Reversibly deformable corneal implants for replacing excised corneal tissue, the implants including an optical portion and an anchoring portion having different mechanical properties from each other.

Reversibly deformable corneal implants for replacing excised corneal tissue, the implants including an optical portion and an anchoring portion having different mechanical properties from each other.

Systems and methods are disclosed to protect a medical device from scarring a body after implanting the device in the body by creating a bonding matrix on a surface of the device; exposing the surface to hyaluronic acid (HA) or polyethylene glycol (PEG); cross linking the HA or PEG; and preventing capsular contracture after implanting the device in the body.

A stent includes a tubular body possessing a plurality of gaps. The tubular body includes a plurality of circumferentially extending linear struts. The stent includes a plurality of links connecting the linear struts. At least one of the links has first and second connection portions. The first connection portion is integrally formed with one strut, and the second connection portion is integrally formed with an adjacent strut. The stent includes a biodegradable material between the first connection portion and the second connection portion to connect the first and second connection portions to each other. The biodegradable material restrains the one strut and the adjacent strut from moving to their original shapes. The first and second connection portions move relative to one another in a separation direction when a connection by the biodegradable material is released so that the original shapes of the struts are restored.

The invention relates to an implant (1) for treating and/or for replacing a heart valve (100) diseased by an inflammation and/or infection, wherein the implant (1) has a catching device (2) which, in a compressed state, can be introduced in a minimally invasive manner into the body of the patient, and which can be expanded at the implantation site on the diseased heart valve (100), wherein the catching device (2) is designed, at least in the implanted and expanded state, to compartmentalise tissue changes or tissue deposits (101), in particular in the form of heart valve vegetation or deposits, in particular by using the catching device (2) to engage around and/or receive at least regions of the tissue change or deposit (101).

Disclosed are coating compositions, processes, and designs for endowing vascular devices with thromboresistant and endothelializing properties. Also disclosed are designs of vascular devices used as aneurysm treating devices for assisting in the delivery, packing, and maintenance of embolization coils within an aneurysm, particularly a neurovascular aneurysm.

Disclosed are coating compositions, processes, and designs for endowing vascular devices with thromboresistant and endothelializing properties. Also disclosed are designs of vascular devices used as aneurysm treating devices for assisting in the delivery, packing, and maintenance of embolization coils within an aneurysm, particularly a neurovascular aneurysm.

In various embodiments, the present invention is directed to a degradable poly(ester urea) (PEU)-based adhesion barrier, particularly suitable for use in connection with surgical mesh repair in the treatment of hernias and other soft tissue injuries comprising an amino acid based poly(ester urea) backbone and one or more zwitterionic side chains connected to the amino acid based poly(ester urea) backbone through a sulfide bond. In some other embodiments, the present invention is directed to method of making the PEU-based adhesion barriers comprising: preparing an amino acid based PEU polymer or terpolymer having one or more allyl functional groups; preparing a thiol functionalized zwitterionic compound; and reacting the allyl functionalized PEU polymer or terpolymer with the thiol functionalized zwitterionic compound to form a degradable PEU-based adhesion barrier having an amino acid based PEU backbone having zwitterionic side chains.

A cardiovascular graft is provided with highly reduced thrombogenicity. The cardiovascular graft is an electrospun non-woven mesh produced from supramolecular polymers with large diameter fibers. The cardiovascular graft can be implemented as a vascular graft into the human body to allow vascular bypass/reconstruction, or repeated venous access for dialysis treatment, as well as other disorders of small-diameter blood vessels.

In various embodiments, the present invention is directed to a degradable poly(ester urea) (PEU)-based adhesion barrier, particularly suitable for use in connection with surgical mesh repair in the treatment of hernias and other soft tissue injuries comprising an amino acid based poly(ester urea) backbone and one or more zwitterionic side chains connected to the amino acid based poly(ester urea) backbone through a sulfide bond. In some other embodiments, the present invention is directed to method of making the PEU-based adhesion barriers comprising: preparing an amino acid based PEU polymer or terpolymer having one or more allyl functional groups; preparing a thiol functionalized zwitterionic compound; and reacting the allyl functionalized PEU polymer or terpolymer with the thiol functionalized zwitterionic compound to form a degradable PEU-based adhesion barrier having an amino acid based PEU backbone having zwitterionic side chains.