key: cord-0709597-9nhf2a5u authors: Nagel, Tobi; Musila, Lillian; Muthoni, Milkah; Nikolich, Mikeljon; Nakavuma, Jesca L; Clokie, Martha RJ title: Phage banks as potential tools to rapidly and cost-effectively manage antimicrobial resistance in the developing world date: 2022-02-15 journal: Curr Opin Virol DOI: 10.1016/j.coviro.2022.101208 sha: 7913486d76a2206587afebe74b3df5f0c3f5ac30 doc_id: 709597 cord_uid: 9nhf2a5u Lower and middle-income countries seldom develop vaccines and therapeutics for their own populations and are dependent on supplies from industrialized countries, which are often hampered by financial or supply chain limitations. This has resulted in major delays in delivery with significant loss of life, as seen with the coronavirus pandemic. Since the vast majority of deaths from the antimicrobial resistance crisis are expected to occur in developing countries, there is an urgent need for in-country production of antibacterial therapies such as phages. Nationally controlled phage banks might provide such a solution since locally developed phage therapies tailored to endemic bacterial strains could offer cost-effective antibiotic alternatives. Phage banks as potential tools to rapidly and costeffectively manage antimicrobial resistance in the developing world Tobi Nagel 1 , Lillian Musila 2 , Milkah Muthoni 3 , Mikeljon Nikolich 4 , Jesca L Nakavuma 5 and Martha RJ Clokie 6 Lower and middle-income countries seldom develop vaccines and therapeutics for their own populations and are dependent on supplies from industrialized countries, which are often hampered by financial or supply chain limitations. This has resulted in major delays in delivery with significant loss of life, as seen with the coronavirus pandemic. Since the vast majority of deaths from the antimicrobial resistance crisis are expected to occur in developing countries, there is an urgent need for incountry production of antibacterial therapies such as phages. Nationally controlled phage banks might provide such a solution since locally developed phage therapies tailored to endemic bacterial strains could offer cost-effective antibiotic alternatives. When global epidemics occur, developing countries receive essential medicines much later than industrialized nations do. For example, during the HIV/AIDS crisis, death rates in the US started to plummet a full decade before numbers in African countries began to abate because it took that long for the poorer countries to procure adequate supplies of antiretroviral drugs [1] . And while the US has more than enough coronavirus vaccines to fully vaccinate its entire population, African nations only have enough for an average of 5.8% of their populations [2,3]. A similar delay in drug delivery from industrialized countries will likely occur for the antimicrobial resistance (AMR) crisis, which by 2050 is expected to kill five times more people annually than either HIV/ AIDS or COVID-19 have -with roughly 90% of the AMR deaths occurring in Africa and Asia [4 ]. To avoid this catastrophe with AMR, developing countries must gain greater autonomy and capacity to develop and manufacture antibiotic alternatives for their own populations, rather than rely on receiving newly developed drugs from industrialized countries. This is a daunting task, but one that might be achieved by using naturally occurring bacteriophages (phages), which are viruses that can kill bacteria, including antibiotic-resistant strains. Collections of locally isolated, pre-characterized phages could be established as national or regional 'phage banks', which could be quickly deployed to address outbreaks of antibiotic-resistant infections. If such phage banks were managed by national health agencies with support from a network of local as well as international scientific institutions, they could provide rapid, cost-effective, in-country solutions for combating AMR. There is precedence for using phage banks in this way -the former Soviet Union did so for decades [5, 6 ] . Numerous public and private organizations in industrialized countries have already begun establishing phage banks to prepare for AMR [7,8 ,9-11,12 ,13,14] . It may be even more critical for developing nations to do so. Phages were used as antibacterial therapeutics even before antibiotics were discovered, and with the growing threat of AMR, interest in developing phage-based drugs has increased rapidly worldwide [15] . As natural viral predators of bacteria, phages work through different molecular mechanisms than antibiotics and thus are able to kill both antibiotic-resistant and antibiotic-sensitive bacteria. Phages also kill bacterial species more specifically than broad-spectrum antibiotics do; as a result, phages can protect patients' microbiomes. Furthermore, unlike conventional antibiotics, phage products can be designed to minimize future bacterial resistance against them or even cause bacteria to become resensitized to antibiotics [16 ] . Over the past century, a number of institutions have established large repositories of phages targeting a wide range of bacterial species. Perhaps the best known are the phage banks in the former Soviet Union, particularly at the Eliava Institute of Bacteriophages, Microbiology and Virology, now in the country of Georgia, which contains more than 1000 phages, and the Hirszfeld Institute of Immunology and Experimental Therapy in Poland, which has more than 850 phages [17, 18] . Tens of thousands of patients have received phage treatment via these two institutions, often with individually customized phages selected for their ability to specifically kill each patient's infecting bacteria. In other cases, the broad collections of phages have been screened against disease-causing bacteria found to be circulating in the general population, then pre-set phage mixtures are made available as over-the-counter treatments. Importantly, those pre-set mixtures -typically called phage cocktails are screened twice a year to make sure they are still active against the currently circulating bacteria; if not, the cocktails are updated [6 ,19,20] . This approach of developing cocktails for the general population -rather than employing personalized phage therapy for individualsmight be particularly valuable for developing countries. Other phage banks have been established largely to provide resources for laboratory research. The longeststanding of those include the Felix d'Herelle Reference Center for Bacterial Viruses in Canada (>400 phages), the American Type Culture Collection (ATCC) in the US (350 phages), the German Collection of Microorganisms and Cell Cultures (also known as DSMZ; with 450 phages), the National Collection of Type Cultures (NCTC) in the UK (>100 phages), and the Bacteriophage Bank of Korea (>1000 phages). In the past few years, more banks have been set up specifically to provide phage therapy for patients, with funding primarily through governmental grants as well as some private donations. These include banks at the Queen Astrid Military typically set up to provide treatment for individual patients in situations when other treatment options have been exhausted. The phages can be approved through expanded access (often called 'compassionate use') regulatory pathways, which can apply to either emergency or non-emergency clinical cases. Some of these banks also use their phage collections to formulate phage cocktails for clinical trials and product development by more conventional regulatory pathways. In Belgium, the magistral phage pathway has been established, through which phage collections can be used for routine therapy for individuals, and this system is being considered by other countries in Europe. A number of academic research groups and companies around the world have also established collections of phages, with some of those containing more phages than the formalized phage banks listed above and some banks focused on a narrow set of pathogens. A notable example is the SEA-PHAGES collection hosted at the University of Pittsburgh, through which more than 19 000 phages have been isolated, mostly targeting soil dwelling nonpathogenic mycobacteria, although including some phages that target related pathogenic mycobacteria that have been used for clinical phage therapy [21] . Many aspects of phages make them particularly wellsuited for use in the developing world. Most importantly, phages are able to kill antibiotic-resistant bacteria, a crucial treatment need as antibiotics fail at alarmingly high rates in developing countries. In addition, phages can be isolated locally using laboratory equipment that is readily available to scientists in developing countries. In fact, it is often best to isolate phages in the region where they will be used, since phages naturally adapt to target strains of bacteria that have evolved locally. It is also relatively inexpensive to isolate, characterize and propagate phages. This aspect of phages could help overcome a key problem in the worldwide antibacterial drug market: conventional drug development is so expensive that companies cannot recoup their development costs by selling the antibiotics. In fact, several companies that have developed effective new antibiotics have recently gone bankrupt when sales revenues could not cover operating costs [22] . Antibacterial drugs simply cannot garner the same high prices as other drug classes. The problem is exacerbated by the fact that public health policies dictate that any new drugs that can successfully kill antibiotic-resistant bacteria should be held in reserve as last-line treatments -thereby minimizing any reimbursements that companies might be able to gain from developing good drugs. This has prompted global policymakers to propose new financial incentives for antibacterial drugs, with minimal success thus far. Ultimately, local phage banks could enable national or regional control of phage-based drugs to help manage antibiotic-resistant outbreaks, thereby decreasing dependence on drug delivery from industrialized countries. Furthermore, if phages could be manufactured locally, this could decrease costs and logistics, since the phage products would not need to be shipped from overseas [23] . This might be accomplished through partnerships with existing organizations such as GAVI or GALVmed, which currently manufacture medicines for people as well as livestock in developing countries. Realistically, producing purified phages at scale would likely require collaborations with experts in developed countries, at least initially. But this technology transfer could be achieved over time, with the added benefit of providing new in-country jobs. Developing and manufacturing phage products locally could also increase community trust in the drugs, as long as safety and efficacy was demonstrated and the product quality was certified. An example of such "national pride" and associated social acceptance seems to be observed with a traditional (non-mRNA) COVID-19 vaccine that has recently been manufactured in Vietnam, Thailand and Brazil for clinical trials in those countries [24, 25] . Theoretically, the ideal organization for phage banks would be to have each bank managed by a central authority within each country. We envision that such banks would be hosted at government-funded universities or research institutions and supported with public and philanthropic funds, such as the examples currently being tested in Belgium, the US, Israel, the Netherlands and Australia. Phage banks within neighboring countries should be set up to coordinate rapid responses to regional outbreaks. The phages best suited to fight the outbreak should be used, regardless of the country where the phage originated -acknowledging that bacteria and phages can easily cross national boundaries. Thus, contracts and licensing agreements would need to be in place to recognize the phages as goods to be used for general public benefit, rather than as products controlled exclusively by private enterprise. Using in-country-derived phages in this way would be consistent with the Nagoya Protocol, an international agreement designed to 'provide for the fair and equitable sharing of benefits arising from the utilization of genetic resources' [26] . This would be a drastic shift from traditional drug development in which pharmaceutical companies drive the development of new antibacterial products. Instead, nationally appointed agencies would curate well-characterized endemic phages -and ideally provide phage products at cost or at supplemented rates. Realistically, public-private partnerships would likely be needed for some aspects of developing optimized phage cocktails, then manufacturing and disseminating them. The exact nature of such contractual details would undoubtedly be country-specific and complex, but establishing such agreements would be essential if phage banks are to be used to save lives in developing countries. For phages to be safely delivered through such a centralized system, phage bank facilities would need standardized management systems following agreed-upon guidelines, such as those defined by the International Organization of Standardization (ISO), the Minimum Information About Biobank Data Sharing (MIABIS), or the International Society for Biological and Environmental Repositories (ISBER). These include requirements such as stable and secure databases, efficiently monitored storage facilities with access controls, as well as robust power supply backup systems. In addition, there would need to be standardized protocols for each step of the processing pipeline, including phage isolation, characterization, purification and routine quality control testing. Requirements for genomic and phenotypic data should also be standardized to allow easy phage selection, particularly in outbreak situations [27] . Ideally, well-characterized bacterial host strains would also be available, potentially secured through national AMR surveillance programs. Recently isolated bacteria could then be screened against the phage bank at regular intervals to select phage cocktails that could kill the problem bacteria similar to the system that has been employed in the former Soviet Union for decades. All of this would require technically competent staffing, as well as oversight by governmental regulatory bodies, institutional review boards, and ethics committees relevant to each country. Over the past 5-10 years, research groups in at least 13 countries in Africa have begun isolating phages, including in Eastern Africa (Ethiopia, Kenya, Tanzania, Uganda), Western Africa (Benin, Burkina Faso, Cote d'Ivoire, Ghana, Nigeria and Senegal), Northern Africa (Egypt and Tunisia), and Southern Africa (South Africa). In particular, scientists from institutions across Eastern Africa have already isolated more than 450 phages, though full characterization of most of those has yet to be completed (Nagel, personal communication). With a critical mass of isolated phages in Eastern Africa, there has been interest from the local scientific community in establishing centralized phage banks there. While it might be ideal to eventually create an Eastern Africa regional phage bank, it seems most realistic to begin with country-specific phage banks, given that each nation has its own regulatory framework. National phage banks could be set up at institutions that already have the appropriate infrastructures and internationally recognized management systems in place. Some established biorepositories might fit those criteria, as they adhere to rigorous regulations for storing isolated patient specimens. For example, in Nairobi both the Kenya Medical Research Institute (KEMRI) and the International Livestock Research Institute (ILRI) are ISO-certified institutions that maintain repositories of various biological samples, with KEMRI being the nationally mandated governmental research institute for human health and ILRI focusing on safe use of livestock and associated food products. In Uganda, the College of Health Sciences at Makerere University recently established a biorepository that handles specimens according to standard operating procedures dictated by ISBER. Biorepositories such as these might provide excellent settings for initial phage bank storage. Also, the close proximity between academics and the biorepositories would facilitate easier study of phages, allowing researchers to initiate projects to unravel specific aspects of phage biology. Many of the collected phages target bacteria causing infections in humans like antibiotic-resistant tuberculosis, pneumonia, and diarrhea -some of the leading causes of death in developing countries. Others kill bacteria carried by animals that can contaminate food products such as meat, fish, dairy or agriculture crops, which can subsequently cause illness in people. Thus, these phages could be utilized through a One Health approach, recognizing that bacteria can move between people, animals and the environment. Given that more antibiotics are used in livestock than in people worldwide, the use of phages in animals could further help with the AMR crisis by slowing the development of antibiotic resistance in food sources. A paradigm shift is needed in AMR drug development to avoid huge death tolls Past and current pandemics demonstrate that the developing world should not count on receiving needed medical supplies from abroad. The traditional strategy of developing drugs in the commercial sector in industrialized countries, then utilizing government support to provide those drugs to developing countries has not worked well to address public health needs with sufficient speed and efficacy. This will be an even bigger issue for antimicrobial drugs since, if nothing is done, the death toll from AMR infections will be manyfold larger than any previous infectious disease crises -including COVID-19. Instead, there must be a paradigm shift in how antibacterial drugs are developed and distributed to underserved populations. Phages may constitute muchneeded antibiotic alternatives, and centrally organized phage banks may provide cost-effective, local mechanisms through which developing countries can effectively respond to antibiotic-resistant outbreaks. Phage treatment of human infections This paper remains one of the most comprehensive reviews of phage therapy over the past century, including discussion of the early work carried out in Georgia Processing phage therapy requests in a Brussels military hospital: lessons identified Development and use of personalized bacteriophage-based therapeutic cocktails to treat a patient with a disseminated resistant Acinetobacter baumannii infection complex case of a patient treated with phages in the US. It illustrates the value of phage banks, since the phages were obtained from three separate phage collections: from the military, a university, and a company. This demonstrated how different institutions can contribute rapidly and effectively to a successful phage therapy outcome Characterizing phage genomes for therapeutic applications The Israeli Phage Bank (IPB). Antibiotics 2020 Tailored antibacterials and innovative laboratories for phage (phi) research: personalized infectious disease medicine for the most vulnerable at-risk patients Australian phage biobanking network: phage biobank: present challenges and future perspectives This paper describes the key factors that should be considered when utilizing a centralized phage bank, based on the initial experience of establishing a government-funded bank in Australia Bacteriophage therapy: developments and directions. Antibiotics 2020 Phage selection restores antibiotic sensitivity in MDR Pseudomonas aeruginosa from phages can cause antibiotic-resistant bacteria to become re-sensitised to antibiotics. This opens up a new strategy by which phages may be used to extend the effective usage of existing antibiotics Phage therapy in Poland -a centennial journey to the first ethically approved treatment facility in Europe Phage therapy in clinical practice: treatment of human infections Metagenomic analysis of therapeutic PYO phage cocktails from Bacteriophage Introductions. PHAGE 2020 This material has been reviewed by the Walter Reed Army Institute of Research. There is no objection to its presentation and/or publication. The opinions or assertions contained herein are the private views of the authors, and are not to be construed as official, or as reflecting true views of the Department of the Army or the Department of Defense.This research did not receive any specific grant from funding agencies in the public, commercial, or not-for-profit sectors. Nothing declared.