Surgery – Instruments – Electrical application
Reexamination Certificate
1999-05-11
2001-04-10
Dvorak, Linda C. M. (Department: 3739)
Surgery
Instruments
Electrical application
C606S041000, C606S045000, C606S049000
Reexamination Certificate
active
06214003
ABSTRACT:
FIELD OF THE INVENTION
This invention is related generally to an electrosurgical tool useful for performing surgical procedures. More particularly, this invention is related to an electrosurgical tool that has handle-mounted switches, is relatively easy to manufacture, provides an indication if fluid penetrates its handle and that has tip that fosters fluid circulation adjacent the surgical site to which it is applied.
BACKGROUND OF THE INVENTION
Electrosurgical tools have been used for a number of years to cut and shape tissue at the surgical sites to which these tools are applied. A typical electrosurgical tool has an elongated shaft with a handle at one end and a tip at the opposed end. One type of electrode surgical tool available to surgeons is referred to as a bipolar electrosurgical tool. An active electrode is fitted into the tip of this tool. The shaft of the bipolar electrosurgical tool functions as the return or reference electrode. The tool is applied to a surgical site at which there is a saline solution, a conductive fluid. A voltage is applied at a very high frequency, 50 kHz to 10 MHz, from the active electrode to the adjacent end of the shaft. This signal flows through, arcs through, the saline solution and the body tissue against which the tip is applied. When the signal is at a relatively low power, typically under 40 Watts, the signal can coagulate fluid such as blood to seal the tissue closed. When the signal is at a relatively high power, typically 20 Watts or more, it vaporizes the tissue to which it is applied so as to ablate, remove, the tissue. The overlap in the power ranges between the coagulation and ablation modes of operation is due to the fact that, for a given power setting, whether or not a particular electrode coagulates or ablates tissue is also a factor of the size and shape of the head of the electrode. Often, when an electrosurgical tool is used to ablate tissue, it is considered to be operated in the “cutting” mode.
Many currently available electrosurgical tools are designed so that mounted to the handles are switches for regulating the on/off state of the tool and the mode in which the tool is operated. The mounting of these switches to the tool handle makes it possible for the surgeon to, with a single hand, control both the position of the tool and the operation of the tool. The switches are typically mounted to the tool handle in liquid-tight seal assemblies. This mounting is necessary to prevent the conductive liquid that is often present in a surgical environment from entering the handle and shorting out any electrical components therein.
Presently available electrosurgical tools work reasonably well for the purposes for which they are designed. However, there are still some limitations associated with the currently available tools. Some of these limitations are due to the fact that, when an electrosurgical tool is operated in the ablation mode, bubbles form on the surface of the active electrode. One reason these bubbles form is that the electrical energy discharged by the electrode heats the conductive saline solution that surrounds the electrode. The heating of this solution causes it to vaporize and form bubbles. Initially, when relatively low levels of heat are present, the fluid immediately adjacent the surface of the electrode is subjected to thin film boiling and transitional boiling. In this type of vaporization, relatively small bubbles of gaseous state solution form.
However, when additional thermal or electromagnetic energy is radiated from the surface of the active electrode, the adjacent saline solution is subjected to rapid nucleate boiling. During nucleate boiling, relatively large bubbles of vaporized solution form on the surface of the electrode. These bubbles are sometimes referred to as gas pockets. Moreover, during some high powered cutting modes of operation, the electrical current applied to the solution and surrounding tissue causes electrochemical processes to occur in this tissue and liquid. These electrochemical processes produce gaseous state products that contribute the formation of large bubbles and the gas pockets.
At a minimum, these bubbles are a nuisance. The presence of these bubbles interfere with the surgeon's view of the surgical site. This is especially a problem when the electrosurgical tool is employed in an endoscopic surgical procedure. In an endoscopic procedure, the electrosurgical tool is applied to the surgical site through a small opening formed in the patient's body known as a portal. The surgeon views the surgical site through an endoscope which is directed to the surgical site through another portal. An advantage of an endoscopic surgical procedure in comparison to a conventional surgical procedure is that it requires less of the patient's body to be opened up in order to gain access to the surgical site. However, when a conventional electrosurgical tool is employed in an endoscopic surgical procedure, the bubbles generated in the relatively small confines of the space of the surgical site can significantly block the surgeon's view of the site.
Moreover, these bubbles are electrically and thermally insulating. The large bubbles that form gas pockets during high powered cutting can inhibit the flow of new solution that rewets the electrode. Consequently, the bubbles reduce the extent to which current can arc through the tissue that is to be ablated. Sometimes, these bubbles significantly reduce current flow through the tissue. The current flow stays in the reduced state until the bubbles collapse or move away and the saline solution or body fluid flows back into the space between the electrode and the shaft. Thus, sometimes when a presently available electrosurgical tool is actuated, the current only flows in a pulse pattern through the tissue to be ablated.
Moreover, many current electrosurgical tools are provided with wire wound electrodes. It is difficult to form wire wound electrodes so that they have heads with shapes that are especially useful for performing electrosurgical procedures.
Providing a seal around the handle switches can significantly add to the overall cost and assembly of the tool.
Also, sometimes, even with the best seals, there may be liquid leakage into the handle of an electrosurgical tool. This leakage, if not promptly detected can, at a minimum, lead to the degradation of the tool performance. In a worse case scenario, this leakage can cause a conductive path to develop along the outer surface of the handle. If this occurs, the personnel handling the tool may be subjected to electrical shock.
SUMMARY OF THE INVENTION
This invention is related generally to a new and useful electrosurgical tool. The tool of this invention has a tip assembly with an electrode that facilitates the flow of conductive fluid to constantly rewet the active electrode during low powered operation as well as the eduction of large bubbles/gas pockets away from electrode during higher powered operation. More specifically, the tip assembly is designed to foster convective fluid circulation around the surfaces of the electrode that constantly rewets those surfaces and transports the larger bubbles away from the electrode. This circulation also serves to clean debris away from the electrode. In order to foster this fluid flow, the electrode and a complementary insulator of the tip assembly of this invention are formed with portals through which this fluid flows.
The tool of this invention also has a handle, a nose cone, in which the circuitry internal to the tool is mounted on a printed circuit board. A leak detect circuit is located on the periphery of the printed circuit board. A complementary control console continually monitors the signal from this leak detect circuit. The switches integral with the nose cone include static components that are mounted on the printed circuit board. The switches have moving components that are integrally formed on a web that is fitted to the nose cone. The web is designed to self-seal into place when mounted to the nose cone.
REFER
Morgan Roy
Saravia Heber
Voges Jens
Dvorak Linda C. M.
Flynn ,Thiel, Boutell & Tanis, P.C.
Kearney R.
Stryker Corporation
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