A particulate, modified release barrier coated drug-cation exchange resin complex comprising a core composed of a drug complexed with a pharmaceutically acceptable ion-exchange resin is provided. Methods of making and products containing this coated complex are described.

A targetable nanoconstruct capable of simultaneously serving as a therapeutic platform for photodynamic therapy as well as an MR molecular imaging agent, free of heavy metal atoms. F3-cys targeting agent nanoconstructs, including 8PEGA-Ce6 NCs. A label-free 8PEGA nanoconstruct that can be directly and selectively imaged by MRI, using standard spin-echo imaging sequences with large diffusion magnetic field gradients to suppress the water signal.

The present invention discloses a method for analysis of drug resistance of tumor cells. The method includes the steps of: (a) providing silicon dioxide nanoparticles, polystyrene-co-polyacrylic acid nanoparticles or metal-organic framework nanoparticles; (b) co-incubating the silicon dioxide nanoparticles, the polystyrene-co-polyacrylic acid nanoparticles or the metal-organic framework nanoparticles with the tumor cells; and (c) detecting endocytosis of the silicon dioxide nanoparticles, the polystyrene-co-polyacrylic acid nanoparticles or the metal-organic framework nanoparticles by the tumor cells. The analysis method of the present invention can analytically identify drug-resistant tumor cells in a clear, intuitive and efficient way. The provided nanoparticles feature simple synthesis processes that take short periods of time, and after they are co-incubated with the tumor cells, a flow cytometer is used for detection. Based on a result of the detection, a degree of drug-resistance of the tumor cells and a proportion of drug-resistant cells therein are determined, making the method simple and efficient.

The invention provides novel photolytic compounds and prodrugs, nanoparticles and compositions thereof, and methods of conducting photolysis mediated by triplet-triplet annihilation.

Disclosed is a nanoparticle system consisting of a polymer support or substrate in the form of nanoparticles to which a hydrolase enzyme able to degrade hyaluronic acid and one or more biologically and/or pharmacologically active molecules are covalently bonded, its preparation process and its uses in the diagnostic, prognostic and therapeutic fields.

The present invention provides compositions comprising tolerizing immune modified particles (TIMPs) and methods for using and making said TIMPs. In particular, carrier polymer is covalently conjugated with antigenic peptide before particle formation, which allows for exquisite control of particle size and antigen encapsulation (e.g., for use in eliciting induction of immunological tolerance).

Disclosed herein are conjugated polymers comprising a polymer and an all-trans retinoic acid (ATRA) prodrug covalently bound to the polymer by a hydrolysable linker L or a pharmaceutically acceptable salt thereof, and methods of using same to treat certain disorders. In an embodiment, the conjugated polymer comprises poly (vinyl alcohol) covalently bound to ATRA through an ester linkage.

Disclosed is a nanoparticle system consisting of a polymer support or substrate in the form of nanoparticles to which a hydrolase enzyme able to degrade hyaluronic acid and one or more biologically and/or pharmacologically active molecules are covalently bonded, its preparation process and its uses in the diagnostic, prognostic and therapeutic fields.

We have developed novel shear-thinning biomaterials using silica nanoparticles, gelatin-based polymers and polypeptides such as anti-PD-1 antibodies. Shear-thinning biomaterial technology offers enables polymers and drugs loaded inside such polymers to be easily delivered directly through catheters into target area for use, for example, in cancer therapy and immunotherapy. When a force above a certain threshold is applied to inject such materials, they “thin” and behaves as a semi-solid, allowing the material to readily flow through a catheter. When the force is removed, the material instantly becomes a soft solid with significant cohesive properties that prevent it from dislodging or breaking up.

A cerium oxide nanocomplex, a composition containing the cerium oxide nanocomplex as an active ingredient, and uses thereof for preventing or treating peritonitis are disclosed. The cerium oxide nanocomplex improves the biomedical stability, biocompatibility, and efficiency of the production process of nanoparticles while maintaining the excellent inhibitory activity against inflammation by applying a biocompatible polymer composed of an optimal combination. The cerium oxide nanocomplex may be used as an excellent therapeutic composition that may greatly improve patients' survival rate by effectively inhibiting inflammatory response and quickly blocking tissue damage at early stage of peritonitis when a radical inflammatory injury occurs because of the penetration of bacteria, foreign body and immune cells into a perforated organ in the abdominal cavity.