Trapping virus-loaded aerosols using granular protein nanofibrils and iron oxyhydroxides nanoparticles

The ongoing COVID-19 pandemic has revealed that developing effective therapeutics against viruses might be outpaced by emerging variants,1-5 waning immunity,6-9 vaccine skepticism/hesitancy,10-12 lack of resources,13-16 and the time needed to develop virus-specific therapeutics,17,18 emphasizing the importance of non-pharmaceutical interventions as the first line of defense against virus outbreaks and pandemics.19-23 However, fighting the spread of airborne viruses has proven extremely challenging,23-28 much more if this needs to be achieved on a global scale and in an environmentally-friendly manner.29,30 Here, we introduce an aerosol filter made of granular material based on whey protein nanofibrils and iron oxyhydroxides nanoparticles. The material is environmentally-friendly, biodegradable, and composed mainly of a dairy industry byproduct.31 It features remarkable filtration efficiencies between 95.91% and 99.99% for both enveloped and non-enveloped viruses, including SARS-CoV-2, the influenza A virus strain H1N1, enterovirus 71, bacteriophage {Phi}6, and bacteriophage MS2. The developed material is safe to handle and recycle, with a simple baking step sufficient to inactivate trapped viruses. The high filtration efficiency, virtually-zero environmental impact, and low cost of the material illuminate a viable role in fighting current and future pandemics on a global scale.

Methylene Blue has a potent antiviral activity against SARS-CoV-2 in the absence of UV-activation in vitro

Methylene blue is an FDA and EMA approved drug with an excellent safety profile. It displays broad-spectrum virucidal activity in the presence of UV light and has been shown to be effective in inactivating various viruses in blood products prior to transfusions. In addition, its use has been validated for methemoglobinemia and malaria treatment. Here we show the virucidal activity of methylene blue at low micromolar concentrations and in the absence of UV activation against SARS-CoV2.

Bacteriophage therapy of Salmonella enterica: a fresh appraisal of bacteriophage therapy.

BACKGROUND: The most serious criticisms leveled at bacteriophage therapy are as follows: phages induce neutralizing antibodies, phages are active only when administered shortly after bacterial infection, and phage-resistant bacteria emerge rapidly in the course of therapy. METHODS: Phages lytic for several Salmonella enterica serovars were isolated by means of standard protocols from feces of patients with gastroenteritis. Growth of S. enterica serovar Paratyphi B (Salp572(phi1S)) in the presence of phage phi1 (selected from among 8 phages for its larger host range) provided a phage phi1-resistant bacterial strain (Salp572(phi1R)). The properties of the Salp572(phi1S) and Salp572(phi1R) strains and of phage phi1 were studied in a mouse model of experimental infection. RESULTS: Phages induced nonneutralizing antibodies and were active 2 weeks after experimental infection of mice; phage-resistant bacteria were avirulent and short lived in vivo. More importantly, phage-resistant bacteria were excellent vaccines, protecting against lethal doses of heterologous S. enterica serovars. CONCLUSIONS: Phage therapy effectiveness has not yet been properly assessed.