An extrudable polyvinyl alcohol (PVA) powder with improved flowability containing particles of PVA, which has been cryo-milled, and which has d.sub.50 particle sizes in the range of 45 to 1400 μm; or which has a particle size distribution of d.sub.10=20±10 μm, d.sub.20=30±10 μm, d.sub.50=70±10 μm, d.sub.90=200±30 μm, and d.sub.99=300±30 μm; and a powdery composition for the preparation of pharmaceutical formulations which contains the polyvinyl alcohol homogeneously mixed with at least one active pharmaceutical ingredient (API); and a process for producing a solid pharmaceutical dosage form by extruding or forming a homogeneous melt of a mixture of ingredients containing the powdered polyvinyl alcohol and at least one active pharmaceutical ingredient (API), and forming a powder or a molded form.

The present invention provides scaffolds that include a polymer and a cyclic peptide ligand. The peptide ligand increases the attachment of endothelial cells and/or progenitor cells to the scaffold. The present invention also provides engineered tissues that include the provided scaffolds. The present invention also provides coatings that include a coating polymer and a cyclic peptide ligand. The present invention also provides methods of improving endothelialization and vascularization of endothelial cells and/or progenitor cells for tissue regeneration in a subject and of repairing bone defects in a subject, by implanting a provided scaffold.

Disclosed are hydrogels polymerized with or around a solid biofunctional moiety, biodegradable or permanent, designed to be implantable in a mammalian body, intended to block or mitigate the formation of tissue adhesions, and intended to aid in functional healing. The hydrogels of the present invention are characterized by comprising multiphasic structural elements: a) at least one gel phase, b) at least one solid phase, c) optional polymeric chains connecting gel and solid phases, d) optional shape designs that provide for an interpenetrating geometry between gels and solids, e) optional shape designs that enhance a tissue-hydrogel interface, and f) optional shape designs that provide a biofunctional aspect. The hydrophobicity of the various phases is chosen to reduce tissue adhesion and enhance tissue healing. The morphology of the polymers comprising the gel phase is typically of high molecular weight and has morphology that encourages entanglement. Useful polymeric structures include branching chains, comb or brush, and dendritic morphologies.

The invention provides compositions featuring chitosan and polyethylene glycol and methods for using such compositions for the local delivery of biologically active agents to an open fracture, complex wound or other site of infection. Advantageously, the chitosan-PEG compositions can be loaded with one or more antimicrobial agents, including hydrophobic agents, and can be tailored to the needs of particular patients at the point of care (e.g., in a surgical suite, clinic, physician's office, or other clinical setting).

The present invention relates to micellar nanocomplexes and a method of forming the same. The micellar nanocomplex comprises a micelle and an agent encapsulated within said micelle, where the micelle comprises a polymer-flavonoid conjugate, wherein said polymer is bonded to the B ring of said flavonoid. The micellar nanocomplex may have useful applications as a drug-delivery system.

The invention relates to oligofluorinated coatings and their use in drag delivery. The oligofluorinated coatings are compositions comprising formula (XVII). These coatings are used in a method of delivering a biologically active agent to a tissue surface in a mammalian tissue. This method occurs by contacting the surface with the coating including an oligofluorinated oligomer and a biologically active agent wherein the coating resides on the tissue surface and release the biologically active agent to the tissue surface.

The invention provides methods and polymer-containing formulations for treating retinal detachment and other ocular disorders, where the methods employ polymer compositions that can form a hydrogel in the eye of a subject. The hydrogel is formed by reaction of (a) a nucleo-functional polymer is a biocompatible polyalkylene polymer substituted by (i) a plurality of —OH groups, (ii) a plurality of thio-functional groups —R.sup.1—SH wherein R.sup.1 is an ester-containing linker, and (iii) optionally one or more —OC(O)—(C.sub.1-C.sub.6 alkyl) groups, such as a thiolated poly(vinyl alcohol) polymer and (ii) an electro-functional polymer that is a biocompatible polymer containing at least one thiol-reactive group, such as a poly(ethylene glycol) polymer containing alpha-beta unsaturated ester groups. Formulations are provided containing a nucleo-functional polymer, a poly(ethylene glycol) polymer, and an aqueous pharmaceutically acceptable carrier, for use in the therapeutic methods.

Provided are a crosslinked hyaluronic acid product in the form of powder and a method of preparing the same, and a crosslinked hyaluronic acid hydrogel prepared using the crosslinked hyaluronic acid product in the form of powder, and a method of preparing the same. The crosslinked hyaluronic acid hydrogel according to the present disclosure exhibits excellent rheological properties, and mass production thereof is easy and quality uniformity thereof is excellent.

A fiber for protein adsorption has a water absorption percentage of 1 to 50%, and the fiber includes a polymer containing as repeat units an aromatic hydrocarbon or a derivative thereof, wherein part of aromatic rings contained in the repeat units are cross-linked through a structure represented by Formula (I). A column for protein adsorption uses the fibers. A in Formula (I) is selected from an alkyl aliphatic group, phenyl aromatic group and amino group.

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Biodegradable, cross-linked polymer particle embolics and methods of making the same are described. The particle embolics can be used as embolization agents.