Antimicrobial resistance (AMR) is commonly described within a
One Health framework, which emphasizes the interconnected relationships between human health, animal health, and the environment. Antimicrobial use in clinical medicine, veterinary practice, and agriculture has been associated with the selection and spread of resistant microorganisms across these sectors. Research indicates that resistant bacteria and antimicrobial resistance genes can move between humans, animals, and environmental reservoirs through multiple pathways, including food production systems, direct contact, and exposure to contaminated water or soil. These pathways contribute to the persistence and wider dissemination of antimicrobial resistance beyond individual settings. Environmental sources have been increasingly examined in relation to AMR. Wastewater systems, agricultural runoff, and pharmaceutical residues have been identified as potential reservoirs where resistant microorganisms and resistance genes may persist. Such reservoirs may facilitate ongoing transmission between environmental, animal, and human populations. Efforts to address AMR within a One Health framework typically involve coordinated strategies across sectors, including antimicrobial stewardship, infection prevention and control, and improvements in sanitation and hygiene. Evidence from systematic reviews suggests that interventions such as farm biosecurity and water, sanitation, and hygiene (WASH) practices may reduce antimicrobial use and contribute to limiting the development and spread of resistance.
Duration of antimicrobials Delaying or minimizing the use of antibiotics for certain conditions may help safely reduce their use. Antimicrobial treatment duration should be based on the infection and other health problems a person may have. For many infections once a person has improved there is little evidence that stopping treatment causes more resistance. ResistanceOpen is an online global map of antimicrobial resistance developed by
HealthMap which displays aggregated data on antimicrobial resistance from publicly available and user submitted data. The website can display data for a radius from a location. Users may submit data from
antibiograms for individual hospitals or laboratories. European data is from the EARS-Net (European Antimicrobial Resistance Surveillance Network), part of the
ECDC. ResistanceMap is a website by the
Center for Disease Dynamics, Economics & Policy and provides data on antimicrobial resistance on a global level. The WHO's AMR global action plan also recommends antimicrobial resistance surveillance in animals. Initial steps in the EU for establishing the veterinary counterpart EARS-Vet (EARS-Net for veterinary medicine) have been made. AMR data from pets in particular is scarce, but needed to support antibiotic stewardship in veterinary medicine. By comparison there is a lack of national and international monitoring programs for antifungal resistance.
Limiting antimicrobial use in humans Antimicrobial stewardship programmes appear useful in reducing rates of antimicrobial resistance. The antimicrobial stewardship program will also provide pharmacists with the knowledge to educate patients that antibiotics will not work for a virus for example. Excessive antimicrobial use has become one of the top contributors to the evolution of antimicrobial resistance. Since the beginning of the antimicrobial era, antimicrobials have been used to treat a wide range of infectious diseases. Overuse of antimicrobials has become the primary cause of rising levels of antimicrobial resistance. The main problem is that doctors are willing to prescribe antimicrobials to ill-informed individuals who believe that antimicrobials can cure nearly all illnesses, including viral infections like the common cold. In an analysis of drug prescriptions, 36% of individuals with a cold or an
upper respiratory infection (both usually viral in origin) were given prescriptions for antibiotics. These prescriptions accomplished nothing other than increasing the risk of further evolution of antibiotic resistant bacteria. Using antimicrobials without prescription is another driving force leading to the overuse of antibiotics to self-treat diseases like the common cold, cough, fever, and dysentery resulting in an epidemic of antibiotic resistance in countries like Bangladesh, risking its spread around the globe. Introducing strict antibiotic stewardship in the outpatient setting to reduce inappropriate prescribing of antibiotics may reduce the emerging bacterial resistance. The
WHO AWaRe (Access, Watch, Reserve) guidance and antibiotic book has been introduced to guide antibiotic choice for the 30 most common infections in adults and children to reduce inappropriate prescribing in primary care and hospitals.
Narrow-spectrum antibiotics are preferred due to their lower resistance potential, and
broad-spectrum antibiotics are only recommended for people with more severe symptoms. Some antibiotics are more likely to confer resistance, so are kept as reserve antibiotics in the AWaRe book. Various diagnostic strategies have been employed to prevent the overuse of antifungal therapy in the clinic, proving a safe alternative to empirical antifungal therapy, and thus underpinning antifungal stewardship schemes.
At the hospital level Antimicrobial stewardship teams in hospitals are encouraging optimal use of antimicrobials. The goals of antimicrobial stewardship are to help practitioners pick the right drug at the right dose and duration of therapy while preventing misuse and minimizing the development of resistance. Stewardship interventions may reduce the length of stay by an average of slightly over 1 day while not increasing the risk of death. Dispensing, to discharged in-house patients, the exact number of antibiotic pharmaceutical units necessary to complete an ongoing treatment can reduce antibiotic leftovers within the community as community pharmacies can have antibiotic package inefficiencies. A 2025 cross-sectional study of 125 pharmacists at a UK NHS Foundation Trust examined knowledge, attitudes, and perceptions regarding antimicrobial stewardship following the COVID-19 pandemic. The study found that 85.2% of pharmacists recognized antimicrobial resistance as a public health concern, while 85.6% supported antimicrobial stewardship for prudent antibiotic use. However, the pandemic created challenges, with 80% reporting that COVID-19 patient conditions influenced antibiotic prescribing and 79.2% noting that time pressure affected antibiotic decision-making. The research highlighted the critical role of communication, with 79.2% of respondents valuing enhanced communication with microbiologists and stewardship teams during the pandemic period. A 2026 systematic review of 73 studies examined arthropod-mediated pathogen transmission in hospitals. Research indicates that cockroaches, flies, and ants frequently harbor multidrug-resistant bacteria, fungi, and viruses. While direct causality is difficult to prove, genetic evidence links these pests to hospital-associated infections.
At the primary care level Given the volume of care provided in primary care (general practice), recent strategies have focused on reducing unnecessary antimicrobial prescribing in this setting. Simple interventions, such as written information explaining when taking antibiotics is not necessary, for example in common infections of the upper respiratory tract, have been shown to reduce antibiotic prescribing. Various tools are also available to help professionals decide if prescribing antimicrobials is necessary. Parental expectations, driven by the worry for their children's health, can influence how often children are prescribed antibiotics. Parents often rely on their clinician for advice and reassurance. However a lack of plain language information and not having adequate time for consultation negatively impacts this relationship. In effect parents often rely on past experiences in their expectations rather than reassurance from the clinician. Adequate time for consultation and plain language information can help parents make informed decisions and avoid unnecessary antibiotic use. The prescriber should closely adhere to the five rights of drug administration: the right patient, the right drug, the right dose, the right route, and the right time. Microbiological samples should be taken for culture and sensitivity testing before treatment when indicated and treatment potentially changed based on the susceptibility report. Health workers and pharmacists can help tackle antibiotic resistance by: enhancing infection prevention and control; only prescribing and dispensing antibiotics when they are truly needed; prescribing and dispensing the right antibiotic(s) to treat the illness.
At the individual level People can help tackle resistance by using antibiotics only when infected with a bacterial infection and prescribed by a doctor; completing the full prescription even if the user is feeling better, never sharing antibiotics with others, or using leftover prescriptions. The CDC recommends that you follow these behaviors so that you avoid these negative side effects and keep the community safe from spreading drug-resistant bacteria.
Country examples • The
Netherlands has the lowest rate of antibiotic prescribing in the
OECD, at a rate of 11.4
defined daily doses (DDD) per 1,000 people per day in 2011. The defined daily dose (DDD) is a statistical measure of drug consumption, defined by the World Health Organization (WHO). •
Germany and
Sweden also have lower prescribing rates, with Sweden's rate having been declining since 2007. •
Greece,
France and
Belgium have high prescribing rates for antibiotics of more than 28 DDD.
Water, sanitation, hygiene Infectious disease control through improved
water, sanitation and hygiene (WASH) infrastructure needs to be included in the antimicrobial resistance (AMR) agenda. The "Interagency Coordination Group on Antimicrobial Resistance" stated in 2018 that "the spread of pathogens through unsafe water results in a high burden of gastrointestinal disease, increasing even further the need for antibiotic treatment." This is particularly a problem in
developing countries where the spread of infectious diseases caused by inadequate WASH standards is a major driver of antibiotic demand. Growing usage of antibiotics together with persistent infectious disease levels have led to a dangerous cycle in which reliance on antimicrobials increases while the efficacy of drugs diminishes. An increase in
hand washing compliance by hospital staff results in decreased rates of resistant organisms. Water supply and sanitation infrastructure in health facilities offer significant co-benefits for combatting AMR, and investment should be increased.
Industrial wastewater treatment Manufacturers of antimicrobials need to improve the treatment of their wastewater (by using
industrial wastewater treatment processes) to reduce the release of residues into the environment. For this reason only antimicrobials that are deemed "not-clinically relevant" are used in these practices. Unlike resistance to antibacterials, antifungal resistance can be driven by
arable farming, currently there is no regulation on the use of similar antifungal classes in agriculture and the clinic. The possibility for co-selection of AMR resistances in the food chain pipeline may have far-reaching implications for human health.
Country examples Europe In 1997, European Union health ministers voted to ban
avoparcin and four additional antibiotics used to promote animal growth in 1999. In 2006 a ban on the use of antibiotics in European feed, with the exception of two antibiotics in poultry feeds, became effective. In Scandinavia, there is evidence that the ban has led to a lower prevalence of antibiotic resistance in (nonhazardous) animal bacterial populations. As of 2004, several European countries established a decline of antimicrobial resistance in humans through limiting the use of antimicrobials in agriculture and food industries without jeopardizing animal health or economic cost.
United States The
United States Department of Agriculture (USDA) and the
Food and Drug Administration (FDA) collect data on antibiotic use in humans and in a more limited fashion in animals. About 80% of antibiotic use in the U.S. is for agriculture purposes, and about 70% of these are medically important. Fluroquinolones have been banned from extra-label use in food animals in the USA since 2007. However, they remain widely used in companion and exotic animals.
Global action plans and awareness At the
79th United Nations General Assembly High-Level Meeting on AMR on 26 September 2024, world leaders approved a political declaration committing to a clear set of targets and actions, including reducing the estimated 4.95 million human deaths associated with bacterial AMR annually by 10% by 2030. A global action plan to tackle the growing problem of resistance to antibiotics and other antimicrobial medicines was endorsed at the Sixty-eighth
World Health Assembly in May 2015. • Videos are being produced for the general public to generate interest and awareness. • The
Irish Department of Health published a National Action Plan on Antimicrobial Resistance in October 2017. The Strategy for the Control of Antimicrobial Resistance in Ireland (SARI), Iaunched in 2001 developed Guidelines for Antimicrobial Stewardship in Hospitals in Ireland in conjunction with the
Health Protection Surveillance Centre, these were published in 2009. Following their publication a public information campaign 'Action on Antibiotics' was launched to highlight the need for a change in antibiotic prescribing. Despite this, antibiotic prescribing remains high with variance in adherence to guidelines. • The United Kingdom published a 20-year vision for antimicrobial resistance that sets out the goal of containing and controlling AMR by 2040. The vision is supplemented by a 5-year action plan running from 2019 to 2024, building on the previous action plan (2013–2018). • The World Health Organization has published the 2024 Bacterial Priority Pathogens List which covers 15 families of antibiotic-resistant bacterial pathogens. Notable among these are
gram-negative bacteria resistant to last-resort antibiotics, drug-resistant
mycobacterium tuberculosis, and other high-burden resistant pathogens such as
Salmonella,
Shigella,
Neisseria gonorrhoeae,
Pseudomonas aeruginosa, and
Staphylococcus aureus. The inclusion of these pathogens in the list underscores their global impact in terms of burden, as well as issues related to transmissibility, treatability, and prevention options. It also reflects the R&D pipeline of new treatments and emerging resistance trends.
Antibiotic Awareness Week The World Health Organization has promoted the first
World Antibiotic Awareness Week running from 16 to 22 November 2015. The aim of the week is to increase global awareness of antibiotic resistance. It also wants to promote the correct usage of antibiotics across all fields in order to prevent further instances of antibiotic resistance. World Antibiotic Awareness Week has been held every November since 2015. For 2017, the Food and Agriculture Organization of the United Nations (FAO), the World Health Organization (WHO) and the
World Organisation for Animal Health (OIE) are together calling for responsible use of antibiotics in humans and animals to reduce the emergence of antibiotic resistance.
United Nations In 2016 the Secretary-General of the
United Nations convened the Interagency Coordination Group (IACG) on Antimicrobial Resistance. The IACG worked with international organizations and experts in human, animal, and plant health to create a plan to fight antimicrobial resistance. • Accelerate progress in countries • Innovate to secure the future • Collaborate for more effective action • Invest for a sustainable response • Strengthen accountability and global governance
One Health Approach The
One Health approach recognizes that human, animal, and environmental health are interconnected in the development and spread of antimicrobial resistance (AMR). Key strategies include:
Integrated Surveillance • Monitoring antibiotic use and resistance trends across human medicine, agriculture, and environmental sectors. • For example, 73% of the world's antibiotics are used in livestock, often for non-therapeutic purposes like growth promotion.
Policy Interventions • Banning non-therapeutic antibiotics in agriculture (e.g., European Union's 2006 growth promoter ban). • Incentivizing development of new antibiotics and alternatives (e.g., vaccines, bacteriophages).
Environmental Mitigation • Reducing pharmaceutical waste in water systems and soil through improved waste management. • Addressing resistance genes in wastewater from hospitals, farms, and drug manufacturing sites. ==Mechanisms and organisms==