An implant and a handheld medical device using which the implant may be removed particularly easily and without traumatizing the patient. This is achieved in that a proximal end of an implant has a coupling part having a ferromagnetic element, the implant being able to be withdrawn from the urethra via this coupling part.

A system includes an adjustable implant configured for implantation internally within a subject and includes a permanent magnet configured for rotation about an axis of rotation, the permanent magnet operatively coupled to a drive transmission configured to alter a dimension of the adjustable implant. The system includes an external adjustment device configured for placement on or adjacent to the skin of the subject having at least one magnet configured for rotation, the external adjustment device further comprising a motor configured to rotate the at least one magnet and an encoder. Rotation of the at least one magnet of the external adjustment device effectuates rotational movement of the permanent magnet of the adjustable implant and alters the dimension of the adjustable implant. Drive control circuitry is configured to receive an input signal from the encoder.

The present disclosure is directed to a branched endoprosthesis comprising a graft component and at least one support component. In various embodiments, the branched endoprosthesis comprises a body portion and a plurality of leg portions, wherein the legs are in an aligned configuration for ease of cannulation. In various embodiments, at least one leg is in an open configuration for ease of cannulation. Cannulation methods are also described.

A medical device has an artificial contractile structure including at least one contractile element adapted to contract a hollow body organ in such a way that said contractile element is adapted to be in a resting position or in an activated position, the activated position being defined with the contractile element constricting the hollow body organ and the resting position being defined with the contractile element not constricting the hollow body organ. The medical device further includes a tensioning device adapted to apply a force so as to tighten the contractile element around the hollow body organ, the tensioning device having a flexible transmission with a tensioning element arranged in a sheath. The sheath has an inner coiled wire coiled in a first direction, and an outer coiled wire surrounding the inner coiled wire and coiled in a second direction opposite to said first direction.

Disclosed herein is a unique family of medical implants which are engineered outside of a subject's body into a form which may be manipulated in vivo. The implants comprise a region of at least one weldable material which allows welding of the implant to a polymeric material introduced into the body prior to, together with or after the implant has been positioned.

A stent apparatus for use in surgical applications having a hollow tubular section with a proximal end and a distal end. Additionally, the stent apparatus can have at least one anchor point connected to the hollow tubular section. The hollow tubular section may also have a modifiable member, and a magnetic connection node. The stent may also be wrapped in a material that has magnetic properties. The delivery of the stent can include a stent delivery tool for inserting a stent into a vessel.

A magnet assisted surgical device, system, and method employs magnetic sections, catheters, and guidewires to modify tubular stentgrafts in-situ. One example application provides a more reliable way for surgeons to modify stentgrafts insitu to allow blood flow to continue to branching blood vessels that would otherwise be blocked by the stentgraft itself. One such method includes placing a tip section of the device in the desired location, deploying a stentgraft, placing a magnetic device inside the stentgraft, connecting the magnetic device to the tip section, and excising the portion of the stentgraft held between the magnet and the tip section.

An implantable device includes an adjustable spacer and at least one anchor. The adjustable spacer is configured to be positioned between native heart valve leaflets to reduce regurgitation therebetween. The adjustable spacer can comprise a first side and a second side opposite the first side. Each side can be adjustable between a first width and a second width. Each side can be independently moved between the first width and the second width. The adjustable spacer can be made from a sponge material.

A method for placing an implant on a patient in a robotic surgical procedure using a robotic system. During the robotic surgical procedure, a navigation system tracks the patient. The navigation system also provides information to the robotic system to guide movement of a cutting tool to remove material from the patient such that a cut surface is created to receive the implant. The implant is then robotically placed on the cut surface.

Ski goggles for a goggles wearer having: a frame with a first side facing the face and a second side facing away from the face during normal use; a nose bridge for resting on the wearer's nose; a lens having a first surface facing the face and a second surface facing away from the face during normal use; a pad connected to the frame and resting on the face during normal use; a strap holding the goggles on the head during normal use; a coupling arrangement adapted to releasably couple the lens to the frame. The coupling arrangement includes a first coupling point at a nose area of the first side and a second coupling point disposed around at least a portion of a perimeter of the first side. The coupling arrangement includes the nose bridge. The bridge is releasably coupleable to the frame and provides the first coupling point.