An oral irrigator has a separate high pressure water system and low pressure mouth rinse system to deliver two different fluids to a pick or other accessories. The water system and mouth rinse system are combined in a handle. The pick is connected to the handle. The water system has a blocking valve located in the handle and the mouth rinse system has a hand pump located in the handle. The hand pump sits next to a valve button for closing the blocking valve. When the hand pump is pressed, it presses against the valve button of the blocking valve to shut off the source of high pressure water to the pick. The pressure in the pick drops so that the hand pump can then introduce mouth rinse into the pick. When the hand pump is released, the blocking valve opens up and high pressure water returns to the pick.

A treatment system for debriding a treatment area of a tissue site and applying negative pressure is disclosed. In some embodiments, the treatment system may include an ultrasonic bubble generator fluidly coupled to a negative-pressure source, fluid source, and a dressing. Fluid may be drawn from the fluid source to the ultrasonic bubble generator, whereby micro-bubbles and ultrasonic waves may be generated in the fluid before the fluid is instilled to the dressing.

A system and method to irrigate a user's auditory canal. A fluid can be dispensed from a reservoir through a fluid path and out through openings of a delivery element into the auditory canal. A pump may be used to facilitate the process of dispensing the fluid. The fluid can be delivered to the user's auditory canal for a predetermined period of time. Such a time period may be user selectable. The discharge from the irrigation is removed from the user's auditory canal via a discharge port located on the delivery element. The discharge exits the delivery element and proceeds to a discharge reservoir via a discharge path. A vacuum may be used to generate a negative pressure to facilitate the removal of the discharge from the auditory canal.

Methods and systems for delivering fluids, aerosols, and/or acoustic energy to target sites on tissue surfaces and within body cavities or lumens, obstructions or undesired materials associated with body cavities and tissue surfaces and, particularly, target sites on tissue surfaces or at obstructions within natural orifices, such as ear, nose and throat passages and, particularly, nasal passages and cavities, are provided. Delivery of acoustic energy may be accomplished using a flexible, expandable member adapted to be expanded at a target site using an acoustically transmissive material for delivery of acoustic energy to tissue surfaces in irregularly configured tissue cavities and passageways.

A canister stand suitable for holding at least one dispensing canister in a system for removal, delivery and/or transplantation of body tissues and other substances in medical procedures may include a canister stand frame. A frame panel may be carried by the canister stand frame. At least one overhang may be formed by the canister stand frame. At least one canister opening may be provided in the frame panel at the at least one overhang. The at least one canister opening may be suitably sized and configured to accommodate the at least one dispensing canister.

A pneumatic vibrational injection apparatus suitable for use in a system for removal, delivery and/or transplantation of body tissues and other substances in medical procedures may include an apparatus housing having an air inlet chamber, an air outlet chamber, a connecting chamber connecting the air outlet chamber and the air inlet chamber and an injection chamber disposed between the air inlet chamber and the air outlet chamber. An injection nozzle may be disposed in fluid communication with the injection chamber. An injection cannula may be disposed in fluid communication with the injection nozzle. An inlet transducer wheel and an outlet transducer wheel may be mounted for rotation in the air inlet chamber and the air outlet chamber, respectively, of the apparatus housing. A vibration transducer may be disposed in physical contact with the inlet transducer wheel and the outlet transducer wheel. The injection nozzle may be disposed in physical contact with the vibration transducer.

A vibrational injection apparatus suitable for use in a system for removal, delivery and/or transplantation of body tissues and other substances in medical procedures may include an apparatus housing. A vibration mechanism may be provided in the apparatus housing. A material injector may be provided in the apparatus housing and mechanically coupled to the vibration mechanism. An injection cannula may be disposed in fluid communication with the material injector.

A pneumatic vibrational injection apparatus suitable for use in a system for removal, delivery and/or transplantation of body tissues and other substances in medical procedures may include an apparatus housing having an air inlet chamber, an air outlet chamber, a connecting chamber connecting the air outlet chamber and the air inlet chamber and an injection chamber disposed between the air inlet chamber and the air outlet chamber. An injection nozzle may be disposed in fluid communication with the injection chamber. An injection cannula may be disposed in fluid communication with the injection nozzle. An inlet transducer wheel and an outlet transducer wheel may be mounted for rotation in the air inlet chamber and the air outlet chamber, respectively, of the apparatus housing. A vibration transducer may be disposed in physical contact with the inlet transducer wheel and the outlet transducer wheel. The injection nozzle may be disposed in physical contact with the vibration transducer. A syringe plunger may slidably engage the injection chamber in the apparatus housing.

A pump includes a cylinder, a piston and a controller. The cylinder has first and second ends and includes first and second inlet-outlet ports, each of the first and second inlet-outlet ports is configured to alternately intake a fluid to the cylinder and output the fluid from the cylinder. The piston is configured to be moved within the cylinder between the first and second ends by alternately reversing a direction of movement of the piston, so as to pump the fluid through the first and second inlet-outlet ports. The controller is configured to control the movement of the piston within the cylinder, including: (a) choosing between first and second operational modes, (b) in the first operational mode, controlling the piston to oscillate over a predefined interval that does not exceed a predefined distance from the first end or from the second end, and (c) in the second operational mode, controlling the piston to move at a selected speed between the first end and the second end.

A system and method to irrigate a user's auditory canal. A fluid can be dispensed from a reservoir through a fluid path and out through openings of a delivery element into the auditory canal. A pump may be used to facilitate the process of dispensing the fluid. The fluid can be delivered to the user's auditory canal for a predetermined period of time. Such a time period may be user selectable. The discharge from the irrigation is removed from the user's auditory canal via a discharge port located on the delivery element. The discharge exits the delivery element and proceeds to a discharge reservoir via a discharge path. A vacuum may be used to generate a negative pressure to facilitate the removal of the discharge from the auditory canal.