A flexible anchor for coupling a suture to a bone is provided. The anchor is composed of non-woven electrospun fibers and has an elongate tubular body that extends from a first end to a second end. The anchor is configured to receive a suture that enters the anchor through a first aperture and exits the anchor through a second aperture. When free ends of the suture are pulled, the anchor transitions from a first configuration to a second anchoring configuration.

Various embodiments disclosed relate to drug-coated balloon catheters for treating strictures in body lumens and methods of using the same. A drug-coated balloon catheter for delivering a therapeutic agent to a target site of a body lumen stricture includes an elongated balloon having a main diameter. The balloon catheter includes a coating layer overlying an exterior surface of the balloon. The coating layer includes one or more water-soluble additives and an initial drug load of a therapeutic agent.

Various embodiments disclosed relate to drug-coated balloon catheters for treating strictures in body lumens and methods of using the same. A drug-coated balloon catheter for delivering a therapeutic agent to a target site of a body lumen stricture includes an elongated balloon having a main diameter. The balloon catheter includes a coating layer overlying an exterior surface of the balloon. The coating layer includes one or more water-soluble additives and an initial drug load of a therapeutic agent.

Various embodiments disclosed relate to drug-coated balloon catheters for treating strictures in body lumens and methods of using the same. A drug-coated balloon catheter for delivering a therapeutic agent to a target site of a body lumen stricture includes an elongated balloon having a main diameter. The balloon catheter includes a coating layer overlying an exterior surface of the balloon. The coating layer includes one or more water-soluble additives and an initial drug load of a therapeutic agent.

The present disclosure is directed to peptide-polymer conjugates, and to their use in treating intra-articular diseases or disorders.

Intraocular pressure sensors, systems, and methods of use. Implantable intraocular pressure sensing devices that are hermetically sealed and adapted to wirelessly communicate with an external device. The implantable devices can include a hermetically sealed housing, the hermetically sealed housing including therein: an antenna in electrical communication with a rechargeable power source, the rechargeable power source in electrical communication with an ASIC, and the ASIC in electrical communication with a pressure sensor.

A method of making a bone matrix includes exposing a bone tissue to a solution including a surfactant and a protease; treating the bone tissue with an acid solution following exposing the bone tissue; and electrophoretically treating the acid treated bone tissue. A bone matrix has a DNA content of not greater than 0.1 micrograms per milligram sample and a modulus in a range of 180 kPa to 250 kPa.

A method for depositing a coating comprising a polymer and at least two pharmaceutical agents on a substrate, comprising the following steps: providing a stent framework; depositing on said stent framework a first layer comprising a first pharmaceutical agent; depositing a second layer comprising a second pharmaceutical agent; Wherein said first and second pharmaceutical agents are selected from two different classes of pharmaceutical agents.

Disclosed herein are cohesive soft tissue fillers, for example, dermal and subdermal fillers, based on hyaluronic acids and optionally including proteins. In one aspect, hyaluronic acid-based compositions described herein include zero-length cross-linked moieties and optionally at least one active agent. The present hyaluronic acid-based compositions have enhanced flow characteristics, hardness, and persistence compared to known hyaluronic acid-based compositions. Methods and processes of preparing such hyaluronic acid-based compositions are also provided.

Biomaterials disclosed herein can comprise a hydrogel comprising PEG, gelatin, and a glycosaminoglycan with sulfated moiety; and chondrogenic, osteogenic, and immunomodulatory cytokines; wherein the biomaterial is capable of potentiating bone regeneration in a compromised wound while reducing inflammatory response. The glycosaminoglycan with sulfated moiety can comprise heparin, heparan sulfate, keratin sulfate, chondroitin sulfate, dermatan sulfate, and/or similar materials. The biomaterial can further comprise mesenchymal stem cells (MSCs), a crosslinking initiator, microparticles and nanoparticles, and or other materials. The biomaterial can be injectable into a wound, or the biomaterial can be loaded in, or further comprise a porous scaffold providing mechanical support for other components of the biomaterial, such that it can be implanted into a wound.