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.

Described are ready-to-use injectable compositions comprising polymeric microspheres or microparticles of non-animal origin, a hydrogel comprising water and a cellulose-derivative gelling agent, and polysorbate 80. Further described are methods of using the ready-to-use injectable compositions for reparative or plastic surgery, esthetic dermatology, facial contouring, body contouring, and gingival augmentation.

An oxygen-releasing biomaterial, articles and methods, and more particularly an oxygen-releasing biomaterial with sustained oxygen-releasing properties of four to five weeks, which is suitable for tissue engineering scaffolds, is disclosed. The biomaterial contains a hydrogel with a plurality of microparticles suspended in the hydrogel. The microparticles contain an oxygen carrier that is encapsulated in a biocompatible hydrophobic material, where the release of oxygen from the oxygen carrier is sustained over a four to five week period. The biomaterial has application in tissue engineering, osteogenesis, burn and wound treatment, and treatment of cardiac conditions, and has further antimicrobial properties.

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.

The present invention is directed to an implantable device comprising a biocompatible and biodegradable matrix impregnated with a bioactive complex suitable for selectively targeting the lymphatic system, wherein the bioactive complex comprises one or more particle forming materials and one or more bioactive agents. The invention is further directed to methods of using and the process of preparing, the implantable device.

This invention relates to imageable polymers, particularly those comprising poly vinylalcohol and to methods for making them as well as to embolic microspheres comprising the polymers. The microspheres are imageable during embolization procedures and can be loaded with drugs or other therapeutic agents to provide an imageable drug delivery system.

The present disclosure relates to a polycaprolactone microsphere containing vitamin C, a filler including the same and a preparation method therefor. Provided is a polycaprolactone microsphere filler obtained by encapsulating vitamin C in polycaprolactone microspheres, which, when injected into a living body, exhibits a rapid collagen formation effect as well as a high tissue restoration property and maintains the effects for a long period of time, thereby showing excellent restoration or volume expansion or wrinkle improvement properties of soft tissues such as cheeks, breasts, nose, lips, and buttocks and reducing wrinkles.

Nanofiber segments and nanofiber microspheres are provided as well as methods of use thereof and methods of making.

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.