Abstract: Polyelectrolyte nanoparticle compositions for biomedical applications are provided comprising at least two carrier domains comprising multivalent ionic domains and an agent exhibiting biological activity when contained within the nanoparticle or on the nanoparticle surface. The multivalent ionic domains may be contained in two separate molecules or in separate but linked domains of a single molecule. The nanoparticle optionally can further comprise an exposed targeting ligand and/or protective surface. The nanoparticle can be contacted to cells or administered directly to an animal for biomedical applications including therapeutics and immune response. The nanoparticle may alternatively be comprised of a carrier material capable of delivering various medically important antigens as vaccine.

Abstract: Polyelectrolyte nanoparticle compositions for biomedical applications are provided comprising at least two carrier domains comprising multivalent ionic domains and an agent exhibiting biological activity when contained within the nanoparticle or on the nanoparticle surface. The multivalent ionic domains may be contained in two separate molecules or in separate but linked domains of a single molecule. The nanoparticle optionally can further comprise an exposed targeting ligand and/or protective surface. The nanoparticle can be contacted to cells or administered directly to an animal for biomedical applications including therapeutics and immune response. The nanoparticle may alternatively be comprised of a carrier material capable of delivering various medically important antigens as vaccine.

Abstract: Biomedical nanoparticles are disclosed based on new engineered modular carrier macromolecules, on engineered macromolecules or associated entities providing an internal nanoparticle structure, and compositions for minimizing non-specific binding of the nanoparticles while enabling efficient and convenient targeting to cells and tissues. These nanoparticles may be used to deliver atomic or molecular or associated entities which are useful for diagnostics, primarily in vivo imaging, for therapeutics, for vaccines, or for experimental research. Nanoparticles comprising combinations of active entities such as gene inhibitors with gene expression cassettes or imaging agents with therapeutic agents, and polyamide compounds useful for treatment of microbial infections are also disclosed.

Abstract: Polyelectrolyte nanoparticle compositions for biomedical applications are provided comprising at least two carrier domains comprising multivalent ionic domains and an agent exhibiting biological activity when contained within the nanoparticle or on the nanoparticle surface. The multivalent ionic domains may be contained in two separate molecules or in separate but linked domains of a single molecule. The nanoparticle optionally can further comprise an exposed targeting ligand and/or protective surface. The nanoparticle can be contacted to cells or administered directly to an animal for biomedical applications including therapeutics and immune response. The nanoparticle may alternatively be comprised of a carrier material capable of delivering various medically important antigens as vaccine.

Abstract: The present invention embodies a multi-disciplinary approach to validate or identify targets involved in any given biological process or pathway, such as an immune response, or progression or regression of disease. By introducing a target(s) with, e.g., gene delivery vector(s) or other foreign substance(s) to an in vivo system and by integrating, for example, pathological, pharmacological, bioassay, microarray and bioinformatics data obtained from the in vivo system, the present inventors are able to (1) identify one or more targets, e.g., genes, that are involved in a biological pathway of interest, (2) implement these identified targets for further analysis of the biological process or pathway and (3) provide a scalable approach in vivo for potential large quantities of target(s) discovery and validation. This process can be used in any number of applications, including the identification of agonists and antagonists to a biological process or pathway, which can lead to drugs and vaccine discovery.

Abstract: It has been found that certain synthetic vectors and nucleic acid sequences that encode viral genomic sequences can, for example, be administered to a subject repeatedly as a vehicle for effectively delivering one or more therapeutic nucleic acid molecules or polypeptides to a cell or tissue. Accordingly, the disclosed nucleic acid delivery vehicles can be used, for instance, as part of a therapeutic regimen that involves an ongoing use of a therapeutic nucleic acid molecule or polypeptide.

Abstract: Methods and compositions are provided for down regulation of target gene expression in vivo by RNA interference. The methods are useful for target discovery and validation of gene-based drug development, and for treatment of human diseases.

Abstract: Certain hydrophilic polymers, such as a polyoxazoline, when conjugated to a polypeptide or small molecule agent, can enhance the bioavailability of the agent when administered in vivo. Accordingly, hydrophilic polymers of the invention can be used as a delivery vehicle to treat any number of disorders and/or confer a myriad of therapeutic benefits to a subject.

Abstract: The inventions provide compositions and methods for nucleic acid delivery comprising IIPMA conjugated to a polyamine. These compositions have the benefit of the steric hindrance of HPMA and the nucleic acid binding capability of a polyamine. Useful polyamines for this purpose include spermine, spermidine and their analogues, and DFMO. These polyamines have the ability not only to bind nucleic acids, but also have anti-cancer effects themselves. The compounds provided can also include ligand binding domains, such as vascular endothelial growth factors, somatostatin and somatostatin analogs, transferring, melanotropin, ApoE and ApoE peptides, von Willebrand's factor and von Willebrand's factor peptides, adenoviral fiber protein and adenoviral fiber protein peptides, PD 1 and PD 1 peptides, EGF and EGF peptides, RGD peptides, CCK peptides, antibody and antibody fragments, folate, pyridoxyl and sialyl-LewisX and chemical analogs.

Abstract: The present invention embodies a multi-disciplinary approach to validate or identify targets involved in any given biological process or pathway, such as an immune response, or progression or regression of disease. By introducing a target(s) with, e.g., gene delivery vector(s) or other foreign substance(s) to an in vivo system and by integrating, for example, pathological, pharmacological, bioassay, microarray and bioinformatics data obtained from the in vivo system, the present inventors are able to (1) identify one or more targets, e.g., genes, that are involved in a biological pathway of interest, (2) implement these identified targets for further analysis of the biological process or pathway and (3) provide a scalable approach in vivo for potential large quantities of target(s) discovery and validation. This process can be used in any number of applications, including the identification of agonists and antagonists to a biological process or pathway, which can lead to drugs and vaccine discovery.

Abstract: Non-naturally occurring vector for gene therapy are provided, comprised of chemically defined reagents, where the vector is self-assembling and where the vector comprises (1) a core complex comprising a nucleic acid and (2) at least one complex forming reagent, where the vector has fusogenic activity. The vector optionally may contain reagents permitting fusion with cell membranes and nuclear uptake. The vector also may contain an outer shell moiety that is anchored to the core complex, whereby the outer shell stabilizes the complex, protects it from unwanted interactions and enhances delivery of the nucleic acid into a target tissue or cell. The outer shell optionally may be sheddable, that is, it may be designed such that it dissociates from the vector upon entry into the target cell or tissue.

Abstract: It has been found that certain synthetic vectors and nucleic acid sequences that encode viral genomic sequences can, for example, be administered to a subject repeatedly as a vehicle for effectively delivering one or more therapeutic nucleic acid molecules or polypeptides to a cell or tissue. Accordingly, the disclosed nucleic acid delivery vehicles can be used, for instance, as part of a therapeutic regimen that involves an ongoing use of a therapeutic nucleic acid molecule or polypeptide.