Combined ablation and ultrasound imaging

The invention claimed is: 1. A system ( 100 ) for combined ablation and ultrasound imaging of associated tissue ( 40 , 540 ), the system comprising an interventional device ( 20 ), the interventional device comprising, an ultrasound transducer ( 5 , 505 ), and an ablation unit ( 15 , 516 ), and a controlling unit (CTRL) being operably connected to the interventional device ( 20 ), the controlling unit (CTRL) being arranged to send a control signal (CoS) to the ultrasound transducer ( 5 , 505 ), receive a response signal (ReS) from the ultrasound transducer, the response signal (ReS) being indicative of the presence of one or more bubbles within said associated tissue ( 40 , 540 ), and calculate a predictor value (PV), where the predictor value (PV) relates to a risk of an impending tissue damage due to a rapid release of a bubble energy, wherein the controlling unit ((CTRL) is further arranged to send a primary signal (RS) if the predictor value (PV) exceeds a threshold value, and wherein the primary signal (RS) is arranged to control an ablation parameter while ablation is continued. 2. A system ( 100 ) for combined ablation and ultrasound imaging of associated tissue according to claim 1 , wherein the threshold value (TV) is a function of any one of: a power dissipated in the associated tissue ( 40 , 540 ), the previous history of the response signal, a measured contact force between the interventional device and the associated tissue ( 40 , 540 ), an electrical impedance of the associated tissue ( 40 , 540 ), a structure of the associated tissue ( 40 , 540 ), a duration of the ablation, the ability of the associated tissue to exchange heat with the surroundings, a temperature of the associated tissue ( 40 , 540 ), the temperature of the ablation electrode, and the irrigation flow rate at the electrode tip. 3. A system ( 100 ) for combined ablation and ultrasound imaging of associated tissue ( 40 , 540 ) according to claim 2 , wherein the controlling unit (CTRL) is arranged to vary the primary signal (RS) depending on the value of the predictor value (PV). 4. A system ( 100 ) for combined ablation and ultrasound imaging of associated tissue ( 40 , 540 ) according to claim 3 , wherein the controlling unit (CTRL) is arranged to form part of a feedback circuit. 5. A system ( 100 ) for combined ablation and ultrasound imaging of associated tissue ( 40 , 540 ) according to claim 3 , wherein the ultrasound transducer ( 5 , 505 ) is disposed behind or in an irrigation hole ( 21 ) of the interventional device ( 20 ), so as to allow an irrigation fluid to flow out of the irrigation hole ( 21 ), and so as to allow transmitting and/or receiving an ultrasonic signal (A 2 ) through the irrigation hole ( 21 ). 6. A system ( 100 ) for combined ablation and ultrasound imaging of associated tissue ( 40 , 540 ) according to claim 3 , wherein the ablation unit ( 15 , 516 ) comprises any one of: a heating element, a radio frequency electrode, an ultrasound transducer, and a laser. 7. A system ( 100 ) for combined ablation and ultrasound imaging of associated tissue ( 40 , 540 ) according to claim 3 , the system comprising any one of: an electrode capable of serving as an electrode for measuring electrical impedance, a force sensor capable of measuring a contact force applied between the interventional device and the associated tissue ( 40 , 540 ), and a temperature sensor and localization sensor. 8. A system ( 100 ) for combined ablation and ultrasound imaging of associated tissue ( 40 , 540 ) according to claim 3 , wherein the primary signal (RS) is controlling any one of: the ablation unit ( 15 , 516 ), an irrigation flow, a contact force applied between the interventional device and the associated tissue ( 40 , 540 ), and a position of the ablation unit. 9. The system according to claim 3 , wherein the ablation parameter controlled based on the primary signal is an irrigation flow. 10. The system according to claim 3 , wherein the ablation parameter controlled based on the primary signal is a contact pressure between the interventional device and the associated tissue. 11. A method for assessing a risk of impending tissue damage due to a rapid release of a bubble energy, the method comprising emitting (S 1 ) a primary ultrasonic signal into a tissue, and receiving (S 2 ) a secondary ultrasonic signal from within the tissue, and determining (S 3 ) if one or more bubbles are formed within the tissue, based upon information derived from the secondary ultrasonic signal, and sending (S 4 ) the information derived from the secondary ultrasonic signal to a processor, and calculating (S 5 ) a predictor value (PV) based on information derived from the secondary ultrasonic signal, where the predictor value (PV) relates to the risk of impending tissue damage due to the rapid release of the bubble energy, sending a primary signal (RS) if the predictor value (PV) exceeds a threshold value, and controlling an ablation parameter while ablation is continued. 12. The method according to claim 11 , wherein the ablation parameter controlled based on the primary signal is an irrigation flow. 13. The method according to claim 11 , wherein the ablation parameter controlled based on the primary signal is a contact pressure between the interventional device and the associated tissue. 14. A computer program product comprising a non-transitory, computer readable storage medium being adapted to enable a computer system comprising at least one computer having data storage means associated therewith to operate a processor arranged for receiving information derived from an ultrasonic signal indicative of the presence of one or more bubbles within associated tissue, calculating a predictor value (PV) based on information derived from the secondary ultrasonic signal, where the predictor value relates to a risk of an impending tissue damage due to a rapid release of a bubble energy sending a primary signal (RS) if the predictor value (PV) exceeds a threshold value, and controlling an ablation parameter while ablation is continued based on the primary signal. 15. The computer program product according to claim 14 , wherein the ablation parameter controlled based on the primary signal is an irrigation flow. 16. The computer program product according to claim 14 , wherein the ablation parameter controlled based on the primary signal is a contact pressure between the interventional device and the associated tissue.