Abstract: Metastatic triple negative breast cancer (TNBC) still carries a dismal prognosis with the current treatment paradigms. The effectiveness of drug treatment for many solid tumors such as TNBC is limited by tumor heterogeneity, lack of tumor specificity, off-target toxicities, and transient therapeutic action(s). Strategies that provide tumor-specific, sustained concentrations of drugs to the tumors and tumor receptor-specific binding, while reducing off-target effects are needed to ensure sufficient tumor cell uptake within the primary and metastatic tumor microenvironment. The decreased non-specific adhesivity, receptor-targeted nanoparticle formulations (“DART” nanoparticles) of the invention were assessed for clinical potential in directing biological agents to the cell surface receptor Fn14, which is expressed in many solid cancer types, including TNBC primary tumors and metastatic lesions.

Abstract: Metastatic triple negative breast cancer (TNBC) still carries a dismal prognosis with the current treatment paradigms. The effectiveness of drug treatment for many solid tumors such as TNBC is limited by tumor heterogeneity, lack of tumor specificity, off-target toxicities, and transient therapeutic action(s). Strategies that provide tumor-specific, sustained concentrations of drugs to the tumors and tumor receptor-specific binding, while reducing off-target effects are needed to ensure sufficient tumor cell uptake within the primary and metastatic tumor microenvironment. The decreased non-specific adhesivity, receptor-targeted nanoparticle formulations (“DART” nanoparticles) of the invention were assessed for clinical potential in directing biological agents to the cell surface receptor Fn14, which is expressed in many solid cancer types, including TNBC primary tumors and metastatic lesions.

Abstract: Provided are targeted structure-specific particulate-based delivery systems comprising: a nanoparticle; a PEG polymer coating on the surface of the nanoparticle; a targeting moiety conjugated on a surface of the nanoparticle and configured to promote specific binding to a cell surface molecule expressed by a target cell; and a biologically active agent in or on the nanoparticle, wherein the biologically active agent is selected to enhance a desired response in a target cell intracellularly or extracellularly. Methods of treating a disease or disorder administering the delivery system are contemplated.

Abstract: Metastatic triple negative breast cancer (TNBC) still carries a dismal prognosis with the current treatment paradigms. The effectiveness of drug treatment for many solid tumors such as TNBC is limited by tumor heterogeneity, lack of tumor specificity, off-target toxicities, and transient therapeutic action(s). Strategies that provide tumor-specific, sustained concentrations of drugs to the tumors and tumor receptor-specific binding, while reducing off-target effects are needed to ensure sufficient tumor cell uptake within the primary and metastatic tumor microenvironment. The decreased non-specific adhesivity, receptor-targeted nanoparticle formulations (“DART” nanoparticles) of the invention were assessed for clinical potential in directing biological agents to the cell surface receptor Fn14, which is expressed in many solid cancer types, including TNBC primary tumors and metastatic lesions.

Abstract: Metastatic triple negative breast cancer (TNBC) still carries a dismal prognosis with the current treatment paradigms. The effectiveness of drug treatment for many solid tumors such as TNBC is limited by tumor heterogeneity, lack of tumor specificity, off-target toxicities, and transient therapeutic action(s). Strategies that provide tumor-specific, sustained concentrations of drugs to the tumors and tumor receptor-specific binding, while reducing off-target effects are needed to ensure sufficient tumor cell uptake within the primary and metastatic tumor microenvironment. The decreased non-specific adhesivity, receptor-targeted nanoparticle formulations (“DART” nanoparticles) of the invention were assessed for clinical potential in directing biological agents to the cell surface receptor Fn14, which is expressed in many solid cancer types, including TNBC primary tumors and metastatic lesions.

Abstract: Non-adhesive particles as large as 110 nm can diffuse rapidly in the brain ECS, if coated with hydrophilic coatings such as PEG coatings and preferably having neutral surface charge. The ability to achieve brain penetration with larger particles will significantly improve drug and gene delivery within the CNS since larger particles offer higher drug payload, improved drug loading efficiency, and significantly longer drug release durations.

Abstract: Provided are targeted structure-specific particulate-based delivery systems comprising: a nanoparticle; a PEG polymer coating on the surface of the nanoparticle; a targeting moiety conjugated on a surface of the nanoparticle and configured to promote specific binding to a cell surface molecule expressed by a target cell; and a biologically active agent in or on the nanoparticle, wherein the biologically active agent is selected to enhance a desired response in a target cell intracellularly or extracellularly. Methods of treating a disease or disorder administering the delivery system are contemplated.

Abstract: Non-adhesive particles as large as 110 nm can diffuse rapidly in the brain ECS, if coated with hydrophilic coatings such as PEG coatings and preferably having neutral surface charge. The ability to achieve brain penetration with larger particles will significantly improve drug and gene delivery within the CNS since larger particles offer higher drug payload, improved drug loading efficiency, and significantly longer drug release durations.