Embodiments of immunogens comprising a recombinant Mumps (MuV) F ectodomain trimer stabilized in a prefusion conformation or a recombinant Measles (MeV) F ectodomain trimer stabilized in a prefusion conformation are provided. Also provided are embodiments of immunogens comprising chimeric proteins comprising the recombinant MuV or MeV F ectodomain trimer and one or more MuV HN or MeV H ectodomains. Also disclosed are nucleic acids encoding the immunogens and methods of their production. Methods for inducing an immune response in a subject by administering a disclosed immunogen to the subject are also provided. In some embodiments, the immune response treats or inhibits MuV and/or MeV infection in a subject.

Disclosed herein are methods for generating a protective immunogenic response via intranasal administration of an immunogenic composition (e.g., vaccine)/therapeutic immunogenic composition in a mammalian subject. Certain dosing positions of the subject during the administration of immunogenic agents, such that nostrils are tilted upwards, while in a modified sitting, reclining and/or supine posture, is surprisingly correlated with the generation of a strong immunogenic response in both humans and animals.

Disclosed herein are methods for generating a protective immunogenic response via intranasal administration of an immunogenic composition (e.g., vaccine)/therapeutic immunogenic composition in a mammalian subject. Certain dosing positions of the subject during the administration of immunogenic agents, such that nostrils are tilted upwards, while in a modified sitting, reclining and/or supine posture, is surprisingly correlated with the generation of a strong immunogenic response in both humans and animals.

Disclosed herein are methods, compositions, and kits useful to enhance an immune response against an antigen and to improve vaccine efficacy. The disclosed methods, compositions, and kits may be utilized to improve vaccine immunogenicity and enhance immune protection following subsequent antigen challenges. In some embodiments, the methods include co-administering a blocker of the IFN-I pathway with an antigen that is used as part of a vaccine, such as a viral vaccine.

Disclosed herein are methods, compositions, and kits useful to enhance an immune response against an antigen and to improve vaccine efficacy. The disclosed methods, compositions, and kits may be utilized to improve vaccine immunogenicity and enhance immune protection following subsequent antigen challenges. In some embodiments, the methods include co-administering a blocker of the IFN-I pathway with an antigen that is used as part of a vaccine, such as a viral vaccine.

Described herein are processes for the purification of viruses and compositions thereof.

Described herein are processes for the purification of viruses and compositions thereof.

A method for producing at least one microneedle containing a vaccine for transdermal delivery of the vaccine to a patient includes preparing microparticles or nanoparticles of encapsulated vaccine by preparing a solution comprising a vaccine antigen and a biocompatible polymer matrix; and spray drying the solution to form the microparticles or nanoparticles. The method includes the further steps of preparing a film composition including at least one pre-polymer solution; preparing a suspension comprising the microparticles or nanoparticles and the film composition; loading the suspension into a 3D printer; printing, via the 3D printer, at least one microneedle made from the suspension; and, converting the pre-polymer solution into a cross-linked biopolymer by exposing the at least one microneedle to UV light. Also disclosed are microneedles containing a vaccine for transdermal delivery.

A method for producing at least one microneedle containing a vaccine for transdermal delivery of the vaccine to a patient includes preparing microparticles or nanoparticles of encapsulated vaccine by preparing a solution comprising a vaccine antigen and a biocompatible polymer matrix; and spray drying the solution to form the microparticles or nanoparticles. The method includes the further steps of preparing a film composition including at least one pre-polymer solution; preparing a suspension comprising the microparticles or nanoparticles and the film composition; loading the suspension into a 3D printer; printing, via the 3D printer, at least one microneedle made from the suspension; and, converting the pre-polymer solution into a cross-linked biopolymer by exposing the at least one microneedle to UV light. Also disclosed are microneedles containing a vaccine for transdermal delivery.

It is an object of the present invention to provide a medicament or a pharmaceutical composition, which is effective for the treatment of various cancers.

More specifically, the present invention relates to a pharmaceutical composition for use in the treatment of cancers, which comprises rMV-SLAM-blind or rMV-V(−)-SLAM-blind. The pharmaceutical composition has the effect of causing the regression of tumor, even if it is intravenously administered, and it also exhibits effects on cancer metastasized from a primary lesion.