A method of manufacturing a tissue expander for implanting into a body of a living subject can include mixing granules of a solute with an elastomer. The method can further include forming a matrix with the elastomer. The granules can be embedded within the elastomer. The elastomer can define boundaries of a plurality of chambers within the matrix. The method can further include curing the elastomer, such that the boundaries of the matrix are permeable to water at a temperature between a desired temperature range.

Soft tissue repair grafts are provided for supporting, covering, and/or retaining an implant positioned in the body of a subject. The grafts are particularly suitable for use for pre-pectoral breast reconstruction with a breast implant or tissue expander. The grafts include positional notches for more accurate positioning in a subject. The grafts also include at least one cuff element which is folded to form a reinforced folded edge for suturing the graft more securely to adjacent tissues than previously known grafts. The grafts also include a plurality of arcuate slots which form a plurality of circular patterns arranged concentrically about a focal point, thereby enabling the grafts to expand without tearing and to conform more closely to the implant and/or adjacent body tissues such as the breast pocket, than previously known grafts. Acellular dermal matrices are particularly suitable for making the soft tissue repair grafts.

A hybrid medical device that can aid in reconstructive or augmentative surgery of the breast is disclosed. The device can utilize a suitable biological collagen tissue matrix combined with a synthetic material, for example, that can impart a high initial strength to the repair site while permitting proper healing and revitalization of the implanted device.

A post-lumpectomy breast implant can include a spherical outer shell comprising a medical-grade silicone and an inner chamber within the outer shell filled with a medical-grade silicone gel, the spherical outer shell and the inner chamber having a total volume of less than 100 cc.

An implantable scaffold device comprises a non-biodegradable backbone and a biodegradable dermal compartment comprising live cells. Method of fabricating implantable devices via 3D printing using a synthetic ink formulation coprinted with a biodegradable bioink.

The present invention relates to the field of implants. In particular, the present invention relates to an implant for tissue reconstruction which comprises a scaffold structure that includes a void system for the generation of prevascularized connective tissue with void spaces for cell and/or tissue transplantation. Moreover, the present invention relates to a method of manufacturing such an implant, to the internal architecture of such an implant, to a removal tool for mechanical removal of space-occupying structures from such an implant, to a kit comprising such an implant and such a removal tool, to a removal device for the removal of superparamagnetic or ferromagnetic space-occupying structures from such an implant, as well as to a guiding device for providing feedback to a surgeon during the procedure of introducing transplantation cells into the void spaces generated upon removal of space-occupying structures from such an implant.

An implantable device includes a first sealed flexible shell configured for implantation within a breast of a human subject, an elastic filler material contained within the first sealed flexible shell, and a second sealed flexible, inelastic shell, which is disposed within the elastic filler material inside the first sealed flexible shell and is inflated with a volume of gas. The second shell includes a material selected such that an amount of the gas escaping from the second shell does not exceed 10.sup.8 Torr-liter/second when the gas pressure inside the second shell is 250 mbar higher than the gas pressure outside the second shell.

The present disclosure provides anchor bolsters for three-dimensional biologic scaffolds, including related methods of formation and use. The composite bolster-scaffold provides an improved device to securely anchor a three-dimensional tissue scaffold in position relative to surrounding anatomic structures, allowing time for colonization of native cells and subsequent incorporation of the three-dimensional tissue scaffold by the recipient tissue bed.

Described are methods for producing tissue constructs, tissue constructs produced by the methods, and their use. The described method of producing a tissue construct comprises providing a granular tissue, depositing one or more filaments on or in the granular tissue, each filament comprising an ink, and gelling or fusing the granular tissue, thereby producing the tissue construct.

A soft tissue filler comprising a biodegradable amino-acid derived polycarbonate-urethanes and methods of repairing soft tissue defects are provided. The biodegradable soft tissue filler comprises a porous scaffold that is the reaction product of: a) a divinyl oligomer component that comprises a carbonate-derived divinyl oligomer that is the reaction product of a lysine-derived diisocyanate, a vinyl coupling agent, and a polycarbonate and, optionally, an ether-derived divinyl oligomer, wherein the ether-derived divinyl oligomer is the reaction product of a lysine-derived diisocyanate, a vinyl coupling agent, and an ether; b) at least one anionic monomer; and c) at least one hydrophobic monomer. The molar ratio of (a):(b+c) is between about 1:21 and about 1:30, the soft tissue filler has a porosity of >75%; and a compressive moduli of between about 1 kPa and about 50 kPa.