Abstract: Emulsion-based and micromolded (“MM”) or three dimensional printed (“3DP”) polymeric formulations for single injection of antigen, preferably releasing at two or more time periods, have been developed. Formulations are preferably formed of biocompatible, biodegradable polymers. Discrete regions encapsulating antigen, alone or in combination with other antigens, adjuvants, stabilizers, and release modifiers, are present in the formulations. Antigen is preferably present in excipient at the time of administration, or on the surface of the formulation, for immediate release, and incorporated within the formulation for release at ten to 45 days after initial release of antigen, optionally at ten to 90 day intervals for release of antigen in one or more additional time periods. Antigen may be stabilized through the use of stabilizing agents such as trehalose glass. In a preferred embodiment for immunization against polio, antigen is released at the time of administration, and two, four and six months thereafter.

Abstract: Polymers and nanoparticle formulations for systemic nucleic acid delivery, including mRNA, are disclosed. A bioassay for simultaneously measuring nanoparticle cell uptake and endosomal disruption also is disclosed.

Abstract: Biodegradable particles for interacting with immune cells to generate an immunosuppressive effect are disclosed. The biodegradable particle comprises a polyester or polyester blend with at least one soluble protein or small molecule encapsulated within the particle and at least two types of protein attached to a surface of the particle or to a coating on the surface thereof, which can be used to induce targeting regulatory T cells (Tregs). The at least two types of protein attached to a surface of the particle or to a coating on the surface thereof include a “Signal 1” protein that binds to an immune cell and a “Signal 2” protein that acts as a co-stimulatory molecule to immune cells. The encapsulated protein can be an interleukin and/or a cytokine. Methods of their use for treating a disease or condition, including an autoimmune disease, are disclosed.

Abstract: The disclosure is directed to a biodegradable particle comprising a polyester or polyester blend, a first protein that binds to an immune cell, and a second protein that promotes proliferation and/or activation of immune cells, and a third soluble protein or small molecule encapsulated within the particle. The second protein is a fusion protein comprising at least a portion of an antibody and at least a portion of a cytokine (i.e., an immunocytokine). The disclosure also is directed to methods for treating a disease or condition in a subject (e.g., an autoimmune disease) comprising administering the aforementioned biodegradable particle to the subject.

Abstract: Synthetic, biodegradable nanoparticles (NPs) encapsulating at least one of a signal 1 protein, a signal 2 protein, and/or a signal 3 protein are disclosed, which, when transfected into one or more a cancer cells, reprogram the one or more cancer cells into “tumor-derived APCs” in vivo to activate T-cells and natural killer (NK) cells for systemic tumor rejection. The NPs can be used for treating cancers, in particular metastatic cancers.

Abstract: Polymeric nanoparticles, microparticles, and gels for delivering cargo, e.g., a therapeutic agent, such as a peptide, to a target, e.g., a cell, and their use for treating diseases, including angiogenesis-dependent diseases, such as age-related macular degeneration and cancer, are disclosed. Methods for formulating, stabilizing, and administering single peptides or combinations of peptides via polymeric particle and gel delivery systems also are disclosed.

Abstract: Emulsion-based and micromolded (“MM”) or three dimensional printed (“3DP”) polymeric formulations for single injection of antigen, preferably releasing at two or more time periods, have been developed. Formulations are preferably formed of biocompatible, biodegradable polymers. Discrete regions encapsulating antigen, alone or in combination with other antigens, adjuvants, stabilizers, and release modifiers, are present in the formulations. Antigen is preferably present in excipient at the time of administration, or on the surface of the formulation, for immediate release, and incorporated within the formulation for release at ten to 45 days after initial release of antigen, optionally at ten to 90 day intervals for release of antigen in one or more additional time periods. Antigen may be stabilized through the use of stabilizing agents such as trehalose glass. In a preferred embodiment for immunization against polio, antigen is released at the time of administration, and two, four and six months thereafter.

Abstract: Emulsion-based and micromolded (“MM”) or three dimensional printed (“3DP”) polymeric formulations for single injection of antigen, preferably releasing at two or more time periods, have been developed. Formulations are preferably formed of biocompatible, biodegradable polymers. Discrete regions encapsulating antigen, alone or in combination with other antigens, adjuvants, stabilizers, and release modifiers, are present in the formulations. Antigen is preferably present in excipient at the time of administration, or on the surface of the formulation, for immediate release, and incorporated within the formulation for release at ten to 45 days after initial release of antigen, optionally at ten to 90 day intervals for release of antigen in one or more additional time periods. Antigen may be stabilized through the use of stabilizing agents such as trehalose glass. In a preferred embodiment for immunization against polio, antigen is released at the time of administration, and two, four and six months thereafter.

Abstract: Polymeric nanoparticles, microparticles, and gels for delivering cargo, e.g., a therapeutic agent, such as a peptide, to a target, e.g., a cell, and their use for treating diseases, including angiogenesis-dependent diseases, such as age-related macular degeneration and cancer, are disclosed. Methods for formulating, stabilizing, and administering single peptides or combinations of peptides via polymeric particle and gel delivery systems also are disclosed.

Abstract: Emulsion-based and micromolded (“MM”) or three dimensional printed (“3DP”) polymeric formulations for single injection of antigen, preferably releasing at two or more time periods, have been developed. Formulations are preferably formed of biocompatible, biodegradable polymers. Discrete regions encapsulating antigen, alone or in combination with other antigens, adjuvants, stabilizers, and release modifiers, are present in the formulations. Antigen is preferably present in excipient at the time of administration, or on the surface of the formulation, for immediate release, and incorporated within the formulation for release at ten to 45 days after initial release of antigen, optionally at ten to 90 day intervals for release of antigen in one or more additional time periods. Antigen may be stabilized through the use of stabilizing agents such as trehalose glass. In a preferred embodiment for immunization against polio, antigen is released at the time of administration, and two, four and six months thereafter.

Abstract: Degradable polymers were synthesized that self-assemble with nucleic acids, proteins, hydrophobic drugs, and other small molecules to form particles that are effective for delivery into a cell, tissue and/or organism either in vitro or in vivo. The presently disclosed polymers demonstrate differential cell-type specificity, an ability to promote endosomal escape to protect the cargos from degradation and enhance delivery to the cytoplasm, and/or bioreducibility, which enables triggered intracellular drug release to be tuned to promote optimal delivery to the target cell type. The presently disclosed materials may be used to treat a wide variety of conditions or diseases, such as cancer, cardiovascular diseases, infectious diseases, and ophthalmic diseases.

Abstract: Emulsion-based and micromolded (“MM”) or three dimensional printed (“3DP”) polymeric formulations for single injection of antigen, preferably releasing at two or more time periods, have been developed. Formulations are preferably formed of biocompatible, biodegradable polymers. Discrete regions encapsulating antigen, alone or in combination with other antigens, adjuvants, stabilizers, and release modifiers, are present in the formulations. Antigen is preferably present in excipient at the time of administration, or on the surface of the formulation, for immediate release, and incorporated within the formulation for release at ten to 45 days after initial release of antigen, optionally at ten to 90 day intervals for release of antigen in one or more additional time periods. Antigen may be stabilized through the use of stabilizing agents such as trehalose glass. In a preferred embodiment for immunization against polio, antigen is released at the time of administration, and two, four and six months thereafter.

Abstract: Polymeric nanoparticles, microparticles, and gels for delivering cargo, e.g., a therapeutic agent, such as a peptide, to a target, e.g., a cell, and their use for treating diseases, including angiogenesis-dependent diseases, such as age-related macular degeneration and cancer, are disclosed. Methods for formulating, stabilizing, and administering single peptides or combinations of peptides via polymeric particle and gel delivery systems also are disclosed.

Abstract: Polymeric nanoparticles, microparticles, and gels for delivering cargo, e.g., a therapeutic agent, such as a peptide, to a target, e.g., a cell, and their use for treating diseases, including angiogenesis-dependent diseases, such as age-related macular degeneration and cancer, are disclosed. Methods for formulating, stabilizing, and administering single peptides or combinations of peptides via polymeric particle and gel delivery systems also are disclosed.

Abstract: A layer-by-layer (LbL) system, which alternately ionically complexes anionic AuNPs to two unique cationic polymers (disulfide-reducible and hydrolytically degradable) and two anionic nucleic acids, is disclosed.

Abstract: Polymeric nanoparticles, microparticles, and gels for delivering cargo, e.g., a therapeutic agent, such as a peptide, to a target, e.g., a cell, and their use for treating diseases, including angiogenesis-dependent diseases, such as age-related macular degeneration and cancer, are disclosed. Methods for formulating, stabilizing, and administering single peptides or combinations of peptides via polymeric particle and gel delivery systems also are disclosed.

Abstract: Degradable polymers were synthesized that self-assemble with nucleic acids, proteins, hydrophobic drugs, and other small molecules to form particles that are effective for delivery into a cell, tissue and/or organism either in vitro or in vivo. The presently disclosed polymers demonstrate differential cell-type specificity, an ability to promote endosomal escape to protect the cargos from degradation and enhance delivery to the cytoplasm, and/or bioreducibility, which enables triggered intracellular drug release to be tuned to promote optimal delivery to the target cell type. The presently disclosed materials may be used to treat a wide variety of conditions or diseases, such as cancer, cardiovascular diseases, infectious diseases, and ophthalmic diseases.

Abstract: A layer-by-layer (LbL) system, which alternately ionically complexes anionic AuNPs to two unique cationic polymers (disulfide-reducible and hydrolytically degradable) and two anionic nucleic acids, is disclosed.

Abstract: Polymeric nanoparticles, microparticles, and gels for delivering cargo, e.g., a therapeutic agent, such as a peptide, to a target, e.g., a cell, and their use for treating diseases, including angiogenesis-dependent diseases, such as age-related macular degeneration and cancer, are disclosed. Methods for formulating, stabilizing, and administering single peptides or combinations of peptides via polymeric particle and gel delivery systems also are disclosed.