Vaccine based on ethanol inactivated pathogens, or part thereof, are described herein. Also disclosed are certain vaccines for treating COVID-19 or other coronavirus related diseases is created by deactivating the genome, genetic material or RNA encapsulated within the shell of virus without eliminating the spikes or spike protein, which both attaches the virus to a host cell and is detected by the body to produce antibodies. Treatment of an active coronavirus with a material such as an effective amount of ethanol will both penetrate the shell and deactivate the genetic material which causes the disease, for preparation of a vaccine.

The present disclosure provides compositions and methods for the generation of an antibody or immunogenic composition, such as a vaccine, through epitope focusing by variable effective antigen surface concentration. Generally, the composition and methods of the disclosure comprise three steps: a “design process” comprising one or more in silico bioinformatics steps to select and generate a library of potential antigens for use in the immunogenic composition; a “formulation process”, comprising in vitro testing of potential antigens, using various biochemical assays, and further combining two or more antigens to generate one or more immunogenic compositions; and an “administering” step, whereby the immunogenic composition is administered to a host animal, immune cell, subject or patient. Further steps may also be included, such as the isolation and production of antibodies raised by host immune response to the immunogenic composition.

The present disclosure provides compositions and methods for the generation of an antibody or immunogenic composition, such as a vaccine, through epitope focusing by variable effective antigen surface concentration. Generally, the composition and methods of the disclosure comprise three steps: a “design process” comprising one or more in silico bioinformatics steps to select and generate a library of potential antigens for use in the immunogenic composition; a “formulation process”, comprising in vitro testing of potential antigens, using various biochemical assays, and further combining two or more antigens to generate one or more immunogenic compositions; and an “administering” step, whereby the immunogenic composition is administered to a host animal, immune cell, subject or patient. Further steps may also be included, such as the isolation and production of antibodies raised by host immune response to the immunogenic composition.

Disclosed are methods of a method of making a nanostructure, comprising adding a component A (compA) protein to a solution comprising a component B (compB) protein under conditions that minimize shear stress, thereby forming a compA:compB complex. Further disclosed are methods of making a nanostructure, comprising (i) providing a first inlet fluid stream comprising a first protein and a second inlet fluid stream comprising a second protein, and (ii) contacting the first inlet fluid stream and the second inlet fluid stream to form an outlet stream, wherein mixing of the first protein and the second protein occurs in the outlet stream, thereby forming a protein complex comprises the first protein and the second protein. A microfluidic mixer may be used. The methods may further comprise purifying the compA:compB complex from excess compA, excess compB, and/or other impurities by filtering the solution with a 1,000 kDa membrane or an equivalent thereof.

Disclosed are methods of a method of making a nanostructure, comprising adding a component A (compA) protein to a solution comprising a component B (compB) protein under conditions that minimize shear stress, thereby forming a compA:compB complex. Further disclosed are methods of making a nanostructure, comprising (i) providing a first inlet fluid stream comprising a first protein and a second inlet fluid stream comprising a second protein, and (ii) contacting the first inlet fluid stream and the second inlet fluid stream to form an outlet stream, wherein mixing of the first protein and the second protein occurs in the outlet stream, thereby forming a protein complex comprises the first protein and the second protein. A microfluidic mixer may be used. The methods may further comprise purifying the compA:compB complex from excess compA, excess compB, and/or other impurities by filtering the solution with a 1,000 kDa membrane or an equivalent thereof.

The present invention relates to prime-boost regimens that involve the administration of at least one mRNA construct, such as the use of such constructs in “boost” administration subsequently to “prime” administration of certain other antigenic composition(s). Such inventive regimens may, in particular, be useful for the induction of an immune response in a subject, and/or the vaccination of such subject against infection from one or more pathogens, and/or the treatment or prevention of one or more diseases or conditions, including a tumour or cancer, allergy or autoimmune conditions, and/or a disease or condition associated with infection from a pathogen. The present invention further describes methods, uses, vaccination compositions, kits and packaged vaccine components related to or useful for one or more of such regimens.

The present invention relates to prime-boost regimens that involve the administration of at least one mRNA construct, such as the use of such constructs in “boost” administration subsequently to “prime” administration of certain other antigenic composition(s). Such inventive regimens may, in particular, be useful for the induction of an immune response in a subject, and/or the vaccination of such subject against infection from one or more pathogens, and/or the treatment or prevention of one or more diseases or conditions, including a tumour or cancer, allergy or autoimmune conditions, and/or a disease or condition associated with infection from a pathogen. The present invention further describes methods, uses, vaccination compositions, kits and packaged vaccine components related to or useful for one or more of such regimens.

The disclosure provides native outer membrane vesicle (NOMV) vaccines containing a coronavirus receptor binding domain (RBD) modified to be a lipoprotein. Also provided are compositions comprising a meningococcal strain having a plasmid-borne gene encoding the SARS-CoV-2 RBD modified to be a lipoprotein. Also provided are a meningococcal strain and a NOMV vaccine containing a plasmid coding for the SARS-CoV-2 RBD with a promoter/enhancer and polyA sequence that provide for expression of the RBD in mammalian cells.

The present invention concerns a nucleotide sequence expressing a fusion protein, said fusion protein comprising or consisting of an exosome-anchoring protein fused at its C-terminus with an antigen, or a DNA expression vector comprising said nucleotide sequence, for use as vaccine.

The present disclosure relates to a compound of Formula (I)

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or a pharmaceutically acceptable salt thereof, which can be incorporated into a lipid particle for delivering an active agent, such as a nucleic acid.