Abstract: Poly(amine-co-ester) polymers, methods of forming active agent-load nanoparticles therefrom, and methods of using the nanoparticles for drug delivery are disclosed. The nanoparticles can be coated with an agent that reduces surface charge, an agent that increases cell-specific targeting, or a combination thereof. Typically, the loaded nanoparticles are less toxic, more efficient at drug delivery, or a combination thereof compared to a control other transfection reagents. In some embodiments, the nanoparticles are suitable for in vivo delivery, and can be administered systemically to a subject to treat a disease or condition.

Abstract: Poly(amine-co-ester) polymers, methods of forming active agent-load nanoparticles therefrom, and methods of using the nanoparticles for drug delivery are disclosed. The nanoparticles can be coated with an agent that reduces surface charge, an agent that increases cell-specific targeting, or a combination thereof. Typically, the loaded nanoparticles are less toxic, more efficient at drug delivery, or a combination thereof compared to a control other transfection reagents. In some embodiments, the nanoparticles are suitable for in vivo delivery, and can be administered systemically to a subject to treat a disease or condition.

Abstract: Polymers including poly(amine-co-ester), poly(amine-co-amide), or a combination thereof, and nanoparticles, particularly solid core nanoparticles, formed therefrom are provided. Solid core nanoparticles fabricated from hydrophobic polymers often require the presence of cationic complexing agents to stabilize negatively charged active agents such as siRNA. However, complexing agents are optional in the disclosed formulations because the nanoparticles contain cationic amines to stabilize negatively charged nucleic acids and hydrophobic domains to condense the nucleic acid into the core of the formed nanoparticles, thus improving encapsulation efficiency. This increase in nucleic acid loading allows the disclosed solid core nanoparticles to deliver more nucleic acid per cell without increasing total polymer delivered, further reducing cytotoxicity.

Abstract: Polymeric nanoparticles encapsulating inhibitory ribonucleic acids (RNAs) and methods of their manufacture and use are provided. Advantageous properties of the nanoparticles include: 1) high encapsulation efficiency of inhibitory RNAs into the nano articles, 2) small size of the nanoparticles that increases cell internalization, and 3) sustained release of encapsulated inhibitory RNAs by the nanoparticles that allows for administration of an effective amount of inhibitory RNAs to cells or tissues over extended periods of time. Encapsulation efficiency of inhibitory RNAs into the nanoparticles is greatly increased by complexing the inhibitory RNAs to polycations prior to encapsulation. Methods of using the polymeric nanoparticles for treating or inhibiting diseases or disorders are provided.

Abstract: Poly(amine-co-ester) polymers, methods of forming active agent-load nanoparticles therefrom, and methods of using the nanoparticles for drug delivery are disclosed. The nanoparticles can be coated with an agent that reduces surface charge, an agent that increases cell-specific targeting, or a combination thereof. Typically, the loaded nanoparticles are less toxic, more efficient at drug delivery, or a combination thereof compared to a control other transfection reagents. In some embodiments, the nanoparticles are suitable for in vivo delivery, and can be administered systemically to a subject to treat a disease or condition.

Abstract: Polymeric nanoparticles encapsulating inhibitory ribonucleic acids (RNAs) and methods of their manufacture and use are provided. Advantageous properties of the nanoparticles include: 1) high encapsulation efficiency of inhibitory RNAs into the nanoparticles, 2) small size of the nanoparticles that increases cell internalization, and 3) sustained release of encapsulated inhibitory RNAs by the nanoparticles that allows for administration of an effective amount of inhibitory RNAs to cells or tissues over extended periods of time. Encapsulation efficiency of inhibitory RNAs into the nanoparticles is greatly increased by complexing the inhibitory RNAs to polycations prior to encapsulation. Methods of using the polymeric nanoparticles for treating or inhibiting diseases or disorders are provided.

Abstract: Modular nanoparticle vaccine compositions and methods of making and using the same have been developed. Modular nanoparticle vaccine compositions comprise an antigen encapsulated in a polymeric particle and adaptor elements which modularly couple functional elements to the particle. The modular design of these vaccine compositions, which involves flexible addition and subtraction of antigen, adjuvant, immune potentiators, molecular recognition and transport mediation elements, as well as intracellular uptake mediators, allows for exquisite control over variables that are important in optimizing an effective vaccine delivery system.

Abstract: Brain-penetrating polymeric nanoparticles that can be loaded with drugs and are optimized for intracranial convection-enhanced delivery (CED) have been developed. In the preferred embodiment, these are loaded with FDA-approved compounds, identified through library screening to target brain cancer stem cells (BSCSs). The particles are formed by emulsifying a polymer-drug solution, then removing solvent and centrifuging at a first force to remove the larger particles, then collecting the smaller particles using a second higher force to sediment the smaller particles having a diameter of less than 100 nm, more preferably less than 90 nanometers average diameter, able to penetrate brain interstitial spaces.

Abstract: Polyamine-co-ester-co-ortho ester) polymers, methods of forming active agent-load nanoparticles therefrom, and methods of using the nanoparticles for drug delivery are disclosed. The nanoparticles can be coated with an agent that reduces surface charge, an agent that increases cell-specific targeting, or a combination thereof. Typically, the loaded nanoparticles are less toxic, more efficient at drug delivery, or a combination thereof compared to a control or other transfection reagents.

Abstract: An embodiment of the invention is directed to a microfabricated, silicon-based, Convection Enhanced Delivery (CED) device. The device comprises a silicon shank portion, at least one individual parylene channel disposed along at least a part of an entire length of the shank, wherein the channel has one or more dimensioned fluid exit ports disposed at one or more respective locations of the channel and a fluid (drug) input opening. The fluid input opening may be configured or adapted to be connected to a fluid reservoir and/or a pump and/or a meter and/or a valve or other suitable control device(s) or apparatus that supplies and/or delivers fluid (e.g., a drug) to the microfabricated device. The device may have multiple channels disposed side by side or in different surfaces of the device. The device may be rigid, or flexible, in which case a flexible device can be attached to a bio-degradable support scaffold that provides sufficient structural rigidity for insertion of the device into the target tissue.

Abstract: Poly(amine-co-ester) polymers, methods of forming active agent-load nanoparticles therefrom, and methods of using the nanoparticles for drug delivery are disclosed. The nanoparticles can be coated with an agent that reduces surface charge, an agent that increases cell-specific targeting, or a combination thereof. Typically, the loaded nanoparticles are less toxic, more efficient at drug delivery, or a combination thereof compared to a control other transfection reagents. In some embodiments, the nanoparticles are suitable for in vivo delivery, and can be administered systemically to a subject to treat a disease or condition.

Abstract: Modular nanoparticle vaccine compositions and methods of making and using the same have been developed. Modular nanoparticle vaccine compositions comprise an antigen encapsulated in a polymeric particle and adaptor elements which modularly couple functional elements to the particle. The modular design of these vaccine compositions, which involves flexible addition and subtraction of antigen, adjuvant, immune potentiators, molecular recognition and transport mediation elements, as well as intracellular uptake mediators, allows for exquisite control over variables that are important in optimizing an effective vaccine delivery system.

Abstract: An embodiment of the invention is directed to a microfabricated, silicon-based, Convection Enhanced Delivery (CED) device. The device comprises a silicon shank portion, at least one individual parylene channel disposed along at least a part of an entire length of the shank, wherein the channel has one or more dimensioned fluid exit ports disposed at one or more respective locations of the channel and a fluid (drug) input opening. The fluid input opening may be configured or adapted to be connected to a fluid reservoir and/or a pump and/or a meter and/or a valve or other suitable control device(s) or apparatus that supplies and/or delivers fluid (eg, a drug) to the microfabricated device. The device may have multiple channels disposed side by side or in different surfaces of the device.

Abstract: Polymeric microparticles are used to deliver recombinagenic or mutagenic nucleic acid molecules such as donor nucleic acid alone, or in combination with triplex-forming molecules, to induce a site-specific mutation in the target DNA. Target cells endocytose the particles, releasing the nucleic acid molecules inside of the cell, where they induce mutagenesis or recombination at a target site. The examples demonstrate that triplex forming oligonucleotides, preferably PNAs, preferably in combination with a donor nucleotide molecule, can be encapsulated into polymeric microparticles, which are delivered into cells. Results demonstrate significantly greatly levels of uptake and expression, and less cytotoxicity, as compared to direct transfer of the nucleic acid molecules into the cell by nucleofection.

Abstract: Methods for ex vivo administration of drugs to grafts using polymeric micro- and nanoparticles and applications for these methods are described herein. The particles contain encapsulated molecules which are released locally at the site of implantation and function to prevent graft rejection or aid in the proper adaptation of the graft to the host. The disclosed methods may be used to inhibit or reduce hyperplasia and stenosis of vascular grafts or to prevent graft rejection.

Abstract: Modular nanoparticle vaccine compositions and methods of making and using the same have been developed. Modular nanoparticle vaccine compositions comprise an antigen encapsulated in a polymeric particle and adaptor elements which modularly couple functional elements to the particle. The modular design of these vaccine compositions, which involves flexible addition and subtraction of antigen, adjuvant, immune potentiators, molecular recognition and transport mediation elements, as well as intracellular uptake mediators, allows for exquisite control over variables that are important in optimizing an effective vaccine delivery system.

Abstract: Polymeric delivery devices have been developed which combine high loading/high density of molecules to be delivered with the option of targeting. As used herein, “high density” refers to microparticles having a high density of ligands or coupling agents, which is in the range of 1000-10,000,000, more preferably between 10,000 and 1,000,000 ligands per square micron of microparticle surface area. A general method for incorporating molecules into the surface of biocompatible polymers using materials with an HLB of less than 10, more preferably less than 5, such as fatty acids, has been developed. Because of its ease, generality and flexibility, this method has widespread utility in modifying the surface of polymeric materials for applications in drug delivery and tissue engineering, as well other fields.

Abstract: Polymeric microparticles have been developed which encapsulate therapeutic compounds such as drugs, cellular materials or components, and antigens, and can have targeting ligands directly bound to the microparticle surface. Preferred applications include use in tissue engineering matrices, wound dressings, bone repair or regeneration materials, and other applications where the microparticles are retained at the site of application or implantation. Another preferred application is in the use of microparticles to deliver anti-proliferative agents to the lining of blood vessels following angioplasty, transplantation or bypass surgery to prevent or decrease restenosis, and in cancer therapy. In still another application, the microparticles are used to treat or prevent macular degeneration when administered to the eye, where agents such as complement inhibitors are administered.

Abstract: Polymeric microparticles have been developed which encapsulate therapeutic compounds such as drugs, cellular materials or components, and antigens, and can have targeting ligands directly bound to the microparticle surface. Preferred applications include use in tissue engineering matrices, wound dressings, hone repair or regeneration materials, and other applications where the microparticles are retained at the site of application or implantation. Another preferred application is in the use of microparticles to deliver anti-proliferative agents to the lining of blood vessels following angioplasty, transplantation or bypass surgery to prevent or decrease restenosis, and in cancer therapy. In still another application, the microparticles are used to treat or prevent macular degeneration when administered to the eye, where agents such as complement inhibitors are administered.

Abstract: Polymeric microparticles have been developed which encapsulate therapeutic compounds such as drugs, cellular materials or components, and antigens, and can have targeting ligands directly bound to the microparticle surface. Preferred applications include use in tissue engineering matrices, wound dressings, bone repair or regeneration materials, and other applications where the microparticles are retained at the site of application or implantation. Another preferred application is in the use of microparticles to deliver anti-proliferative agents to the lining of blood vessels following angioplasty, transplantation or bypass surgery to prevent or decrease restenosis, and in cancer therapy. In still another application, the microparticles are used to treat or prevent macular degeneration when administered to the eye, where agents such as complement inhibitors are administered.