Terminating drying cycles by monitoring impedance in electrosurgical systems

The invention claimed is: 1. A surgical generator configured to generate and provide controlled electrical power of a therapeutic signal to biological tissue in electrical communication with a surgical instrument, the surgical generator comprising: a measurement circuit coupled to a control circuit and configured to measure a first impedance, a second impedance, and a third impedance of the biological tissue during a therapeutic phase; and the control circuit in communication with an electrical-energy source, the electrical-energy source electrically coupled to the surgical instrument and configured to generate the therapeutic signal, the control circuit configured to: store the first impedance measurement as a minimum impedance measurement; store the second impedance measurement as the minimum impedance measurement when the second impedance measurement is less than the first impedance measurement; control an energy delivery of the therapeutic signal provided to the biological tissue during a therapeutic phase; and in response to the third impedance measurement changing by a predetermined delta impedance value, reduce but continue the energy delivery during the therapeutic phase, wherein the predetermined delta impedance is a change in impedance relative to the minimum impedance measurement during a pulse of the therapeutic signal. 2. The surgical generator of claim 1 , wherein the control circuit is configured to: control an electrical power of the therapeutic signal provided to the biological tissue. 3. The surgical generator of claim 1 , wherein the control circuit is configured to: control a voltage of the therapeutic signal provided to the biological tissue. 4. The surgical generator of claim 3 , wherein the control circuit is configured to: monitor the voltage of the therapeutic signal; and maintain the voltage when the voltage meets a voltage threshold. 5. The surgical generator of claim 1 , wherein the therapeutic phase is a drying phase. 6. The surgical generator of claim 5 , wherein the measurement circuit is configured to measure the first impedance conducted by the biological tissue and measure the third impedance conducted by the biological tissue during the drying phase, and wherein the control circuit is configured to: control the electrical-energy source to provide a drying signal to the biological tissue during the drying phase; and reduce the drying phase in response to a comparison between minimum impedance measurement and the third impedance measurement indicating a phase change of liquid in the biological tissue. 7. The surgical generator of claim 6 , wherein the control circuit is configured to control the drying signal according to a drying schedule. 8. A surgical generator configured to generate and provide controlled electrical power of a therapeutic signal to biological tissue in electrical communication with a surgical instrument, the surgical generator comprising: a measurement circuit coupled to a control circuit and configured to measure a first impedance, a second impedance, and a third impedance of the biological tissue during a therapeutic phase; and the control circuit in communication with an electrical-energy source, the electrical-energy source electrically coupled to the surgical instrument and configured to generate the therapeutic signal, the control circuit configured to: store the first impedance measurement as a minimum impedance measurement; store the second impedance measurement as the minimum impedance measurement when the second impedance measurement is less than the first impedance measurement; control an energy delivery of the therapeutic signal provided to the biological tissue during a therapeutic phase; and in response to the third impedance measurement changing by a predetermined delta impedance value, reduce but continue the energy delivery during the therapeutic phase, wherein the predetermined delta impedance is a change in impedance relative to the minimum impedance measurement taken at a set time interval after the therapeutic phase has begun. 9. The surgical generator of claim 8 , wherein the control circuit is configured to: control an electrical power of the therapeutic signal provided to the biological tissue. 10. The surgical generator of claim 8 , wherein the control circuit is configured to: control a voltage of the therapeutic signal provided to the biological tissue. 11. The surgical generator of claim 10 , wherein the control circuit is configured to: monitor the voltage of the therapeutic signal; and maintain the voltage when the voltage meets a voltage threshold. 12. The surgical generator of claim 8 , wherein the therapeutic phase is a drying phase. 13. The surgical generator of claim 12 , wherein the measurement circuit is configured to measure the first impedance conducted by the biological tissue and measure the third impedance conducted by the biological tissue during the drying phase, and wherein the control circuit is configured to: control the electrical-energy source to provide a drying signal to the biological tissue during the drying phase; and reduce the drying phase in response to a comparison between minimum impedance measurement and the third impedance measurement indicating a phase change of liquid in the biological tissue. 14. The surgical generator of claim 13 , wherein the control circuit is configured to control the drying signal according to a drying schedule. 15. A method of generating and providing controlled electrical power of a therapeutic signal to biological tissue in electrical communication with a surgical instrument, the method comprising: measuring a first impedance, a second impedance, and a third impedance of the biological tissue during a therapeutic phase; storing the first impedance measurement as a minimum impedance measurement; storing the second impedance measurement as the minimum impedance measurement when the second impedance measurement is less than the first impedance measurement; generating the therapeutic signal; controlling an energy delivery of the therapeutic signal provided to the biological tissue during a therapeutic phase; and in response to the third impedance measurement changing by a predetermined delta impedance value, reducing but continuing the energy delivery during the therapeutic phase, wherein the predetermined delta impedance is a change in impedance relative to the first impedance measurement during a pulse of the therapeutic signal. 16. The method of claim 15 , comprising: controlling an electrical power of the therapeutic signal provided to the biological tissue. 17. The method of claim 15 , comprising: controlling a voltage of the therapeutic signal provided to the biological tissue. 18. The method of claim 17 , comprising: monitoring the voltage of the therapeutic signal; and maintaining the voltage when the voltage meets a voltage threshold.