The present disclosure relates to a method for modeling a personalized breast implant including the operations of: obtaining medical image data and body scan data; obtaining first image data by 3D modeling the medical image data; obtaining second image data by 3D modeling the body scan data; creating third image data by merging the first image data and the second image data; and creating breast implant appearance information on the basis of the third image data.

The particle (1) is suitable for the manufacture of an implantable soft tissue engineering material and comprises: a three-dimensionally warped and branched sheet (2) where (i) the three-dimensionally warped and branched sheet (2) is made from a biocompatible material having a Young's modulus of 1 kPa to 1 GPa; (ii) the three-dimensionally warped and branched sheet (2) has an irregular shape which is encompassed in a virtual three-dimensional envelope (3) having a volume V.sub.E; (iii) the three-dimensionally warped and branched sheet (2) has a mean sheet thickness T; iv) the three-dimensionally warped and branched sheet (2) has a volume V.sub.S; (v) the particle (1) has a Young's modulus of 100 Pa to 15 kPa; and (vi) the particle (1) further comprises a number of protrusions where the three-dimensionally warped and branched sheet (2) reaches the envelope (3); (vii) the particle (1) has a number of interconnected channel-type conduits (5) defined by the branching of the sheet (2) and/or by voids in the sheet (2); and (viii) where the conduits (5) have (a) a mean diameter D.sub.C; and (b) an anisotropicity index of 1.01 to 5.00.

The particle (1) is suitable for the manufacture of an implantable soft tissue engineering material and comprises: a three-dimensionally warped and branched sheet (2) where (i) the three-dimensionally warped and branched sheet (2) is made from a biocompatible material having a Young's modulus of 1 kPa to 1 GPa; (ii) the three-dimensionally warped and branched sheet (2) has an irregular shape which is encompassed in a virtual three-dimensional envelope (3) having a volume V.sub.E; (iii) the three-dimensionally warped and branched sheet (2) has a mean sheet thickness T; iv) the three-dimensionally warped and branched sheet (2) has a volume V.sub.S; (v) the particle (1) has a Young's modulus of 100 Pa to 15 kPa; and (vi) the particle (1) further comprises a number of protrusions where the three-dimensionally warped and branched sheet (2) reaches the envelope (3); (vii) the particle (1) has a number of interconnected channel-type conduits (5) defined by the branching of the sheet (2) and/or by voids in the sheet (2); and (viii) where the conduits (5) have (a) a mean diameter D.sub.C; and (b) an anisotropicity index of 1.01 to 5.00.

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 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.

Devices, systems, and methods for delivering prosthesis implants into surgically-created implant pockets in a subject and for preventing capsular contracture resulting from surgical insertion of prosthesis implants. The device may include a delivery member operable to wrap around the implant thereby forming a conforming cavity around the implant that conforms to the shape of the implant. The delivery member is also operable to propel the implant from the conforming cavity into the implant pocket in the subject upon the application of mechanical force to the delivery member. The device also includes a shielding member coupled with the delivery member. The shielding member is operable to shield the implant from at least a portion of the dissection tunnel connecting the incision to the implant pocket during delivery of the implant to the implant pocket. The device is capable of shielding the implant from microbial contamination, including contamination by the endogenous flora of the subject, during delivery of the implant into the surgically-created implant pocket.

Devices, systems, and methods for delivering prosthesis implants into surgically-created implant pockets in a subject and for preventing capsular contracture resulting from surgical insertion of prosthesis implants. The device may include a delivery member operable to wrap around the implant thereby forming a conforming cavity around the implant that conforms to the shape of the implant. The delivery member is also operable to propel the implant from the conforming cavity into the implant pocket in the subject upon the application of mechanical force to the delivery member. The device also includes a shielding member coupled with the delivery member. The shielding member is operable to shield the implant from at least a portion of the dissection tunnel connecting the incision to the implant pocket during delivery of the implant to the implant pocket. The device is capable of shielding the implant from microbial contamination, including contamination by the endogenous flora of the subject, during delivery of the implant into the surgically-created implant pocket.

A lightweight reinforced mesh, such as a surgical mesh, suitable for use in various applications, including breast reconstruction, cosmetic breast surgery, mastopexy, breast augmentation, breast reduction, soft tissue reconstruction, hernia repair, tissue plication reinforcement, tissue support and repair, tendon support and repair, tissue engineering, and procedures or other applications requiring additional soft tissue strength or thickness. In addition, disclosed is a use of such a mesh for tissue engineering, regardless of the surgical application. In particular, the present disclosure relates to a surgical mesh capable of providing enhanced support while maintaining flexibility, low density, and absorbable characteristics. Further the present disclosure, focuses on reducing the material burden of a scaffold while increasing void space to facilitate tissue ingrowth.

The present invention relates to a patient-specific breast implant. More particularly, the present invention relates to a patient-specific breast implant which, when a breast-conserving surgery (BCS, also called lumpectomy or partial mastectomy) is performed to remove breast cancer while leaving as much normal breast tissue as possible, prevents deformation of breast that may occur due to the depression of breast skin or adhesions of remaining breast tissues after the BCS, shortens surgery time, and facilitates securing breast symmetry, thereby ultimately dramatically increasing the success rate of surgery and maximizing patient satisfaction.

Implantable transponders comprising no ferromagnetic parts for use in medical implants are disclosed herein. Such transponders may assist in preventing interference of transponders with medical imaging technologies. Such transponders may optionally be of a small size, and may assist in collecting and transmitting data and information regarding implanted medical devices. Methods of using such transponders, readers for detecting such transponders, and methods for using such readers are also described.