1. Technical Field
The present disclosure is directed to electrosurgical systems and methods and, more particularly, to patient return electrode systems and methods for performing monopolar surgery and RF ablation using the same.
2. Background
During electrosurgery, a source or active electrode delivers energy, such as radio frequency energy, from an electrosurgical generator to a patient. A return electrode carries the current back to the electrosurgical generator. In monopolar electrosurgery, the source electrode is typically a hand-held instrument placed by the surgeon at the surgical site and the high current density flow at this electrode creates the desired surgical effect of cutting, ablating and/or coagulating tissue. The patient return electrode is placed at a remote site from the source electrode and is typically in the form of a pad adhesively adhered to the patient.
The return electrode typically has a relatively large patient contact surface area to minimize heat concentrations at that patient pad site (i.e., the smaller the surface area, the greater the current density and the greater the intensity of the heat.) Hence, the overall area of the return electrode that is adhered to the patient is generally important because it minimizes the chances of current concentrating in any one spot which may cause patient burns. A larger surface contact area is desirable to reduce heat intensity. The size of return electrodes is based on assumptions of the anticipated maximum current during a particular surgical procedure and the duty cycle (i.e., the percentage of time the generator is on) during the procedure. The first types of return electrodes were in the form of large metal plates covered with conductive jelly. Later, adhesive electrodes were developed with a single metal foil covered with conductive jelly or conductive adhesive. However, one problem with these adhesive electrodes was that if a portion thereof peeled away from the patient, the contact area of the electrode with the patient decreased, thereby increasing the current density at the adhered portion and, in turn, increasing the heat applied to the tissue. This resulting in an increased risk of burning the patient in the area under the adhered portion of the return electrode if the tissue was heated beyond the point where normal circulation of blood could cool the skin.
To address this problem, split return electrodes and hardware circuits, generically called Return Electrode Contact Quality Monitors (RECQMs), were developed. These split electrodes consist of two separate conductive foils arranged as two halves of a single return electrode. The hardware circuit uses an AC signal between the two electrode halves to measure the impedance therebetween. This impedance measurement is indicative of how well the return electrode is adhered to the patient since the impedance between the two halves is directly related to the area of patient contact. That is, if the electrode begins to peel from the patient, the impedance increases since the contact area of the electrode decreases. Current RECQMs are designed to sense this change in impedance so that when the percentage increase in impedance exceeds a predetermined value or the measured impedance exceeds a threshold level, the electrosurgical generator is shut down to reduce the chances of burning the patient.
As new surgical and therapeutic RF procedures continue to be developed that utilize higher current and higher duty cycles, increased heating of tissue under the return electrode may occur. Ideally, each conductive pad would receive substantially the same amount of current, therefore reducing the possibility of a pad site burn. However, this is not always possible due to patient size, incorrect placement of pads, differing tissue consistencies, etc.
The present disclosure is directed to patient return electrode systems and methods for performing monopolar surgery and RF ablation using the same.
According to an aspect of the present disclosure, a return electrode for use in an electrosurgical system is provided. The return electrode includes a non-conductive pad, and a plurality of concentric, electrically isolated conductive elements coupled to a surface of the non-conductive pad. Each conductive element defines a leading edge located in relatively close proximity to a source of electrosurgical energy. Each conductive element is independently electrically connectable to the source of electrosurgical energy.
According to another aspect of the present disclosure, an electrosurgical system is provided and includes an electrosurgical generator, and a return electrode selectively connectable to the electrosurgical generator. The return electrode includes a plurality of concentric, electrically isolated conductive elements. Each conductive element defines a leading edge located in relative close proximity to the electrosurgical generator. Each conductive element is independently electrically connectable to the electrosurgical generator.
According to a further aspect of the present disclosure, a method of performing monopolar surgery is provided and includes the step of providing an electrosurgical system. The electrosurgical system includes an electrosurgical generator, and a return electrode connected to the electrosurgical generator, the return electrode including a plurality of concentric, electrically isolated conductive elements. Each conductive element defines a leading edge located in close proximity to the electrosurgical generator. Each conductive element is independently electrically connectable to the electrosurgical generator.
The method further includes the steps of placing the return electrode into contact with a patient, generating electrosurgical energy via the electrosurgical generator, transmitting electrosurgical energy between an active electrode and the return electrode via the patient, measuring the current along the leading edge of each conductive element, and switching a respective conductive element out-of a circuit when the measured current along the leading edge of the respective conductive element exceeds a predetermined threshold current level.
According to the present disclosure, a return electrode pad has advantageously been designed which has the ability to relieve large current concentrations on a leading edge thereof and to make adjustments so as to reduce the current concentration at said leading edge thereof, thereby reducing the likelihood of patient burns.
The above and other aspects, features, and advantages of the present disclosure will become more apparent in light of the following detailed description when taken in conjunction with the accompanying drawings in which:
Embodiments of the presently disclosed electrosurgical system and method of using the same are described herein with reference to the accompanying drawing figures wherein like reference numerals identify similar or identical elements. In the following description, well-known functions or constructions are not described in detail to avoid obscuring the disclosure in unnecessary detail.
Referring initially to
As seen in
Turning now to
Return electrode 200 includes a plurality of conductive elements 220 supported on top surface 212 of pad 210. As seen in
In the illustrated embodiment a first conductive element 220a surrounds a second conductive element 220b, while second conductive element 220b surrounds a third conductive element 220c. Each conductive element 220a-220c may be formed as a foil of conductive material or other suitable highly conductive media.
While three conductive elements 220 are shown and described, return electrode 200 may include any suitable number of conductive elements 220. Additionally, each conductive element 220 may have a uniform width or may have a varying width along the length thereof. Also, each conductive element 220 may have a different width as compared to other conductive elements 220 of return electrode 200. Any combination of these arrangements and/or configurations of conductive elements 220 falls within the scope of the present disclosure.
In an embodiment the number of conductive elements 220 and the area/size/dimension of each conductive element 220 is selected and/or optimized in order to achieve the greatest effect in dissipating current concentrations and/or temperature concentrations.
Each conductive element 220a-220c defines a leading edge 222a-222c, respectively. As used herein, the term “leading edge” is defined as the edge or corner of each conductive element 220a-220c that is closest to the source of energy or generator 120, or closest to connection device 300.
Each conductive element 220a-220c is separately and independently electrically connected or connectable to generator 120 and/or to a processor or computer 180, as seen in
In operation, according to one method, computer 180 may switch the conductive elements 220a-220c into or out of the circuit at predefined or predetermined intervals, may sequentially cycle through conductive elements 220a-220c according to said predefined or predetermined intervals and/or may randomly cycle through conductive elements 220a-220c according to said predefined or predetermined intervals.
According to another method of operation, computer 180 may switch the conductive elements 220a-220c into or out of the circuit in response to inputs received and/or temperature measurements taken at the patient/return-electrode interface and/or temperature measurements taken within return electrode 200.
As illustrated in
In an embodiment, the leading edge 222a-222c of each respective conductive element 220a-220c may include at least one discrete current sensor 402 operatively connected thereto. The current sensors operatively associated with the leading edges 222a-222c of conductive elements 220a-220c are independent of the current sensors operatively associated with the remainder of conductive elements 220a-220c. Moreover, each current sensor 402a-402f may be connected via a common cable 250 to a comparator 180 disposed within connection device 300 or generator 120.
Generally, the area of the return electrode 200 that is in contact with the patient “P” affects the current density of a signal that heats the patient “P.” The greatest current density usually occurs along the leading edge of the conductive elements of the return electrode. Typically, the smaller the contact area of return electrode 200 with the skin of the patient “P,” the greater the current density and in turn the greater the heating of tissue at the contact site. Conversely, the greater the contact area of return electrode 200 with the skin of the patient “P,” the smaller the current density and in turn the smaller the heating of tissue at the contact site.
As can be appreciated and as mentioned above, higher current densities may be located along the leading edges of the conductive elements of the return electrodes, which lead to greater heating of tissue and greater probability of patient burn in the areas where the leading edges of the conductive elements of the return electrodes are in contact with the skin of the patient “P”. It is therefore important to either ensure a relatively high amount of contact area between return electrode 200 and the patient “P,” or otherwise maintain a relatively low current density on the return electrode 200.
While there are various methods of maintaining a relatively low current density the present disclosure ensures relatively low current densities along the leading edges 222a-222c of conductive elements 220a-220c. This may be accomplished by sensing the amount of current returning to each of the plurality of conductive elements 220a-220c of the return electrode 200 and switching the conductive elements 220a-220c out of the circuit in response to inputs received and/or temperature measurements taken at the patient/return-electrode interface and/or temperature measurements taken within return electrode 200, thereby reducing current densities at the patient site.
Referring now to
Current sensor(s) 402a-402d may take a number of suitable forms including, but not limited to, open loop sensors, closed loop sensors, digital current sensors, Hall-effect devices or a current sense transformer (not shown), the operation of which is described hereinbelow. In use, the return current for each return electrode 200a-200d is passed through a toroidal magnetic, which forms a 1:N current sense transformer comprised of 1 turn from the return wire and N turns of the toroidal core. The waveform representing the current can be converted to a voltage waveform by placing a resistor between the terminations of the toroidal core turns. This voltage waveform is substantially sinusoidal in nature and may require further modification. AC/DC converter circuits 408a-408d may be utilized to substantially convert the alternating current signal of the return current into a direct current signal. This eliminates any phase or frequency modulation that could lead to inaccuracies in measurement. This DC response is representative of the amount of RF current flowing through each return electrode 200a-200d. AC/DC converter circuit may be associated with each respective sensor 402a-402d.
Once the DC response of each return electrode 200a-200d is obtained, the signal may then be fed into a respective comparator 404a-404f. Each comparator 404a-404f receives two distinct DC inputs, each from a separate return electrode 200a-200d. One possible type of comparator is an instrumentation amplifier. Instrumentation amplifier receives a DC input from two different return electrode 200a-200d and calculates the current differential between the two. This difference is then multiplied by the gain of comparator or instrumentation amplifier 404a-404f in order to obtain a scaled representation of imbalances between any two of the return electrode 200a-200d. Ideally, the current differential would be negligible with each return electrode receiving the same amount of return current. However, if a substantial imbalance is present, a warning is provided via a suitable warning device (audible or visual) or safety control algorithms that are utilized to mitigate return electrode site burns.
Generator 120 may contain, inter alia, embedded software. This embedded software may be utilized to develop safety control algorithms or similar warning mechanisms. Using the information provided by comparator(s) 404a-404f, generator 120 may be able to modulate the amount of power delivered to each return electrode 200a-200d, thereby minimizing the chances of return electrode site burns. Moreover, this information may also be processed using a variety of suitable techniques, including but not limited to, neural networks or fuzzy logic algorithms.
A current sense transformer may be replaced with any current measuring device, such as a non-inductive sense resistor. Similarly, comparator or instrumentation amplifier could be replaced with a number of different devices including, but not limited to, differential amplifiers. Moreover, AC/DC converter circuit(s) 408a-408d may take on a number of suitable forms, such as a full-wave rectifier circuit.
To further limit the possibility of patient burns, an adhesive layer 500 may be disposed about the periphery of return electrode 200, as illustrated in
The return electrode(s) 200 may be entirely disposable, entirely re-usable, or a combination thereof. In one embodiment, the conductive elements 220 are re-usable, while the adhesive layer 500 is disposable. Other combinations of disposable/re-usable portions of the return electrode 200 are within the scope of the present disclosure.
As seen in
The present disclosure also includes a method for performing monopolar surgery. The method utilizes one or more return electrodes associated with a current detection system 400, as described above. The method also includes placing one or more return electrodes into contact with a patient, generating electrosurgical energy via an electrosurgical generator 120, supplying the electrosurgical energy to the patient via a surgical instrument 110, measuring the current density along the leading edge of each conductive element of each return electrode, detecting spikes and/or relatively large readings of the current in the leading edge of each conductive element and comparing said readings with predetermined levels, warning the user of a possible hazardous condition; and providing a means for substantially correcting the imbalances. The imbalances are corrected by removing from the circuit a conductive element exhibiting the current density level above said predetermined level.
While several embodiments of the disclosure have been shown in the drawings, it is not intended that the disclosure be limited thereto, as it is intended that the disclosure be as broad in scope as the art will allow and that the specification be read likewise. Therefore, the above description should not be construed as limiting, but merely as exemplifications of various embodiments. For example, the return electrode 200 may be at least partially coated with a positive temperature coefficient (PTC) material to help distribute the heat across the return electrode 200.