Electroporation system and method

1 - 20 . (canceled) 21 . An electroporation generator comprising: a positive high-voltage direct current (+HVDC) supply having a first polarity; a negative high-voltage direct current (−HVDC) supply having a second polarity opposite the first polarity; a plurality of semiconductor switches connected in a bridge configuration to regulate application of the +HVDC supply and the −HVDC supply to first and second conductors for a catheter; and a microcontroller communicatively coupled to the plurality of semiconductor switches and configured to control commutation of the plurality of semiconductor switches to transmit a biphasic pulse signal through the first and second conductors for the catheter. 22 . The electroporation generator of claim 21 , wherein the microcontroller is further configured to generate the biphasic pulse signal comprising: a first phase having the first polarity and a first pulse duration; a second phase having the second polarity, and a second pulse duration, each of the first and second phase having a voltage amplitude of at least 500 volts and a pulse duration of less than 20 microseconds; and wherein the second phase is generated at a non-zero interval following the first phase. 23 . The electroporation generator of claim 21 further comprising an opto-isolator coupled between the microcontroller and the plurality of semiconductor switches. 24 . The electroporation generator of claim 21 further comprising a plurality of gate drivers coupled between the microcontroller and corresponding ones of the plurality of semiconductor switches, wherein the plurality of gate drivers are configured to supply gate driving current based on at least one signal from the microcontroller. 25 . The electroporation generator of claim 24 further comprising a gate driving impedance coupled between each of the plurality of gate drivers and the corresponding ones of the plurality of semiconductor switches, the gate driving impedance configured to calibrate a rise time for high-voltage DC supplied through the plurality of semiconductor switches, and further configured to reduce oscillatory response by the plurality of semiconductor switches. 26 . The electroporation generator of claim 21 , wherein the plurality of semiconductor switches comprises a plurality of insulated-gate bipolar transistors. 27 . A method of generating a pulse signal, the method comprising: supplying a positive high-voltage direct current (+HVDC) supply having a first polarity to a plurality of semiconductor switches connected in a bridge configuration; supplying a negative high-voltage direct current (−HVDC) supply having a second polarity opposite the first polarity to the plurality of semiconductors; commutating the plurality of semiconductor switches to apply the +HVDC supply to a first conductor of a catheter and to apply the −HVDC supply to a second conductor of the catheter for a first duration; commutating the plurality of semiconductor switches, after the first duration, to electrically disconnect the first conductor and the second conductor from the +HVDC supply and the −HVDC supply for a second duration; commutating the plurality of semiconductor switches, after the second duration, to apply the +HVDC supply to the second conductor and to apply the −HVDC supply to the first conductor for a third duration; and commutating the plurality of semiconductor switches, after the third duration, to electrically disconnect the first conductor and the second conductor from the +HVDC supply and the −HVDC supply. 28 . The method of claim 27 , wherein an opto-isolator is coupled between a microcontroller and the plurality of semiconductor switches. 29 . The method of claim 28 , wherein a plurality of gate drivers are coupled between the microcontroller and corresponding ones of the plurality of semiconductor switches. 30 . The method of claim 29 , wherein the plurality of gate drivers are configured to supply gate driving current based on at least one signal from the microcontroller. 31 . The method of claim 28 , wherein a gate driving impedance is coupled between each of the plurality of gate drivers and the corresponding ones of the plurality of semiconductor switches. 32 . The method of claim 31 , wherein the gate driving impedance is configured to calibrate a rise time for the +HVDC and −HVDC supplied through the plurality of semiconductor switches. 33 . The method of claim 31 , wherein the gate driving impedance is configured to reduce oscillatory response by the plurality of semiconductor switches. 34 . The method of claim 27 , wherein the plurality of semiconductor switches are a plurality of insulated-gate bipolar transistors. 35 . The method of claim 27 , wherein one or more capacitors are coupled in parallel with a gate of each of the plurality of semiconductor switches 36 . The electroporation generator of claim 21 , further comprising one or more capacitors are coupled in parallel with a gate of each of the plurality of semiconductor switches.