System and method for mitigating rising impedance via a pump assembly during use of cooled radiofrequency probes

What is claimed is: 1. A method of treating tissue of a patient's body, the method comprising: providing a power source coupled to at least one probe assembly, the at least one probe assembly comprising an elongate member with a distal region and a proximal region, the distal region having an electrically and thermally-conductive energy delivery device for delivering one of electrical and radiofrequency energy to the patient's body, the electrically and thermally-conductive energy delivery device having one or more internal lumens for circulating a cooling fluid therethrough and an electrically and thermally-conductive protrusion having a temperature sensing element, the temperature sensing element extending from a distal end of the energy delivery device; inserting the energy delivery device of the at least one probe assembly into the patient's body; routing the energy delivery device of the at least one probe assembly to the tissue of the patient's body; simultaneously circulating the cooling fluid through the one or more internal lumens via at least one pump assembly and delivering energy from the power source to the tissue through the energy delivery device; monitoring one or more procedure parameters while delivering the energy from the power source to the tissue through the energy delivery device; determining, in real-time, whether a rising impedance event is likely to occur in a predetermined time period based on the one or more procedure parameters including at least one of a temperature of the tissue, an impedance of the tissue, and a power demand of the energy delivery device; responsive to determining that the rising impedance event is likely to occur in the predetermined time period, decreasing a flow rate of the at least one pump assembly; and responsive to determining that the rising impedance event is unlikely to occur in the predetermined time period, increasing the flow rate of the at least one pump assembly up to a predetermined maximum flow rate or rotational speed. 2. The method of claim 1 , further comprising measuring the temperature of the tissue using the temperature sensing element. 3. The method of claim 2 , wherein the temperature sensing element comprises a length of less than about 1 millimeter (mm) that extends from the distal end of the energy delivery device. 4. The method of claim 1 , wherein the at least one pump assembly comprises at least one pump communicatively coupled to at least one control module. 5. The method of claim 4 , further comprising: comparing the power demand of the energy delivery device to a predetermined threshold; and if the power demand is greater than the predetermined threshold, decreasing a speed of the at least one pump; and if the power demand is less than the predetermined threshold increasing the speed of the at least one pump up to the predetermined maximum flow rate or rotational speed. 6. The method of claim 4 , further comprising decoupling, at least in part, the control module of the at least one pump assembly from the power source. 7. The method of claim 1 , wherein delivering energy from the power source to the tissue through the energy delivery device further comprises: defining a predetermined threshold temperature for treating the tissue; ramping up a temperature of the tissue via the power source through the energy delivery device to the predetermined threshold temperature; and, maintaining the temperature of the tissue at the predetermined threshold temperature to create a lesion in the tissue. 8. The method of claim 7 , further comprising maintaining the temperature of the tissue at the predetermined threshold temperature as a function of at least one of a power ramp rate, an impedance level, an impedance ramp rate, and/or a ratio of impedance to power. 9. The probe assembly of claim 7 , wherein the predetermined threshold temperature is determined based at least in part on historical testing data. 10. The probe assembly of claim 7 , wherein the predetermined threshold temperature is determined based at least in part on a preset profile corresponding with a desired lesion size. 11. A medical probe assembly for delivering energy to a patient's body, the probe assembly comprising: at least one probe having an elongate member with a distal region and a proximal region, said distal region comprising an electrically non-conductive outer circumferential portion; an electrically and thermally-conductive energy delivery device extending distally from said electrically non-conductive outer circumferential portion for delivering one of electrical and radiofrequency energy to the patient's body, said energy delivery device comprising a conductive outer circumferential surface and one or more internal lumens configured for circulating a cooling fluid to a distal end of said energy delivery device; an electrically and thermally-conductive protrusion extending from said distal end of said energy delivery device, said electrically and thermally-conductive protrusion being electrically coupled to said energy delivery device, said electrically and thermally-conductive protrusion comprising a temperature sensing element; at least one pump assembly for circulating the cooling fluid to and from the electrically and thermally-conductive energy delivery device; one or more sensors for monitoring one or more procedure parameters including at least one of a temperature of the patient's tissue, an impedance of the tissue, and a power demand of the energy delivery device; and a controller communicatively coupled to the one or more sensors, the controller comprises a rising impedance detection engine configured to perform operations comprising: determining, in real-time, whether a rising impedance event is likely to occur in a predetermined time period based on the one or more procedure parameters, responsive to determining that the rising impedance event is likely to occur in the predetermined time period, decreasing a flow rate of the at least one pump assembly, and responsive to determining that the rising impedance event is unlikely to occur in the predetermined time period, increasing the flow rate of the at least one pump assembly up to a predetermined maximum flow rate or rotational speed. 12. The probe assembly of claim 11 , wherein the temperature sensing element is configured to measure the temperature of the tissue. 13. The probe assembly of claim 12 , wherein the temperature sensing element comprises a length of less than about 1 millimeter (mm) that extends from a distal end of the energy delivery device. 14. The probe assembly of claim 11 , wherein the at least one pump assembly comprises at least one pump communicatively coupled to at least one control module. 15. The probe assembly of claim 14 , wherein the at least one pump assembly comprises a plurality of pumps communicatively coupled to the at least one control module, each of the plurality of pumps in separate fluid communication with a different probe assembly. 16. The probe assembly of claim 11 , wherein the controller is further configured to compare the power demand of the energy delivery device to a predetermined threshold, and if the power demand is greater than the predetermined threshold, decrease the speed for the at least one pump, and if the power demand is less than the predetermined threshold, increase the speed for the at least one pump up to the predetermined maximum flow rate or rotational speed. 17. The probe assembly of claim 11 , wherein the one or more operations further comprise: defining a predetermined threshold