Instrument for vessel fusion and separation

What is claimed is: 1. An instrument ( 10 ) for vessel fusion and separation, the instrument comprising: a longitudinal shaft ( 11 ), which extends away from a housing ( 12 ) and which supports a tool ( 18 ) at its distal end, wherein the tool comprises: a first shank ( 19 ) having a first electrode surface ( 52 ), a second shank ( 20 ), which is supported so as to be movable towards the first electrode surface ( 52 ) and away from it, wherein the second shank ( 20 ) has an electrode surface ( 53 ) and a longitudinal slit ( 24 ), a blade ( 21 ) comprising a cutting portion and a blade shaft ( 26 ) and having an electrically conductive material, wherein the blade is arranged so as to be movable in a direction relative to the shaft ( 11 ) and so as to extend into the longitudinal slit ( 24 ) or so as to be retractable into it; a drive element ( 22 ), which extends from the housing ( 12 ) through the shaft ( 11 ) to the blade ( 21 ); and an electrical isolator ( 40 ), which is arranged so as to connect the blade ( 21 ) and the drive element ( 22 ) to one another and to electrically isolate the blade ( 21 ) and the drive element ( 22 ) from each other; wherein the electrical isolator extends along either side of the blade to electrically isolate the blade from the second shank, wherein the electrical isolator is sized and configured to guide the blade within the longitudinal slit of the second shank; wherein the blade shaft ( 26 ) extends into the electrical isolator ( 40 ); wherein the blade ( 21 ) including the blade's shaft and the drive element ( 22 ) define a gap ( 35 ) between one another such that blade and drive element are electrically isolated from one another and are interconnected solely by the electrical isolator; and wherein the blade shaft ( 26 ) encompasses at least one opening ( 39 ), which is permeated by the isolator ( 40 ), and the drive element ( 22 ) encompasses at least one opening ( 47 ), which is permeated by the isolator ( 40 ). 2. The instrument according to claim 1 , wherein the first electrode surface ( 52 ) is a blade gliding surface. 3. The instrument according to claim 1 , wherein a vertical adjusting mechanism ( 50 ) connected to adjust the blade ( 21 ) at right angles to the longitudinal movement as a function of its longitudinal movement, wherein the vertical adjusting mechanism ( 50 ) is equipped to move the blade ( 21 ) vertically towards the first electrode surface ( 52 ) in response to a forwards movement, which is oriented along the first shank ( 19 ), and to move it vertically away from the first electrode surface ( 52 ) in response to a retraction movement, which is oriented along the first shank ( 19 ). 4. The instrument according to claim 1 wherein the second shank ( 20 ) is formed by a metal body, wherein a side of the metal body facing the first electrode surface ( 52 ) of the first shank ( 19 ) defines a shape following a shape of the first electrode surface ( 52 ). 5. The instrument according to claim 1 , wherein at least one of the shanks ( 19 , 20 ) comprises a projection ( 54 ), so as to fix a gap ( 55 ) between the first electrode surface ( 52 ) and the second electrode surface ( 53 ) of the second shank ( 20 ) when the shanks ( 19 , 20 ) of the instrument ( 10 ) are closed. 6. The instrument according to claim 1 , wherein the drive element ( 22 ) is electrically conductive. 7. The instrument according to claim 1 , wherein the blade ( 21 ) is embodied as a lamella comprising two flat lateral sides ( 27 , 28 ). 8. The instrument according to claim 1 , wherein the cutting portion of the blade ( 21 ) comprises a cutting nose ( 25 ). 9. The instrument according to claim 8 , wherein the cutting nose ( 25 ) comprises: a sharpened cutting edge ( 31 ), which faces the first electrode surface ( 52 ) and which is arranged parallel thereto, and a cutting edge ( 30 ), which is sharpened on the front side and which is oriented at an angle to the direction of the movement of the blade ( 21 ). 10. The instrument according to claim 1 , wherein the isolator ( 40 ) encompasses an isolator cutoff wall ( 44 ), which is arranged above a cutting nose ( 25 ) of the blade ( 21 ). 11. The instrument according to claim 1 , wherein the drive element ( 22 ) extends into the isolator ( 40 ). 12. The instrument according to claim 1 , wherein the gap ( 35 ) is oriented transversely to the direction of movement of the blade ( 21 ). 13. A method of operation of an instrument for vessel fusion and separation, the instrument comprising a first shank having a first electrode surface, a second shank having a second electrode surface and defining a longitudinal slit, a blade having an electrically conductive material and disposed to be movable in a shaft, a drive element, and an electrical isolator connecting the blade and the drive element to each other, the method comprising: closing the first shank and the second shank together to trap a vessel between the first electrode surface and the second electrode surface to cause vessel walls of the vessel to touch; coagulating the vessel by application of current through the first electrode surface and the second electrode surface; blocking flow of the current to the blade, the first shank, and the second shank with the isolator, which isolates the blade by surrounding a portion of the shaft of the blade, wherein the blade including the blade's shaft and the drive element define a gap between one another such that blade and drive element are electrically isolated from one another and are interconnected solely by the electrical isolator and wherein the blade shaft encompasses at least one opening, which is permeated by the isolator, and the drive element encompasses at least one opening, which is permeated by the isolator, wherein the electrical isolator extends along either side of the blade to electrically isolate the blade from the second shank, wherein the electrical isolator is sized and configured to guide the blade within the longitudinal slit of the second shank; driving the blade in a forward direction through the longitudinal slit to sever the vessel. 14. The method of claim 13 further comprising adjusting the blade in a direction approximately perpendicular to longitudinal movement of the blade along including moving the blade into contact with the first electrode surface in response to the forward movement of the blade.