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Antimicrobial Resistance: Just Transitions for Shared Futures

Part of: Antimicrobial Resistance: Just Transitions for Shared Futures

Published online by Cambridge University Press:  05 December 2025

Sheila Varadan ,
Sara de Wit ,
Miriam Waltz Open the ORCID record for Miriam Waltz [Opens in a new window]  and
Claas Kirchhelle Open the ORCID record for Claas Kirchhelle [Opens in a new window]
Sheila Varadan*
Affiliation:
Department of Child Law and Health Law, Institute of Private Law Leiden Law School, Leiden University , The Netherlands African Studies Centre Leiden, Leiden University, The Netherlands
Sara de Wit
Affiliation:
Institute for History, Leiden University, The Netherlands African Studies Centre Leiden, Leiden University, The Netherlands
Miriam Waltz
Affiliation:
Cultural Anthropology and Development Sociology, Leiden University, The Netherlands African Studies Centre Leiden, Leiden University, The Netherlands
Claas Kirchhelle
Affiliation:
French National Institute of Health and Medical Research (INSERM), CERMES3, Paris, France
*
Corresponding author: Sheila Varadan; Email: s.r.varadan@law.leidenuniv.nl
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Public Humanities , Volume 1 , 2025 , e175
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In the last decade, we have seen escalating warnings of a looming “antibiotic apocalypse”—a future where antimicrobial resistance (AMR) overtakes modern medicine and routine procedures such as minor surgery or uncomplicated childbirth become costly and life-threatening.Footnote 1 For much of the world, this is already happening. In many lower- and middle-income countries, the threat of drug-resistant infections is an everyday reality—antimicrobial drugs have long since lost their effectiveness or were never accessible in the first place.Footnote 2 While this health crisis is being linked to AMR, it reflects deeper structural inequalities and unseen injustice.Footnote 3 Narratives of AMR as a “silent pandemic” or looming global health threat obscure these realities and fail to recognise that drug-resistance is already exacting a profound and uneven toll on human health and development, particularly among vulnerable and marginalised communities.Footnote 4

In truth, our interdependence with the microbial world is far more complex, and the implications of AMR extend well beyond the clinical setting and economic burden of drug resistance in humans.Footnote 5 Microbes are the basis of all life on Earth. Microbes are key to sustaining the biosphere, regulating planetary biogeochemical cycling, and constitute 70%–90% of all cells within the human body.Footnote 6 Maintaining healthy, sustainable, and diverse microbial environments is essential for all life.Footnote 7

AMR is itself a naturally occurring process within microbial ecosystems: microbes produce antimicrobial substances to compete or communicate with each other and have evolved complex resistance mechanisms to survive exposure to organic and inorganic antimicrobial substances.Footnote 8 Greater exposure to antimicrobials increases selection for resistant organisms and AMR genes. The short-term challenge posed by AMR is that many of the antimicrobial substances we rely on to control microbial environments in medicine, agriculture, and industry (antibiotics, antimalarials, antiparasitics, and antifungals) become less effective.Footnote 9 According to the most recent estimates, over 4 million human deaths were associated with bacterial AMR in 2019—and the number is set to rise further.Footnote 10

Beyond the immediate threat of treatment failure, growing selective pressures–be they pharmaceutical or non-pharmaceutical, such as biocides, disinfectants, and industrial pollutants—also pose a major threat to the functioning of microbial ecosystems that humans and all other life rely upon.Footnote 11 Seen from this angle, AMR is not just a public health challenge, but also a wider signal of planetary stress linked to an accelerating microbial ecocrisis.Footnote 12 This ecocrisis is intimately entwined with the wider triple planetary crisis of biodiversity loss, climate change, and pollution.Footnote 13 There is also a growing body of evidence showing the long-term impact of human-induced environmental destruction (i.e. protracted armed conflict) on microbial environments.Footnote 14

Increasingly, AMR is being recognised as a “superwicked” problem, given its immediacy and magnitude, multifactorial drivers, lack of clear solutions or coordinated policy responses, and interconnectivity with other global crises.Footnote 15 However, unlike climate change, where discourse has centred around societal transitions towards more sustainable and low-carbon economies, there has been little discussion within AMR governance about the widescale changes needed for the longer-term management of AMR and microbial environments.Footnote 16

Until now, the global governance framework for AMR has taken a predominantly public health and individual behaviour-focused approach aimed at reducing the clinical burden of drug-resistant infections.Footnote 17 The WHO Global Action Plan on AMR (WHO GAP), adopted in 2015, articulated its primary goal as “ensur[ing], for as long as possible, continuity of successful treatment and prevention of infectious diseases with effective and safe medicines that are quality-assured…and accessible to all who need them.”Footnote 18 It laid out five key objectives: (1) improving awareness and understanding of AMR through effective communication, education, and training; (2) strengthening surveillance of AMR by strengthening knowledge and the evidence-base; (3) reducing incidence of infection by strengthening infection prevention; (4) optimising use of antimicrobials through stewardship programmes; (5) investing more in new medicines, diagnostic tools, vaccines, and other interventions aimed at mitigating AMR.Footnote 19 That the 2015 WHO GAP did not consider the environmental dimensions of AMR, nor the socio-economic inequities driving antimicrobial-use made it self-limiting from its onset—a “damage-control” rather than longer-term strategy for the sustainable management of AMR and microbial environments.Footnote 20

Attempts to integrate the environment into antimicrobial policy-making have only recently gathered momentum.Footnote 21 In 2022, the “Tripartite” led by the World Health Organization, the Food and Agriculture Organisation, and the World Organisation for Animal Health joined with the UN Environmental Programme, becoming the “Quadrapartite” and formally adding the environmental dimension to AMR governance.Footnote 22 International organisations have also begun to issue guidelines for AMR-sensitive treatment of pharmaceutical and urban waste.Footnote 23 At the national level, major manufacturing hubs such as India have attempted to introduce stricter guidelines for substances that select for AMR—albeit with limited success.Footnote 24 However, new environmental AMR mitigation measures have also triggered resistance from industry groups, including the use of counter-science and the creation of international non-governmental standards that limit sustainability criteria to carbon-focused metrics.Footnote 25 Meanwhile, the breakdown of multilateralism and the recent downturn in funding for international surveillance and stewardship initiatives pose serious challenges for coordinated action against the accelerating antimicrobial challenge.

Compounding these complexities are the structural inequalities that drive antimicrobial use and exacerbate vulnerability to disease and exposure to antimicrobials.Footnote 26 Such challenges are specific to particular communities and contexts, and policies to address antimicrobial use in such contexts often exacerbate existing inequalities, introducing ethical issues.Footnote 27 Communities living with poor sanitation, polluted water systems, contaminated land, or unsafe working conditions are disproportionately exposed to resistant pathogens. Often, these same communities also face the greatest challenges in accessing effective treatment.Footnote 28 Environmental determinants intersect with poverty and marginalisation, creating layered or structural vulnerabilities that current AMR governance does not address.Footnote 29 Overlooking these structural inequalities risks reinscribing the same inequities that AMR governance should be seeking to address.

Faced with these entrenched and accelerating challenges, a new approach to AMR governance is urgently needed—one that embraces interdisciplinarity and allows for a more diverse range of perspectives, knowledge, and evidence to inform AMR discourse and governance.Footnote 30 Rather than being on the sidelines, equity needs to be at the heart of AMR governance and policy moving forward. With a humanities and social sciences lens, we are able to confront the uncomfortable questions: Who bears the heaviest burden of AMR? Who stands to lose the most in AMR-related interventions? Whose knowledge counts in AMR governance? Whose voices are heard and what evidence is valued in the design of AMR interventions? How do power, financial, and special interests shape policy? And how should we manage our relationship with microbes and microbial environments?

Drawing on Just Transitions from climate change, we make a case for prioritising justice, equity, inclusivity, and sustainability in AMR decision-making and governance, placing process over outcome, bottom-up approaches over top-down solutions, and long-term strategies over one-off technical fixes.Footnote 31 Applying Just Transitions widens our perspective, allowing for a deeper inquiry into how AMR impacts the lives of communities around the world, and what processes are needed to forge a sustainable and equitable shared future with microbial environments.

1. What is Just Transitions?

The concept of Just Transitions emerged in the United States in the 1970s, when labour organiser Tony Mazzochi of the Oil Chemical and Atomic Workers’ Union sought compensation for workers adversely impacted by the ban on toxic chemicals and coal.Footnote 32 Mazzochi called on “society to pay workers not to make poisons”—drawing attention to vulnerable communities in societal transitions.Footnote 33 Rather than actively resisting transitions to low-carbon energy, Mazzocchi and others saw an opportunity to embed social justice and equity in grassroots environmental movements, linking equitable transitions to environmental justice.Footnote 34

From its inception, Just Transitions was a battle cry for those adversely impacted by societal changes—calling for a just, equitable, and inclusive process to navigate the hard decisions and trade-offs needed to effect radical transformations. Just Transitions has since become a cornerstone in climate justice, providing a platform for the unseen to be heard, and ensuring steps are taken to avoid “creating new injustices and vulnerabilities” while redressing “pre-existing structural drivers of injustice” in the widescale transitions towards low-carbon economies.Footnote 35 However, Just Transitions has also transcended climate justice discourse, embodying a wider framework for justice, equity, and inclusivity in societal transformations.Footnote 36 Lenihan-Ikin et al. propose an expansive framework for Just Transitions that offers “a viable avenue to address a multiplicity of co-existing and related inequities.”Footnote 37 It encompasses four characteristics: (1) relationality; (2) systems-thinking; (3) place-based; and (4) intergenerational thinking.Footnote 38 Wang and Lo identify five different framings of Just Transitions: (i) a labour-oriented concept; (ii) an integrated framework for justice; (iii) a theory of socio-technical transition; (iv) a governance strategy; and (v) public perception.Footnote 39 Though sometimes criticised for being overly broad and not sufficiently transformative, Just Transitions nonetheless finds currency in policy frameworks, offering a flexible and multifaceted framework to advance societal change through social justice, equity, and inclusivity.Footnote 40

2. Just Transitions for AMR

In this issue, we use Just Transitions as a framing to probe narratives and practices in AMR discourse and governance. We posit that Just Transitions offers a novel and unique vantage point to re-evaluate AMR, shifting attention from the immediacy of averting drug-resistance to the longer-term strategies for shared futures with AMR and microbial environments. We also critique Just Transitions as a conceptual framework, examining its adequacy in addressing the multiplicity of voices and competing interests that need to be negotiated and considered in AMR governance. The articles in this Issue centre around four broad themes of Just Transitions: (1) Justice, (2) Equity, (3) Inclusivity, and (4) Governance.

First, justice is interrogated. Tegama et al. call for a wider conception of justice in “just” transitions, so that marginalised knowledge systems are not overlooked, animals and the environment are considered as moral subjects, historical inequities are acknowledged, and no community is left to bear the disproportionate burden of AMR.Footnote 41 Ho extends this conversation to non-human justice, exploring the idea of microbial rights as part of a broader ecological framing.Footnote 42 Boucrot et al. explore how the right to a healthy environment could be leveraged in AMR to widen its narrative from a public health threat to an environmental and human rights crisis, and in the process advance justice and accountability in AMR governance.Footnote 43 Rekers and Marinova consider how transitional justice frameworks could be applied to AMR governance to address past and ongoing injustices.Footnote 44

Second, equity is examined. Batheja et al. underscore how intersectionality—particularly gender and caste—shapes vulnerability and contributes to structural inequalities in access to treatment and AMR-related decision-making.Footnote 45 Degu et al. highlight inequitable access to treatment for drug-resistant tuberculosis, pointing to the need for resilient, community-based health systems.Footnote 46 The scoping review by Mutua et al. reveals how structural inequities in governance and the overreliance on global action plans and donor priorities risk entrenching gaps between global and local contexts, calling for locally grounded, sustainable, and equitable approaches to AMR governance.Footnote 47

Third, inclusivity is discussed. Ngo et al. show the benefits of participatory practices and how public engagement can enhance understanding and efficacy of national policies at the local level.Footnote 48 Ethnographic work by Gerrets and Rangel-Gutiérrez demonstrates how informal medicine sellers are able to adapt antibiotic practices to reflect community needs, revealing the opportunities that context-sensitive and inclusive governance may hold for AMR “solutions.”Footnote 49 Joubert argues for moving beyond expert-led AMR-awareness campaigns in public communication towards more inclusive, participatory, culturally grounded, and creative approaches built on dialogue, trust, and co-creation with local communities.Footnote 50

Finally, governance is explored. Kirchhelle calls for a paradigm shift in international legal frameworks from antimicrobial stewardship to the governance of microbial commons, embedding microbial and environmental conservation into international legal frameworks.Footnote 51 Wells et al. historicise the “empty pipeline” narrative in antibiotic innovation, revealing how market-oriented R&D models entrench inequities, and calling for alternative governance models that foreground public interest and global access.Footnote 52 Giri et al., in their review of AMR National Action Plans in the Western Pacific Region, reveal a consistently top-down technocratic governance model that gives little consideration to procedural fairness or local participation.Footnote 53 Fortané shows how narrow and technocratic approaches to AMR governance, such as antimicrobial reduction targets in livestock farming, cannot address the structural drivers and infrastructures surrounding antimicrobial use, and thus do not achieve the longer-term transformations needed to sustainably manage AMR and microbial environments.Footnote 54 Mutua et al. argue that governance structures must move beyond the isomorphic mimicry of global action antimicrobial reduction policies and plans to embrace locally grounded strategies that strengthen institutional commitment, equitable stakeholder involvement, and sustainability of resources in low- and middle-income settings.Footnote 55

While this Special Issue primarily focuses on antibiotic resistance, we recognise that AMR manifests in other forms—antifungal, antiviral, and antiparasitic resistance—which also raise similar scientific, socio-economic, and governance challenges and which could also merit further exploration through the lens of Just Transitions.

3. Towards shared futures

Applying Just Transitions to AMR gives us an opening to change the narrative in AMR, from a war against microbes to a transition towards a more just, sustainable, and equitable relationship with microbial environments in the management of AMR. It does not demand “solutions” but rather embraces an open-ended process of negotiation and renegotiation, acknowledging that a diversity of perspectives, knowledge, practices, and contexts will be needed to guide this process. It means not pitting “humans” against nature, but acknowledging the inseparable connections between human life and other forms of life—while also pulling the focus towards intrahuman inequalities.

Anticipating a future with AMR need not be dictated by fear, scarcity, and apocalyptic predictions. It can be shaped by justice, equity, and sustainability—where healthy microbes, ecosystems, and societies thrive together in shared futures.

Acknowledgements

This research was supported by the British Academy Global Convening Programme on Just Transitions for the Equitable and Sustainable Mitigation of Antimicrobial Resistance. The authors gratefully acknowledge the British Academy for facilitating international collaboration through this programme, which has enabled critical interdisciplinary dialogue on justice, equity, and sustainability in AMR governance.

Author contribution

Conceptualization: SV and CK Writing - original draft: SV, SdW, CK and MW; Revising and editing: SV, CK, SdW and MW

Conflicts of interests

The authors declare none.

Footnotes

1 Murray et al. Reference Murray, Shunji Ikuta and Sharara2022; Naghavi et al. Reference Naghavi, Vollset and Ikuta2024.

2 World Health Organization 2025.

3 Varadan et al. Reference Varadan, Chandler and Weed2024.

4 Davis et al. Reference Davis, Limato, Monga, Beatrice, Sneha, Susan and Owen2025.

5 Kirchhelle Reference Kirchhelle2023.

6 Rappuoli et al. Reference Rappuoli, Young, Ron, Pecetta and Pizza2023.

7 Ibid.

8 Kirchhelle and Roberts Reference Kirchhelle and Roberts2025; Rappuoli et al. Reference Rappuoli, Young, Ron, Pecetta and Pizza2023.

9 UNGA Resolution on AMR 2024.

10 Naghavi et al. Reference Naghavi, Vollset and Ikuta2024.

11 United Nations Environment Programme 2023.

12 Kirchhelle and Roberts Reference Kirchhelle and Roberts2025.

13 Van Bavel et al. Reference Van Bavel, Berrang-Ford and Moon2024.

14 Abbara et al. Reference Abbara, Clare, Richard, Wim, Krystel, Reem and Carine2025.

15 Littmann, Viens, and Silva Reference Littmann, Viens, Silva, Jamrozik and Selgelid2020.

16 Varadan et al. Reference Varadan, Chandler and Weed2024.

17 Gradmann and Kirchhelle Reference Gradmann, Kirchhelle, Rubin, Baekkeskov and Munkholm2023.

18 World Health Organization 2015; Ibid., 8.

19 Ibid., 8–12.

20 Kirchhelle et al. Reference Kirchhelle, Portillo, Davis, Doron, Dreser, Fortane and Haddadn.d.

21 UN General Assembly 2024, see paras 9, 74–76, 77, 78.

22 “Memorandum of Understanding between the Food and Agricultural Organization of the United Nations and the World Organization for Animal Health and the World Health Organization and the United Nations Environmental Programme regarding Cooperation to Combat Health Risks at the Animal–Human–Ecosystems Interface in the Context of the ‘One Health’ Approach and Including Antimicrobial Resistance,” 17 March 2022, see Article 2(1), Article 3(1). https://openknowledge.fao.org/server/api/core/bitstreams/0b6a5a41-4383-4840-acf0-ef374e07a4b3/content.

23 World Health Organization 2024.

24 Center for Infectious Disease Research and Policy 2022.

25 Bjerke Reference Bjerke2025.

26 Davis et al. Reference Davis, Limato, Monga, Beatrice, Sneha, Susan and Owen2025; Tompson and Chandler Reference Tompson and Chandler2021.

27 Tegama et al. Reference Tegama, Savić, Bull, Atuire and Johnson2025.

28 Davis et al. Reference Davis, Limato, Monga, Beatrice, Sneha, Susan and Owen2025.

29 Ibid.; Keenan et al. Reference Keenan, Corrêa, Sringernyuang, Nayiga and Clare2025.

30 Ibid.

31 Lenihan-Ikin, Ariana, and Atuire Reference Lenihan-Ikin, Ariana and Atuire2025.

32 Laurent Reference Laurent2024; Stambe et al. Reference Stambe, Marston, Snell and Moss2025.

33 Lenihan-Ikin, Ariana, and Atuire Reference Lenihan-Ikin, Ariana and Atuire2025; Stambe et al. Reference Stambe, Marston, Snell and Moss2025; Stevis and Felli Reference Stevis and Felli2020.

34 Eisenberg Reference Eisenberg2019.

35 Savaresi et al. Reference Savaresi, Setzer and Bookman2024.

36 Wang and Lo Reference Wang and Kevin2021, 2.

37 Lenihan-Ikin, Ariana, and Atuire Reference Lenihan-Ikin, Ariana and Atuire2025, 3.

38 Ibid., 2–5.

39 Wang and Lo Reference Wang and Kevin2021, 2.

40 Ibid., 9.

41 Tegama et al. Reference Tegama, Savić, Bull, Atuire and Johnson2025.

42 Ho Reference Ho2025.

43 Boucrot et al. Reference Boucrot, Sheila and Claas2025.

44 Rekers and Marinova Reference Rekers and Lena2025.

45 Batheja et al. Reference Batheja, Rishiraj and Srishti2025.

46 Degu et al. Reference Degu and Christopher2025.

47 Mutua et al. Reference Mutua, Mercy, Nancy, John, Anita, Hai and Anh2025.

48 Ngo et al. Reference Ngo, Thao, Yen, Nhi, Anh, Kim and Sonia2025.

49 Gerrets and Rangel-Gutiérrez Reference Gerrets and Rodrigo2025.

50 Joubert Reference Joubert2025.

51 Kirchhelle Reference Kirchhelle2025.

52 Wells et al. Reference Wellsn.d.

53 Giri and Lewycka Reference Giri and Sonia2025.

54 Fortané Reference Fortané2025.

55 Mutua et al. Reference Mutua, Mercy, Nancy, John, Anita, Hai and Anh2025.

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