This paper is in the following e-collection/theme issue:

Proposals (non-eHealth) (64) Behavior Change (861) Antimicrobial Stewardship and Antibiotic Resistance (62) Policy (74) Public Health Policy (95)

Published on in Vol 14 (2025)

Preprints (earlier versions) of this paper are available at https://preprints.jmir.org/preprint/66424, first published .
Exploring the Current Situation and Developing Strategies for Behavior Change to Improve Antibiotic Use in West Africa: Protocol for a Multidisciplinary Interventional Research Project

Exploring the Current Situation and Developing Strategies for Behavior Change to Improve Antibiotic Use in West Africa: Protocol for a Multidisciplinary Interventional Research Project

Exploring the Current Situation and Developing Strategies for Behavior Change to Improve Antibiotic Use in West Africa: Protocol for a Multidisciplinary Interventional Research Project

Authors of this article:

Maresa Neuerer1 Author Orcid Image ;   Carine Baxerres2 Author Orcid Image ;   Denise Dekker3 Author Orcid Image ;   Blandine Bila4 Author Orcid Image ;   Daniel Arhinful5 Author Orcid Image ;   Leslie Mawuli Aglanu3, 6, 7 Author Orcid Image ;   Charity Wiafe Akenten3, 6 Author Orcid Image ;   Boubacar Coulibaly8 Author Orcid Image ;   Ali Sié8 Author Orcid Image ;   John Humphrey Amuasi3, 6, 9 Author Orcid Image ;   Aurélia Souares1, 10 Author Orcid Image
Article Authors Cited by Tweetations (1) Metrics

    Protocol

    1Heidelberg Institute of Global Health, Heidelberg University, Heidelberg, Germany

    2Institut de Recherche pour le Développement, Laboratoire Population Environnement Développement, Aix-Marseille Université, Marseille, France

    3Bernhard Nocht Institute for Tropical Medicine, Hamburg, Germany

    4Département Biomedical/Santé Publique, Institut de Recherche en Sciences de la Santé, Ouagadougou, Burkina Faso

    5Noguchi Memorial Institute for Medical Research, University of Ghana, Accra, Ghana

    6Kumasi Centre for Collaborative Research in Tropical Medicine, Kumasi, Ghana

    7University Medical Centre Groningen, University of Groningen, Groningen, The Netherlands

    8Centre de Recherche en Santé de Nouna, Nouna, Burkina Faso

    9School of Public Health, Kwame Nkrumah University of Science and Technology, Kumasi, Ghana

    10German Center for Infection Research, Heidelberg, Germany

    Corresponding Author:

    Maresa Neuerer, MSc

    Heidelberg Institute of Global Health

    Heidelberg University

    Im Neuenheimer Feld 130.3

    Heidelberg, 69120

    Germany

    Phone: 49 6221 56 5044

    Fax:49 6221 56 5948

    Email: maresa.neuerer@uni-heidelberg.de


    Background: Antimicrobial resistance (AMR) is recognized as a global concern, with particularly severe consequences in low- and middle-income countries. Although it may occur naturally, it is also an anthropogenic problem linked to the irrational use of antibiotics in humans and animal husbandry and the use of pesticides in plant agriculture. Generally, data on AMR and evidence of effective and feasible multifaceted interventions are limited in many African countries.

    Objective: This study aims at (1) assessing baseline data on AMR pathogens in Burkina Faso and Ghana; (2) understanding perceptions and quantifying use of antibiotics among health care workers, communities, and livestock farmers; and (3) defining and refining an AMR intervention using a design thinking approach.

    Methods: This multidisciplinary study will be conducted in two rural districts and will consist of two phases. First, baseline data will be collected on AMR pathogens along dominant food production chains. extended-spectrum beta-lactamase (ESBL)–producing Escherichia coli and Klebsiella pneumoniae will be selected as indicator mechanisms for AMR because of their high occurrence among animals and humans. The perception and understanding of AMR and antibiotic use among different stakeholders and community members will be assessed using epidemiologic and socio-anthropological methods. Qualitative methods will include participant observations, in-depth and key informant interviews, and focus group discussions. The quantitative part will consist of the development of an inventory of circulating antibiotics and a household survey. Second, key informant and in-depth interviews will be conducted with One Health stakeholders in preparation for the intervention development. Subsequently, multidisciplinary “design teams” will develop ideas for an intervention on AMR using a design thinking approach.

    Results: Data collection started in April 2022. The analysis of microbiological, anthropological, and socio-epidemiological data is ongoing in both countries. The intervention development has been initiated in Ghana but has not started yet in Burkina Faso. All results are planned to be submitted to peer-reviewed journals by December 2025. First, manuscripts will be published for each discipline. Afterward, the results of the 3 disciplines will be combined in multidisciplinary papers, and a publication of the evaluation of the intervention will follow.

    Conclusions: Owing to the multifactorial nature of AMR, different perspectives need to be considered to develop a holistic context-based intervention that is tailored to local needs. This study stands out in its combination of different disciplinary and epistemological perspectives following the One Health paradigm and taking a design thinking approach to develop an intervention. Thereby, collaboration across disciplines and social levels and a participatory bottom-up approach will be promoted to achieve a common understanding of problems and needs and to develop an accepted and efficacious intervention. The national AMR networks and policymakers will be continuously involved in the project.

    International Registered Report Identifier (IRRID): DERR1-10.2196/66424

    JMIR Res Protoc 2025;14:e66424

    doi:10.2196/66424

    Keywords

    antimicrobial resistanceOne Healthdesign thinkingmultidisciplinaryinterventionsub-Sahara Africamixed methods 


    Overview

    Antimicrobial resistance (AMR) is rising to dangerously high levels in all parts of the world and presents a threat to public health, food security, and (economic) development [1]. Currently, AMR is presented as being responsible for 700,000 deaths per year and could result in 10 million annual deaths per year by 2050 if no action is taken [1]. As new resistance mechanisms are emerging and spreading globally, the ability to treat common infectious diseases and enable chemotherapies, operations, and many other activities is threatened [2,3]. It is acknowledged as an urgent global problem that concerns every country irrespective of its level of income and development, but effects are hypothesized to be even more significant in low- and middle-income countries (LMIC) [1,4]. In social sciences, however, experts highlight how AMR can be exploited for political ends [5], the invisibility of several causes of AMR [6], and significant scientific knowledge gaps on this subject [7]. Legido-Quigley et al [8] described AMR as a “wicked problem,” as it encompasses complex networks of different stakeholders with incompatible interests.

    AMR is spread via diverse agents including humans, animals, alimentation, soil, and water. Although resistance can emerge naturally through evolutionary processes [9,10], it can also occur through anthropogenic pressure resulting from an overreliance on antibiotics. Infections in humans and animals caused by extended-spectrum beta-lactamase (ESBL)–producing Escherichia coli and Klebsiella pneumoniae are increasingly resistant to most antibiotics globally due to their high diversity and rapid mutation [11,12]. The evaluation of these two gram-negative bacteria could serve as an important indicator for the prevalence of AMR in local settings.

    It is critical to recognize how human practices interact with natural microbial ecology in compounding AMR risks. Within the human health sector, the reliance on broad-spectrum antibiotics, especially in the absence of diagnostics, has been identified as a major contributor to the emergence of AMR [13]. The widespread use of antibiotics in livestock exceeds direct human consumption and is driven by economic imperatives to maximize production, prevent disease, and enhance growth [7,14,15]. As most of these antibiotics are not fully metabolized but released into the environment as waste products, misguided antibiotic use has a concurrent ecological impact by affecting wild bacteria populations and promoting further antibiotic resistance development [16]. This highlights the ecological consequences of antibiotic misuse and the entangled nature of environmental, agricultural, and health systems. Additionally, the soil contains microorganisms with naturally occurring genes that can facilitate the development of AMR in the natural environment [3,7].

    The relevance of this research project is multifaceted: First, the availability of information on AMR in Africa is limited. This stems from weak laboratory and surveillance systems and processes, where only a small fraction of facilities conducts bacteriological testing and the microbiological data that do exist are often of poor quality [4,17,18]. Similarly, more data on antibiotic consumption and access to health care in animal and human health are needed [19]. In addition, a One Health approach should be implemented in future studies to develop efficient interventions on AMR and improve AMR surveillance and control in Africa [19,20]. Second, the rates of AMR are higher in certain LMIC, while individual antibiotic consumption is lower in comparison with high-income countries, indicating that other factors are influencing the prevalence of AMR [9]. Third, the effects of AMR on various societal sectors, including health and economic consequences, risk being more significant in African countries due to predominant livelihoods and living conditions [21,22]. In recent years, the use of antibiotics in LMIC has increased substantially both for humans and animals because of economic growth and changes in diet [23]. At the same time, antibiotic policies concerning manufacture, dispensation, and prescription in many LMIC are often missing or lacking regulatory enforcement due to socioeconomic challenges, large population size, and challenged health care systems [24]. Fourth, the current body of literature “has created little clarity about what interventions are best suited to achieve AMR goals across contexts, cultures and health systems” [25]. The need to act on AMR at a global level is well-known and agreed upon; however, an implementation gap of action and interventions can be observed [26]. Evidence of effective and feasible multifaceted interventions in sub-Saharan African countries is limited, and studies show that challenges for implementation of interventions are numerous. Nevertheless, several initiatives at international and local levels have demonstrated that effective interventions are feasible in LMIC and that contextualization is essential [27].

    Study Objectives

    This paper presents the study protocol for a multidisciplinary research project on AMR in 2 districts of Burkina Faso and Ghana using a One Health perspective and design thinking approach. The study has the following aims: (1) assessing baseline data on AMR pathogens along the food chain in the Kossi Province, Burkina Faso, and the Asante Akim North District, Ghana; (2) understanding and quantifying perceptions and use of antibiotics among health care workers, communities, and livestock farmers as well as defining patterns of access and utilization of antibiotics; and (3) defining and refining an intervention aimed at reducing the impact of AMR and improving the way this issue is addressed using a stakeholder-driven approach.


    Study Setting

    The research project will be conducted in Burkina Faso and Ghana, both located in the West African subregion. The research site in Burkina Faso is the rural Kossi Province, located in the northwest of the country and corresponding to the Nouna Health District. The population is mostly living in the semi-urban town Nouna, representing the administrative center of the province [28]. Nouna Health District has a population size of about 320,232 inhabitants and a surface area of 7464 km2 [28]. The main economic activities are farming and animal breeding [29]. A Health and Demographic Surveillance System has been established in the province and is managed by the Centre de Recherche en santé de Nouna (CRSN; Nouna Health Research Center). Burkina Faso has a national human and animal surveillance system for AMR consisting of 15 designated laboratories since 2018 and is enrolled in the Global Antimicrobial Resistance and Use Surveillance System (GLASS) of the World Health Organization (WHO) but is not yet reporting data to the system [30]. Burkina Faso’s National Action Plan (NAP) was published in 2018 but has not been implemented by the government yet [30].

    The research site in Ghana is in the semi-urban and rural Asante Akim North District, which is in the eastern part of the Ashanti Region. The district has a size of 1218 km2 and approximately 85,788 inhabitants [31]. Approximately 72% of the district’s work force is employed in the agrarian sector [32]. Multiple health institutions are serving in the district and are constituted by private sector actors, religious missions, and public sector actors [32]. Ghana is enrolled in the WHO GLASS. However, there is no precise nationwide surveillance system on antimicrobial use and AMR prevalence, and no data were contributed in 2020 and 2021 [33-36]. The establishment of a nationwide AMR surveillance system is outlined in the NAP but has yet to be implemented [36,37]. Ghana is considered a leading country on the African continent for handling AMR due to its work and approach including the establishment, in 2011, of the Ghana National Policy Platform on AMR, which consists of various stakeholders from diverse institutions and sectors, thereby integrating the One Health approach [36]. Moreover, the NAP on AMR (2017-2021) and a policy document on antimicrobial use and resistance were officially launched in April 2018 in the country [36,38]. However, policy and project implementation is lagging due to poor coordination of the different stakeholders, insufficient financial resources and infrastructure, and enforcement of regulations [36].

    Ghana and Burkina Faso are neighboring countries but different in many respects, such as the socioeconomic level, the structure of the health system, the presence of industries, and national security. Therefore, it would be of interest to contrast the information collected between the two study sites and to see the influence of these factors on AMR and what this could mean for possible interventions. In addition, through the development of a south-south collaboration between the two countries, knowledge can be shared, and synergy effects can be used for a holistic approach to AMR.

    Study Design

    Overview

    This research project consists of 2 phases (Figure 1). Phase 1 consists of multidisciplinary research on AMR, looking at it from different perspectives, namely, microbiology, anthropology, and socioepidemiology. This will consist of baseline data collection on AMR pathogens (ie, microbiology [1.1.]) We will explore perceptions and use of antibiotics among health care workers, communities, subsistence and semi-intensive livestock farmers, and institutional actors (ie, anthropology [1.2.] and socioepidemiology [1.3.]). Thereby, we are following an exploratory sequential mixed methods design by initially using qualitative methods to then develop quantitative tools in the next step. In the second phase, we will use a design thinking approach to develop a targeted intervention in collaboration with different stakeholders to improve the way of addressing the issue of AMR (ie, interventional research component [2.]). The identified stakeholders will be involved from the beginning of the project, with their opinions and perceptions of the problem and suggested solutions prioritized in the design thinking process.

    Figure 1. Research design: triangulation between 3 disciplines to develop an intervention using a design thinking approach. AMR: antimicrobial resistance.
    Phase 1.1: Microbiology

    First, we will assess baseline data on AMR pathogens along the dominant food chains: poultry in Ghana and poultry and beef in Burkina Faso. ESBL-producing E. coli and K. pneumoniae will be selected as the indicator mechanisms due to their high prevalence among animals and humans. Farms will be included in the sample if their poultry or cattle are sent to the local abattoir and sold in sampled local markets and retail shops. Due to local practices, the AMR prevalence will also be tested among free-range, so-called backyard, chickens in the villages.

    A total of 1500 fecal samples will be collected from poultry, along with 500 meat samples from markets, 200 from retail shops, and 100 from abattoirs. During each sampling visit, individual fecal droppings from broilers (on poultry farms) or cattle (on farms) will be collected in sterile containers. These samples will then be placed in a transport box maintained at 2 °C to 4 °C to ensure proper preservation. In markets, retail shops, and the abattoir, meat samples of approximately 1 gram each will be collected into a sterile plastic bag and transported on ice to the Kumasi Centre for Collaborative Research in Tropical Medicine laboratory in Kumasi. In a biosafety cabinet, the samples will be transferred into sterile disposable petri dishes, and the meat will be diced into smaller pieces with a sterile surgical blade and transferred into Brain Heart Infusion (Oxoid) broth. After incubation at 37 °C for 18 hours to 24 hours in normal atmosphere, the broth will be plated on Chromagar supplemented with ESBL-selective antibiotics (CHROMagar) and incubated at 37 °C for 18 hours to 24 hours. Presumptive E.coli colonies and K. pneumoniae colonies will be subcultured onto Columbia blood agar and further tested using biochemical methods. Antibiotic sensitivity testing will be performed using the Kirby-Bauer method, and ESBL confirmation will be conducted using the double-disk diffusion method. ESBL-producing bacteria under investigation will be subjected to whole genome sequencing to describe phylogenies as well as virulence and AMR. Data will be entered into a REDCap database, and bacteriological data will be analyzed using STATA (StataCorp). The number and percentage of samples along with descriptive statistics (ie, median, IQR, minimum, and maximum) will be reported for continuous non-normally distributed data. Categorical variables will have the number and percentage of patients reported. Proportions of positive test results will be calculated as percentages of positive results among all valid tests, with exact binomial 95% CIs.

    Phase 1.2: Anthropology

    Ethnographical studies, including daily immersions, participant observations, free discussions, and semistructured interviews, will be used. For the qualitative investigations in human health, a research assistant will be living in a community area of the rural town where the research will take place (Nouna in Burkina Faso, Agogo in Ghana) for a total of 12 months. He or she will become part of the community and, during an exploratory phase, will observe and talk to as many people as he or she meets during their daily life (neighbors; the people he or she meets when shopping, eating, and investigating places where medicines are distributed and care is provided). During the 12 months, he or she will travel to a rural locality around where he or she will live for 2 months and become integrated and that he or she will explore in the same way as previously in the town. Subsequently, he or she will conduct semistructured interviews in 15 households in the urban community and in 15 households in the rural locality (if possible, with the mother and the father). These households will have at least 1 child younger than 10 years and will be chosen to represent different socioeconomic statuses (“affluent” households, “intermediate” households, “deprived” households).

    For the qualitative investigations in poultry farms, ethnography will be performed in approximately one-half of the active farms in the rural town in each country. We will choose the farms according to their operating time (from before 2000 until now) and the number of animals raised (500 to 8000 chickens).

    Antibiotic use by individuals and farmers and waste management practices at the household, farm, and health care system levels will be investigated. In addition to antibiotic use, the overall living and working conditions, constraints experienced, and factors influencing health-seeking behaviors for both humans and animals will be studied. We will also explore practices of professional actors in biomedicine and veterinary medicine in addition to developing an exhaustive inventory of antibiotics in circulation. Semistructured interview guides used within the anthropology work package for the ethnographies conducted on farms and villages can be found in Multimedia Appendix 1 and Multimedia Appendix 2, respectively, and the observation guide for households in the villages for human health and animal health is shown in Multimedia Appendix 3. All other observation guides can be accessed from the corresponding author upon request. All the data will be analyzed using thematic sorting in NVivo 14, identifying redundant themes and subthemes that are relevant to understanding the social realities being studied.

    Phase 1.3: Socioepidemiology Quantitative

    A household survey about the perception of AMR and the use of antibiotics will be implemented at the community level. In Ghana, a double-stage random sampling method will be used, while in Burkina Faso, simple randomization will be used due to the availability of a Health and Demographic Surveillance System. The sample will include approximately 1000 households per country. The questionnaire will be designed using the Multi-Country Public Awareness Survey from the WHO and previous literature. It will consist of 2 sections: one for the head of the household, covering socioeconomic status, demographics, and antibiotic use in livestock and another focusing on knowledge, attitudes, and practices (KAP) related to antibiotics and AMR awareness. Participants belonging to a household will be selected randomly by the interviewer. Data collection will be conducted using tablets by two separate teams in Ghana and Burkina Faso, both of whom will undergo a 5-day training before the start of fieldwork activities.

    Data will be analyzed using STATA 17. Descriptive analysis will be conducted to summarize sample characteristics using frequencies and percentages for categorical data and means with standard deviations for linear data. Socioeconomic status will be calculated using principal component analysis and classified into quintiles. KAP will be assessed by assigning points to correct responses; respondents will then be categorized into groups based on their scores. Regression analysis will be conducted for both countries to explore associations. Collinearity will be assessed to ensure the reliability of the regression models.

    We will look at the circulation of antibiotics in the formal sector in the two districts analyzing the register of the district pharmacy for a period of 2 years. Subsequently, we will investigate the overall quantity of antibiotics according to antibiotic classes and the AWaRe classification. Results will be reported to the general population of the district.

    Phase 1.3: Socioepidemiology Qualitative

    A qualitative survey focusing on prescription patterns and perceptions of AMR will be conducted among health care providers of primary and secondary health care facilities, including Community-based Health Planning and Service compounds, health centers, policlinics, and a district hospital, using in-depth interviews and focus group discussions. Sampling will be done using a stratified purposeful sampling strategy aiming for maximum variation within the 3 strata, namely nurses, physician assistants, and medical doctors. The semistructured interview guide that will be used for this can be found in Multimedia Appendix 4. The semistructured guide developed for the focus group discussions can be accessed from the corresponding author on request. Content analysis will be applied to data coding and analysis with the COM-B (capacity, opportunity, motivation, behavior) model as the underlying framework [39].

    Phase 2: Interventional Research Component

    Using the design thinking approach (Figure 2), a targeted intervention to improve the way of addressing the issue of AMR will be developed in collaboration with different stakeholders in the second phase [40]. Within a system of overlapping nonsequential and iterative spaces of understanding, exploring, and materializing, the following steps will be repeated over time: empathize, define, ideate, prototype, test, and implement [41].

    Figure 2. Description of the design thinking approach.

    Building on the results of the previous study phase and in preparation for the workshops, key informant interviews will be conducted with institutional actors, and in-depth interviews will be conducted with community members and farmers to understand the perception and understanding of AMR among different One Health stakeholders. Institutional actors will be selected via purposeful sampling and will be eligible if involved in a One Health sector, namely animal, environmental, and human health. Community members and farmers will be sampled using a customer-exit strategy at points of sales of antibiotics. The semistructured interview guides used for interviews with farmers and community members can be found in Multimedia Appendix 5 and Multimedia Appendix 6, respectively. Interview guides for institutional actors have been jointly developed by the anthropology and socioepidemiology team and will slightly differ according to the sector of the interview partners. An example of the interview guide for the human health sector can be found in Multimedia Appendix 7. The two remaining interview guides for institutional stakeholders in the environmental and human health sector can be accessed from the corresponding author upon request. All interviews will be transcribed verbatim in French or English. Subsequently, we will code transcripts through a mixed approach of inductive and deductive coding using thematic analysis.

    The design thinking approach follows a human-centered and emerging design and is a collaborative and iterative process aiming to produce relevant results according to the needs and local situation [42,43]. Therefore, initial ideation workshops in both study sites will combine the research results collected in the first phase of the project. Research results will be discussed by workshop participants before collecting ideas on possible interventions on AMR through participatory methods. Therefore, multidisciplinary and collaborative “design teams” will be developed and include the research team, policymakers from the involved countries, and members of nongovernmental organizations working on AMR as well as health care workers, veterinary professionals, livestock farmers, and community members. Discussions will be recorded and transcribed, followed by qualitative data analysis to summarize the ideas generated for an intervention on AMR. Based on these results, the design teams will meet again in each study site to develop the prototype of an intervention. Although the outcome of the design teams’ work will depend on this participatory process, we assume that the intervention could possibly be targeting the community level due to the variety of stakeholders involved in the intervention development. Generally, interventions at the community level, such as education interventions, have been shown to result in positive changes in knowledge and attitudes; however, there is a lack of evidence on the effect of improved knowledge on behavior change [44].

    The intervention will be implemented in Kossi Province and Asante Akim North District and evaluated using a mixed methods triangulation approach combining questionnaires and interviews with stakeholders at different levels to evaluate the process and outcome of the intervention. This will allow refinement and modification of the intervention according to the local needs. Eventually, dissemination meetings will be organized, and policy briefs will be written to ensure wide access to the results by policymakers and scientists in the countries of interest and abroad. In addition, continuous contact with policymakers and the national AMR networks in Burkina Faso and Ghana from the beginning of the research process has the potential to increase the acceptability and scaling of the developed intervention.

    Ethical Considerations

    Ethical approval was obtained from the ethical committee of Heidelberg University Hospital (S-826/2021), National Ethical Committee in Burkina Faso (number 2021-12-270), Nouna Health Research Centre ethical committee (number 2021-018-MS/SG/INSP/CRSN/CIE), Kwame Nkrumah University of Science and Technology Committee on Human Research Publication and Ethics (CHRPE/AP/580/21), and Ghana Health Service Ethics Review Committee (GHS-ERC 004/11/21).

    Informed consent and the ability of participants to opt out of the study at any point will be provided together with an information sheet on the project. Additionally, all data will be de-identified to ensure privacy and confidentiality. All recordings will be deleted once transcription is completed and checked. Participants of the workshops in phase 2 will receive beverages and a meal during the workshops and compensation for their attendance once the workshop has ended, as this presents a day-long commitment. Otherwise, no compensation will be provided for study participants.


    The study received funding in May 2021. Ethical approvals were granted from the various committees between November 2021 and April 2022. Renewal of the ethical approval is requested and received annually from the Kwame Nkrumah University of Science and Technology Committee on Human Research Publication and Ethics.

    Data collection started in April 2022 and was completed in November 2023. For the quantitative socioepidemiology part, we conducted a cross-sectional survey among 1114 participants in Ghana and 1011 participants in Burkina Faso. These numbers were based on prior sample size calculation and reflect completed data collection as of November 2023. Qualitative components in the anthropology work package included daily immersions, participant observations, free discussions, and semistructured interviews, and semistructured interviews and focus group discussions in the socioepidemiology work package. Given the exploratory nature of these methods, participants were recruited progressively across multiple target groups, with data collection continuing until saturation was reached.

    The analysis of the microbiological, anthropological, and socioepidemiological data is ongoing in both countries. The intervention development has been initiated, and the first prototype meeting took place in Ghana in July 2024. The pretesting of the intervention in Ghana is expected to be completed by August 2025. The process of intervention development has not started yet in Burkina Faso, as we are experiencing a delay due to the political situation. All results are planned to be published in peer-reviewed journals before December 2025. Initially, the 3 disciplines involved in the research will analyze their data separately while exchanging information on a regular basis. This will also allow us to put the different results into perspective. For example, to combine microbiological and anthropological results, parasite resistance rates on a specific farm will be considered alongside observations of antibiotic use on the same farm. This could include an assessment of whether resistances described by microbiologists in the geographical contexts studied can be understood based on the descriptions of perceptions and uses of medicines produced by anthropologists in the same context. The congruence or noncongruence of the overall analysis between the disciplines will then be discussed and problematized. Eventually, without strictly comparing our results on each of the questions addressed, we will propose scientific articles providing an overall interpretation of AMR, cross-referenced between microbiology and anthropology and between microbiology, socioepidemiology, and anthropology. Results will not be strictly compared for each question addressed but will be embedded in a holistic analysis of AMR in the specific study contexts.

    First, manuscripts will be published for each discipline. Afterward, the results of the 3 disciplines will be combined in multidisciplinary papers, and a publication of the evaluation of the intervention will follow.


    Overview

    Research has shown that “magic bullet” approaches to AMR focusing on highly technological and biomedical approaches such as surveillance and the development of new antibiotics will not be sufficient to combat the global and multifactorial problem of AMR [13,45]. Even though we currently do not have much data on the prevailing situation in the regions we will be studying, we know that the irrational use of antibiotics in humans and animals significantly contributes to AMR [3,10,26]. Policies and underlying infrastructure of antibiotics, perceptions, understanding, and knowledge of stakeholders and community members need to be understood to develop sustainable and effective solutions while considering their social and economic capital as well as behavioral, ethical, political, and cultural factors [4,15,26,45]. Therefore, the multifactorial nature of AMR, the diverse reasons and drivers underlying the use of antibiotics, and the local contexts and constraints need to be considered and integrated into all efforts.

    Phase 1

    The first phase of the research project will add to the field of One Health by examining the issue of AMR from microbiology, anthropology, and socioepidemiology perspectives. Therefore, this study will address the challenge of disciplinary silos through close multidisciplinary collaboration. It stands out in the combination of different disciplinary and epistemological perspectives through multilateral collaboration between the Burkinabe, Ghanaian, German, and French research institutions. Microbiological data will contribute to a clear picture of prevalent resistance in animals and improve the biomedical understanding of AMR in the study sites. Generally, both AMR surveillance and data on AMR are limited in western sub-Saharan Africa [46]. Furthermore, available studies are mostly done at the health care level, investigating resistance levels in ESBL-producing E. coli and Klebsiella spp. isolates [46] or in febrile children younger than 5 years [47]. Few studies exist on ESBL-producing E. coli and Klebsiella spp. in livestock; however, these have been conducted in urban settings such as Ouagadougou in Burkina Faso [48]. Data on AMR bacteria and their genotype distribution in meat are still scarce especially in rural areas of Ghana and Burkina Faso, for example. In our study, strains will be genotyped to describe phylogenies, mechanisms of resistance, and virulence. Data collected from livestock can also be compared with a human strain collection of an ongoing AMR surveillance system in the 2 districts where the study is implemented in order to describe transmission reservoirs in these parts of Africa.

    Anthropological studies will add to the understanding of antibiotic access and utilization patterns, perceptions, and uses of antibiotics among human and animal health care workers, communities, livestock farmers, medicines suppliers, and institutional actors. It will also identify and outline the constraints and enablers of these actors and how these factors influence their behavior. The socioepidemiology data collected among health care workers will generate knowledge on their perception of AMR and the logic of their prescription patterns, while the household survey will quantify community members’ knowledge of antibiotics, AMR, and antibiotic consumption practices. The anthropology and socioepidemiology perspectives will enable a description of the underlying infrastructure and the social, cultural, economic, and political structures that impact the development and spread of AMR. Thereby, this study will add to available literature on health care–seeking behaviors outside of health care facilities, antibiotic use across different levels of health care providers, and access among community members in Burkina Faso [49-51]. Furthermore, by combining the microbiological data on AMR with the perception of institutional actors at different levels, community members, and farmers, we will be able to develop a holistic description of the situation in the 2 study sites. This will represent a necessary step to develop an intervention reflecting the local context and needs.

    Phase 2

    The second phase of the project will result in the development of an intervention using the design thinking approach, which is increasingly used in global health to apply social innovation for diverse health issues representing “both a social need and a social problem” [52]. A scoping review indicated that design thinking is used within various initiatives of different organizations and institutions to improve human health [52]. Design thinking is iterative, measurable, and result-driven and places the people being served in the center of the design, innovation, and implementation process [42,43]. Therefore, stakeholders’ actual needs and expectations are met, and acceptable, equitable, effective, and sustainable health solutions can be developed through this active engagement [53-55]. Design thinking consists of stakeholder and cross-disciplinary collaboration and a multistep approach to gain an understanding of the situation and context, brainstorm, test, and revise the best solution in a collaborative process [53]. Therefore, the following steps are repeated over time: define, ideate, prototype, test, and implement [41].

    The mixed methods approach and subsequent triangulation of research results will contribute to increasing knowledge and developing a holistic understanding of AMR, which is essential for the development of appropriate interventions at the study sites. Using the One Health perspective, both human and animal health will be examined in this study. The One Health approach will allow us to gain insights into the interconnection of the 2 sectors and to develop a holistic intervention that takes different perspectives and needs into account. Therefore, to follow the One Health paradigm, collaboration across disciplines will be promoted, and actors from different professions and social levels, particularly community members, will be encouraged to bring forward their ideas for solutions. By challenging disciplinary boundaries and through the collaboration of different disciplines within the research team itself and the design teams during the intervention phase, synergy effects and strengths can be brought together to capitalize on innovative potentials. This will be facilitated by a design thinking approach to support innovative potential through the close collaboration of stakeholders and community members, both directly and indirectly affected by AMR. The stakeholder-driven and participatory bottom-up approach to the multifactorial problem of AMR has the potential to result in a common understanding of needs and problems and the subsequent development of a common solution that is tailored to the local situation, context, and needs. Furthermore, it has been shown that moving away from a traditional top-down to a value-driven and participatory bottom-up approach could lead to increased efficacy and acceptability of interventions and improved antibiotic use [26].

    In addition, continuous contact with policymakers and the national AMR networks in Burkina Faso and Ghana from the beginning of the research process has the potential to increase the acceptability and scale-up of the resulting intervention that will be developed. By engaging these stakeholders, existing networks, policies, and projects will be incorporated from the first to the last phase of the design thinking approach, which will be built on existing structures and approaches to ensure acceptability, efficacy, and sustainability of the resulting intervention. Moreover, a south-south collaboration will be facilitated within the research project through sharing of competencies and technical know-how within and between the researchers and AMR networks via regular exchanges and through research and dissemination meetings.

    Limitations and Further Considerations

    The main limitation of this study is the limited involvement of the environmental sector. The influence of environmental factors on AMR has not been highlighted within the scope of this study. Currently no data have been collected from environmental sources to add to the human and animal data sources. However, we intend to complement this research with such data (collaborations are currently being developed to add this component). In addition, environmental stakeholders from the local and national levels will be included in the qualitative interviews and the development of interventions in the 2 countries.

    A diversity of approaches to AMR exists, ranging from research and development of new antibiotics; antibiotic stewardship; improved hygiene; and infection, prevention, and control to behavior change and education of patients and health care professionals. However, social scientists have identified a problematic focus on the causes of AMR linked to the behavior of individuals, both consumers and prescribers, that depoliticizes AMR and isolates it from our modes of life and economies, thereby not acknowledging that AMR is not only a natural phenomenon but also a social fact [56]. Therefore, social scientists urge us to question our way of living in the world, caring for it, and taking care of it [56]. We acknowledge that AMR is a complex and multifaceted issue that needs to be addressed at different levels, taking social and systemic factors into account. For this study, we decided to focus on the behavioral aspects, as these are proven to be an important factor contributing to AMR and lie within the scope of our community-based and participatory approach to develop an intervention. Nonetheless, systemic challenges might become clear within the course of our project and provide important insights for future research projects and policy and decision makers.

    Although this study’s multidisciplinary approach offers innovative potential through the close collaboration of different disciplines during continuous (online) meetings and design thinking workshops, it will also present a challenge due to different perspectives, epistemologies, and methodologies. Furthermore, considering current realities and power relations within science, between disciplines and institutions in the so called “Global North” and the “Global South,” we acknowledge that the approach we are promoting through this work, although bottom-up and participatory through actively including community members and other stakeholders, can be challenged from many points of view. Therefore, this study will provide useful insights on how to mitigate such challenges and ensure equitable collaboration.

    The generated results will be primarily relevant to the districts of the research project. However, due to direct contact with local, regional, and national stakeholders, the developed intervention can serve as a pilot project for a subsequent scale-up within Burkina Faso and Ghana, as well as other countries. It is expected that these interventions will contribute to improving the way the issue of AMR is addressed among communities, health care providers, livestock farmers, and institutional actors in LMIC. If the interventions in Kossi Province and Asante Akim North District provide positive results, the potential scale-up will be supported by the research team. To facilitate this process, national stakeholders will be informed and engaged right from the project’s inception. The results of this study will provide rigorous scientific evidence on the prevalence of AMR along the dominant food production chains and the perspectives and understanding of AMR among community members and stakeholders from the animal, environmental, and human health sectors in the 2 districts in Burkina Faso and Ghana. Furthermore, insights will be provided regarding the development of an AMR intervention through a participatory bottom-up approach using the design thinking process and the multidisciplinary One Health perspective.

    Acknowledgments

    We would like to thank all members of the AMR-B-CHANGE consortium: Alice Bila, Alphonse Zakané, Anastasia Seferiadis, Dramane Kiemdé, Elisenda Cama i Gibernau, Ellis Paintsil, Hélène Sawadogo, Kristina Schottmayer, Marc Egrot, Neyaz Khan, and Stefan Berg.

    Following a competitive grant application and review process, the research project is funded by the French National Research Agency (ANR) and the German Federal Ministry of Education and Research (BMBF; ANR-20-AMRB-0002-01 and 01KI2129A). MN further acknowledges Hans Böckler Foundation as the funder of her PhD. For the publication fee, we acknowledge financial support from Heidelberg University. The funders had no role in the design, data collection, analysis, interpretation of data, or manuscript writing.

    Data Availability

    The data sets used and analyzed during this study will be available from the corresponding author on reasonable request.

    Authors' Contributions

    AS, DD, CB, ASi, and JHA conceived the study, developed the concept, and drafted the study protocol. DD, CWA, and BC developed the sampling procedure, laboratory processes (collection and analyses of the samples), and data processing for the microbiology part. CB, DA, and BB developed the methodology, selected the research units, collected the data, and analyzed the data for the anthropology component. AS developed the socio-epidemiology component part, with JA, ASi, and LMA, for the health care worker qualitative survey and the community survey. LMA, JHA, BC, and ASi were responsible for the ethical aspects and ethical committee procedures. The co-authors contributed to this manuscript in the aforementioned sections according to their contribution to the aforementioned development of the different work packages. Finally, all co-authors have read and approved this manuscript, which was written by MN.

    Conflicts of Interest

    None declared.

    Multimedia Appendix 1

    Interview guide in intensive or semi-intensive livestock farms.

    DOCX File , 20 KB
    Multimedia Appendix 2

    Interview guide in villages for human and animal health.

    DOCX File , 21 KB
    Multimedia Appendix 3

    Observation guide and open discussion with households in the villages for human health and animal health.

    DOCX File , 20 KB
    Multimedia Appendix 4

    In-depth interview questionnaire for health care workers in the Ashanti region, Ghana.

    DOCX File , 25 KB
    Multimedia Appendix 5

    IDI Interview Guide for Farmers in Asante Akim North Municipality.

    DOCX File , 20 KB
    Multimedia Appendix 6

    IDI Interview Guide for Community Members in Asante Akim North Municipality.

    DOCX File , 20 KB
    Multimedia Appendix 7

    Interview Guide (Institutional) Actors AMR – Human Health.

    DOCX File , 19 KB
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    AMR: antimicrobial resistance
    COM-B: capacity, opportunity, motivation, behavior
    CSRN: Centre de Recherche en santé de Nouna
    ESBL: extended-spectrum beta-lactamase
    GLASS: Global Antimicrobial Resistance and Use Surveillance System
    KAP: knowledge, attitudes, and practices
    LMIC: low- and middle-income countries
    WHO: World Health Organization

    Edited by A Schwartz, J Sarvestan; submitted 12.09.24; peer-reviewed by S Sariola; comments to author 09.01.25; revised version received 01.03.25; accepted 30.05.25; published 25.07.25.

    Copyright

    ©Maresa Neuerer, Carine Baxerres, Denise Dekker, Blandine Bila, Daniel Arhinful, Leslie Mawuli Aglanu, Charity Wiafe Akenten, Boubacar Coulibaly, Ali Sié, John Humphrey Amuasi, Aurélia Souares. Originally published in JMIR Research Protocols (https://www.researchprotocols.org), 25.07.2025.

    This is an open-access article distributed under the terms of the Creative Commons Attribution License (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work, first published in JMIR Research Protocols, is properly cited. The complete bibliographic information, a link to the original publication on https://www.researchprotocols.org, as well as this copyright and license information must be included.