System and method for adaptive RF ablation

What is claimed is: 1. A medical system for treating tissue, comprising: a medical device; an ablation electrode and a temperature sensor coupled to the medical device; a source of RF energy in electrical communication with the ablation element, the source having a variable power output, the source of RF energy supplying power to the ablation electrode to ablate the tissue; a control unit in communication with the temperature sensor and operable to receive a temperature signal from the temperature sensor, the control unit programmed to determine a state of contact between the ablation electrode and tissue based at least in part on the temperature signal, the control unit having a delay interval and being programmed to permit the power supplied to the ablation element to be increased when, after a determination that continuous contact has been lost: the ablation element regains continuous tissue contact; and the state of regained continuous tissue contact has continued for a time at least equal to the delay interval; and a feedback controller in communication with the control unit, the temperature sensor, and the source of RF energy, the feedback controller being programmed to modify the power output of the source of RF energy based at least in part on the temperature signal. 2. The medical system of claim 1 , wherein the source of RF energy has a duty cycle of selectable duration. 3. The medical system of claim 2 , wherein the source of RF energy has a duty cycle with a base frequency of at most 10 ms. 4. The medical system of claim 1 , wherein the feedback controller is a P-I-D or P-I controller, and the integration period of the feedback controller is at least the duration of a human heartbeat. 5. The medical system of claim 1 , wherein the control unit is programmed to modify the power output of the source of RF energy based at least in part on the state of contact. 6. The medical system of claim 5 , wherein the control unit is programmed to prevent the feedback controller from increasing the power output of the source of the RF energy based at least in part on the state of contact being no tissue contact. 7. The medical system of claim 1 , wherein the tissue to be treated is cardiac tissue. 8. A medical system, comprising: means for advancing an ablation element of a medical device into contact with tissue to be treated; means for supplying power to the ablation element to ablate the tissue; means for selecting a desired temperature of the ablation element; means for monitoring a temperature of the ablation element; means for determining a state of contact between the ablation electrode and the tissue based on signals from the means for monitoring a temperature of the ablation element; means for reducing the supplied power to the ablation element when the monitored temperature exceeds the desired temperature; and means for initiating an increase in the power to the ablation element when, after a determination that continuous contact has been lost: the ablation element regains continuous tissue contact; and the state of regained continuous tissue contact has continued for at least three seconds. 9. The medical system of claim 8 , further comprising: means for monitoring power delivered to the ablation element; means for calculating the average power produced by the means for supplying power; and means for limiting the average power to a preselected maximum delivered power threshold. 10. The medical system of claim 8 , further comprising: means for setting a maximum duty cycle equal to a current duty cycle value when the power is at least equal to a desired maximum power; and means for reducing a selected power level by limiting the duty cycle value to the maximum duty cycle. 11. A medical system controller, comprising: a power source for supplying power to an ablation element; and a control unit programmed to monitor a temperature of the ablation element and characterize the contact between the ablation element and biological tissue based on the temperature of the ablation element, said contact characterization comprising the states of loss of continuous tissue contact and regained continuous tissue contact, the control unit further being programmed to: limit the power supplied to the ablation element when the contact characterization is loss of continuous tissue contact; and permit an initiation of an increase in the power supplied to the ablation element when the contact characterization is regained continuous tissue contact for at least three seconds. 12. The medical system controller of claim 11 , wherein: the control unit has a maximum limit for the power supplied to the ablation element; and the control unit is programmed to measure the supplied power to the ablation element; the control unit is programmed to calculate the average power supplied to the ablation element; and the control unit is programmed to limit the average power to the maximum limit. 13. The medical system controller of claim 11 , wherein a maximum duty cycle equal to the current duty cycle value is set when the supplied power is at least equal to the maximum limit, and thereafter the duty cycle value is limited to the maximum duty cycle. 14. The medical system controller of claim 11 , wherein: the control unit is programmed to select a desired temperature and a threshold variation; the control unit is programmed to calculate an average temperature of the ablation element, to calculate a difference between the ablation element temperature and the average ablation element temperature, and to calculate a continuity value by subtracting the difference from the desired temperature; and the control unit is programmed to reducing the desired temperature when the continuity value exceeds the threshold variation. 15. The medical system controller of claim 14 wherein the control unit is programmed to increase the desired temperature when the continuity value falls below the threshold variation. 16. The medical system controller of claim 15 wherein the threshold variation is substantially equal to 5 degrees.