Ultrasonic soft tissue cutting and coagulation systems including a retractable grasper

The present invention features an ultrasonic surgical system including an ultrasonically vibrating blade, and retractable grasper. The grasper includes a grasping jaw or clamp that is movable, in a direction perpendicular to the primary vibratory mode of the ultrasonic blade element, from an open, extended position to a closed position in which tissue is grasped between the jaw and the vibrating blade, and to a retracted position for storage. The jaw is preferably hinge-actuated.

STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH

Not Applicable

REFERENCE TO MICROFICHE APPENDIX

Not Applicable

BACKGROUND OF THE INVENTION

For many years, ultrasonic surgical instruments have been used for soft tissue cutting and coagulation. These ultrasonic instruments include ultrasonic transducers which convert the electric energy supplied by a generator into ultrasonic frequency vibratory energy, which can then be applied to the tissue of a patient. Ultrasonic surgical instruments use relatively high-power, low-frequency vibratory energy, typically at a frequency range of about 20 kHz to about 100 kHz.

In general, ultrasonic soft tissue cutting and coagulation systems include a member that is coupled to the ultrasonic transducers, and that can be made to vibrate at ultrasonic frequencies. The ultrasonically vibrating probe is then applied to the tissue, in order to transmit ultrasonic energy to the tissue. In this way, the contacted tissue can be cut or coagulated. Ultrasonic surgical systems offer a number of advantages over conventional surgical systems, for example reduction of bleeding and trauma.

The mechanism through which the ultrasonic probe and the tissue interact, i.e. the physics of ultrasonic soft tissue cutting and coagulation, is not completely understood, however various explanations have been provided by researchers over the years. These explanations include descriptions of mechanical effects and thermal effects. The mechanical viewpoint states that the vibrating tip of the ultrasonic probe generates short-range forces and pressures, which are sufficient to dislodge cells in the tissue, and break up the tissue structures. Various types of forces are postulated as contributing to the rupture of the tissue layer, for example the impact forces resulting from the direct contact of the vibrating tip with tissue, and the shear forces that are the result of the differences in force levels across tissue boundaries. Some energy may be lost due to frictional heating, and by the heating caused by the absorption of acoustic energy by tissue.

Thermal effects may include frictional heat, generated by the ultrasonically vibrating tip, in an amount sufficient to melt a portion of the contacted tissue. Alternatively, the tissue may absorb the vibratory energy, which it then converts into heat. The generated heat may be used to coagulate a blood vessel, by way of example. Other effects that have been postulated in order to explain the probe-tissue interaction include cavitational effects. The cavitation viewpoint postulates that the coupling of ultrasonic energy onto tissue results in the occurrence of cavitation in tissue, namely the formation of gas or vapor-filled cavities or bubbles within the tissue, which may oscillate and propagate. A combination of mechanical, thermal, and cavitational effects may result in the desired surgical outcomes, such as cutting and coagulation.

A number of ultrasonic soft tissue cutting and coagulating systems have been disclosed in the prior art. For example, U.S. Pat. No. 5,322,055 (the “'055 patent”), assigned on its face to Ultracision, Inc., discloses ultrasonic surgical instruments having a non-vibrating clamp for pressing tissue against an ultrasonically vibrating blade, for cutting, coagulating, and blunt-dissecting of tissue. When ultrasonically activated, the blade undergoes longitudinal mode vibrations, parallel to the blade edge. U.S. Pat. No. 6,036,667 (the “'667 patent”), assigned on its face to United States Surgical Corporation and to Misonix Incorporated, discloses an ultrasonic dissection and coagulation system. The ultrasonic system includes an ultrasonic cutting blade, and a clamp member for clamping tissue in conjunction with the blade. The blade has a cutting surface that is angled with respect to the longitudinal axis of the elongated body portion of the system.

U.S. Pat. No. 6,056,735 (the “'735 patent”), assigned on its face to Olympus Optical Co., Ltd., relates to ultrasonic treatment systems, including endoscopic systems and aspiration systems, for treating living tissue. The '735 patent features an ultrasonic treatment system including a probe which conveys ultrasonic vibrations to a stationary distal member. The stationary distal member cooperate with a movable holding member to clamp or free tissue, when manipulated by a scissors-like manipulating means.

In the prior art patents discussed above, the ultrasonically vibrating member must cooperate with a clamp or jaw, in order to grasp the tissue that is being treated. It is desirable to provide systems having a blade/jaw assembly, in which the ultrasonically vibrating member can operate (in conjunction with the jaw) without having to perform, by itself, a grasping function.

SUMMARY OF THE INVENTION

The present invention features an ultrasonic surgical system including a retractable grasper. The grasper includes a grasping jaw or clamp that is movable in a direction perpendicular to the primary vibratory mode of the ultrasonic blade element. The jaw is preferably hinge-actuated, and is operable to grasp tissue. The jaw is movable between an open, extended position, to a closed position in which the jaw presses against the blade element, in a direction substantially parallel to the direction of vibration of the blade. In this way, tissue is grasped between the jaw and the blade. The grasper allows the ultrasonic blade to be used without need for the blade itself to perform a grasping function.

DETAILED DESCRIPTION

The present invention is directed to an ultrasonic surgical system having a retractable grasper that allows an ultrasonically vibrating member to operate in conjunction with a jaw, without requiring the vibrating member itself to perform a grasping function.

FIG. 1illustrates an overall schematic view of an ultrasonic soft tissue cutting and coagulating system100, constructed in accordance with one embodiment of the present invention. The system include a handpiece102that encloses one or more ultrasonic transducers104. An ultrasonic generator is connected to the handpiece102, and supplies electric energy. The transducers104convert the supplied electric energy into ultrasonic frequency vibratory energy. The frequency range at which the system100operates is typically between about 20 kHz and about 100 kHz, and the electric power supplied by the ultrasonic generator is typically between about 100 W to about 150 W, although other frequencies and power levels can be used. The ultrasonic transducers104may be made of piezoelectric material, or may be made of other materials, such as nickel, that are capable of converting electric energy into vibratory energy. The handpiece102may also enclose an amplifier, for example an acoustic horn, which amplifies the mechanical vibrations generated by the ultrasonic transducers104.

An elongated ultrasonic transmission coupler106is connected to the handpiece102. In one embodiment, the transmission coupler106has a proximal end108and a distal end109, and is connected to the handpiece102at the proximal end. The ultrasonic transmission coupler106transmits the ultrasonic vibratory energy, received from the transducers104, from its proximal108end to its distal end109. In one embodiment, a sheath190may enclose the transmission coupler106.

In the illustrated embodiment, an ultrasonic surgical assembly110is connected to the distal end109of the elongated transmission coupler106, and includes an ultrasonic blade element112, and a retractable grasper113. Preferably, the blade element112includes an elongated blade edge197. The blade element112is acoustically coupled to the transmission coupler106, so that the ultrasonic energy is transmitted to, and carried by, the blade element112.

The blade element112undergoes vibratory motion upon receipt of ultrasonic vibrations from the transducer(s)104. The blade element112thereby delivers ultrasonic energy to the contacting tissue, so that desired surgical effects, such as cutting and/or coagulation, can be achieved. In one form of the invention, the blade element undergoes ultrasonic vibrations characterized by at least one primary vibratory mode. In one embodiment, the primary vibratory mode may be along a longitudinal direction substantially parallel to the blade edge. The retractable grasper113includes a grasping jaw114, which is operable to close against the blade element112, so as to engage tissue between their respective operative surfaces.

In one embodiment, the present invention is directed to an accessory for an ultrasonic surgical instrument having an ultrasonic transducer for generating ultrasonic vibrations, and an elongated ultrasonic transmission coupler connected to the transducer to receive ultrasonic vibrations therefrom. The accessory includes a clamp assembly connected to the transducer. The clamp assembly includes a blade element, and a retractable clamp jaw movable relative to the blade element. The clamp jaw is movable from an extended position to a closed position in which the blade element and the clamp jaw are in engagement so as to capture tissue therebetween. The clamp jaw is further movable to a retracted position, suitable for storing the accessory.

FIGS. 2A-2Cillustrate a grasper113, constructed according to one embodiment of the present invention. The grasper113is retractable and extendable, i.e. the grasping jaw114is movable from an extended position to a closed position in which the blade element and the jaw are in engagement so as to capture tissue therebetween, and is further movable to a retracted position.

The retracted position is shown in FIG.2A. When the ultrasonic system100is not in use, the grasper113can be stored in the retracted position. The grasper113in an extended state is illustrated in FIG.2B. In this configuration, the grasping jaw114lies along a horizontal direction substantially parallel to the primary longitudinal mode of vibration of the ultrasonic blade element.

Preferably, a jaw activating mechanism is provided for moving the jaw relative to the blade element, from the extended position to the closed position, and again to the retracted position. In one embodiment, the jaw activating mechanism is a hinge. In this embodiment, the grasping jaw is hinge-actuated, i.e. is pivotable about a pivot point196from an open position to a closed position in which the jaw closes against the ultrasonic blade so as to grasp tissue therebetween, and subsequently to a retracted position, for storage. In the extended state, the pivot point196is preferably aligned with the elongated edge197of the ultrasonic blade, and the grasping jaw114extends beyond the elongated edge, along the horizontal direction.

The jaw114is operable to move, in a direction substantially perpendicular to the primary vibratory mode of the ultrasonic blade, from the open, extended position described above to a closed position illustrated in FIG.2C.FIG. 2Cillustrates the hinge-actuated jaw that closes against the ultrasonic blade, so as to grasp tissue. As seen inFIG. 2C, the jaw closes against the blade in a direction substantially parallel to the direction of the ultrasonic vibrations. The tissue being treated is thereby grasped, between the jaw and the blade. In this way, tissue can be grasped, without requiring the ultrasonic blade by itself to perform a grasping function.