Abstract: An adjustable implant is disclosed herein. The adjustable implant may comprise a shell including membrane and a base and having a first diameter in a plane parallel to the base. A band may be disposed within the shell. The band may have a first end and a second end connected to a spool. The band may be in a round (e.g., elliptical) configuration having a second diameter in the plane that is less than the first diameter. By wrapping the band onto the spool, the diameter of the band may be decreased and the height of the implant may be increased. By unwrapping the band from the spool, the diameter of the band may be increased and the height of the implant may be decreased.

Abstract: An implant delivery sleeve comprises a tubular wall having a proximal end with a proximal opening, a distal end with a distal opening, and an implant delivery channel extending between the proximal and distal ends of said tubular wall. A plurality of bands interconnect portions of the tubular wall for constricting the implant delivery channel adjacent the distal end of the tubular wall. As an implant is advanced toward the distal end of the tubular wall, the constriction squeezes and/or deforms the implant for facilitating insertion into an incision that is smaller than the normal size of the implant.

Abstract: The present disclosure describes various embodiments of adjustable implants, particularly permanent breast implants, intended for implantation into a subject, particularly a human subject. In some embodiments, the adjustable implant comprises a shell including a resilient shell membrane, a first reservoir containing a fluid, e.g., a saline, a second reservoir including a resilient second-reservoir membrane, and a pump. The pump may include a first pump actuator, a first pump inlet, and a first pump outlet. The first reservoir and second reservoir may be disposed within the shell and be in fluid communication via the pump. Fluid may be transferred between the two reservoirs to change the profile of the implant.

Abstract: A tissue expander having an integrated drain includes a shell having an opening and one or more drainage holes, and an injection port disposed in the opening of the shell and forming a fluid-tight seal with the shell. The injection port includes a needle guard having a needle guard base with a top surface. The injection port includes a moveable barrier membrane overlying the top surface of the needle guard base. The moveable barrier membrane is moveable between a first position for inflating and deflating the shell with a first fluid and a second position for draining a second fluid from outside the shell. A magnet is coupled with the moveable barrier membrane, and a compressible spring is connected with the magnet. The compressible spring is compressed for storing energy as the moveable barrier membrane moves from the first position to the second position.

Abstract: A tissue expander having an integrated drain includes an outer shell having an opening and one or more drainage holes. An injection port is disposed in the opening of the shell and forms a fluid-tight seal with the shell. The injection port includes a needle guard having a needle guard base with a top surface, and a barrier membrane that overlies the top surface of the needle guard base. The barrier membrane defines an inflation chamber located between the top surface of the needle guard base and a bottom surface of the barrier membrane, and a drainage chamber overlying a top surface of the barrier membrane. The tissue expander includes one or more inflation ports that are in fluid communication with the inflation chamber for inflating and deflating the outer shell with a first fluid. A drainage conduit is in fluid communication with and extends between the drainage chamber and the one or more drainage holes for draining a second fluid from outside the shell.

Abstract: A method of making an implantable prosthesis having internal ribs includes forming a shell over a substrate, depositing a curable material onto a first surface of the shell to form one or more ribs on the first surface of the shell, removing the shell from the substrate, and inverting the shell so that a second surface of the shell is disposed outside the shell and the first surface of the shell is disposed inside the shell with the one or more ribs projecting inwardly into an interior volume of the shell. The curable material is cured so that the one or more ribs are integrally secured to the first surface of the shell.

Abstract: An implantable prosthesis includes a shell having an apex, a base, a radius located between the apex and the base, and a dome extending between the apex and the radius. The shell has an outer surface and an inner surface that surrounds an interior volume of the shell. At least one rib is integrally formed with the inner surface of the shell and projects inwardly from the inner surface of the shell into the interior volume of the shell. The shell has an interior volume that is adapted to receive a biocompatible filler material.

Abstract: The present disclosure describes various embodiments of adjustable implants, particularly permanent breast implants, intended for implantation into a subject, particularly a human subject. In some embodiments, the adjustable implant comprises a shell including a resilient shell membrane, a first reservoir containing a fluid, e.g., a saline, a second reservoir including a resilient second-reservoir membrane, and a pump. The pump may include a first pump actuator, a first pump inlet, and a first pump outlet. The first reservoir and second reservoir may be disposed within the shell and be in fluid communication via the pump. Fluid may be transferred between the two reservoirs to change the profile of the implant.

Abstract: An adjustable implant is disclosed herein. The adjustable implant may comprise a shell including membrane and a base and having a first diameter in a plane parallel to the base. A band may be disposed within the shell. The band may have a first end and a second end connected to a spool. The band may be in a round (e.g., elliptical) configuration having a second diameter in the plane that is less than the first diameter. By wrapping the band onto the spool, the diameter of the band may be decreased and the height of the implant may be increased. By unwrapping the band from the spool, the diameter of the band may be increased and the height of the implant may be decreased.

Abstract: An adjustable implant is disclosed herein. The adjustable implant may comprise a shell including membrane and a base and having a first diameter in a plane parallel to the base. A band may be disposed within the shell. The band may have a first end and a second end connected to a spool. The band may be in a round (e.g., elliptical) configuration having a second diameter in the plane that is less than the first diameter. By wrapping the band onto the spool, the diameter of the band may be decreased and the height of the implant may be increased. By unwrapping the band from the spool, the diameter of the band may be increased and the height of the implant may be decreased.

Abstract: The present disclosure describes various embodiments of adjustable implants, particularly permanent breast implants, intended for implantation into a subject, particularly a human subject. In some embodiments, the adjustable implant comprises a shell including a resilient shell membrane, a first reservoir containing a fluid, e.g., a saline, a second reservoir including a resilient second-reservoir membrane, and a pump. The pump may include a first pump actuator, a first pump inlet, and a first pump outlet. The first reservoir and second reservoir may be disposed within the shell and be in fluid communication via the pump. Fluid may be transferred between the two reservoirs to change the profile of the implant.

Abstract: Various embodiments of an adjustable implant are disclosed herein. The adjustable implant comprises a hydraulic mechanism disposed within the shell, which includes a first component and a second component that is moveable with respect to the first component, and a band with a first and second end disposed within the shell in a round (e.g., elliptical) configuration having a second diameter in the plane that is less than the first diameter. In some embodiments, the first end of the band may be connected to the first component and the second end of the band may be connected to the second component. In some embodiments, the mechanism may include a fluid and a pump that has a first actuator comprising a first chamber and a second actuator comprising a second chamber. Depressing the first actuator causes the first component to move in a first direction, which reduces the diameter of the band and increases the height of the implant.

Abstract: A tissue expander having an integrated drain includes an outer shell having an opening and one or more drainage holes. An injection port is disposed in the opening of the shell and forms a fluid-tight seal with the shell. The injection port includes a needle guard having a needle guard base with a top surface, and a barrier membrane that overlies the top surface of the needle guard base. The barrier membrane defines an inflation chamber located between the top surface of the needle guard base and a bottom surface of the barrier membrane, and a drainage chamber overlying a top surface of the barrier membrane. The tissue expander includes one or more inflation ports that are in fluid communication with the inflation chamber for inflating and deflating the outer shell with a first fluid. A drainage conduit is in fluid communication with and extends between the drainage chamber and the one or more drainage holes for draining a second fluid from outside the shell.

Abstract: A tissue expander having an integrated drain includes a shell having an opening and one or more drainage holes, and an injection port disposed in the opening of the shell and forming a fluid-tight seal with the shell. The injection port includes a needle guard having a needle guard base with a top surface. The injection port includes a moveable barrier membrane overlying the top surface of the needle guard base. The moveable barrier membrane is moveable between a first position for inflating and deflating the shell with a first fluid and a second position for draining a second fluid from outside the shell. A magnet is coupled with the moveable barrier membrane, and a compressible spring is connected with the magnet. The compressible spring is compressed for storing energy as the moveable barrier membrane moves from the first position to the second position.

Abstract: An implantable prosthesis includes a shell having an apex, a base, a radius located between the apex and the base, and a dome extending between the apex and the radius. The shell has an outer surface and an inner surface that surrounds an interior volume of the shell. At least one rib is integrally formed with the inner surface of the shell and projects inwardly from the inner surface of the shell into the interior volume of the shell. The shell has an interior volume that is adapted to receive a biocompatible filler material.

Abstract: An implant delivery sleeve is disclosed. The sleeve may comprise a first tube including a first segment, a second segment, and a third segment. The first segment may have a first stiffness, the second segment may have a second stiffness, and the third segment may have a third stiffness. The third stiffness may be greater than the second stiffness and the second stiffness may be greater than the first stiffness. The implant-delivery sleeve may be used to deliver a breast implant to a subject. The implant may be deformed within the sleeve, to advance it within the sleeve and extrude it from the distal end of the sleeve.

Abstract: An adjustable implant is disclosed herein. The adjustable implant may comprise a shell including membrane and a base and having a first diameter in a plane parallel to the base. A band may be disposed within the shell. The band may have a first end and a second end connected to a spool. The band may be in a round (e.g., elliptical) configuration having a second diameter in the plane that is less than the first diameter. By wrapping the band onto the spool, the diameter of the band may be decreased and the height of the implant may be increased. By unwrapping the band from the spool, the diameter of the band may be increased and the height of the implant may be decreased.

Abstract: Various embodiments of an adjustable implant are disclosed herein. The adjustable implant comprises a hydraulic mechanism disposed within the shell, which includes a first component and a second component that is moveable with respect to the first component, and a band with a first and second end disposed within the shell in a round (e.g., elliptical) configuration having a second diameter in the plane that is less than the first diameter. In some embodiments, the first end of the band may be connected to the first component and the second end of the band may be connected to the second component. In some embodiments, the mechanism may include a fluid and a pump that has a first actuator comprising a first chamber and a second actuator comprising a second chamber. Depressing the first actuator causes the first component to move in a first direction, which reduces the diameter of the band and increases the height of the implant.