The invention relates to an implant or medical tool made of a metal or having a surface made of a metal for use in a therapeutic treatment, wherein the implant or the tool has, on its/the surface, a coating with polycrystalline doped electrically conductive diamond, wherein the therapeutic therapy is a treatment of a microbial infection of a human or animal body, wherein the implant or the tool is connected as anode (12) in an electrochemical system in the body, wherein the electrochemical system comprises, in addition to the anode (12), a cathode (16), a power source connected in an electrically conductive manner to the anode and to the cathode, and an electrolyte comprising or consisting of a body fluid, or consists of the anode (12), a cathode (16), a power source connected in an electrically conductive manner to the anode and to the cathode, and an electrolyte comprising or consisting of a body fluid, or wherein the implant or the tool is disposed within an electrical field, by means of which a negative charge is induced at a first site and a positive charge at a second site by induction on the implant or tool, by means of which the first site becomes the anode (12) in an electrochemical system and the second site becomes the cathode (16) in the electrochemical system, wherein the electrochemical system comprises, in addition to the implant or the tool, an electrolyte comprising or consisting of a body fluid or consists of the implant or the tool and an electrolyte comprising or consisting of a body fluid.

An end effector including an anvil and a staple cartridge assembly is disclosed. The staple cartridge assembly comprises a deck having steps defined thereon for compressing tissue positioned between the anvil and the staple cartridge assembly to different pressures. The staple cartridge assembly further comprises staples having different unformed heights removably stored therein. The staples are deformed against the anvil to different formed heights.

An end effector including an anvil and a staple cartridge assembly is disclosed. The staple cartridge assembly comprises a deck having steps defined thereon for compressing tissue positioned between the anvil and the staple cartridge assembly to different pressures. The staple cartridge assembly further comprises staples having different unformed heights removably stored therein. The staples are deformed against the anvil to different formed heights.

An end effector including an anvil and a staple cartridge assembly is disclosed. The staple cartridge assembly comprises a deck having steps defined thereon for compressing tissue positioned between the anvil and the staple cartridge assembly to different pressures. The staple cartridge assembly further comprises staples having different unformed heights removably stored therein. The staples are deformed against the anvil to different formed heights.

An antibacterial device is disclosed that includes a substrate and an antibacterial coating or antibacterial surface being provided on at least a part of the substrate's surface. The antibacterial coating or surface includes Angstrom scale flakes, where the Angstrom scale flakes are arranged in a standing position on the substrate surface and are attached to the substrate surface via edge sides thereof. The Angstrom scale flakes can, for example, be graphene flakes, or graphite flakes having a thickness of a few atom layers. It has been found that such standing flakes are efficient in killing prokaryotic cells but do not harm eukaryotic cells.

To provide a magnesium alloy with improved corrosion resistance by surface modification, and a production method thereof. (1) The surface-modified magnesium alloy comprising: a magnesium alloy having an arbitrary shape; a magnesium fluoride layer formed by fluorination of the surface of the magnesium alloy; and a diamond-like carbon layer formed on the magnesium fluoride layer. (2) The method comprising: subjecting a surface of a magnesium alloy having an arbitrary shape to fluorination treatment to form a magnesium fluoride layer on the surface of the magnesium alloy, and then subjecting the magnesium alloy with the magnesium fluoride layer to be placed in a high-frequency plasma CVD device such that a source gas containing carbon is introduced to form a diamond-like carbon layer on the magnesium fluoride layer.

In an embodiment, a method for loading a powder substance (10) into recesses (200) provided at a stent (S) surface, the method comprises: applying compression (100) to the powder substance (10) to thereby form tablets insertable into said recesses (200), inserting the tablets into the recesses (200) of the stent (S).

An implantable mesh device includes a surface layer on at least a portion thereof. The surface layer includes a plurality of extending members that mechanically interact with microbiota to disable the microbiota.

An antibacterial device is disclosed that includes a substrate and an antibacterial coating or antibacterial surface being provided on at least a part of the substrate's surface. The antibacterial coating or surface includes Angstrom scale flakes, where the Angstrom scale flakes are arranged in a standing position on the substrate surface and are attached to the substrate surface via edge sides thereof. The Angstrom scale flakes can, for example, be graphene flakes, or graphite flakes having a thickness of a few atom layers. It has been found that such standing flakes are efficient in killing prokaryotic cells but do not harm eukaryotic cells.

Described is a medical implant with a structure which is made of at least one biocompatible material, can be converted from a first spatially compact state into a second spatially deployed and flexible deformable state, has an modulus of elasticity that corresponds to the wall of a blood vessel in an order of magnitude between 105 N m.sup.−2 and 107 N m.sup.−2, has at least one region with an acoustic impedance of more than 1.63.Math.106 kg/m.sup.2s, and in the second state has an effective operating surface that is flexibly deformable and at least partially reflects ultrasonic waves. In addition, an assembly is described for detecting an intracorporeal movement pattern using the medical implant that has a sonography device, which is positioned extracorporeally such that ultrasonic waves which are generated by the sonographic device and which strike the effective operating surface of the intracorporeally applied medical implant and are partially reflected thereon can be used to detect changes in the spatial distance between the effective operating surface and the sonography device.