The present disclosure provides compositions including alginate microspheres capable of self-degradation upon rehydration, the alginate microspheres comprising alginate, alginate lyase, and divalent metal ions. The present disclosure also provides methods of making compositions including alginate microspheres capable of self-degradation upon rehydration, comprising alginate, alginate lyase, and divalent metal ions. The present disclosure also provides methods of inducing an embolism in a subject in thereof, and syringes containing the compositions of the present disclosure for use in the methods thereof.

Drug delivery balloons have densely packed crystals of small particle size of the drug thereon. An amorphous drug coating is applied to a balloon surface and annealed to provide the crystals. The balloon surface is nucleated to induce formation of drug crystals in the annealing step to provide the crystals in high density with small size.

Compositions and implants for articular cartilage repair or regeneration are described. The compositions are hydrogel-based compositions that can incorporate signaling molecules for cartilage repair. The compositions include microcapsules having predetermined erosion profiles that are loaded with nanogels having predetermined sustained release profiles for signaling molecules conjugated to the nanogels. A plurality of compositions, each carrying different signaling molecules, can be layered to form a multi-layered implant, with each layer sequentially releasing the encapsulated signaling molecules over a predetermined period of time. The compositions can carry additional components to encourage tissue generation such as stem cells and extracellular matrix (ECM) components.

Injectable compositions and use of the injectable compositions in tissue engineering applications are described. The injectable compositions are hydrogel-based compositions that can be crosslinked in situ following placement. The injectable compositions include microcapsules having predetermined erosion profiles that are loaded with nanogels having predetermined sustained release profiles for signaling molecules conjugated to the nanogels. Following crosslinking, the compositions are designed to sequentially release signaling molecules over a predetermined period of time with various release profiles. The compositions can carry additional components to stimulate tissue generation such as stem cells and extracellular matrix (ECM) components.

Luminal grafts and methods of making and using the same. An exemplary luminal graft of the present disclosure is configured as a generally tubular element configured for nerve cells to grow therethrough and comprises at least one sheet of biological tissue having elastin fibers and collagen fibers, with the elastin fibers being a dominant component thereof; and a plurality of microchannels formed on a surface of the at least one sheet of biological tissue, each of the microchannels extending longitudinally between a first end and a second end of the at least one sheet of biological tissue and configured to provide intraluminal structural guidance to nerve cells proliferating therethrough.

Provided herein are scaffolds and methods useful to promote the formation of functional clusters on a tissue, for example, motor endplates (MEPs) or a component thereof on skeletal muscle cells or tissue, as well as the use of scaffolds so produced for repairing a tissue injury or defect.

The present disclosure relates to a polymeric system for release of an active agent, comprising a first polymeric phase containing the active agent, the first polymeric phase forming discrete regions of a set size range and being dispersed within a second polymeric phase comprising a cross-linked polymer-phenol conjugate for release of the active agent therein. The present disclosure further provides an injectable hydrogel comprising the disclosed polymeric system, a carrier for delivering a biologically active substance or a drug comprising the injectable hydrogel, and a method for producing the disclosed polymeric system.

The present invention discloses a preparation method of a titanium nail capable of loading a drug. The titanium nail capable of loading a drug includes a titanium nail body capable of loading a drug, and a microporous ceramic layer capable of loading a drug arranged on the surface of the titanium nail body. The steps of the method include: pretreating the surface of the titanium nail body, preparing a microporous mould for hyaluronic acid-alginic acid microspheres, preparing a titanium sol solution, coating film, pore-forming and calcining. It fails to generate the exfoliations and the wear debris to prevent the human body from wear debris disease and reaction to a foreign body. Moreover, various drugs such as the antibacterial drugs, and the drugs for promoting the healing etc. can be loaded, targeted and slow-released, which is good for medical usage.

Disclosed are a sustained-release injection formulation containing a biodegradable polymer double microcapsule that contains a conjugate of poly-L-lactic acid (hereinafter referred to as PLLA) filler and hyaluronic acid (hereinafter referred to as HA) and is capable of controlling the release rate of PLLA, and a method of preparing the same.

Disclosed herein is a drug-coated medical device in the form of a balloon having an inner surface and an outer hydrophobic surface, an adhesion balance layer directly on the outer hydrophobic surface of the balloon, comprising a hydrophilic polymer and/or a hydrophilic compound where the hydrophilic compound has a molecular weight of less than 1,000 Daltons, and a therapeutic layer directly on the adhesion balance layer comprising a therapeutic agent and a pharmaceutically acceptable carrier, wherein the therapeutic agent is a hydrophobic therapeutic agent with one or more hydrogen-bonding groups and is provided as discrete drug particles in the therapeutic layer, the drug particles have at least one dimension that is less than 25 .Math. and are uniformly distributed on the surface of the balloon, and the pharmaceutically acceptable carrier is hydrophilic and has a molecular weight of less than 1,000 Daltons. A process to make the drug-coated medical device and uses thereof are also disclosed.