Development of Next-Generation COVID-19 Vaccines: BARDA Supported Phase 2b Study Designs.

In response to the COVID-19 pandemic, vaccines were quickly and successfully developed and deployed, saving millions of lives globally. While first generation vaccines are safe and effective in preventing disease caused by SARSCoV-2, next-generation vaccines have the potential to improve efficacy and safety. Vaccines delivered by a mucosal route may elicit greater protective immunity at respiratory surfaces thereby reducing transmission. Inclusion of viral antigens in addition to the spike protein may enhance protection against emerging variants of concern. Next-generation vaccine platforms with a new mechanism of action may necessitate efficacy trials to fulfill regulatory requirements. The Biomedical Advanced Research and Development Authority (BARDA) will be supporting Phase 2b clinical trials of candidate next-generation vaccines. The primary endpoint will be improved efficacy in terms of symptomatic disease relative to a currently approved COVID-19 vaccine. In this paper, we discuss the planned endpoints and potential challenges to this complex program.

Efficacy of different AV7909 dose regimens in a nonclinical model of pulmonary anthrax.

Pulmonary anthrax caused by exposure to inhaled Bacillus anthracis, the most lethal form of anthrax disease, is a continued military and public health concern for the United States. The vaccine AV7909, consisting of the licensed anthrax drug substance AVA adjuvanted with CpG7909, induces high levels of toxin neutralizing antibodies in healthy adults using fewer doses than AVA. This study compares the ability of one- or two-dose regimens of AV7909 to induce a protective immune response in guinea pigs challenged with a lethal dose of aerosolized B. anthracis spores 6 weeks after the last vaccine dose. The results indicated that AV7909 was less effective when delivered as a single dose compared to the two-dose regimen that resulted in dose-dependent protection against death. The toxin neutralizing assay (TNA) titer and anti-PA IgG responses were proportional to the protective efficacy, with a 50% TNA neutralizing factor (NF50) greater than 0.1 associated with survival in animals receiving two doses of vaccine. The strong protection at relatively low TNA NF50 titers in this guinea pig model supports the exploration of lower doses in clinical trials to determine if these protective levels of neutralizing antibodies can be achieved in humans; however, protection with a single dose may not be feasible.

Developing Vaccines to Improve Preparedness for Filovirus Outbreaks: The Perspective of the USA Biomedical Advanced Research and Development Authority (BARDA).

Outbreaks of viral hemorrhagic fever caused by filoviruses have become more prevalent in recent years, with outbreaks of Ebola virus (EBOV), Sudan virus (SUDV), and Marburg virus (MARV) all occurring in 2022 and 2023. While licensed vaccines are now available for EBOV, vaccine candidates for SUDV and MARV are all in preclinical or early clinical development phases. During the recent outbreak of SUDV virus disease, the Biomedical Advanced Research and Development Authority (BARDA), as part of the Administration for Strategic Preparedness and Response within the U.S. Department of Health and Human Services, implemented key actions with our existing partners to advance preparedness and enable rapid response to the outbreak, while also aligning with global partners involved in the implementation of clinical trials in an outbreak setting. Beyond pre-existing plans prior to the outbreak, BARDA worked with product sponsors to expedite manufacturing of vaccine doses that could be utilized in clinical trials. While the SUDV outbreak has since ended, a new outbreak of MARV disease has emerged. It remains critical that we continue to advance a portfolio of vaccines against SUDV and MARV while also expediting manufacturing activities ahead of, or in parallel if needed, outbreaks.

Landscape of Push Funding in Antibiotic Research: Current Status and Way Forward.

The growing need for effective antibiotics is attributed to the intrinsic ability of bacteria to develop survival mechanisms. The speed at which pathogens develop resistance is at par or even faster than the discovery of newer agents. Due to the enormous cost of developing an antibiotic and poor return on investment, big pharmaceutical companies are stepping out of the antibiotic research field, and the world is now heading towards the silent pandemic of antibiotic resistance. Lack of investment in research has further led to the anemic antibiotic pipeline. To overcome these challenges, various organizations have come forward with push funding to financially assist antibiotic developers. Although push funding has somewhat reinvigorated the dwindled field of antibiotic development by bearing the financial risks of failure, the landscape is still large and staggered. Most of the funding is funneled towards the early stages; however, to carry the promising compounds forward, equal or more funding is required formid- and late-stage research. To some extent, the complexity associated with accessing the funding mechanisms has led to their underutilization. In the present review, we discuss several major push funding mechanisms, issues in their effective utilization, recent strategies adopted, and a way forward to streamline funding in antibiotic research.

Advancing development of medical countermeasures: Incorporating COVID-19 lessons learned into future pandemic preparedness planning.

The COVID-19 pandemic profoundly disrupted, and, out of necessity, accelerated innovation of research and development of medical countermeasures to combat COVID-19. Although countermeasures were developed with unprecedented speed as a result of decades of long-term Federal investments in platform technologies and existing partnerships, the pandemic also revealed gaps in our preparedness and response capabilities that threaten our readiness posture. Challenges include limited federal funding that hinders sustainable development and manufacturing of, and equitable access to, medical countermeasures. Here we discuss lessons learned from the development and production efforts of medical countermeasures, such as vaccines and immunotherapeutics, to combat COVID-19. This commentary highlights some of the key gaps and challenges that must be addressed to ensure preparation for future outbreaks caused by viruses of pandemic potential.

Partnering on vaccines to counter multi-drug resistant threats: Workshop proceedings, Biomedical Advanced Research and Development Authority.

On March 12, 2021, the Biomedical Advanced Research and Development Authority (BARDA) sponsored a virtual market research workshop, "Partnering on Vaccines to Counter Multi-Drug Resistant Threats," to discuss the threat of antimicrobial resistance in the context of BARDA's mission space and the challenges encountered during the development of vaccines for specific antimicrobial resistant bacteria. The workshop convened representatives with expertise in vaccine development from government, academia, and industry. This report summarizes the presentations and subsequent discussions from the workshop and highlights existing challenges to advance the development of vaccine candidates for antimicrobial resistant pathogens, including Escherichia coli, Klebsiella pneumoniae, Pseudomonas aeruginosa, and Staphylococcus aureus.

Dose-Dependent Response to Infection with Ebola Virus in the Ferret Model and Evidence of Viral Evolution in the Eye.

Filoviruses cause high-consequence infections with limited approved medical countermeasures (MCMs). MCM development is dependent upon well-characterized animal models for the assessment of antiviral agents and vaccines. Following large-scale Ebola virus (EBOV) disease outbreaks in Africa, some survivors are left with long-term sequelae and persistent virus in immune-privileged sites for many years. We report the characterization of the ferret as a model for Ebola virus infection, reproducing disease and lethality observed in humans. The onset of clinical signs is rapid, and EBOV is detected in the blood, oral, and rectal swabs and all tissues studied. We identify viral RNA in the eye (a site of immune privilege) and report on specific genomic changes in EBOV present in this structure. Thus, the ferret model has utility in testing MCMs that prevent or treat long-term EBOV persistence in immune-privileged sites. IMPORTANCE Recent reemergence of Ebola in Guinea that caused over 28,000 cases between 2013 and 2016 has been linked to the original virus from that region. It appears the virus has remained in the region for at least 5 years and is likely to have been maintained in humans. Persistence of Ebola in areas of the body for extended periods of time has been observed, such as in the eye and semen. Despite the importance of reintroduction of Ebola from this route, such events are rare in the population, which makes studying medical interventions to clear persistent virus difficult. We studied various doses of Ebola in ferrets and detected virus in the eyes of most ferrets. We believe this model will enable the study of medical interventions that promote clearance of Ebola virus from sites that promote persistence.

The Strategic National Stockpile: identification, support, and acquisition of medical countermeasures for CBRN incidents.

The Strategic National Stockpile (SNS) serves as a repository of materiel, including medical countermeasures (MCMs), that would be used to support the national health security response to a chemical, biological, radiological, or nuclear (CBRN) incident, either natural or terrorism-related. To support and advance the SNS, the National Institutes of Health (NIH) manages targeted investigatory research portfolios, such as Countermeasures Against Chemical Terrorism (CounterACT) for chemical agents, that coordinate projects covering basic research, drug discovery, and preclinical studies. Project BioShield, managed by the Biomedical Advanced Research and Development Agency (BARDA), guides and supports academia and industry with potential MCMs through the Food & Drug Administration's approval process and ultimately supports the acquisition of successful products into the SNS. Public health emergencies such as the COVID-19 pandemic and the ever-increasing number of MCMs in the SNS present logistical and financial challenges to its maintenance. While MCMs for biological agents have been readily adopted, those for chemical agents have required sustained investments. This paper reviews the methods by which MCMs are identified and supported for inclusion in the SNS, the current status of MCMs for CBRN threats, and challenges with SNS maintenance as well as identifies persistent obstacles for MCM development and acquisition, particularly for ones focused on chemical weapons.

"Warp Speed" Operations in the COVID-19 Pandemic: Moving Too Quickly?

The COVID-19 (coronavirus disease-2019) pandemic has presented unprecedented challenges to regulatory organizations, the biotech and pharmaceutical industry, and the publishing industry. This Translational Perspectives paper attempts to highlight some of the challenges and perils of moving extraordinarily fast in an effort to save human lives in the midst of a global pandemic. As with the development of all new therapeutic approaches, it will take time to assess the risks and benefits of developing new therapies at "warp speed".

Female rats are less susceptible during puberty to the lethal effects of percutaneous exposure to VX.

Nerve agents with low volatility such as VX are primarily absorbed through the skin when released during combat or a terrorist attack. The barrier function of the stratum corneum may be compromised during certain stages of development, allowing VX to more easily penetrate through the skin. However, age-related differences in the lethal potency of VX have yet to be evaluated using the percutaneous (pc) route of exposure. Thus, we estimated the 24 and 48 h median lethal dose for pc exposure to VX in male and female rats during puberty and early adulthood. Pubescent, female rats were less susceptible than both their male and adult counterparts to the lethal effects associated with pc exposure to VX possibly because of hormonal changes during that stage of development. This study emphasizes the need to control for both age and sex when evaluating the toxicological effects associated with nerve agent exposure in the rat model.

Long-term immunogenicity of an AS03-adjuvanted influenza A(H1N1)pdm09 vaccine in young and elderly adults: an observer-blind, randomized trial.

BACKGROUND: This study (NCT00979602) evaluated the immunogenicity and relative protective efficacy of one dose of influenza A(H1N1)pdm09 vaccine with or without AS03 (an α-tocopherol oil-in-water emulsion based Adjuvant System). METHODS: Four thousands and forty-eight healthy adults aged ≥ 18 years were randomized (1:1) to receive one dose of either the adjuvanted split virion (3.75 µg hemagglutinin antigen [HA]/AS03) or non-adjuvanted (15 µg HA) vaccine. Hemagglutination inhibition [HI] antibody response was evaluated before vaccination and at Days 21, 42 and 182 (Month 6). Safety of the study vaccines was evaluated during the entire study duration. RESULTS: At Day 21, both study vaccines induced HI immune responses meeting the US regulatory criteria in subjects 18-64 years (seroprotection rate [SPR]: 98.0% [97.1-98.6]; seroconversion rate [SCR]: 89.7% [88.0-91.2] in the AS03-adjuvanted group; SPR: 91.4% [89.9-92.8]; SCR: 74.6% [72.3-76.9] in the non-adjuvanted group) and >64 years of age (SPR: 86.0% [82.5-89.0]; SCR: 75.3% [71.1-79.2] in the AS03-adjuvanted group; SPR: 69.1% [64.6-73.3]; SCR: 56.7% [52.0-61.3] in the non-adjuvanted group). The AS03-adjuvanted vaccine induced higher HI geometric mean titers than the non-adjuvanted vaccine at all time points. At Month 6, only subjects 18-64 years of age from both vaccine groups still met the US regulatory criteria (SPR: 82.1% [80.0-84.1]; SCR: 62.3% [59.6-64.8] in the AS03-adjuvanted group; SPR: 75.3% [72.9-77.5]; SCR: 53.7% [51.0-56.4] in the non-adjuvanted group). Protective efficacy was not evaluated due to low number of RT-qPCR-confirmed A(H1N1)pdm09 influenza cases. Through Month 12, 216 serious adverse events (in 157 subjects: 84 in the AS03-adjuvanted and 73 in the non-adjuvanted group) and 12 potentially immune mediated diseases (5 in the AS03-adjuvanted and 7 in the non-adjuvanted group) were reported. CONCLUSION: A single dose of either adjuvanted or non-adjuvanted influenza A(H1N1)pdm09 vaccine induced protective HI antibody levels against the A/California/7/2009 strain that persisted through Month 6 in the 18-64 years population.

Animal models for Francisella tularensis and Burkholderia species: scientific and regulatory gaps toward approval of antibiotics under the FDA Animal Rule.

The development and regulatory approval of medical countermeasures (MCMs) for the treatment and prevention of bacterial threat agent infections will require the evaluation of products in animal models. To obtain regulatory approval, these models must accurately recapitulate aspects of human disease, including, but not necessarily limited to, route of exposure, time to disease onset, pathology, immune response, and mortality. This article focuses on the state of animal model development for 3 agents for which models are largely immature: Francisella tularensis, Burkholderia mallei, and Burkholderia pseudomallei. An overview of available models and a description of scientific and regulatory gaps are provided.