Abstract: Described are tubular silk fibroin compositions and methods for their manufacture and use. Tubular compositions as described herein can be produced in a range of high burst strengths, can easily be made in a range of inner diameters, can be derivatized with functional moieties, and can be produced in a range of permeabilities suitable for particularized uses. In one aspect, the tubular compositions can be used in the repair or replacement of damaged or diseased blood vessels, including, but not limited to vessels smaller than about 6 mm.

Abstract: Embodiments of various aspects described herein are directed to silk-based compositions for ocular delivery of at least one active agent, e.g., at least one therapeutic agent and methods of using the same. In some embodiments, the silk-based compositions can provide sustained release of at least one therapeutic agent to at least a portion of an eye. Thus, some embodiments of the silk-based compositions can be used for treatment of an ocular condition, e.g., age-related macular degeneration.

Abstract: The present invention is directed to silk-based drug delivery compositions for controlled, sustained delivery of therapeutic agent(s) as well as methods of making and using the same.

Abstract: A system and method for making a biomaterial device includes a support structure providing a shape for a biomaterial device. At least one applicator has a supply of biomaterial solution and is positioned along the support structure. The at least one applicator forms a biomaterial fiber by applying shear force to the biomaterial solution and delivering the biomaterial fiber to the support structure. A controller causes relative movement between the support structure and the at least one applicator, and the biomaterial fiber is arranged on the support structure according to the relative movement to form the biomaterial device. The biomaterial may be silk fibroin which may be wound onto a reciprocating and rotating mandrel. Control over the properties of the biomaterial device is achieved through appropriate selection of material processing, winding strategy, and post-winding processing.

Abstract: The present invention is directed to silk-based drug delivery compositions for controlled, sustained delivery of therapeutic agent(s) as well as methods of making and using the same.

Abstract: Embodiments of various aspects described herein are directed to silk-based compositions for ocular delivery of at least one active agent, e.g., at least one therapeutic agent and methods of using the same. In some embodiments, the silk-based compositions can provide sustained release of at least one therapeutic agent to at least a portion of an eye. Thus, some embodiments of the silk-based compositions can be used for treatment of an ocular condition, e.g., age-related macular degeneration.

Abstract: Described are tubular silk fibroin compositions and methods for their manufacture and use. Tubular compositions as described herein can be produced in a range of high burst strengths, can easily be made in a range of inner diameters, can be derivatized with functional moieties, and can be produced in a range of permeabilities suitable for particularized uses. In one aspect, the tubular compositions can be used in the repair or replacement of damaged or diseased blood vessels, including, but not limited to vessels smaller than about 6 mm.

Abstract: A system and method for making a biomaterial device includes a support structure providing a shape for a biomaterial device. At least one applicator has a supply of biomaterial solution and is positioned along the support structure. The at least one applicator forms a biomaterial fiber by applying shear force to the biomaterial solution and delivering the biomaterial fiber to the support structure. A controller causes relative movement between the support structure and the at least one applicator, and the biomaterial fiber is arranged on the support structure according to the relative movement to form the biomaterial device. The biomaterial may be silk fibroin which may be wound onto a reciprocating and rotating mandrel. Control over the properties of the biomaterial device is achieved through appropriate selection of material processing, winding strategy, and post-winding processing.