Provided are methods, devices and compositions for reducing and/or inhibiting postsurgical tissue adhesion using a hydrogel film disposed onto a target tissue, thereby providing an adhesion barrier that remains over said target tissue for a prescribed period of time. In some embodiments, the hydrogel film is formed by the gelation of a pre-gel mixture applied onto the target tissue as a plurality of particles having an average maximum dimension, such as diameter, of at most about 500 μm. In some embodiments, the hydrogel film has a minimum storage modulus of 100 Pa. In some embodiments, the pre-gel mixture comprises an ECM digest having a collagen to carbohydrate ratio (by mass) of at least 70:1.

Provided are methods, devices and compositions for reducing and/or inhibiting postsurgical tissue adhesion using a hydrogel film disposed onto a target tissue, thereby providing an adhesion barrier that remains over said target tissue for a prescribed period of time. In some embodiments, the hydrogel film is formed by the gelation of a pre-gel mixture applied onto the target tissue as a plurality of particles having an average maximum dimension, such as diameter, of at most about 500 μm. In some embodiments, the hydrogel film has a minimum storage modulus of 100 Pa. In some embodiments, the pre-gel mixture comprises an ECM digest having a collagen to carbohydrate ratio (by mass) of at least 70:1.

Stents comprising a first region and a second region are provided, where at least the second region comprises one or more phase transforming cellular materials configured to move the outlet between an open configuration and a closed configuration in response to certain triggers. Such stents can also comprise one or more analog for a shape memory alloy (ASMA) unit cells on an inner surface of the first region such that, in response to resistive forces, the ASMA unit cells exert controllable motion to clear the stent. Methods of treatment of cancer, jaundice, and other diseases are also provided.

Disclosed are Self-Gelling materials and structures or materials or structures having one or more self-gelling components that overcome existing gel limitations due to hydrogel localization for medical applications by providing, for example, 1) microstructurally, or physically, anchored characteristics to help localize the gel, and the overall printed, or otherwise formed structure, giving structural form to the gel that allows the gel to be localized within the body, and even sutured in place, and mitigates gel migration and extends its residence time; 2) to provide an underlying 3D printed structure to help contain and support the gel after implantation; and more. Self-Gelling 3D printed structures may be further processed via milling to yield deconstructed scaffold micro-granules, with the composition and nano-/micro- structure of the original larger structure. Deconstructed scaffold micro-granules may be hydrated to form a micro-granule embedded gel network that can be injected, giving form to injectable gels.

According to the invention there is provided inter alia a medical device for delivering a paclitaxel to a tissue, the device the device having a coating layer applied to a surface of the device, the coating layer comprising components i), ii) and iii), wherein component i) is a therapeutic agent which is paclitaxel; and component ii) is urea or a pharmaceutically acceptable salt thereof, or a urea derivative or a pharmaceutically acceptable salt thereof; and component iii) is succinic acid, glutaric acid or caffeine, or a pharmaceutically acceptable salt of any one thereof.

The present disclosure provides a method for producing a multifunctional implantable structure, the method having: preparing an implantable base; coating a polymer layer on the base, wherein the polymer layer is partially curable; curing the polymer layer such that the polymer layer has cured and non-cured portions; and dry-etching the polymer layer to remove the non-cured portion thereof, to allow the polymer layer to have a nano-turf structure having pores defined therein.

A surgical device for assisting in the placement of a prosthetic implant. One or more sheets of polymer are in the form of a conical frustum such that a proximal end is sealed and a distal end is open, with an elongated slit extending from the distal end toward the proximal end. A single opening is formed by the distal opening and the elongated slit with a set of inter-lockable fastener elements disposed along opposing sides and configured to seal the elongated slit such that the distal end remains open to allow for egress of the prosthetic implant for placement into a surgical pocket. A lubricious coating is applied to the interior cavity of the frustum in addition to one or more surface active coatings. Movement of the prosthetic implant across the one or more surface active coatings causes the coatings to provide one or more offered benefits.

A method for controlling generation of biologically desirable voids in a composition placed in proximity to bone or other tissue in a patient by selecting at least one water-soluble inorganic material having a desired particle size and solubility, and mixing the water-soluble inorganic material with at least one poorly-water-soluble or biodegradable matrix material. The matrix material, after it is mixed with the water-soluble inorganic material, is placed into the patient in proximity to tissue so that the water-soluble inorganic material dissolves at a predetermined rate to generate biologically desirable voids in the matrix material into which bone or other tissue can then grow.

Some embodiments are directed to a cellulite treatment system that contains a laser generating device. A hydrogel patch may include a region, at a first side of the hydrogel patch, to be in contact with a person's skin. The region may contain an adsorbing medium (e.g., carbon black or any other substance that would have a similar effect) that, when receiving a laser beam from the laser generating device, results in Extracorporeal Shock Wave Therapy (“ESWT”) being applied to the person's skin to treat cellulite.

Artificial heart valves, their manufacture, and methods of use are described. Generally, artificial heart valves can be deployed to replace or supplement defective heart valves in a patient. These artificial heart valves can comprise a frame with an inner skirt and leaflets. These inner skirt and leaflets can be generated from regenerative tissue to allow integration of the tissue with the body of a patient, while the frame can be generated from bioabsorbable material to allow dissolution of the frame over time. This combination of materials may allow for the artificial valve to grow with a patient and avoid costly and potentially dangerous replacement for patients receiving artificial valves.