System for simultaneous tissue coagulation and tissue dissection

What is claimed is: 1. A system ( 8 ) comprising an instrument ( 10 ), comprising: at least two coagulation electrodes ( 19 , 20 ), a single cutting electrode ( 31 ), at least two counter electrodes ( 39 , 40 ), an energy supply unit comprising a generator ( 9 ), a single-phase transformer (T) having only a single primary winding (W 1 ), wherein the single primary winding is connected to an outlet of the generator, and a first outlet of the single-phase transformer (A 1 ) that is connected with the cutting electrode ( 31 ), and a second outlet of the single-phase transformer (A 2 ) that is connected with the coagulation electrodes ( 19 ) such that the single-phase transformer simultaneously provides a cutting voltage to the single cutting electrode and a coagulation voltage to the coagulation electrodes so that the cutting and coagulation electrodes are active at the same time to begin cutting and coagulation of tissue by the respective electrodes simultaneously, and at least one current limiting element ( 67 ) located between the first outlet (A 1 ) and the single cutting electrode ( 31 ), wherein the at least one current limiting element is a capacitor configured such that the cutting electrode is supplied with an elevated internal resistance and the coagulation electrodes are supplied with a lower internal resistance than the single cutting electrode, wherein no switch is present between the first and second outlets of the single-phase transformer and the respective cutting and coagulation electrodes such that cutting and coagulation electrodes are each active at the same time whenever the single-phase transformer is active, wherein the single cutting electrode ( 31 ), the coagulation electrodes ( 19 , 20 ) and the counter electrodes ( 39 , 40 ) are located in branches ( 15 , 16 ) of a tool ( 12 ) and arranged such that the single cutting electrode is disposed between opposing pairs of the coagulation and counter electrodes, such that one of the branches can be moved toward and away from another of the branches. 2. The system according to claim 1 , wherein the single cutting electrode ( 31 ) and the counter electrodes ( 39 , 40 ) are located at two different ones of the branches ( 15 , 16 ) of the instrument ( 10 ), of which at least one branch ( 15 ) of the branches can be moved toward and away from another of the branches and that specify a squeeze gap ( 45 , 46 ) that is separated from the cutting electrode ( 31 ) by a tissue receptacle ( 53 , 54 ). 3. The system according to claim 2 , wherein the tissue receptacle ( 53 , 54 ) extends above the squeeze gap ( 45 , 46 ) into one of the branches ( 15 , 16 ) as well as below the squeeze gap ( 45 , 46 ) into another of the branches ( 15 , 16 ). 4. The system according to claim 1 , wherein the single cutting electrode ( 31 ) has an electrically conducting front face ( 32 ) and is substantially electrically isolated on lateral surfaces of the cutting electrode ( 31 ) facing the coagulation electrodes ( 19 , 20 ). 5. The system according to claim 1 , further comprising an insulated counter bearing element ( 42 ) located opposite to the single cutting electrode ( 31 ). 6. The system according to claim 5 , wherein the counter bearing element ( 42 ) is mounted in a displaceable manner. 7. The system according to claim 6 , wherein the counter bearing element ( 42 ) is mounted or designed in a resilient manner. 8. The system according to claim 1 , wherein individual ones of the coagulation electrodes ( 19 , 20 ) are formed by a series of individual electrodes ( 25 , 26 ) that are at a distance to each other. 9. The system according to claim 1 , wherein individual ones of the counter electrodes ( 39 , 40 ) are formed by a series of individual electrodes ( 55 ) and ( 56 ) that are at a distance to each other. 10. The system according to claim 1 , wherein individual ones of the coagulation electrodes ( 19 , 20 ) are formed by a series of individual electrodes ( 25 , 26 ) and individual ones of the counter electrodes ( 39 , 40 ) are formed by a series of individual electrodes ( 55 ) and ( 56 ), wherein the individual electrodes ( 19 , 20 ) of the coagulation electrodes ( 19 ) and the individual electrodes ( 55 , 56 ) of the corresponding counter electrodes ( 39 , 40 ) are arranged so that they do not overlap each other. 11. The system according to claim 1 , wherein the single-phase transformer (T) is designed such that the first outlet (A 1 ) delivers a higher voltage than the second outlet (A 2 ). 12. The system according to claim 1 , wherein impedance of the current limiting element ( 67 ) is larger than an internal resistance of the single-phase transformer (T) at its first outlet (A 1 ). 13. The system according to claim 1 , wherein impedance of the current limiting element ( 67 ) is larger than an internal resistance of the single-phase transformer (T) at its second outlet (A 2 ). 14. The system according to claim 1 , wherein the single primary winding (W 1 ) of the single-phase transformer (T) is supplied with a coagulation voltage (Ua), and outlet voltages provided at the first outlet (A 1 ) and the second outlet (A 2 ) are dimensioned such that cutting starts at a same time as a coagulation process and is finished prior to ending of the coagulation process. 15. The system according to claim 5 wherein the counter bearing element ( 42 ) is formed by an elastomer. 16. The system according to claim 1 , wherein there is no capacitor electrically connected between the second outlet of the single-phase transformer and the coagulation electrodes. 17. A system ( 8 ) comprising an instrument ( 10 ), comprising: at least two coagulation electrodes ( 19 , 20 ), at least one cutting electrode ( 31 ), at least two counter electrodes ( 39 , 40 ), an energy supply unit comprising a generator ( 9 ), a single-phase transformer (T) having only a single primary winding (W 1 ), wherein the single primary winding is connected to an outlet of the generator, and a first outlet of the single-phase transformer (A 1 ) that is connected with the cutting electrode ( 31 ), and a second outlet of the single-phase transformer (A 2 ) that is connected with the coagulation electrodes ( 19 , 20 ) such that the single-phase transformer simultaneously provides a cutting voltage to the cutting electrode and a coagulation voltage to the coagulation electrodes so that the cutting and coagulation electrodes are active at the same time to begin cutting and coagulation of tissue by the respective electrodes simultaneously, and at least one current limiting element ( 67 ) located between the first outlet (A 1 ) and the cutting electrode ( 31 ), wherein the at least one current limiting element is a capacitor, wherein an impedance of the capacitor is larger than an internal resistance of the single-phase transformer (T) at the first outlet (A 1 ) or the second outlet (A 2 ), wherein no switch is present between the first and second outlets of the single-phase transformer and the cutting and coagulation electrodes such that cutting and coagulation electrodes are each active at the same time whenever the single-phase transformer is active, wherein the cutting electrode ( 31 ), the coagulation electrodes ( 19 , 20 ) and the counter electrodes ( 39 , 40 ) are located in branches ( 15 , 16 ) of a tool ( 12 ) and arranged such that the cutting electrode is disposed between opposing pairs of the coagulation and counter electrodes, such that one of the branches can be moved toward and away from another of the branches.