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Journal article
Current Challenges and Potential Strategies to Enhance Efficacy of Oral Phage Therapy in Food Animals: A Systematic Review with Quantitative Analysis
Viruses, Vol.18(5), 544
2026
Abstract
Phage therapy has enormous potential in combating bacterial resistance in food animals. However, its application via the oral route remains limited due to challenges associated with the gastrointestinal tract (GIT) environment and a lack of rigorous clinical trial evidence. Therefore, we systematically searched in Google Scholar, PubMed, Scopus, and Web of Science databases following PRISMA guidelines and finally identified 111 articles on oral phage therapy in food animals from where we summarized the key physiological and chemical factors of the gut environment hindering the effectiveness of oral phage therapy (OPT), examined the methods used to evaluate phage stability in the GI environment, and highlighted potential strategies to mitigate these challenges. In addition, we performed quantitative analysis to visualize in vitro pH and thermal stability patterns of phages targeting bacteria isolated from food animals and variability in buffer and incubation period across stability studies. The GIT consists of several anatomically and functionally distinct segments, where complex interactions occur among digestive enzymes, gastric acids, electrolytes, commensal microbiota, and mucosal immune components. The acidic pH of the stomach is a major barrier to successful oral phage delivery. According to our analysis of pH stability testing data from the reviewed studies, most phages targeting antimicrobial-resistant bacteria in food animals remained stable at pH 5–9 and inactivated under highly acidic (pH ≤ 2) or highly alkaline (pH ≥ 11) conditions. In addition, phages are susceptible to high temperatures (above 60 °C), digestive enzymes (e.g., pepsin, trypsin, lipases), bile salts, and host immune responses. Several in vitro laboratory techniques are available to assess phage stability under simulated GI conditions, but variations occur in the assessment protocols. Microencapsulation using alginate and chitosan has been used to protect phages from the adverse GI environment. Additionally, enteric-coated capsules, antacids, co-encapsulation with acid-neutralizing agents, consumption of alkaline water, and daily phage administration are suggested to improve phage survival and efficacy. For the successful clinical implementation of OPT in food animals, future research should focus on elucidating the molecular and physicochemical determinants of phage stability, understanding the humoral immune response to OPT, standardizing laboratory protocol for assessing phage viability, improving the scalability of encapsulation methods, and exploring other potential delivery techniques.
Details
- Title
- Current Challenges and Potential Strategies to Enhance Efficacy of Oral Phage Therapy in Food Animals: A Systematic Review with Quantitative Analysis
- Authors/Creators
- Md Ashiqur Rahman - Murdoch UniversityRebecca Abraham - Murdoch UniversityDavid J. Hampson - Murdoch UniversitySam Abraham - Murdoch UniversityJasim M. Uddin - Murdoch University
- Publication Details
- Viruses, Vol.18(5), 544
- Publisher
- MDPI
- Identifiers
- 991005883279107891
- Copyright
- © 2026 by the authors.
- Murdoch Affiliation
- Harry Butler Institute; School of Medical, Molecular and Forensic Sciences; School of Veterinary Medicine; Centre for Animal Production and Health
- Language
- English
- Resource Type
- Journal article
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