The present invention provides compositions, systems, kits, and methods for expression of one or more biomolecules in a subject, human or non-human mammal, (e.g., at therapeutic levels for the extended periods of time required to produce therapeutic effects). In certain embodiments, compositions, systems, kits, and methods are provided that comprise a first composition comprising polycationic structures (e.g., empty cationic liposomes, cationic micelles, cationic emulsions, or cationic polymers) and a second composition comprising expression vectors (e.g., non-viral expression vectors not associated with liposomes or other carriers) encoding one or more biomolecules of interest.

AAV vectors expressing anti-influenza antibodies are provided. Also described are pharmaceutical compositions useful in delivery same for prophylactic or anti-viral purposes. Methods of delivering such vectors are provided.

Provided are NK-92 cells expressing a chimeric antigen receptor (CAR). The CAR can comprise an intracellular domain of FcϵRIγ. Also described are methods for treating a patient having or suspected of having a disease that is treatable with NK-92 cells, such as cancer or a viral infection, comprising administering to the patient NK-92-CAR cells.

Binding molecules, including bispecific antibodies that include at least two anti-influenza binding domains are disclosed, including binding molecules having a first binding domain that specifically binds influenza A virus and a second binding domain that specifically binds influenza B virus.

The present disclosure is directed to peptide antigens derived from a previously undefined epitope on influenza A virus hemagglutinin and methods for use thereof.

Methods and devices are provided herein for identifying a cell population comprising an effector cell that exerts an extracellular effect. In one embodiment the method comprises retaining in a microreactor a cell population comprising one or more effector cells, wherein the contents of the microreactor further comprise a readout particle population comprising one or more readout particles, incubating the cell population and the readout particle population within the microreactor, assaying the cell population for the presence of the extracellular effect, wherein the readout particle population or subpopulation thereof provides a direct or indirect readout of the extracellular effect, and determining, based on the results of the assaying step, whether one or more effector cells within the cell population exerts the extracellular effect on the readout particle. If an extracellular effect is measured, the cell population is recovered for further analysis to determine the cell or cells responsible for the effect.

The invention relates to human antibodies binding to and neutralizing Influenza (flu) virus and their uses.

The present invention relates to antibodies or antigen-binding fragments that are useful for treating influenza B viruses. The present invention also relates to various pharmaceutical compositions and methods of treating influenza using the antibodies or antigen-binding fragments.

The present invention includes an antibody or antigen-binding fragment thereof that binds specifically to TMPRSS2 and methods of using such antibodies and fragments for treating or preventing viral infections (e.g., influenza virus infections).

The present invention relates to a RNA encoding an antibody or a fragment or variant thereof and a composition, in particular a passive vaccine, comprising such an RNA. The present invention further relates to the use of such an RNA or of such a composition for treatment of tumours and cancer diseases, cardiovascular diseases, infectious diseases, autoimmune diseases, virus diseases and monogenetic diseases, e.g. also in gene therapy. The present invention also relates to a combination of at least two modified RNA's, in particular wherein one RNA encodes a heavy chain variable region of an antibody and another RNA encodes the corresponding light chain variable region of said antibody.