used proxies of structural disturbance in predicting bear habitat use. Our predictions suggest that brown bear shrinks its ecological niche as a consequence of intense human use of otherwise suitable habitat. These constraints may limit the potential range expansion of bears to establish a viable Alpine-Dinaric metapopulation. Conclusive conservation and future land use planning towards human-wildlife coexistence should account for the functional presence of humans on the landscape. The proposed COI could help determine where mitigation measures should be enforced.

Published

2021

8. Biologging and Remote-Sensing of Behavior

Author

Francesca Cagnacci, Ferdinando Urbano, and Federico Ossi

Subjects

Geography, Remote sensing (archaeology), Settore BIO/07 - ECOLOGIA, GPS telemetry, Camera trap, Loggers, Remote sensing

Published

2019