Abstract: Products, such as devices, prostheses, and materials, whose surfaces have been modified in order to impart beneficial properties to these products are disclosed. The surface-modified products have improved biocompatibility compared to a corresponding product that lacks the modification. Following implantation in a subject, the surface-modified products induce a lower foreign-body response, compared to a corresponding unmodified product.

Abstract: Covalently modified alginate polymers, possessing enhanced biocompatibility and tailored physiochemical properties, as well as methods of making and use thereof, are disclosed herein. The covalently modified alginates are useful as a matrix for coating of any material where reduced fibrosis is desired, such as encapsulated cells for transplantation and medical devices implanted or used in the body.

Abstract: Covalently modified alginate polymers, possessing enhanced biocompatibility and tailored physiochemical properties, as well as methods of making and use thereof, are disclosed herein. The covalently modified alginates are useful as a matrix for the encapsulation and transplantation of cells. Also disclosed are high throughput methods for the characterizing the biocompatibility and physiochemical properties of modified alginate polymers.

Abstract: Covalently modified alginate polymers, possessing enhanced biocompatibility and tailored physiochemical properties, as well as methods of making and use thereof, are disclosed herein. The covalently modified alginates are useful as a matrix for coating of any material where reduced fibrosis is desired, such as encapsulated cells for transplantation and medical devices implanted or used in the body.

Abstract: The present disclosure relates to compositions and methods for modifying a gene sequence, and for systems for deliverying such compositions. For example, the disclosure relates to modifying a gene sequence using a CRISPR-Cas9 or other nucleic acid editing system, and methods and delivery systems for achieving such gene modification, such as viral or non-viral delivery systems.

Abstract: A sensor comprises a substrate; an array of nanowire field effect transistors (NWFETs) formed in said substrate, each of the NWFETs having source, drain and gate terminals; a nanowire coupled between the source terminal and the drain terminal of each NWFET; and a layer of radiation sensitive material disposed over said NWFETs and said nanowires with each of the source, drain and gate terminals configured to be coupled to respective ones of first, second or third reference potentials, wherein each NWFET is configured such that the conductivity between the source and drain changes in response to radiation absorbed in the layer of radiation sensitive material such that the sensor generates an output signal in response to radiation absorbed by the radiation sensitive material.

Abstract: Biocompatible hydrogel capsules encapsulating mammalian cells having a diameter of greater than 1 mm, and optionally a cell free core, are disclosed which have reduced fibrotic overgrowth after implantation in a subject. Methods of treating a disease in a subject are also disclosed that involve administering a therapeutically effective amount of the disclosed encapsulated cells to the subject.

Abstract: Compositions and methods for modified dendrimer nanoparticle (“MDNP”) delivery of therapeutic, prophylactic and/or diagnostic agent such as large repRNA molecules to the cells of a subject have been developed. MDNPs efficiently drive proliferation of antigen-specific T cells against intracellular antigen, and potentiate antigen-specific antibody responses. MDNPs can be multiplexed to deliver two or more different repRNAs to modify expression kinetics of encoded antigens and to simultaneous deliver repRNAs and mRNAs including the same UTR elements that promote expression of encoded antigens.

Abstract: Biocompatible hydrogel capsules encapsulating mammalian cells having a diameter of greater than 1 mm, and optionally a cell free core, are disclosed which have reduced fibrotic overgrowth after implantation in a subject. Methods of treating a disease in a subject are also disclosed that involve administering a therapeutically effective amount of the disclosed encapsulated cells to the subject.

Abstract: Methods of transfecting cells in vivo, by administering an injectable pharmaceutical composition including a genome editing composition and a pharmaceutically acceptable carrier to a subject by hydrodynamic injection into a vessel of the subject are disclosed. Typically, the pharmaceutical composition is administered in a volume and at rate of injection suitable to transfect target eukaryotic cells in the subject with an effective amount of the genome editing composition to alter the genome of the target cells. In preferred embodiments the subject is a mammal, such as rodent, or a primate such as a human. The methods can be used to treat one or more symptoms of a genetic disease or condition.

Abstract: Covalently modified alginate polymers, possessing enhanced biocompatibility and tailored physiochemical properties, as well as methods of making and use thereof, are disclosed herein. The covalently modified alginates are useful as a matrix for the encapsulation and transplantation of cells. Also disclosed are high throughput methods for the characterizing the biocompatibility and physiochemical properties of modified alginate polymers.

Abstract: Covalently modified alginate polymers, possessing enhanced biocompatibility and tailored physiochemical properties, as well as methods of making and use thereof, are disclosed herein. The covalently modified alginates are useful as a matrix for the encapsulation and transplantation of cells. Also disclosed are high throughput methods for the characterizing the biocompatibility and physiochemical properties of modified alginate polymers.

Abstract: Injectable insulin loaded microgels that are capable of modifying the amount of insulin released based on the patient's tissue glucose levels, methods for making and using these compositions have been developed. The microgels contain insulin, glucose oxidase entrapped in or bound to the microgels, and an agent that reduces hydrogen peroxide, entrapped in or bound to the microgels, wherein the polymeric microgel expands when pH decreases from physiological pH and shrinks when pH increases towards physiological pH, thereby releasing insulin at a rate corresponding to the glucose concentration. In one embodiment, the glucose oxidase and/or the agent reducing hydrogen peroxide are encapsulated in nanogels, then encapsulated within the microgel.

Abstract: A system for “smart” delivery of a therapeutic, prophylactic or diagnostic agent, such as glucose-mediated delivery of insulin through an injectable nano-network consisting of oppositely-charged dextran nanoparticles encapsulating insulin and glucose-specific enzymes forming a gel-like 3D scaffold. As demonstrated by the examples, the system effectively dissociates to release insulin in a hyperglycemic condition, where the catalytic conversion of glucose into gluconic acid and the subsequent degradation of polymeric matrix are facilitated. This formulation design provides a delivery strategy for both self-regulated and long-term diabetes management.

Abstract: Biomedical devices for implantation with decreased pericapsular fibrotic overgrowth are disclosed. The device includes biocompatible materials and has specific characteristics that allow the device to elicit less of a fibrotic reaction after implantation than the same device lacking one or more of these characteristic that are present on the device. Biocompatible hydrogel capsules encapsulating mammalian cells having a diameter of greater than 1 mm, and optionally a cell free core, are disclosed which have reduced fibrotic overgrowth after implantation in a subject. Methods of treating a disease in a subject are also disclosed that involve administering a therapeutically effective amount of the disclosed encapsulated cells to the subject.

Abstract: Covalently modified alginate polymers, possessing enhanced biocompatibility and tailored physiochemical properties, as well as methods of making and use thereof, are disclosed herein. The covalently modified alginates are useful as a matrix for coating of any material where reduced fibrosis is desired, such as encapsulated cells for transplantation and medical devices implanted or used in the body.

Abstract: Water-responsive composite materials are provided containing a polymeric matrix and a water-responsive gel integrated into the polymeric matrix. The water-responsive gel can include a polyol or an alkoxylated polyol crosslinked by reversibly hydrolysable bonds, such as borate ester bonds. The polymeric matrix can include conjugated polymers such as poly(pyrrole) containing polymers. The composite material is capable of rapid actuation in the presence of a water gradient and can exhibit power densities greater than 1 W/kg. Methods of making water-responsive composite materials are provided, including by electropolymerization. Devices containing water-responsive composite materials are provided for sensing, locomotion, and power generation.

Abstract: Compounds, compositions, and methods for “smart” delivery of a therapeutic, prophylactic or diagnostic agent, such as glucose-mediated delivery of insulin through glucose-sensing insulin derivatives, are provided. The insulin derivatives bind serum albumin or agglomerate in vivo. The insulin derivatives effectively dissociate to release insulin in a hyperglycemic condition, where the complexation of glucose to a glucose-sensing element alters properties of the insulin derivative leading to the dissociation. The compounds, compositions, and methods provide a delivery strategy for both self-regulated and long-term diabetes management.

Abstract: Provided are derivatized therapeutic, prophylactic, or diagnostic agents, such as nucleic acids, that can be effectively delivered to cells and tissues. Also provided are methods of affecting a biological process by administering a therapeutic, prophylactic, or diagnostic agent, such as functional nucleic acid, to a cell or a subject, where the therapeutic, prophylactic, or diagnostic agent, such as functional nucleic acid, is derivatized therapeutic, prophylactic, or diagnostic agent, such as nucleic acid.

Abstract: The invention provides for delivery, engineering and optimization of systems, methods, and compositions for manipulation of sequences and/or activities of target sequences. Provided are delivery particle formulations and/or systems comprising one or more components of a CRISPR-Cas system, which are means for targeting sites for delivery. The delivery particle formulations of the invention are preferably nanoparticle delivery formulations and/or systems. Also provided are vectors and vector systems some of which encode one or more components of a CRISPR complex, as well as methods for the design and use of such vectors. Also provided are methods of directing CRISPR complex formation in eukaryotic cells to ensure enhanced specificity for target recognition and avoidance of toxicity and to edit or modify a target site in a genomic locus of interest to alter or improve the status of a disease or a condition.