Abstract: A removable applicator nozzle for use in treating a wound is provided. The removable applicator nozzle includes a nozzle, a valve and a cup. The nozzle includes a proximal portion, a distal opening and a valve interface. The proximal portion of the nozzle is engagable with a portion of a transducer of an ultrasound wound therapy device. The distal opening of the nozzle allows at least a portion of a tip of the transducer to pass therethrough. The valve is engagable with the valve interface of the nozzle and the valve selectively allows fluid to flow therethrough. The cup includes an aperture and a puncturing device. The aperture is engagable with the valve and the puncturing device is able to puncture a bottle that is inserted on the cup. Fluid flows from the bottle, through the aperture and the valve and onto a tip of the transducer. The fluid is then moved to the distal opening of the nozzle by a vacuum effect.

Abstract: A medical ultrasound apparatus and associated methods of use is disclosed enabling a relatively non-invasive or minimally invasive method to treat skin or tissue. The apparatus is constructed from an ultrasound tip mechanically coupled to a shaft. The shaft is mechanical coupled to an ultrasound transducer driven by an ultrasound generator. The ultrasound tip possesses at least one radial surface, a cavity, or some other form of a hollowed out area, within at least one of the radial surfaces, and a non-metallic sheath covering portions of the tip so that only the sheath and not the tip would normally contact the patient's skin. The disclosed method of treating spider, reticular or small varicose veins with the apparatus can be practiced by contacting the sheath with the patient's epidermal skin layers and delivering ultrasonic energy released from the various surfaces of the vibrating tip to the skin and/or tissue through direct contact and/or with a coupling fluid focused from a cavity.

Abstract: A medical ultrasound apparatus and associated methods of use is disclosed enabling a relatively non-invasive or minimally invasive method to treat skin or tissue. The apparatus is constructed from an ultrasound tip mechanically coupled to a shaft. The shaft is mechanical coupled to an ultrasound transducer driven by an ultrasound generator. The ultrasound tip possesses at least one radial surface, a cavity, or some other form of a hollowed out area, within at least one of the radial surfaces, and a non-metallic sheath covering portions of the tip so that only the sheath and not the tip would normally contact the patient's skin. The disclosed method of treating spider, reticular or small varicose veins with the apparatus can be practiced by contacting the sheath with the patient's epidermal skin layers and delivering ultrasonic energy released from the various surfaces of the vibrating tip to the skin and/or tissue through direct contact and/or with a coupling fluid focused from a cavity.

Abstract: The method and device of the present invention for pain relief using ultrasound waves in combination with cryogenic energy includes a generator and a transducer to produce ultrasonic waves and a cryogenic source to produce cryogenic energy. Ultrasound waves are delivered to the target in combination with cryogenic energy. Ultrasound waves and cryogenic energy can be delivered to the target from the radial side of the ultrasound horn and/or tip or can be delivered from the distal end of the ultrasound tip. Cryogenic energy can also be delivered directly to the target through a central orifice. Ultrasound energy can also be delivered through a cryogenic spray at the distal end. The use of ultrasound waves in combination with cryogenic energy can provide an analgesic effect.

Abstract: The present invention relates to an ultrasound assisted cryogenic surgical instrument, more particularly, to methods and devices utilizing ultrasound energy for treatment of the endometrium to control heavy uterine bleeding (menorrhagia) or other conditions. The device of the present invention comprises an ultrasound generator, an ultrasound transducer, a transducer tip at the distal end of the ultrasound transducer, and a radiation surface. Ultrasonic radiation is directed into the tissue being ablated. A cryogenic solution is circulated through the ultrasound tip to transfer thermal energy away from the tissue to freeze the tissue being ablated by providing a synergistic effect with the ultrasonic radiation.

Abstract: An ultrasound assisted liquid blade cutting device such as a scalpel that may be used for routine surgical operations is disclosed in this invention. The ultrasound scalpel comprises an ultrasound generator, ultrasound transducer, transducer tip, a cavity on the transducer tip using a liquid spray shaped to form a cutting surface. The spray serves as a carrier medium for the applied ultrasound energy which enhances the features and performance of the scalpel. Ultrasonic energy transmitted from the transducer tip assists the transport of the liquid to a liquid blade formed outside of the cavity. The ultrasound energy focuses and activates the liquid to allow cutting of tissue with the liquid blade. This device may be utilized for cutting through skin and/other soft tissues during surgical operations, thereby enhancing cutting efficacy, decreasing and/or eliminating necrosis formation.

Abstract: An ultrasound assisted liquid blade cutting device such as a scalpel that may be used for routine surgical operations is disclosed in this invention. The ultrasound scalpel comprises an ultrasound generator, ultrasound transducer, transducer tip, a cavity on the transducer tip using a liquid spray shaped to form a cutting surface. The spray serves as a carrier medium for the applied ultrasound energy which enhances the features and performance of the scalpel. Ultrasonic energy transmitted from the transducer tip assists the transport of the liquid to a liquid blade formed outside of the cavity. The ultrasound energy focuses and activates the liquid to allow cutting of tissue with the liquid blade. This device may be utilized for cutting through skin and/other soft tissues during surgical operations, thereby enhancing cutting efficacy, decreasing and/or eliminating necrosis formation.

Abstract: The present invention relates to an ultrasound assisted cryogenic surgical instrument, more particularly, to methods and devices utilizing ultrasound energy for treatment of the endometrium to control heavy uterine bleeding (menorrhagia) or other conditions. The device of the present invention comprises an ultrasound generator, an ultrasound transducer, a transducer tip at the distal end of the ultrasound transducer, and a radiation surface. Ultrasonic radiation is directed into the tissue being ablated. A cryogenic solution, is circulated through the ultrasound tip to transfer thermal energy away from the tissue to freeze the tissue being ablated by providing a synergistic effect with the ultrasonic radiation.

Abstract: The present invention relates to ultrasound assisted tissue welding, more particularly, to a method and device utilizing ultrasound energy for effective closure and sealing of surgical incisions or other wounds. The device of the present invention comprises an ultrasound generator, an ultrasound transducer, a transducer tip at the distal end of the ultrasound transducer, and a radiation surface. A web such as gauze is placed over the incision. In an embodiment, the device may be used to bring the edges of the tissue to be sealed together as the device applies energy to the tissues. Ultrasonic waves emanating from the radiation surface pass through the web and seal the incision creating a continuous seam. The device may be used with or without additional adhesive materials or therapeutic agents.

Abstract: The present invention relates to ultrasound assisted tissue welding, more particularly, to a method and device utilizing ultrasound energy for effective closure and sealing of surgical incisions or other wounds. The device of the present invention comprises an ultrasound generator, an ultrasound transducer, a transducer tip at the distal end of the ultrasound transducer, and a radiation surface. A web such as gauze is placed over the incision. In an embodiment, the device may be used to bring the edges of the tissue to be sealed together as the device applies energy to the tissues. Ultrasonic waves emanating from the radiation surface pass through the web and seal the incision creating a continuous seam. The device may be used with or without additional adhesive materials or therapeutic agents.

Abstract: The invention discloses methods and devices to energize a portable carrier media which may be applied to a person's skin to provide pain relief. The carrier media may be recharged at an energizing station that ultrasonically activates the carrier media, such as a credit card, so that the plastic is energized by the exposure to the ultrasound into an activated state. The credit card can then held against the user's body to provide localized pain relief. If desired, the energized carrier media may be stored until needed in a suitable storage container such as a plastic bag or envelope. The energized carrier media is preferably held against the user's body with a suitable media attachment mechanism such as adhesive, tape or an elastic strap, however, the carrier media may be simply hand held in place for short periods of time.

Abstract: An ultrasound scalpel that may be used for surgical operations is disclosed in this invention. The ultrasound scalpel comprises an ultrasound generator, housing, transducer horn, retaining member and scalpel blade. The device is able to utilize sharp stainless steel surgical blades amenable to being produced as disposable single-use replacement blades. Ultrasonic energy transmitted from transducer horn to surgical blade causes bending waves to be created due to the off-center attachment and/or placement of the surgical blade. This device may be utilized for cutting through skin and/other soft tissues during surgical operations, thereby enhancing cutting efficacy, decreasing and/or eliminating necrosis formation.

Abstract: The present invention relates to the use of a low frequency ultrasonic device for the delivery and activation of collagen based foam sealants to a human and/or animal patient for sealing puncture wounds in vascular tissues. The ultrasonic vascular closure method relates to an ultrasonic generator, an ultrasound transducer, a chamber containing a foam sealant, a transducer tip, a radiation surface, an orifice located at the distal end of the chamber. The foam sealant is ejected into a puncture wound and activated with ultrasonic waves emitting from the radiation surface. The ultrasonic waves induce vibrations within the foam sealant, slightly warming the foam sealants to assist the rapid sealing the puncture. The ultrasonic waves also provide and anesthetic effect for the pain and discomfort from the puncture site.

Abstract: An ultrasound scalpel that may be used for surgical operations is disclosed in this invention. The ultrasound scalpel comprises an ultrasound generator, housing, transducer horn, retaining member and scalpel blade. The method of use of the device is able to utilize sharp stainless steel surgical blades amenable to being produced as disposable single-use replacement blades. Ultrasonic energy transmitted from transducer horn to surgical blade causes bending waves to be created due to the off-center attachment and/or placement of the surgical blade. This device may be utilized for cutting through skin and/other soft tissues during surgical operations, thereby enhancing cutting efficacy, decreasing and/or eliminating necrosis formation.

Abstract: The present invention relates to the use of a low frequency ultrasonic device for the delivery and activation of collagen based foam sealants to a human and/or animal patient for sealing puncture wounds in vascular tissues. The ultrasonic vascular closure device comprises an ultrasonic generator, an ultrasound transducer, a chamber containing a foam sealant, a transducer tip, a radiation surface, an orifice located at the distal end of the chamber. The foam sealant is ejected into a puncture wound and activated with ultrasonic waves emitting from the radiation surface. The ultrasonic waves induce vibrations within the foam sealant, slightly warming the foam sealants to assist the rapid sealing the puncture. The ultrasonic waves also provide and anesthetic effect for the pain and discomfort from the puncture site.

Abstract: An ablative apparatus and associated methods that can be used to treat atrial fibrillation and other cardiac arryhythmias by ablating cardiac tissue is disclosed. When the distal end of the apparatus reaches the tissue to be ablated, an ablation probe driven by a transducer is vibrated. Scratching the tissue with abrasive members, the vibrating ablation probe is capable of mechanically ablating tissues. This mechanical ablation may be utilized to penetrate epicardial fat, thereby exposing the underlying myocardium. The ablative apparatus may then be used subject the exposed myocardium to mechanical ablation, cryoablation, ultrasonic ablation, and/or any combination thereof.

Abstract: This invention discloses deflector shields to protect an operator from splashing from the use of hand-held ultrasound wound care devices. The deflector shield is for use with an ultrasound generator, ultrasound tip with a radiation surface and a fluid to serve as a coupling medium between the radiation surface and wound surface. The deflector shield is used to protect the operator from splashing fluid and removed tissue. The deflector shield consists of a hub portion and conical portion. The deflector shield is preferably transparent, disposable and easily installed. The deflector shield is preferably useable on several hand-held ultrasound wound care devices.

Abstract: An ablative apparatus that can be used to treat atrial fibrillation and other cardiac arrhythmias by ablating cardiac tissue is disclosed. When the distal end of the apparatus reaches the tissue to be ablated, an ablation probe driven by a transducer is vibrated. Scratching the tissue with abrasive members, the vibrating ablation probe is capable of mechanically ablating tissues. This mechanical ablation may be utilized to penetrate epicardial fat, thereby exposing the underlying myocardium. The ablative apparatus may then be used subject the exposed myocardium to mechanical ablation, cryoablation, ultrasonic ablation, and/or any combination thereof.

Abstract: An ultrasound atomization apparatus including an ultrasound transducer, a horn attached to the distal end of the transducer, a chamber within the horn that receives a fluid to be atomized, a radiation surface, and a channel leading from the chamber to the radiation surface. Vibrations produced by the transducer travel down the horn to the radiation surface. The vibrations induce the release of energy into the fluid to be atomized as it travels through the horn's internal chamber and exits the horn at the radiation surface. Controllably increasing the kinetic energy of the fluid, energy emitted into the fluid assists and/or drives fluid atomization. Assisting and/or driving fluid atomization by utilizing vibrations to increase the kinetic energy of the fluid, the ultrasound atomization apparatus can preserve a desired spray pattern when changing environmental conditions would otherwise destroy the spray pattern and/or reduce atomization.

Abstract: An ultrasound apparatus capable of mixing and/or atomizing fluids is disclosed. The apparatus includes a horn having an internal chamber through which fluids to be atomized and/or mixed flow. Connected to the horn's proximal end, a transducer powered by a generator induces ultrasonic vibrations within the horn. Traveling down the horn from the transducer, the ultrasonic vibrations induce the release of ultrasonic energy into the fluids to be atomized and/or mixed as they travel through the horn's internal chamber. As the ultrasonic vibrations travel through the chamber, the fluids within the chamber are agitated and/or begin to cavitate, thereby mixing the fluids. Upon reaching the front wall of the chamber, the ultrasonic vibrations are reflected back into the chamber, like an echo. The ultrasonic vibrations echoing off the front wall pass through the fluids within the chamber a second time, further mixing the fluids.