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.

The present invention relates to a kit for preparing a customizable flesh simulating silicone gel or a flesh simulating silicone foam in particular for use in medical devices and a process for preparing said customizable flesh simulating silicone gel or silicone foam, in particular by using a 3D-printer.

The present invention relates to a kit for preparing a customizable flesh simulating silicone gel or a flesh simulating silicone foam in particular for use in medical devices and a process for preparing said customizable flesh simulating silicone gel or silicone foam, in particular by using a 3D-printer.

This invention provides a method for determining breast implant geometric properties, engineering stresses, engineering strains and engineering moduli; directly and quickly, using a load frame apparatus. More generally the invention provides a method for determining geometric properties and engineering mechanical properties of any elastomeric device, using a load frame apparatus. Engineering stress and engineering strain properties of breast implants are critical to their safety and durability. The geometric properties of breast implants undergoing compression also relates to the shape stability of breast implants, which may also be related to clinical outcomes such as capsular contracture and other untoward outcomes involving a breast capsule, such as Anaplastic Large Cell Lymphoma (ALCL), double capsule formation, seroma formation and associated breast implant illness (BII).

This invention provides a method for determining breast implant geometric properties, engineering stresses, engineering strains and engineering moduli; directly and quickly, using a load frame apparatus. More generally the invention provides a method for determining geometric properties and engineering mechanical properties of any elastomeric device, using a load frame apparatus. Engineering stress and engineering strain properties of breast implants are critical to their safety and durability. The geometric properties of breast implants undergoing compression also relates to the shape stability of breast implants, which may also be related to clinical outcomes such as capsular contracture and other untoward outcomes involving a breast capsule, such as Anaplastic Large Cell Lymphoma (ALCL), double capsule formation, seroma formation and associated breast implant illness (BII).

The invention relates to a mesh support device (10) for supporting a breast implant, which mesh support device (10) comprises a first mesh panel (11), which comprises a first arm (31) having a length L.sub.1 and a second arm (32) having a length L.sub.2, and a second mesh panel (12), which comprises a first opening (21), which is arranged to receive the first arm (31), and a second opening (22), which is arranged to receive the second arm (32), wherein 30 mm <L.sub.1<210 mm and 30 mm L.sub.2<210 <mm.

The invention relates to a mesh support device (10) for supporting a breast implant, which mesh support device (10) comprises a first mesh panel (11), which comprises a first arm (31) having a length L.sub.1 and a second arm (32) having a length L.sub.2, and a second mesh panel (12), which comprises a first opening (21), which is arranged to receive the first arm (31), and a second opening (22), which is arranged to receive the second arm (32), wherein 30 mm <L.sub.1<210 mm and 30 mm L.sub.2<210 <mm.

A tissue expander includes a shell having an anterior wall with superior and inferior zones, and one or more drainage openings formed in the inferior zone. A fill port assembly is located within the superior zone, and a drain port assembly is located within the inferior zone and is in fluid communication with the one or more drainage openings. The fill port assembly is isolated from the drain port assembly that is located within the inferior zone. The drain port assembly includes a drain cover having an elongated body, a central hub, one or more fluid reservoirs between the first and second ends of the elongated body, and an outer face that surrounds the fluid reservoirs. The outer face of the drain cover is secured to an inner surface of the anterior wall and surrounds the one or more drainage openings formed in the inferior zone of the shell.

A tissue expander includes a shell having an anterior wall with superior and inferior zones, and one or more drainage openings formed in the inferior zone. A fill port assembly is located within the superior zone, and a drain port assembly is located within the inferior zone and is in fluid communication with the one or more drainage openings. The fill port assembly is isolated from the drain port assembly that is located within the inferior zone. The drain port assembly includes a drain cover having an elongated body, a central hub, one or more fluid reservoirs between the first and second ends of the elongated body, and an outer face that surrounds the fluid reservoirs. The outer face of the drain cover is secured to an inner surface of the anterior wall and surrounds the one or more drainage openings formed in the inferior zone of the shell.

A prosthetic implant, such as a tissue expander, includes a silicone shell having an anterior wall and a posterior wall, and a needle stop patch secured over an inner surface of the posterior wall of the silicone shell. The needle stop patch has two or more layers of a textile material that are stacked atop one another. The textile material is flexible and includes woven threads or fiber. A bonding material bonds together the two or more layers of the textile material that are stacked atop one another. The outer edges of the respective layers are feathered for minimizing step effects between adjacent ones of the layers. A self-sealing membrane covers the anterior wall of the silicone shell. The dernier level of the textile layers increases between top and bottom layers for progressively increasing resistance tom a needle passing through the needle stop patch.