Antimicrobial Resistance and Poultry Production in Developing Countries
Antibiotics are natural, synthetic, or semi-synthetic substances that kill or interfere with the growth of microorganisms, specifically bacteria. They are used to treat or prevent infections in humans and animals. Antimicrobial drugs, such as antibiotics, are essential to protecting animal health in livestock production systems. However, their misuse and/or abuse can cause antimicrobial resistance (AMR), which is when microbes acquire the ability to tolerate one or more drugs we rely on to treat microbial infections. This publication considers AMR and poultry production in developing countries amid challenges of food insecurity, gender equity, shortage of Extension personnel, and lack of educational/training opportunities for smallholder farmers (particularly women).
Antimicrobial Use
Animal agriculture in developing countries is increasingly important. As many countries transition to more intensive farming practices, antimicrobial use increases, resulting in an increased risk of antimicrobial resistance in animals and humans. This is particularly true across Africa, where livestock (especially poultry) is economically important.
Since the 1950s, antibiotics have been used in food animal production to treat and prevent disease. They have also been used as feed enhancers and growth promoters. While some regions and countries, including Europe and the U.S., have banned the use of antibiotics as growth promoters, other countries with fewer regulations, particularly in the developing world, still use them for this purpose.
Globally, more than 70 percent of antimicrobials produced on Earth are used in food-animal production, including poultry. The Food and Agriculture Organization (FAO) reported a global increase in egg and poultry meat production worldwide, with a total of 87 million tons of eggs and 123 million tons of poultry meat (37 percent of total meat production) in 2017. However, this intensive poultry production in resource-limited settings may come with increased antimicrobial usage that could increase AMR if biosecurity safeguards are lacking.
Antibiotic use in many low- to middle-income countries has reached and exceeded levels observed in high-income countries, and agricultural intensification could lead to a 67 percent increase in antimicrobial use by 2030, predominantly led by low- and middle-income countries. Africa is no exception; like other developing regions, use of antimicrobials in many African countries remains largely unregulated. Furthermore, poor antimicrobial use practices contribute to antimicrobial residues in food of animal origin.
Poultry Production and AMR
Poultry is one of the fastest growing meats consumed per capita in the world. In the last 50 years, the annual global poultry growth rate was 5 percent. In contrast, it was 1.5 percent for beef, 3.1 percent for pork, and 1.7 percent for small ruminants. Chickens account for about 90 percent of global poultry production, amounting to approximately 23 billion chickens. This number has increased about five times in 50 years.
Antibiotics are frequently used in food animal production in developing countries (including much of Africa) to promote animal well-being and growth. Many of these antibiotics can be purchased over the counter. Antibiotic use in food animals can enhance animals’ overall health and promote their general output, but the practice can also lead to emergence and subsequent dissemination of AMR traits and antimicrobial-resistant bacteria. The challenges of AMR are particularly problematic in developing African countries given the hardship of disease challenges, alongside livelihoods and living conditions that include numerous close interactions between humans and livestock.
Studies in developing countries provide evidence that AMR is transmitted among people, animals, and the environment. For example, in Tanzania, similarity in resistant enteric bacteria in people, animals (livestock and wildlife), and the environment have been found. In addition, salmonella in people and animals in Uganda has shown similar patterns. Antimicrobial residues have been reported in several African countries, including Egypt, Ethiopia, Ghana, Kenya, Nigeria, South Africa, Sudan, and Tanzania.
In many developing, low-resource settings, applying intensive poultry farming practices may increase the disease threat and preexisting health burdens, which could potentially lead to regional outbreaks or global disease pandemics. In addition, local smallholder farmer poultry systems have numerous constraints, including adequate poultry nutrition programs, matching genetic breeding stock to the environment, predator control, infrastructure and capital, education and training programs, governmental policies, farm groups and organizations, and biosecurity risks.
In addition, developing regions lack poultry educational and training opportunities for smallholder farmers and do not have enough qualified Extension personnel to deliver the training. Without proper education, training, assistance, and oversight, small-scale poultry production can be a double-edged sword at times, inadvertently exacerbating poverty and food insecurity.
However, despite issues and constraints, numerous studies highlight how smallholder farmer poultry production has enhanced economic stability, increased food security, and improved gender equity. Furthermore, researchers in Mozambique reported that village poultry provided poverty alleviation and economic stability among rural populations burdened by HIV/AIDS. In Bangladesh, large poultry operation models were scaled down and women’s groups were appointed as managers. This intervention proved so successful that it was later adapted in other countries.
Gender Equity and Poverty Issues
Interventions aimed at improving gender equity are very important in many developing countries. According to the World Bank, there are 900 million poor people worldwide living on less than $1.90 (U.S.) per day. About half of them depend directly on livestock for their livelihoods. Some 290 million poor smallholder livestock keepers are estimated to be women, largely caretakers of poultry and small ruminants.
The FAO has indicated priority should be given to improving conditions of women working in the livestock sector to help improve gender equality in agricultural populations. However, this is difficult because women have limited access to educational training opportunities in general and AMR training specifically.
Poultry production offers a pathway to poverty alleviation and economic development in many developing countries. It is estimated that 250 million to 300 million people depend on livestock for their income and livelihood, with livestock representing an average of 30 percent of the agricultural gross domestic product (GDP) and approximately 10 percent of the total GDP. Poultry can contribute to three major pathways out of poverty:
- increasing resilience
- improving smallholder productivity
- increasing market participation
Sustainable Development Goals
The United Nations (UN) recently launched the 2030 Agenda for Sustainable Development that established 17 sustainable development goals (SDGs) to mitigate impacts of human pressure on the planet. These SDGs have stimulated increased development of poultry husbandry programs, and many fit well with smallholder farmer poultry systems (Table 1).
Contribution of Smallholder Poultry System |
Sustainable Development Goals Met |
---|---|
Increasing availability, accessibility, use, and stability of supply of food and nutrients. |
2. Zero hunger 3. Good health and well-being |
Smallholder farmer poultry can be kept by vulnerable groups, giving them access to a source of income. Community-supported models for Newcastle disease prevention can provide employment, particularly for women, and increased production can promote rural economic growth. |
1. No poverty 8. Decent work and economic growth |
Targeting a livestock species and production system that is largely under women’s control allows improvements to small-scale poultry production systems that can preferentially benefit women, promoting their empowerment. Income under women’s control is also more likely to be used to support their children’s education. |
5. Gender equality 4. Quality education |
To efficiently and sustainably use natural resources while achieving adequate nutrition globally, high-income countries must decrease food waste and consumption of calorie-dense, nutrient-poor foods, while low- and middle-income countries increase their consumption of nutrient-rich foods. Small-scale poultry is nutritious and locally available, typically with a short supply chain. Measures to improve poultry health and welfare will improve production efficiency and ensure sustainability. |
12. Responsible consumption/production |
Small-scale poultry production does not require land clearing, contributes positively to ecosystem health, and can reduce loss of biodiversity by being a rich pool of genetic diversity and an alternate protein source to bushmeat. |
15. Life on the land |
Adapted from Mottet and Tempio (2017) and Wong et al. (2017).
These programs are often led by international aid agencies, developmental agencies, and nongovernmental organizations that invest in smallholder farmer poultry systems. Smallholder farmer development poultry programs have been widely implemented in recent years to promote economic stability, increase food security, and improve gender equity, particularly in developing and resource-limited locations.
Antibiotic Alternatives Needed
Managing antimicrobial resistance is a challenge with the constraints placed on food and agricultural production systems by a growing population, pressure on natural resources, challenges associated with climate variability and change, and demands of ensuring food security/safety in a global economy. The problem is particularly challenging across many developing African countries where antibiotics are frequently used not for disease treatment but to promote food animal well-being and growth. While this practice may provide some benefits to producers and consumers at large, a major concern is that repeatedly exposing animals to small doses of antibiotics is contributing to AMR.
For example, a recent study evaluating antibiotic application in food animals in Rwanda revealed that up to 97 percent of smallholder farmers use antibiotics, mainly for disease prevention and growth promotion. The study also indicated that most farmers have limited expertise on antibiotic use in food animals, calling attention to the need for educational and training programs.
Antibiotic alternatives must play a larger role in food animal production to lessen the threat of AMR in both developed and developing countries. In addition, in developing countries around the world, over-the-counter availability of antibiotics and antibiotic use in animal feed should come under increased monitoring and regulation to ensure that antimicrobials are used for treatment of sick animals, not as prophylactics. Improved farm biosecurity is another important alternative intervention that focuses on preventing entry and spread of disease on the farm, thereby lessening dependence on antibiotics for disease control and prevention.
Summary
Use of antimicrobial drugs in food-producing animals yields healthier and increasingly prolific animal production. However, emergence of antimicrobial-resistant bacteria is likely linked to antimicrobial drug use in humans and animals. Increased use of antimicrobials corresponds to increased emergence of antimicrobial-resistant bacteria.
Unfortunately, many smallholder farmers across developing countries make decisions on antimicrobial use with little or no assistance from Extension or animal health personnel, who are often inaccessible or nonexistent because of distance, logistical, or financial considerations. This underscores the need for additional Extension personnel and increased outreach and educational efforts.
Addressing AMR at the global level will require efforts from both the developed and developing world. However, interventions in the developing world will likely differ from those of the developed world because of unique cultural and socioeconomic factors affecting emergence of AMR in the developing world.
References
Aidara-Kane, A., F. J. Angulo, J. M. Conly, et al. 2018. World Health Organization (WHO) guidelines on use of medically important antimicrobials in food-producing animals. Antimicrob. Resist. Infect. Control. Jan 17;7:7. doi: 10.1186/s13756-017-0294-9
Alders, R. G., and R. A. E. Pym. 2009. Village poultry: Still important to millions, eight thousand years after domestication. World’s Poult. Sci. J. 65:181–190.
Alders, R., J. A. Awuni, B. Bagnol, et al. 2014. Impact of avian influenza on village poultry production globally. EcoHealth. 11:63–72.
Alders, R. G., S. E. Dumas, E. Rukambile, et al. 2018. Family poultry: Multiple roles, systems, challenges, and options for sustainable contributions to household nutrition security through a planetary health lens. Matern. Child Nutr. 14(Suppl 3): e12668. 14 pages.
Alexandratos, N., and J. Bruinsma. 2012. World agriculture towards 2030/2050: The 2012 revision (No. 12-03, p. 4). FAO; ESA Working paper. Rome.
Afema, J. A., D. K. Byarugaba, D. H. Shah, et al. 2016. Potential source and transmission of Salmonella and antimicrobial resistance in Kampala, Uganda. PLoS ONE. 11: e0152130.
Alonso, C. A., M. Zarazaga, R. Ben Sallem, et al. 2017. Antibiotic resistance in Escherichia coli in husbandry animals: The African perspective. Lett. Appl. Microbiol. 64:318–334.
Boyd, W. 2001. Making meat: Science, technology, and American poultry production. Technol. Cult. 42:631–664.
Brown, K., R. R. E. Uwiera, M. L. Kalmokoff, et al. 2017. Antimicrobial growth promoter use in livestock: A requirement to understand their modes of action to develop effective alternatives. Int. J. Antimicrob. Agents. 49:12–24.
Castanon, J. I. R. 2007. History of the use of antibiotic as growth promoters in European poultry feeds. Poult. Sci. 86:2466–2471.
Caudell, M. A., A. Dorado-Garcia, S. Edkford, et al. 2020. Towards a bottom-up understanding of antimicrobial use and resistance on the farm: A knowledge, attitudes, and practices survey across livestock systems in five African countries. PLoS ONE. 15(1). e0220274.
Cully, M. 2014. Public health: The politics of antibiotics. Nature. 509:S16–S17.
Darwish, W. S., E. A. Eldaly, M. T. El-Abbsay, et al. 2013. Antibiotic residues in food: The African scenario. Jpn. J. Vet. Res. 61(Suppl):S13–S22.
Davies J., and D. Davies. 2010. Origins and evolution of antibiotic resistance. Microbiol. Mol. Biol. Rev. 74:417–433.
Dibner, J. J., and J. D. Richards. 2005. Antibiotic growth promoters in agriculture: History and mode of action. Poult. Sci. 84:634–643.
Durso, L. M., and K. L. Cook. 2014. Impacts of antibiotic use in agriculture: What are the benefits and risks? Curr. Opin. Microbiol. 19:37–44.
Elliott, K. A., C. Kenny, and J. A. Madan. 2017. Policy paper. A global treaty to reduce antimicrobial use in livestock. Center for Global Development, Washington, D.C. Available at: https://www.cgdev.org/sites/default/files/global-treaty-reduce-antimicrobial-use-livestock.pdf. Accessed: November 17, 2020. 29 pages.
FAO (Food and Agriculture Organization). 2014. Animal production and health guidelines No. 16. Decision tools for family poultry development. FAO. Rome.
FAO-AGAL. 2016. Synthesis – Livestock and the Sustainable Development Goals. Available at: http://www.livestockdialogue.org/fileadmin/templates/res_livestock/docs/2016/Panama/FAO-AGAL_synthesis_Panama_Livestock_and_SDGs.pdf. Accessed: November 18, 2020. 12 pages.
FAO (Food and Agriculture Organization). 2019. FAOSTAT. Agri-environmental indicators, livestock patterns domain. FAO. Rome.
Flock, D. K., K. F. Laughlin, and J. Bentley. 2005. Minimizing losses in poultry breeding and production: How breeding companies contribute to poultry welfare. World’s Poult. Sci. J. 61:227–237.
Founou, L.L., R. C. Founou, and S. Y. Essack. 2016. Antibiotic resistance in the food chain: A developing country perspective. Front Microbiol. 7:1881. 19 pages.
Gilchrist, M. J., C. Greko, D. B. Wallinga, et al. 2007. The potential role of concentrated animal feeding operations in infectious disease epidemics and antibiotic resistance. Environ. Health Perspect. 115:313–316.
Graham, J. P., J. N. S. Eisenberg, G. Trueba, et al. 2017. Small-scale food animal production and antimicrobial resistance: Mountain, molehill, or something in-between? Environ. Health Perspect. 125(10), 104501. 5 pages.
Guenther, S., C. Ewers, and L. Wieler. 2011. Extended-spectrum beta-lactamases producing E. coli in wildlife, yet another form of environmental pollution? Front. Microbiol. 2:246. 13 pages.
Hamilton-West, C., H. Rojas, J. Pinto, et al. 2012. Characterization of backyard poultry production systems and disease risk in the central zone of Chile. Res. Vet. Sci. 93:121–124.
Harun, M., and F. A. Massango. 2000. Village poultry production in Mozambique: Farming systems and ethnoveterinary knowledge in Angonia and Tsangano Districts, Tete Province. Australian Centre for International Agricultural Research (ACIAR). Parkvill, Victoria, Australia, pp. 76–79.
Hedman, H. D., K. A. Vasco, and L. Zhang. 2020. A review of antimicrobial resistance in poultry farming within low-resource settings. Animals. 10:1264.
ILRI (International Livestock Research Institute). 2008. ILRI annual report 2007: Markets that work: Making a living from livestock. ILRI, Nairobi, Kenya
Katakweba, A. A. S., K. S. Møller, J. Muumba, et al. 2014. Antimicrobial resistance in faecal samples from buffalo, wildebeest, and zebra grazing together with and without cattle in Tanzania. J. Appl. Microbiol. 118:966–975.
Khaitsa M. L., and D. Doetkott 2011. Antimicrobial drug resistance and molecular characterization of Salmonella isolated from domestic animals, humans, and meat products. In: Salmonella: A Dangerous Pathogen / Book 1, ISBN 979-953-307-044-4. Edited by Dr. Barakat S. M. Mahmoud.
Klein, E. Y., T. P. Van Boeckel, E. M. Martinez, et al. 2018. Global increase and geographic convergence in antibiotic consumption between 2000 and 2015. Proc. Nat. Acad. Sci. USA. 115:3463–3470.
Landers, T. F., B. Cohen, T. E. Wittum, and E. L. Larson. 2012. A review of antibiotic use in food animals: Perspective, policy, and potential. Public Health Reports. 127(1):4–22.
Levy, S. B., and B. Marshall. 2004 Antibacterial resistance worldwide: Causes, challenges, and responses. Nature Medicine. 10:S122–S129.
Littmann, J., A. Buyx, and O. Cars. 2015. Antibiotic resistance: An ethical challenge. Int. J. Antimicrob. Agents. 46:359–361.
Mahero, M., D. K. Byarugaba, D. K. Doetkott, et al. 2013. Antimicrobial resistance and presence of Class 1 integrons in Salmonella serovars isolated from clinical cases of animals and humans in North Dakota, USA, and Kampala, Uganda. J. Clinic Microb. 2(6) ISSN: 2327–5073 CMO.
Manishimwe, R., K. Nishimwe, and L. Ojok. 2017. Assessment of antibiotic use in farm animals in Rwanda. Trop. Anim. Health. Prod. 49:1101–1106.
Mensah, S. E., O. D. Koudandé, P. Sanders, et al. 2014. Antimicrobial residues in foods of animal origin in Africa: Public health risks. Rev. Sci. Tech. Off. Int. Epiz. 33(3):987–996.
Mottet, A., and G. Tempio. 2017. Global poultry production: Current state and future outlook and challenges. World’s Poult. Sci. J. 73:245–256.
Nesemeier, B., A. B. Ekiri, D. Landblom, et al. 2015. Prevalence and antimicrobial resistance of Salmonella enterica shed from range and feedlot cattle from post-weaning to slaughter. J Food Protect. Trends 35(4):280–289.
Nielsen, H., N. Roos, and S. H. Thilsted. 2003. The impact of semi-scavenging poultry production on the consumption of animal-source foods by women and girls in Bangladesh. J. Nutr. 133:4027S–4030S.
O’Neill, J. 2015. Tackling a global health crisis: Initial steps. London: Wellcome Trust and UK Department of Health. Available at: http://www.amr-review.org. Accessed: November 12, 2020.
Rushton, J. 2015. Anti-microbial use in animals: How to assess the tradeoffs. Zoonoses and Public Health. 62(Suppl. 1):10–21.
Tabler, T., M. L. Khaitsa, S. H. Mbaga, et al. 2020. Poultry Extension personnel needed across East Africa. Mississippi State University Extension Service. Publ. No. 3497. July.
Thomke, S., and K. Elwinger. 1998. Growth promotants in feeding pigs and poultry. I. Growth and feed efficiency responses to antibiotic growth promotants. Anum. Res. 47:85–97.
Van, T. T. H., Z. Yidana, P. M. Smooker, and P. J. Coloe. 2020. Antibiotic use in food animals worldwide, with a focus on Africa: Pluses and minuses. J. Global Antimicrobial Resist. 20:170–177.
Van Boeckel, T. P., C. Browser, M. Gilbert, et al. 2015. Global trends in antimicrobial use in food animals. Proc. Nat. Acad. Sci. USA. 112:5649–5654.
Van Boeckel, T. P., J. Pires, R. Silvester, et al. 2019. Global trends in antimicrobial resistance in animals in low- and middle-income countries. Science. Sep 20;365(6459):eaaw1944.
Wong, J. T., J. de Bruyn, B. Bagnol, et al. 2017. Small-scale poultry and food security in resource-poor settings: A review. Glob Food Secur. 15:43–52.
WHO (World Health Organization). 2015. Global action plan on antimicrobial resistance. Geneva. WHO. Available at: https://apps.who.int/iris/bitstream/handle/10665/193736/9789241509763_eng.pdf?sequence=1. Accessed: November 12, 2020.
World Bank. 2015. Ending extreme poverty and sharing prosperity: Progress and policies. Available at: https://www.worldbank.org/en/research/brief/policy-research-note-03-ending-extreme-poverty-and-sharing-prosperity-progress-and-policies. Accessed: November 18, 2020.
Publication 3728 (POD-11-21)
By Tom Tabler, Extension Professor, Poultry Science; Margaret L. Khaitsa, Professor, Epidemiology (International Emphasis), Pathobiology and Population Medicine, College of Veterinary Medicine; Jessica Wells, Assistant Clinical/Extension Professor, Poultry Science; and Jonathan Moon, Poultry Operation Coordinator, Poultry Science.
The Mississippi State University Extension Service is working to ensure all web content is accessible to all users. If you need assistance accessing any of our content, please email the webteam or call 662-325-2262.