The present invention provides compositions comprising peptide-coupled biodegradable poly(lactide-co-glycolide) (PLG) particles. In particular, PLG particles are surface-functionalized to allow for coupling of peptide molecules to the surface of the particles (e.g., for use in eliciting induction of immunological tolerance).

The invention relates to inhibitors of the PKC signaling pathway for use in the treatment of septic cholestasis, wherein the inhibitors are targeted into the liver by a selective nanostructured delivery system, wherein the selective nanostructured delivery system comprises at least one carbohydrate targeting moiety and at least one polymer and/or at least one lipid and/or at least one virus-like particle.

Provided herein are pharmaceutical compositions for local administration of metabolic inhibitors, methods of locally administering such compositions, and rapid diagnostic methods for identifying mutant allele during the course of a surgical procedure.

The invention relates to inhibitors of the PKC signaling pathway for use in the treatment of septic cholestasis, wherein the inhibitors are targeted into the liver by a selective nanostructured delivery system, wherein the selective nanostructured delivery system comprises at least one polymethine dye and at least one polymer and/or at least one lipid and/or at least one virus-like particle, wherein the at least one polymethine dye is a symmetrical or asymmetrical polymethine.

The invention provides compositions and methods for delivering agents to localized regions, tissues, or organs in vivo by conjugating agent-loaded nanoparticles to cells having homing capability. The agents may be therapeutic or diagnostic agents such as cancer chemotherapeutic agents and imaging agents respectively.

The present invention provides compositions comprising peptide-coupled biodegradable poly(lactide-co-glycolide) (PLG) particles. In particular, PLG particles are surface-functionalized to allow for coupling of peptide molecules to the surface of the particles (e.g., for use in eliciting induction of immunological tolerance).

Disclosed herein is a glucose-responsive insulin delivery system based on the interaction between the glucose-modified insulin and glucose transporters (GLUTs) on erythrocytes (or red blood cells, RBCs). After being conjugated with glucose, insulin can efficiently bind to RBC membranes. The binding is reversible in the setting of hyperglycemia, resulting in fast release of insulin and subsequent drop of blood glucose (BG) level in vivo. In some embodiments, the delivery vehicle can include: 1) intravenously injectable polymeric nanoparticles (˜100 nm in diameter) coated with RBC membrane and loaded with glucose-modified insulin and/or 2) painless microneedle (MN) patches loaded with the complex of GLUT and glucose-modified insulin.

In one aspect, methods of targeted nanoparticle and cell delivery are described herein. In some embodiments, methods described herein comprise coupling nanoparticles and cells to a carrier cell to form a nanoparticle-cell conjugate or cell-cell conjugate, disposing the nanoparticle-cell or cell-cell conjugate in a biological environment, and delivering the nanoparticles and cells to target cells or tissues located within the biological environment. The nanoparticles comprise a biodegradable photoluminescent polymer, and the nanoparticle-cell conjugate is formed using one or more click chemistry reaction products.

The present disclosure provides method of making a nanoparticle complex wherein the nanoparticle complex comprises a ligand and a metal cation. The disclosure also provides nanoparticle complexes, methods of treating a disease in a patient utilizing the nanoparticle complexes, methods of identifying a disease in a patient utilizing the nanoparticle complexes, and kits involving the nanoparticle complexes.

The present disclosure provides polymeric particles comprising biomolecules of interest attached thereto, methods for using the same, and methods for making the same. The surface of the polymeric particles can be functionalized by attaching multiple different biomolecules of interest in a desired ratio for co-presentation. In addition, the polymeric particles may also encapsulate bio-molecules, such as, therapeutic nucleic acids, peptide and/or polypeptides for release in vivo. The present disclosure also provide synthetic particles and methods for enhancing proliferation of CAR-T cells. Additionally, the present disclosure provide biomolecule-coated films and methods.