Systems and methods for cleaning body cavities are presented. Some embodiments reduce size of fecal matter pieces within an evacuation conduit. Some comprise devices and methods for purging an evacuation conduit. Some comprise reduced cross-sectional profiles of a cleaning device. Some protect intestinal tissue by preventing exposure to excessively high and low pressures.

A vacuum motor comprising a working plunger, an internal space, in which the working plunger is arranged such that it is mobile in linear direction, a resetting element that exerts, at least for part of the time, a force on the working plunger that acts in the direction of a front side of the internal space, a gas inlet opening for supplying ambient air or a compressed gas into the internal space, and a gas outlet opening for discharging the gas from the internal space. The gas outlet opening is connectable to a negative pressure source, whereby a control plunger is arranged between the working plunger and a rear side of the internal space such as to be mobile in linear direction in the internal space. The control plunger is supported as in a bearing such as to be mobile with respect to the working plunger, and a catch element and/or a spacer is arranged on said working plunger and/or control plunger, whereby the catch element, upon a motion of the working plunger towards the front side of the internal space, transfers the control plunger into the first position, and whereby the catch element or the spacer, upon a motion of the working plunger towards the rear side of the internal space, transfers the control plunger into the second position.

In one aspect of the invention, a medical fluid pumping system and method of pumping medical fluid are provided. The medical fluid pumping system includes a medical fluid pump chamber. A fluid exchange conduit is fluidly coupled to the medical fluid pump chamber. At least one pump configured to pump medical fluid to and drain medical fluid from a cavity of a patient via a patient line is coupled to the fluid exchange conduit. A pump controller is communicably coupled to the at least one pump. The pump controller is configured to cause the pump to transmit fluid pulses.

A nozzle (12) for an oral irrigator device (10) having a guidance tip (34) with an orifice at one end, and a dynamic nozzle actuator (64) positioned within said guidance tip. The orifice (36) is configured to expel a fluid as one of a jet, a spray, or any combination thereof. The dynamic nozzle actuator (64) comprises at least one responsive material adapted for being energized and configured to implement at least one dynamic actuation of an effective channel (62) for dynamically influencing at least one of (i) a direction of fluid expelled from the orifice (36), (ii) an angle of fluid expelled from the orifice (36), (iii) a cross-sectional width of fluid expelled from the orifice (36), and (iv) any combination thereof.

The present application relates to a hydraulic assembly (100) of a generator of medium-pressure and high-pressure pulsed or non-pulsed jets comprising a hydraulic pipe: (101) comprising a flexible deformable zone (103) that can have a state of rest and a shut-off state, and a unit (102) configured to hold the hydraulic pipe (101) and comprising a first clamp (110) and a second clamp (111) holding the hydraulic pipe (101) on each side of the flexible deformable zone (103), and an open space (112) defined between the first clamp (110) and the second clamp (111).

The invention is directed to providing, at the exit from the nozzle of an irrigator, an intermittent gas-liquid jet for enabling effective cleaning, while being easy to use, A bulb (1) has an aerator introduced therein which is in the form of a tubular element (7) with open tips (71, 72) and a perforation region (73) in the side wall of the element (7), the region having at least one hole. The end of the tubular element (7) on the open-ended side is freely disposed in the cavity of the bulb (1), and the tip (71) is disposed with clearance from the base of the bulb.

A fluid ejection device includes: a fluid ejection unit that ejects a fluid in a pulsed manner; a fluid accommodation portion that accommodates the fluid at a predetermined pressure or higher; a fluid supply unit that supplies the fluid accommodated in the fluid accommodation portion to the fluid ejection unit; a connection channel that connects the fluid ejection unit and the fluid accommodation portion, and acts as a channel through which the fluid flows; an opening and closing unit that opens and closes the connection channel; and a control unit that sends an open signal for opening the connection channel to the opening and closing unit, and sends an ejection signal for ejecting the fluid to the fluid ejection unit. The control unit sends the ejection signal after a predetermined amount of time has elapsed from the sending of the open signal.

A fluid ejection device includes a fluid ejection unit that ejects a fluid, an ejection control unit that receives a fluid ejection command input, and controls the ejection of the fluid from the fluid ejection unit, a fluid container that accommodates the fluid to be supplied to the fluid ejection unit; and a supply control unit that controls the supply of the fluid from the fluid container to the fluid ejection unit, and determines whether the fluid can be supplied to the fluid ejection unit from the fluid container. When the supply control unit determines that the fluid cannot be supplied even after the ejection command input is received, and then a predetermined amount of time has elapsed, the ejection control unit reports a fault, and prohibits the fluid ejection unit from ejecting the fluid until the ejection command input is canceled.

A system for catheter-based aspiration includes an aspiration catheter having a distal portion configured for insertion within a blood vessel of a subject, the aspiration catheter including an aspiration lumen having a distal opening at the distal portion of the aspiration catheter, an injection lumen having a distal end at the distal portion of the aspiration catheter, and an orifice located at or near the distal end of the injection lumen, the orifice configured to direct liquid into the aspiration lumen at or near the distal opening of the aspiration lumen; an injector configured to pressurize the liquid within the injection lumen, such that liquid exits the orifice and enters the aspiration lumen; and a mechanical oscillator coupled to the injector and configured to cause a pulsatile pressure of the liquid as it is injected through the injection lumen.

Described herein are shock wave catheters and methods of use thereof for delivering an active agent of a drug to the CNS via a body lumen or cavity, such as sinonasal cavity, which can bypass the blood-brain barrier (BBB). The catheters described herein can be advanced through an intranasal passage to the nasal cavity such that at least a portion of the enclosure is disposed in the nasal cavity. The enclosure can be coated with a drug coating. The method can include filling the enclosure with a conductive fluid. At least one shock wave can be generated at a shock wave emitter of the catheter disposed within the enclosure. The at least one shock wave can cause a therapeutically effective amount of the active agent of the drug coating to be delivered to the CNS via tissue of the nasal cavity, in turn, treating central nervous system diseases.