Various forms of anti-clog suction tips apparatus are disclosed. An exemplary anti-clog suction tip apparatus includes a suction tip assembly having a suction tip with a suction opening at a first end thereof for removing debris through suction, a hose attachment portion for attaching the suction tip assembly to a suction source, and an ejection wire channel. The apparatus further includes an ejection wire assembly having an ejection wire extending within the channel and an ejection button integral with or connected to the ejection wire. Applying a force to the ejection button advances the ejection wire through the channel such that an end portion of the ejection wire enters the suction tip and dislodges debris clogging the suction tip. The ejection wire may include an enlarged end portion such as, for example a ball tip. One or more of the components of the apparatus may be single-use and disposable.

An anti-clog suction tip apparatus includes a suction tip having a suction opening and an interior defining a suction channel. An ejection wire channel extends to a wire exit opening into the suction channel that is located proximate the suction opening. An ejection wire including a ball tip at an end thereof occupies the ejection wire channel and is transitionable between a retracted configuration and an advanced configuration such that, in the retracted configuration, the ejection wire including the ball tip is retained within the ejection wire channel and does not obstruct suctioning of debris through the suction channel; and in the advanced configuration, the ball tip of the ejection wire does not extend more than three millimeters beyond the suction opening.

A method and a kit for the prevention of venous stenosis associated with the use of hemodialysis AV shunts. The kit may use a bifurcated needle for providing access to the shunt or blood vessel. One of the arms is used for returning the blood to the subject after dialysis treatment, while the other arm is used for inserting a device for cleaning the vein, the device being either an autonomous crawling device, or a passive tethered device moved down the vein by the blood flow. The autonomous crawling device may be a series of sequentially inflatable chambers, the stenosis being cleared by pressure from the outer walls of the chambers when inflated and moved. The passive device may be an element having a flexible disc-like structure, whose flexible peripheral edge slides along the inner walls of the blood vessel, compressing or clearing the material attached thereto.

A drainage and/or collection system (1) for biological fluids includes at least one conduit (40) for transporting a biological fluid (F) from a catheter (10) to a collection device (50) and a gas pressure source (70) configured to feed a gas (G) into the at least one conduit (40) between the catheter (10) and the collection device (50). The gas (G) causes the biological fluid (F) arranged in the at least one conduit (40) to drain into the collection device (50). A method includes inserting a catheter (10), draining a fluid (F) into a collection device (50) via a conduit (40), and introducing gas (G) into the conduit (40) so as to force fluid (F) remaining in the conduit (40) into the collection device (50).

A device for moving contents of a tube by acting on the exterior of the tube is provided. The device includes a housing having a top portion and a bottom portion, the top portion including a tube passageway extending along a length thereof for holding a tube therein. A roller housed within a roller chassis contacts the tube and is configured to move between a first position in which the tube is disengaged and a second position in which the tube is engaged. A second roller is rotatably coupled to an actuator for rotatably energizing the second roller and is moveable between a first position in which the tube is disengaged and a second position in which the tube is engaged. A lever is operably coupled to the housing and configured to actuate a motor to move the second roller to the second position. The first roller and the second roller are configured to compress the tube to move contents within the tube.

A surgical instrument has a hollow tubular member, and a pressurization unit that has an outer valve portion, a pressurization device having a movable part configured to generate pressurized fluid when the movable part is moved, and an inner valve portion. The inner valve portion includes a first flow passage that is configured to fluidically connect a first port and a second port of the outer valve portion to each other when the inner valve portion is in a first position, and a second flow passage that is configured between the inner valve portion and the outer valve portion to fluidically connect the first port and a third port when the inner valve portion is in a second position. A sealing system fluidically isolates the second port and the third port from each other at any position of the inner valve portion. Pressurized fluid from the pressurization device causes the inner valve portion to move from the first position to the second position, thereby providing positive pressure to the hollow tubular member.

An anti-clog suction tip apparatus includes a suction tip having a suction opening and an interior defining a suction channel. An ejection wire channel extends to a wire exit opening into the suction channel that is located proximate the suction opening. An ejection wire including a ball tip at an end thereof occupies the ejection wire channel and is transitionable between a retracted configuration and an advanced configuration such that, in the retracted configuration, the ejection wire including the ball tip is retained within the ejection wire channel and does not obstruct suctioning of debris through the suction channel; and in the advanced configuration, the ball tip of the ejection wire does not extend more than three millimeters beyond the suction opening.

Various forms of anti-clog suction tips apparatus are disclosed. An exemplary anti-clog suction tip apparatus includes a suction tip assembly having a suction tip with a suction opening at a first end thereof for removing debris through suction, a hose attachment portion for attaching the suction tip assembly to a suction source, and an ejection wire channel. The apparatus further includes an ejection wire assembly having an ejection wire extending within the channel and an ejection button integral with or connected to the ejection wire. Applying a force to the ejection button advances the ejection wire through the channel such that an end portion of the ejection wire enters the suction tip and dislodges debris clogging the suction tip. The ejection wire may include an enlarged end portion such as, for example a ball tip. One or more of the components of the apparatus may be single-use and disposable.

A method and a kit for the prevention of venous stenosis associated with the use of hemodialysis AV shunts. The kit may use a bifurcated needle for providing access to the shunt or blood vessel. One of the arms is used for returning the blood to the subject after dialysis treatment, while the other arm is used for inserting a device for cleaning the vein, the device being either an autonomous crawling device, or a passive tethered device moved down the vein by the blood flow. The autonomous crawling device may be a series of sequentially inflatable chambers, the stenosis being cleared by pressure from the outer walls of the chambers when inflated and moved. The passive device may be an element having a flexible disc-like structure, whose flexible peripheral edge slides along the inner walls of the blood vessel, compressing or clearing the material attached thereto.

A wound therapy system and method for clearing fluids from a conduit includes a wound dressing apparatus, a pneumatic pump, a valve, and a controller. The wound dressing apparatus is fluidly coupled to a wound, the pump, and the valve. The controller is configured to determine a volume of instillation fluid that has been delivered to the wound, to operate the pneumatic pump and the valve to apply a negative pressure to the wound dressing apparatus to purge a first portion of the instillation fluid, and to operate the pneumatic pump and the valve during a purge operation to deliver a volume of air through the wound dressing apparatus that is approximately equal to or greater than the volume of instillation fluid to purge a second portion of the instillation fluid from the wound dressing apparatus.