Patent Application
20150272655
n/a
n/a
The present invention relates to a method and system for the delivery of radiofrequency (RF) energy in a multi-electrode system. Specifically, the present invention relates to a method and system for the safe delivery of unipolar and/or bipolar RF energy in a multi-electrode system while eliminating or mitigating the delivery of unintended delivery of bipolar RF energy that may cause collateral damage to tissue.
Tissue ablation is a medical procedure commonly used to treat conditions such as cardiac arrhythmia, which includes atrial fibrillation. For treating cardiac arrhythmia, ablation can be performed to modify tissue, such as to stop aberrant electrical propagation and/or disrupt aberrant electrical conduction through cardiac tissue. Although non-thermal or chemical ablation may be used, tissue ablation is typically performed by delivering or removing energy from tissue, which causes the tissue to heat or cool to lethal temperatures. Other energy modalities, such as microwave energy, laser energy, and ultrasound energy may similarly cause cell damage by heating the tissue. The same procedures may be used to heat or cool tissue to non-lethal temperatures, for example, cryotreatment, cryocooling, and/or mapping procedures.
One type of frequently used thermal ablation technique is the application of radiofrequency (RF) energy to tissue. RF energy may be passed from an energy generator to one or more electrodes. When the electrodes are placed in contact with an area of target tissue, the delivery of RF energy from the one or more electrodes into the tissue may increase the temperature of the tissue to lethal temperatures.
There are two general types of RF energy delivery: unipolar and bipolar. In unipolar mode, energy travels from an electrode of a medical device (for example, an RF ablation catheter) through the target tissue. The energy may pass through the tissue to a ground or return electrode, usually located external to the patient. In bipolar mode, on the other hand, energy travels through the tissue between a first electrode and second electrode, which are usually located on the same medical device. For either energy mode, the ablation device may include more than two electrodes, and these devices may be referred to as multi-electrode devices. Unipolar RF energy delivery may cause deeper lesions than bipolar RF energy delivery. As such, unipolar RF energy delivery may be preferred when ablating thicker or tougher areas of tissue. However, well-controlled bipolar RF energy delivery may be preferred, or essential, when ablating thinner or more delicate areas of tissue or when there is concern of possible collateral damage to target or non-target tissue. However, too much bipolar energy between electrodes can cause a significant amount of local heating between the two electrodes, resulting in unintended consequences such as thermal coagulum of the blood, charring of the tissue, excessive microbubble formation, tissue overheating and steam pops, or collateral damage to target or non-target tissue.
In most currently known RF ablation systems, voltage is adjusted to change the power delivered to an electrode. When a voltage-controlled system for delivering unipolar energy to an electrode is adapted for a multi-electrode catheter or system, bipolar energy will flow between adjacent electrodes if there is a voltage difference between those electrodes. In fact, a voltage difference between adjacent electrodes frequently exists in such systems, because each individual electrode is monitored and adjusted individually based on the energy level that is required at each electrode. The resulting unintended bipolar energy can easily reach levels that are unsafe for the patient if not accounted for by the system.
It is therefore desirable to provide a method and system for ensuring the delivery of unipolar RF energy in a multi-electrode system, and for the delivery of unipolar RF energy in a multi-electrode system while preventing the unintended delivery of bipolar RF energy and/or delivering bipolar RF energy in a controlled way that prevents unintended tissue damage.
The present invention advantageously provides a method and system for the delivery of radiofrequency (RF) energy in a multi-electrode system. Specifically, the present invention relates to a method and system for the safe delivery of unipolar and/or bipolar RF energy in a multi-electrode system while eliminating or mitigating the unintended delivery of bipolar RF energy at levels that may cause unintended damage tissue damage. In one embodiment, a system for preventing unintended tissue damage from the delivery of bipolar RF energy may include an ablation device including a plurality of electrodes and a RF energy delivery unit, the delivery unit being in electrical communication with each of the plurality of electrodes. The ablation device may further include a plurality of carrier arms, with at least one of the plurality of electrodes being located on each carrier arm. The energy delivery unit may be programmed to transmit unipolar RF energy to each of the plurality of electrodes, the transmission of RF energy to each of the plurality of electrodes being started at the same time, being in phase, and having the same voltage. The delivery unit may be further programmed to transmit RF energy having the same recurring waveform to each of the plurality of electrodes. The delivery unit may include at least one processor and a programmable logic device (PLD). The PLD may create a timing signal that causes the delivery unit to transmit RF energy having, for example, square waves. The square-wave RF energy may be filtered so that the square waveform is changed to a sinusoidal (or “sine”) waveform before the RF energy is delivered by each of the plurality of electrodes. The delivery unit may be programmed to deliver RF energy in unipolar mode only, or it may be programmed to deliver unipolar RF energy and bipolar RF energy. In the latter case, the bipolar RF energy transmitted to each electrode may include waves that are out of phase from RF energy transmitted one or more adjacent electrodes. The delivery unit may be further programmed to monitor an amount of bipolar energy delivered between each pair of adjacent electrodes. Further, monitoring the amount of bipolar energy delivered between each pair of adjacent electrodes may include monitoring a voltage difference between each pair of adjacent electrodes and/or monitoring the power delivered to each of the plurality of electrodes. The control unit may be further programmed to determine whether the amount of bipolar energy delivered by each pair of adjacent electrodes exceeds a predetermined safety threshold. For example, the predetermined safety threshold voltage may be determined before RF energy is transmitted to the plurality of electrodes. The delivery unit may be further programmed to reduce the voltage of RF energy transmitted to an electrode of a pair of adjacent electrodes that is delivering energy at a higher voltage than another of the pair of adjacent electrodes when the delivery unit determines that the amount of bipolar energy delivered between the pair of adjacent electrodes exceeds the predetermined safety threshold. For example, the voltage of RF energy transmitted to the electrode of a pair of adjacent electrodes that is delivering energy at a higher voltage than the other of the pair of adjacent electrodes is reduced such that both electrodes of the pair of adjacent electrodes each deliver RF energy having substantially the same voltage. Additionally or alternatively, the delivery unit may be further programmed to deactivate an electrode of a pair of adjacent electrodes that is delivering energy at a lower voltage than another of the pair of adjacent electrodes and/or deactivate both electrodes of the pair of electrodes, when the delivery unit determines that the amount of bipolar energy delivered between the pair of adjacent electrodes exceeds the predetermined safety threshold. Additionally or alternatively, the delivery unit may be further programmed to deliver energy to a pair of adjacent electrodes according to a duty cycle. For example, the duty cycle may include delivering RF energy at the same voltage to each electrode of the pair of adjacent electrodes.
In another embodiment, a system for preventing unintended tissue damage from the delivery of bipolar RF energy may include an ablation device including a plurality of electrodes, each of the plurality of electrodes having at least one adjacent electrode; a RF energy delivery unit in electrical communication with each of the plurality of electrodes, the RF energy delivery unit being configured to deliver RF energy including RF energy waves; and a return electrode in electrical communication with the delivery unit. The RF energy delivery unit may be programmable to: transmit unipolar RF energy to the plurality of electrodes when the RF energy transmitted to each of the plurality of electrodes is in phase, has the same voltage, and when the energy delivery unit starts the delivery of RF energy to each of the plurality of electrodes simultaneously; transmit bipolar RF energy to the plurality of electrodes when the RF waves are out of phase; monitor voltage differences between each pair of adjacent electrodes; and adjust at least one electrode in a pair of electrodes when the RF energy delivery unit determines that the voltage difference between the pair of electrodes indicates that bipolar energy is being delivered at a level that exceeds a predetermined safety threshold. Adjusting at least one electrode in a pair of electrodes may include reducing the RF energy voltage delivered by an electrode of the pair of electrodes that is delivering the higher voltage of RF energy to a voltage that is substantially the same as the voltage delivered to an electrode of the pair of electrodes that is delivering the lower voltage of RF energy. Additionally or alternatively, adjusting at least one electrode in a pair of electrodes may include deactivating an electrode of the pair of electrodes that is delivering the lower voltage of RF energy. Additionally or alternatively, adjusting at least one electrode in a pair of electrodes may include deactivating both electrodes of the pair of adjacent electrodes.
In another embodiment, a system for preventing unintended tissue damage from the delivery of bipolar RF energy may include an ablation device including a plurality of electrodes, each of the plurality of electrodes having at least one adjacent electrode and a radiofrequency energy delivery unit in electrical communication with each of the plurality of electrodes, the RF energy delivery unit being configured to deliver RF energy including RF energy waves. The RF delivery unit may be programmed to monitor voltage differences between each pair of adjacent electrodes and adjust at least one electrode in a pair of electrodes when the radiofrequency energy delivery unit determines that the voltage difference between the pair of electrodes indicates that bipolar energy is being delivered at a level that exceeds a predetermined safety threshold. Adjusting at least one electrode in a pair of electrodes may include at least one of: reducing the voltage of RF energy transmitted to an electrode of a pair of electrodes that is delivering energy at a higher voltage than another of the pair of electrodes; and deactivating an electrode of a pair of electrodes that is delivering energy at a lower voltage than another of the pair of electrodes. The RF energy delivery unit may further be programmed to monitor power differences between each pair of adjacent electrodes and adjust at least one electrode in a pair of electrodes when the RF energy delivery unit determines that the power difference between the pair of electrodes indicates that bipolar energy is being delivered at a level that exceeds a predetermined safety threshold.
In one embodiment, a method for preventing unintended tissue damage may include transmitting unipolar RF energy to a plurality of electrodes of a multi-electrode medical device, the RF energy being transmitted coherently to each of the plurality of electrodes, the RF transmitted to each of the plurality of electrodes being in phase with the RF energy delivered to the other of the plurality of electrodes and the RF energy transmitted to each of the plurality of electrodes having the same voltage. The method may further include transmitting RF energy to each of the plurality of electrodes according to a duty cycle. Further, each of the plurality of electrodes may have at least one adjacent electrode to create a pair of adjacent electrodes, the plurality of electrodes including a plurality of adjacent pairs of electrodes. The method may further comprise: transmitting bipolar RF energy between at least one pair of adjacent electrodes when RF energy delivered to a first electrode of the pair of adjacent electrodes is out of phase with or at a different voltage than RF energy delivered to a second electrode of the pair of adjacent electrodes; monitoring voltage differences between the at least one pair of adjacent electrodes; and adjusting RF energy delivered to at least one electrode in the at least one pair of adjacent electrodes when the RF energy delivery unit determines that the voltage difference between the electrodes of the at least one pair of adjacent electrodes indicates that bipolar energy is being delivered at a level that exceeds a predetermined safety threshold. Adjusting at least one electrode in the at least one pair of adjacent electrodes may include at least one of: reducing the RF energy voltage transmitted to an electrode of the at least one pair of adjacent electrodes that is delivering the higher voltage of RF energy such that both electrodes in the at least one pair of adjacent electrodes deliver substantially the same voltage; and deactivating an electrode of the at least one pair of adjacent electrodes that is delivering the lower voltage of RF energy.
A more complete understanding of the present invention, and the attendant advantages and features thereof, will be more readily understood by reference to the following detailed description when considered in conjunction with the accompanying drawings wherein:
RF ablation system;
Referring now to
Referring to
Referring again to
Referring now to
As discussed, RF energy may be delivered from each of the electrodes 40 as sinusoidal waves 58. Although a user may intend to deliver only unipolar RF energy from the electrodes 40, unintended phase shifts may occur between electrodes 40 (for example, as shown in
Bipolar RF voltage=(sin(degrees phase shift/2)'2)×unipolar RF voltage
As a non-limiting example for illustration only, the phase shift may be 180° and the unipolar RF voltage may be 100V. Using the above equation, the 180° phase shift will result in a 200V difference between the adjacent electrodes 40, meaning that 200V of bipolar energy is being delivered.
If a phase shift, either intended or unintended, generates an amount of bipolar RF energy that is greater than desired by the user (for example, because the amount of RF energy delivered would cause collateral damage to target or non-target tissue), the control unit 34 may be programmed or programmable to transmit energy to adjacent electrodes according to a duty cycle and/or to automatically deactivate one of an adjacent pair of electrodes 40.
Currently known systems adjust the voltage of energy being transmitted to electrodes in order to control the ablative effect of a treatment on target tissue. That is, voltage delivered to an electrode may be adjusted to produce a desired electrode temperature. However, because this adjustment is made at each electrode based on monitoring that electrode in isolation from adjacent electrodes, such adjustment can result in the unintended delivery of bipolar RF energy. For example, in a currently known multi-electrode unipolar RF energy delivery system, the voltage of each electrode may be monitored to determine the temperature being delivered to the tissue. An electrode may have a first surface that is in contact with tissue and a second surface that is in contact with flowing blood rather than tissue. The flowing blood helps cool the second surface of the electrode, which causes the temperature of the first side of the electrode to increase. As the first side of the electrode ablates the tissue, the electrode may sink into the tissue (referred to as becoming buried within the tissue). Although this is a desired effect, it may reduce or eliminate contact between the second side of the electrode and the flowing blood. As a result, the electrode may need only a fraction of the original power to effectively ablate tissue, and delivering the original amount of energy may result in tissue charring. In order to reduce the amount of energy being delivered, the system may reduce the voltage of the buried electrode. Although this may be effective to reduce the temperature of that electrode, it may also result in the unintended delivery of bipolar energy between that electrode and an adjacent electrode, often in an amount that exceeds a predetermined safety threshold. For example, 100V of energy may be delivered to each of two adjacent electrodes. If one electrode becomes buried in the tissue, that electrode may need only 10V to produce the correct electrode temperature. If the system reduces the voltage on that electrode to 10V, there is now a 90V difference between the two adjacent electrodes. That is, 90V of unintended bipolar energy is being delivered between the adjacent electrodes.
Unlike currently known systems, the present system either does not adjust voltage of individual electrodes to control electrode temperature or does so only after determining the resulting bipolar effect between adjacent electrodes. In the first case, the voltage of energy delivered to all electrodes may be the same and constant, but each electrode 40 may be operated according to a duty cycle in which the electrode 40 is activated for a certain amount of time and deactivated for a certain amount of time. For example, if 100 watts of RF energy is being delivered but only 10 watts is required to produce the desired electrode temperature, that electrode 40 may be activated for 10% of a given period of time and deactivated for 90% of that duration of time. The delivery unit 34 may be programmed to execute an algorithm that determines the correct duty cycle based on, for example, transmitted voltage, duration treatment time, electrode temperature, or other factors. Additionally, the delivery unit 34 may be programmed to create a duty cycle for one or more electrodes 40 as needed, based at least in part on, for example, temperature data received from one or more temperature sensors on one or more electrodes 40. When an electrode 40 is deactivated (rather than reduced to 0V), it may be referred to as being in a high-impedance state. Thus, when an electrode is in a high-impedance state, no bipolar energy is possible between the deactivated or high-impedance electrode and an adjacent electrode, even though the electrode is being maintained at a desired temperature. Further, even if two adjacent electrodes are delivering energy at the same time (for example, each electrode is at an activation stage of its duty cycle), no bipolar energy will be delivered between the electrodes because the delivery unit 34 is transmitting energy at the same voltage to all electrodes. For this reason, the energy pathway between electrodes 40A and 40B in
In the second case, the delivery unit 34 may monitor the voltage of energy delivered by each electrode and the amount of bipolar energy delivered between adjacent electrodes 40. The determined amount of bipolar energy may be compared to a predetermined safety threshold to determine whether the amount of bipolar energy is a safe amount or whether it is likely to cause collateral damage, such as tissue charring and/or unintended damage to non-target tissue. For example, the delivery unit 34 may make the comparison based on voltage differences between adjacent electrodes 40 and/or bipolar power delivered, which may be calculated as the product of the current and the voltage. Based on this comparison, the delivery unit 34 may reduce the voltage of the higher of the two electrodes 40 if the delivered bipolar energy is above a safe level. That is, if a first electrode 40A is delivering RF energy at a greater voltage than an adjacent electrode 40B, the voltage of energy delivered by electrode 40A may be reduced in order to reduce or eliminate the amount of bipolar RF energy being delivered to the target tissue. As a non-limiting embodiment, if electrode 40A is delivering RF energy at 40V and electrode 40B is delivering RF energy at 30V, the voltage delivered by electrode 40A may be reduced to 30V. Additionally or alternatively, the delivery unit 34 may be programmed or programmable to deactivate the lower of the two electrodes 40 if the delivered bipolar energy is above a safe level. That is, if a first electrode 40A is delivering RF energy at a greater voltage than an adjacent electrode 40B, electrode 40B may be deactivated (that is, transitioned to a high-impedance state), thereby preventing the delivery of bipolar RF energy between the electrodes 40A, 40B. As a non-limiting example, this method of preventing the delivery of unintended bipolar energy may be useful in existing voltage-controlled systems.
In these methods, bipolar energy may be delivered in a carefully controlled way, so that the user may apply bipolar energy before, during, or instead of unipolar energy while mitigating or eliminating the chance of unintended tissue damage. The threshold above with bipolar energy is not being delivered at a safe level may be determined empirically and/or based on individual patient characteristics. Further, this threshold may be determined before the delivery of ablation energy begins, and this predetermined threshold may be programmed into the RF delivery unit 34 through, for example, the user interface 48.
Referring now to
Referring now to
If bipolar energy delivered does exceed the safety threshold, however, the user and/or system 10 may perform either or both of the steps in
Continuing to refer to
It will be understood that the methods and systems disclosed herein may be used in any multi-electrode RF ablation system, including voltage-controlled systems. Thus, the methods and systems of the present invention may be implemented in an existing RF ablation system in order to prevent the delivery of bipolar RF energy and/or to control the delivery of bipolar RF energy so that bipolar energy is delivered at levels that do not exceed a predetermined safety threshold. Further, both the method of
It will be appreciated by persons skilled in the art that the present invention is not limited to what has been particularly shown and described herein above. In addition, unless mention was made above to the contrary, it should be noted that all of the accompanying drawings are not to scale. A variety of modifications and variations are possible in light of the above teachings without departing from the scope and spirit of the invention, which is limited only by the following claims.
