Hostname: page-component-cd9895bd7-gbm5v Total loading time: 0 Render date: 2024-12-22T11:40:29.208Z Has data issue: false hasContentIssue false

Transdisciplinarity, tempocoupling, and the role of culture in zoonosis research

Published online by Cambridge University Press:  14 February 2024

Denise Margaret S. Matias*
Affiliation:
Center for Development Research, University of Bonn, Bonn, Germany Eberswalde University for Sustainable Development, Eberswalde, Germany Non-Timber Forest Products Exchange Programme Asia, Quezon City, Philippines

Abstract

Non-technical summary

The general public became familiar with the term and definition of zoonosis during the COVID-19 pandemic. Because of the pandemic, several responses to mitigate zoonotic risk has been put forward. Often cited are stricter biodiversity conservation and wildlife protection but there are also suggestions to educate people who traditionally consume wildlife for food. This implicit condemnation of culture also manifested explicitly in the form of racism especially against Asians during the height of the pandemic. If the world is to avoid a pandemic, it also needs to work against Orientalism and ensure research is inclusive, equitable, and just.

Technical summary

The COVID-19 pandemic widely introduced the term and definition of zoonosis to the general public. More than just a knee-jerk reaction, stricter biodiversity conservation and wildlife protection are now seen as essential strategies in mitigating zoonotic risks while some researchers have called for education campaigns that should discredit ingrained cultural practices such as wildlife consumption. This implicit condemnation of culture may have been initially confined to research papers but it eventually manifested as explicit racism in everyday life during the height of the pandemic, highlighting the need to decolonize Western scientific views on pandemic prevention and to refrain from Orientalism. This Intelligence Briefing makes the case for the inclusion of history and culture as necessary elements in zoonosis research alongside a critical reflection of transdisciplinary approaches. Emphasizing epistemic humility and authentic interest to learn from other actors such as Indigenous communities on the frontlines of human-wildlife interfaces, this Intelligence Briefing recommends the Future Earth Health Knowledge-Action Network to stay the course toward promoting approaches that are ‘transdisciplinary, multi-scalar, inclusive, equitable, and broadly communicated’ in zoonosis research.

Social media summary

History and culture are necessary elements of zoonosis research alongside transdisciplinary approaches.

Type
Intelligence Briefing
Creative Commons
Creative Common License - CCCreative Common License - BYCreative Common License - NC
This is an Open Access article, distributed under the terms of the Creative Commons Attribution-NonCommercial licence (http://creativecommons.org/licenses/by-nc/4.0), which permits non-commercial re-use, distribution, and reproduction in any medium, provided the original article is properly cited. The written permission of Cambridge University Press must be obtained prior to any commercial use.
Copyright
Copyright © The Author(s), 2024. Published by Cambridge University Press

The COVID-19 pandemic widely introduced the term and definition of zoonosis to the general public. People became aware that wildlife can be potential hosts of infectious bacteria and viruses. Early on, two mammalian species were singled out as sources of SARS-CoV-2, with bats as the reservoir and pangolins as the intermediate host alongside discovery of a wet market in Wuhan (China) as the epicenter of COVID-19 (Andersen et al., Reference Andersen, Rambaut, Lipkin, Holmes and Garry2020; Lam et al., Reference Lam, Jia, Zhang, Shum, Jiang, Zhu, Tong, Shi, Ni, Liao, Li, Jiang, Wei, Yuan, Zheng, Cui, Li, Pei, Qiang and Cao2020). While research on the definitive sources of SARS-CoV-2 is still ongoing as of this writing, there is now a broader consensus on previous scientific advice to implement zoonotic surveillance as a pandemic risk mitigation plan (Morse et al., Reference Morse, Mazet, Woolhouse, Parrish, Carroll, Karesh, Zambrana-Torrelio, Lipkin and Daszak2012; Wu, Reference Wu2023; Xiao et al., Reference Xiao, Newman, Buesching, Macdonald and Zhou2021). More than just a knee-jerk reaction, stricter biodiversity conservation and wildlife protection are now seen as essential strategies in mitigating zoonotic risks; corollary to these are restrictions on wildlife use such as consumption albeit in a culturally-sensitive manner (Alonso Aguirre et al., Reference Alonso Aguirre, Basu, Kahn, Morin, Echaubard, Wilcox and Beasley2019; Dobson et al., Reference Dobson, Pimm, Hannah, Kaufman, Ahumada, Ando, Bernstein, Busch, Daszak, Engelmann, Kinnaird, Li, Loch-Temzelides, Lovejoy, Nowak, Roehrdanz and Vale2020). Indeed, some researchers from high-income countries have called for ‘wisely directed education campaigns that aim to discredit ingrained cultural beliefs’ in order to discourage wildlife consumption in China (Ribeiro et al., Reference Ribeiro, Bingre, Strubbe and Reino2020). Recommendations such as these, on the one hand, recognize the social-ecological nature of zoonosis while blaming social systems and its cultural beliefs, on the other hand. This implicit condemnation of culture may have been initially confined to research papers but it eventually manifested as explicit racism in everyday life during the height of the pandemic. This eventually prompted United Nations Secretary General António Guterres to make a global appeal to ‘end the virus of hate’ against Chinese and other Asians due to China being the epicenter of COVID-19 (HRW, 2020). Several researchers also weighed in against the neocolonial and paternalistic recommendations being put forward by peers. This highlighted the need to decolonize Western scientific views on pandemic prevention and to refrain from Orientalism or the ‘corporate institution for dealing with the Orient – (…) making statements about it, authorizing views of it, describing it, by teaching it, settling it, ruling over it: in short, (…) a Western style for dominating, restructuring, and having authority over the Orient’ (Pagani-Núñez, Reference Pagani-Núñez2020; Said, Reference Said1978; Schneider et al., Reference Schneider, Matias, Burkhart, Drees, Fickel, Hummel, Liehr, Schramm and Mehring2021). Apart from this, historical dynamics in low-income and middle-income countries where colonial medicine enabled vaccine clinical trials abuse impacted vaccination as a pandemic response (Mutombo et al., Reference Mutombo, Fallah, Munodawafa, Kabel, Houeto, Goronga, Mweemba, Balance, Onya, Kamba, Chipimo, Kayembe and Akanmori2022). It, therefore, becomes necessary to incorporate diverse knowledge and perspectives and respect historical dynamics and cultural practices in order for pandemic prevention to be transdisciplinary (Jahn et al., Reference Jahn, Bergmann and Keil2012).

1. Zoonosis and transdisciplinarity

The issue of zoonosis is loaded with social and ecological entanglements that require both interdisciplinary and transdisciplinary approaches. Transdisciplinarity has become more mainstream in recent years, with the International Science Council commissioning a discussion paper to closely look at the approach (ISC, 2023). This is a welcome development in signaling to the often more ‘powerful’ hard sciences to work with the social sciences, just as Future Earth has been advocating through its Global Research Networks in the past years (Malmer et al., Reference Malmer, Tengö, Fernandez-Llamazares Onrubia, Woodward, Crawhall, Hill, Trakansuphakon, Athayde, Carino, Crimella, Ferrari, Perez, Spencer, Trakansuphakon, Bicksler, Carino, Lengoisa, Lungharwo and Tahi2019). The Future Earth Health Knowledge-Action Network (KAN), launched right before the onset of the COVID-19 pandemic in 2019, developed a research agenda that calls for research approaches that are ‘transdisciplinary, multi-scalar, inclusive, equitable, and broadly communicated’ (Ebi et al., Reference Ebi, Harris, Sioen, Wannous, Anyamba, Bi, Boeckmann, Bowen, Cissé, Dasgupta, Dida, Gasparatos, Gatzweiler, Javadi, Kanbara, Kone, Maycock, Morse, Murakami and Capon2020). One example of a transdisciplinary approach in zoonosis was the PREDICT project under the United States Agency for International Development (USAID) Emerging Pandemic Threats (EPT-1) Program that worked in 20 countries in Africa, Asia, and Latin America. PREDICT engaged a wide range of actors from government, scientific institutions, and local groups for emerging infectious disease (EID) surveillance, diagnosis, viral evolution, and ecological driver identification (Kelly et al., Reference Kelly, Karesh, Johnson, Gilardi, Anthony, Goldstein, Olson, Machalaba, Mazet, Aguirre, Aguirre, Akongo, Robles, Ambu, Antonjaya, Aguilar, Barcena, Barradas, Bogich and Zimmerman2017). Indeed, there is no lack of papers mentioning how current zoonotic risk prevention measure are atomistic that mostly focus on ecological systems, rendering social systems as an afterthought and instead suggesting that a systems approach is necessary where zoonosis is tackled at a social-ecological interface (Schneider et al., Reference Schneider, Matias, Burkhart, Drees, Fickel, Hummel, Liehr, Schramm and Mehring2021). In the prevailing narrative on zoonosis, people especially those directly interacting with wildlife are inconvenient antagonists to wildlife species. However, these very same people could become convenient sources of local knowledge when it comes to implementing transdisciplinary approaches, underlining the need for inclusion of ethics and justice in transdisciplinarity to avoid the pitfall of tokenism and using people as a means to an end. Therefore, being reflexive and seeing people as an end in themselves could bring an appreciation toward efforts to understand how and why people interact with animals in and how these are important in the prevention and control of zoonoses (Friant et al., Reference Friant, Bonwitt, Ayambem, Ifebueme, Alobi, Otukpa, Bennett, Shea, Rothman, Goldberg and Jacka2022). Indigenous peoples whose human-wildlife interaction date back thousands of years have accumulated a huge store of knowledge about animals through the centuries and have closely integrated this knowledge in their cultural heritage (Alves & Souto, Reference Alves and Souto2015). More than just being causes of zoonosis (as was the case for COVID-19), culture should also be seen as a repository of solutions. Taboos such as in the Idu Mishmi community of Northeast India have been shown significantly reduce wild meat consumption, which has been identified as a zoonotic pathway (Nijhawan & Mihu, Reference Nijhawan and Mihu2023). Beyond the individual level is the collective influence of culture that can play a role in the risk of zoonosis: wild meat consumption can be either a cultural practice or a cultural taboo (Ortega et al., Reference Ortega, Ortega, Simón, Ortega, Ortega and Simón2022). There is, therefore, a case to be made for culture and history to become integral elements of zoonosis research.

2. Integrating culture and history in zoonosis research

The Intergovernmental Science-Policy Platform on Biodiversity and Ecosystem Services (IPBES) thematic assessment on the sustainable use of wild species highlighted how wild species are not only central to livelihoods of many IPLCs but also to their identities and cultural expressions (Fromentin et al., Reference Fromentin, Emery, Donaldson, Danner, Hallosserie, Kieling, Balachander, Barron, Chaudhary, Gasalla, Halmy, Hicks, Park, Parlee, Rice, Ticktin and Tittensor2022). The cultural aspect of human-wildlife interaction can pave the way toward examining the historical, economic, sociological, anthropological and environmental aspects of the relationships between humans and wild species like the bats or pangolins found in the wet market in Wuhan (Alves & Souto, Reference Alves and Souto2015). Medical anthropologists have been questioning the role of culture in zoonotic transmission (Keck & Lynteris, Reference Keck and Lynteris2018), with culture again seen as a cause rather than a solution, but if a step back is taken and judgment is postponed, it can be seen that culture is useful as an archive because culture also evolves alongside economic, environmental, and political changes. By recognizing culture as dynamic and ever-evolving, we avoid perpetuating static cultural stereotypes while at the same time promote recognition of generational or individual human agency in determining social structures. Within the realm of zoonosis research, this requires the expertise of historians (through archival research) and even archeologists (through excavations) in unraveling historical human-wildlife interactions (e.g. Peters & Schmidt, Reference Peters and Schmidt2004). Working together with anthropologists, historians, and archeologists, zoonosis researchers can understand worldviews and values attached to human-wildlife interaction and understand the context (e.g. socio-political, economic, or environmental) where changes to human-wildlife interactions occurred. This highlights the importance of ‘re-engaging with multiple dimensions of time’ where extended timescales from the past and into the future are considered in backcasting and forecasting in zoonotic risk surveillance and management (Satterwhite et al., Reference Satterwhite, Sheridan and Miller2016). The concept of shifting baseline, mostly used in ecology, could be expanded to not only account for changing wildlife species abundance through time but also for evolving human-wildlife interactions (Hanazaki et al., Reference Hanazaki, Herbst, Marques and Vandebroek2013; Pauly, Reference Pauly1995).

3. Using the concept of tempocoupling in zoonosis research

The concept of ‘telecoupling’ is a useful framework to understand how distant interactions such as international trade and land use changes are interconnected and create feedback across multiple scales (Hull & Liu, Reference Hull and Liu2018). Telecoupling explains how demand for pangolin from upper-middle-income countries such as China has driven illegal trade in a lower-middle-income country like Nigeria (Omifolaji et al., Reference Omifolaji, Ikyaagba, Jimoh, Ibrahim, Ahmad and Luan2020). Nevertheless, there are also interconnections on a temporal scale where effects echo through time. These are often discussed in research dealing with ‘historical’ impacts or dynamics, which could explain persistent social-ecological phenomena. In order to capture this and incorporate temporal feedback, the term ‘tempocoupling’ can expand the telecoupling concept and could be especially useful for problem definition and unearthing sustainability solutions from the past (Matias, Reference Matias2020). We have to be mindful that not all societies move at the same pace and this is why E.F. Schumacher in his nominal book ‘Small is Beautiful’ proposed the idea of intermediate technologies, which are more productive than indigenous ones but is significantly cheaper than the highly-capital intensive technologies of modern industry. E.F. Schumacher (Reference Schumacher1973) emphasized the need for innovations and technologies to be appropriate and suited to local conditions; a reminder from half-a-century ago to move away from blanket paternalistic solutions that are often pushed as necessary innovations. Therefore, when creating present zoonotic risk mitigation plans, it is important to take a look back and learn how previous communities adapted to zoonotic risk or zoonotic episodes. In the pursuit of transdisciplinarity in zoonosis research, we must exercise epistemic humility and sincerely believe that we can also learn from actors such as Indigenous peoples and local communities who have since been infantilized and seen as people who needs to be taught how to handle wild species; they have long been interacting with these species, who are we mostly living within four-walled offices or laboratories to tell them how to do so?

4. The pursuit of social-ecological justice in conservation of potential zoonotic host species

‘Ang hindi marunong lumingon sa pinanggagalingan ay hindi makakarating sa pinaroroonan.’ (A person who does not know how to look back at where they came from will never get to their destination.) – this is a quote often attributed to Dr. Jose Rizal (1861–1896), the national hero of the Philippines, which is one of the countries hosting endemic pangolin species. All eight known pangolin species in the world (four species from Asia and four species from Sub-Saharan Africa) are listed under Appendix I of the Convention on International Trade in Endangered Species of Wild Flora and Fauna (CITES) or the most endangered CITES-limited animals and plants. With most efforts toward conservation being regulatory top-down or ‘command and control’ policies, it is not surprising that these are failing such as in Southeast Asia (Blair et al., Reference Blair, Le, Sethi, Thach, Nguyen, Amato, Birchette and Sterling2017). The same can be said for West and African states such as in Nigeria where there was an increased frequency of pangolin poaching incidents despite the CITES regulation (Omifolaji et al., Reference Omifolaji, Ikyaagba, Jimoh, Ibrahim, Ahmad and Luan2020). Conservation policies fail to take into consideration that the complexity of wildlife trade, in part, stems from traditional uses and cultural values relating to wildlife and wildlife products (Blair et al., Reference Blair, Le, Sethi, Thach, Nguyen, Amato, Birchette and Sterling2017). In the case of the Philippine pangolin (Manis culionensis), it is now illegal to collect these animals but from a historical perspective we see that it has not always been the case. There are indigenous rights to wildlife collection enshrined in law, but Indigenous peoples in the Philippines were still included in the blanket ban on hunting of the Philippine pangolin. In the La Amistad Biosphere Reserve in Costa Rica, protected area regulations heavily restrict wildlife hunting, which is part of traditional food access (Sylvester et al., Reference Sylvester, Segura and Davidson-Hunt2016). As a powerful index of social, political, and economic inequality, ‘illegality’ and ‘illegalization’ should be investigated not in opposition to, but alongside studies of the state, power, ethics, and the law. Moreover, power dynamics also influences which actor is openly ‘named and shamed’ similar to how the indigenous Palaw'an and Tagbanua groups were called poachers in a feature article on the environmental website Mongabay (see Abano, Reference Abano2019). As pointed out by Thomas and Galemba (Reference Thomas and Galemba2013), social marginalization of people, places, and practices is often part of what makes ‘illegality’ come to seem like an objective, even commensensical, attribute. On the flip side, there are also ‘command and control’ policies that cause further endangerment of species such as the mass culling of bats such as in Australia, Mauritius, and Thailand purportedly to minimize fruit depredation (Florens & Baider, Reference Florens and Baider2019; O'Shea et al., Reference O'Shea, Cryan, Hayman, Plowright and Streicker2016). Top-down policies should be challenged; we should do away with instantly labeling actors as law breakers especially the downstream ones who are on the frontlines directly interacting with nature and wildlife. By adopting judgment, we automatically assign bias that may render us blind to distal underlying factors influencing potential zoonosis. If we go back to the research agenda of Future Earth's Health KAN that aims to promote research approaches that are ‘transdisciplinary, multi-scalar, inclusive, equitable, and broadly communicated,’ we find that these are essential in moving toward the next decade of sustainability research and innovation. To be (1) transdisciplinary is to see every relevant actor as partners and equals in designing, implementing, and communicating research projects; to be (2) multi-scalar is to consider distant scales such as in telecoupling (geographical scales) and tempocoupling (temporal scales) in the past and in the future for zoonotic risk monitoring and surveillance; to be (3) inclusive and equitable is to approach zoonotic research reflexively where positionalities, privilege, and power are duly acknowledged and both technical and traditional knowledge are respected; and to (4) communicate research broadly, we should aim to speak to all rungs of society and to contribute to culturally-appropriate local education (Matias et al., Reference Matias, Borgemeister and von Wehrden2018). In sum, the research agenda of Future Earth's Health KAN can be seen as one of the strategic catalysts for promoting zoonosis research that is genuinely transdisciplinary, holistic through space and time, and just.

Acknowledgements

I would like to thank the ZooMap teams at the Mongolian University of Life Sciences and Palawan State University for inspiring me to write this piece. I would also like to thank the Guest Editors of this Special Issue for their initial feedback on my abstract.

Author contributions

The article was solely conceptualized and written by the author.

Funding statement

Part of this work was supported by the Volkswagen Foundation (grant number 9B983 & 9C447).

Competing interest

None.

References

Abano, I. (2019, April 22). The extinction clock ticks for the little-known Philippine pangolin. https://news.mongabay.com/2019/04/the-extinction-clock-ticks-for-the-little-known-philippine-pangolin/Google Scholar
Alonso Aguirre, A., Basu, N., Kahn, L. H., Morin, X. K., Echaubard, P., Wilcox, B. A., & Beasley, V. R. (2019). Transdisciplinary and social-ecological health frameworks – novel approaches to emerging parasitic and vector-borne diseases. Parasite Epidemiology and Control, 4, e00084. https://doi.org/10.1016/J.PAREPI.2019.E00084CrossRefGoogle ScholarPubMed
Alves, R. R. N., & Souto, W. M. S. (2015). Ethnozoology: A brief introduction. Ethnobiology and Conservation, 4, 1. https://doi.org/10.15451/ec2015-1-4.1-1-13Google Scholar
Andersen, K. G., Rambaut, A., Lipkin, W. I., Holmes, E. C., & Garry, R. F. (2020). The proximal origin of SARS-CoV-2. Nature Medicine, 26(4), 450452. https://doi.org/10.1038/s41591-020-0820-9Google Scholar
Blair, M. E., Le, M. D., Sethi, G., Thach, H. M., Nguyen, V. T. H., Amato, G., Birchette, M., & Sterling, E. J. (2017). The importance of an interdisciplinary research approach to inform wildlife trade management in Southeast Asia. BioScience, 67(11), 9951003. https://doi.org/10.1093/biosci/bix113CrossRefGoogle Scholar
Dobson, A. P., Pimm, S. L., Hannah, L., Kaufman, L., Ahumada, J. A., Ando, A. W., Bernstein, A., Busch, J., Daszak, P., Engelmann, J., Kinnaird, M. F., Li, B. V., Loch-Temzelides, T., Lovejoy, T., Nowak, K., Roehrdanz, P. R., & Vale, M. M. (2020). Ecology and economics for pandemic prevention: Investments to prevent tropical deforestation and to limit wildlife trade will protect against future zoonosis outbreaks. Science (New York, N.Y.), 369(6502), 379381. https://doi.org/10.1126/SCIENCE.ABC3189/SUPPL_FILE/ABC3189_DOBSON_SM.PDFGoogle Scholar
Ebi, K. L., Harris, F., Sioen, G. B., Wannous, C., Anyamba, A., Bi, P., Boeckmann, M., Bowen, K., Cissé, G., Dasgupta, P., Dida, G. O., Gasparatos, A., Gatzweiler, F., Javadi, F., Kanbara, S., Kone, B., Maycock, B., Morse, A., Murakami, T., … Capon, A. (2020). Transdisciplinary research priorities for human and planetary health in the context of the 2030 agenda for sustainable development. International Journal of Environmental Research and Public Health, 17(23), 8890. https://doi.org/10.3390/IJERPH17238890Google Scholar
Florens, F. B. V., & Baider, C. (2019). Mass-culling of a threatened island flying fox species failed to increase fruit growers’ profits and revealed gaps to be addressed for effective conservation. Journal for Nature Conservation, 47, 5864. https://doi.org/10.1016/J.JNC.2018.11.008Google Scholar
Friant, S., Bonwitt, J., Ayambem, W. A., Ifebueme, N. M., Alobi, A. O., Otukpa, O. M., Bennett, A. J., Shea, C., Rothman, J. M., Goldberg, T. L., & Jacka, J. K. (2022). Zootherapy as a potential pathway for zoonotic spillover: A mixed-methods study of the use of animal products in medicinal and cultural practices in Nigeria. One Health Outlook, 4(1). https://doi.org/10.1186/S42522-022-00060-3Google Scholar
Fromentin, J. M., Emery, M. R., Donaldson, J., Danner, M. C., Hallosserie, A., Kieling, D., Balachander, G., Barron, E. S., Chaudhary, R. P., Gasalla, M., Halmy, M., Hicks, C., Park, M. S., Parlee, B., Rice, J., Ticktin, T., & Tittensor, D. (2022). Summary for policymakers of the thematic assessment of the sustainable use of wild species of the Intergovernmental Science-Policy Platform on Biodiversity and Ecosystem Services (IPBES). https://doi.org/10.5281/ZENODO.6810036CrossRefGoogle Scholar
Hanazaki, N., Herbst, D. F., Marques, M. S., & Vandebroek, I. (2013). Evidence of the shifting baseline syndrome in ethnobotanical research. Journal of Ethnobiology and Ethnomedicine, 9(1), 111. https://doi.org/10.1186/1746-4269-9-75/FIGURES/3CrossRefGoogle ScholarPubMed
HRW. (2020, May 12). Covid-19 Fueling Anti-Asian Racism and Xenophobia Worldwide | Human Rights Watch. Human Rights Watch. https://www.hrw.org/news/2020/05/12/covid-19-fueling-anti-asian-racism-and-xenophobia-worldwideGoogle Scholar
Hull, V., & Liu, J. (2018). Telecoupling: A new frontier for global sustainability. Ecology and Society, 23(4), 41. https://doi.org/10.5751/ES-10494-230441Google Scholar
ISC. (2023, April 25). Looking at the Future of Transdisciplinary Research — Centre for Science Futures. International Science Council. https://futures.council.science/publications/transdisciplinaryGoogle Scholar
Jahn, T., Bergmann, M., & Keil, F. (2012). Transdisciplinarity: Between mainstreaming and marginalization. Ecological Economics, 79, 110. https://doi.org/10.1016/J.ECOLECON.2012.04.017CrossRefGoogle Scholar
Keck, F., & Lynteris, C. (2018). Zoonosis: Prospects and challenges for medical anthropology. Medicine Anthropology Theory, 5(3), 114. https://doi.org/10.17157/MAT.5.3.372Google Scholar
Kelly, T. R., Karesh, W. B., Johnson, C. K., Gilardi, K. V. K., Anthony, S. J., Goldstein, T., Olson, S. H., Machalaba, C., Mazet, J. A. K., Aguirre, A., Aguirre, L., Akongo, M. J., Robles, E. A., Ambu, L., Antonjaya, U., Aguilar, G. A., Barcena, L., Barradas, R., Bogich, T., … Zimmerman, D. (2017). One health proof of concept: Bringing a transdisciplinary approach to surveillance for zoonotic viruses at the human-wild animal interface. Preventive Veterinary Medicine, 137, 112118. https://doi.org/10.1016/J.PREVETMED.2016.11.023Google Scholar
Lam, T. T. Y., Jia, N., Zhang, Y. W., Shum, M. H. H., Jiang, J. F., Zhu, H. C., Tong, Y. G., Shi, Y. X., Ni, X. B., Liao, Y. S., Li, W. J., Jiang, B. G., Wei, W., Yuan, T. T., Zheng, K., Cui, X. M., Li, J., Pei, G. Q., Qiang, X., … Cao, W. C. (2020). Identifying SARS-CoV-2-related coronaviruses in Malayan pangolins. Nature, 583(7815), 282285. https://doi.org/10.1038/s41586-020-2169-0CrossRefGoogle ScholarPubMed
Malmer, P., Tengö, M., Fernandez-Llamazares Onrubia, A., Woodward, E. R., Crawhall, N., Hill, R., Trakansuphakon, P., Athayde, S., Carino, C., Crimella, D., Ferrari, F., Perez, E., Spencer, R., Trakansuphakon, N., Bicksler, A., Carino, J., Lengoisa, J., Lungharwo, T., & Tahi, B.… (2019). Dialogue across Indigenous, local and scientific knowledge systems reflecting on the IPBES Assessment on Pollinators, Pollination and Food Production. Stockholm Resilience Centre. http://hdl.handle.net/10138/319171Google Scholar
Matias, D. M. S., Borgemeister, C., & von Wehrden, H. (2018). Ecological changes and local knowledge in a giant honey bee (Apis dorsata F.) hunting community in Palawan, Philippines. Ambio, 47(8), 924934. https://doi.org/10.1007/s13280-018-1038-7Google Scholar
Morse, S. S., Mazet, J. A. K., Woolhouse, M., Parrish, C. R., Carroll, D., Karesh, W. B., Zambrana-Torrelio, C., Lipkin, W. I., & Daszak, P. (2012). Prediction and prevention of the next pandemic zoonosis. The Lancet, 380(9857), 19561965. https://doi.org/10.1016/S0140-6736(12)61684-5CrossRefGoogle ScholarPubMed
Mutombo, P. N., Fallah, M. P., Munodawafa, D., Kabel, A., Houeto, D., Goronga, T., Mweemba, O., Balance, G., Onya, H., Kamba, R. S., Chipimo, M., Kayembe, J. M. N., & Akanmori, B. (2022). COVID-19 vaccine hesitancy in Africa: A call to action. The Lancet Global Health, 10(3), e320e321. https://doi.org/10.1016/S2214-109X(21)00563-5Google Scholar
Nijhawan, S., & Mihu, A. (2023). Relations of Blood: Hunting Taboos and Wildlife Conservation in the Idu Mishmi of Northeast India. https://doi.org/10.2993/0278-0771-40.2.149, 40(2), 149–166. https://doi.org/10.2993/0278-0771-40.2.149CrossRefGoogle Scholar
Omifolaji, J. K., Ikyaagba, E. T., Jimoh, S. O., Ibrahim, A. S., Ahmad, S., & Luan, X. (2020). The emergence of Nigeria as a staging ground in the illegal pangolin exportation to South East Asia. Forensic Science International: Reports, 2, 100138. https://doi.org/10.1016/J.FSIR.2020.100138Google Scholar
Ortega, C., Ortega, J., Simón, M. C., Ortega, C., Ortega, J., & Simón, M. C. (2022). Anthropology and one health: A transdisciplinary approach to understanding diseases emergence. Open Access Library Journal, 9(6), 112. https://doi.org/10.4236/OALIB.1108756Google Scholar
O'Shea, T. J., Cryan, P. M., Hayman, D. T. S., Plowright, R. K., & Streicker, D. G. (2016). Multiple mortality events in bats: A global review. Mammal Review, 46(3), 175190. https://doi.org/10.1111/MAM.12064/SUPPINFOGoogle Scholar
Pagani-Núñez, E. (2020). COVID-19: Ban “orientalism” by critics of wildlife trade. Nature, 579(7800), 497. https://doi.org/10.1038/D41586-020-00870-3Google Scholar
Pauly, D. (1995). Anecdotes and the shifting baseline syndrome of fisheries. Trends in Ecology & Evolution, 10(10), 430. https://doi.org/10.1016/S0169-5347(00)89171-5Google Scholar
Peters, J., & Schmidt, K. (2004). Animals in the symbolic world of pre-pottery Neolithic Göbekli Tepe, south-eastern Turkey: A preliminary assessment. Anthropozoologica, 39(1), 179218.Google Scholar
Ribeiro, J., Bingre, P., Strubbe, D., & Reino, L. (2020). Coronavirus: Why a permanent ban on wildlife trade might not work in China. Nature, 578(7794), 217. https://doi.org/10.1038/D41586-020-00377-XGoogle Scholar
Satterwhite, R., Sheridan, K., & Miller, W. M. (2016). Rediscovering deep time: Sustainability and the need to re-engage with multiple dimensions of time in leadership studies. Journal of Leadership Studies, 9(4), 4753. https://doi.org/10.1002/JLS.21426Google Scholar
Schneider, F. D., Matias, D. M., Burkhart, S., Drees, L., Fickel, T., Hummel, D., Liehr, S., Schramm, E., & Mehring, M. (2021). Biodiversity conservation as infectious disease prevention: Why a social-ecological perspective is essential. Global Sustainability, 4(e13). https://doi.org/10.1017/sus.2021.11Google Scholar
Schumacher, E. F. (1973). Small is beautiful; economics as if people mattered. Vintage.Google Scholar
Sylvester, O., Segura, A. G., & Davidson-Hunt, I. J. (2016). The protection of forest biodiversity can conflict with food access for indigenous people. Conservation and Society, 14(3), 279290. https://doi.org/10.4103/0972-4923.191157Google Scholar
Thomas, K., & Galemba, R. B. (2013). Illegal anthropology: An introduction. PoLAR: Political and Legal Anthropology Review, 36(2), 211214. https://doi.org/10.1111/PLAR.12022Google Scholar
Wu, K. J. (2023, March 16). The Strongest Evidence Yet That an Animal Started the Pandemic - The Atlantic. The Atlantic. https://www.theatlantic.com/science/archive/2023/03/covid-origins-research-raccoon-dogs-wuhan-market-lab-leak/673390/Google Scholar
Xiao, X., Newman, C., Buesching, C. D., Macdonald, D. W., & Zhou, Z. M. (2021). Animal sales from Wuhan wet markets immediately prior to the COVID-19 pandemic. Scientific Reports, 11(1), 17. https://doi.org/10.1038/s41598-021-91470-2Google Scholar