A system for safe radioisotope preparation and injection of H.sub.2.sup.15O for use in Positron Emission Tomography (PET). The disclosure also relates to a safety valve for controlling a flow of H215O for use in PET, to a use of said safety valve and to a method for preparing and injecting H.sub.2.sup.15O.

A system is described herein that can irrigate a tissue site using negative-pressure. The system may include a tissue interface configured to be placed adjacent to the tissue site, and a sealing member configured to be placed over the tissue interface to form a sealed space. The system may also include a negative-pressure source configured to be fluidly coupled to the sealed space and a fluid source. The system may further include an irrigation valve. The irrigation valve can have a fluid inlet configured to be fluidly coupled to the fluid source. The irrigation valve can also have a fluid outlet configured to be fluidly coupled to the sealed space. The irrigation valve may also include a clamp configured to be actuated by the negative-pressure source to regulate fluid flow from the fluid source through the fluid outlet.

This purge device comprises a connection element comprising a plurality of fluid flow channels which each comprise a proximal end, intended to be connected fluidically to a respective fluid flow conduit of a flow tube, and a distal end opposite the respective proximal end, and a plurality of fluid flow openings which are each connected fluidically to a respective fluid flow channel; a closure element comprising a fluid evacuation opening and a closure part, the closure element being mounted movably with respect to the connection element and being configured to occupy a plurality of closure positions, in each of which the closure part closes the distal end of a fluid flow channel and the fluid evacuation opening is connected fluidically to the fluid flow opening associated with the fluid flow channel, of which the distal end is closed by the closure part; and a connection nozzle intended to be connected to a catheter.

A bone cement delivery system includes a plunger configured to selectively displace bone cement from a cement reservoir through an exit port. Additionally, the system includes a flow diverter comprising a diverter inlet, a first diverter outlet, and a second diverter outlet. The system also includes a cannula coupler configured for connection to a delivery cannula for directing the bone cement to a target site, and a drool accumulator defining a drool volume for receiving residual bone cement. The flow diverter includes a valve arranged for selective movement between a first configuration where fluid communication is established between the cement reservoir and the drool volume; and where fluid communication is interrupted between the cement reservoir and the cannula coupler; and a second configuration where fluid communication is established between the cement reservoir and the cannula coupler; and where fluid communication is interrupted between the cement reservoir and the drool volume.

A catheter device having a catheter (24) in which a rotating shaft (25) which is made at least partially from a magnetic material is arranged, and a separating device which contains an annular body (27) surrounding the rotating shaft and having a cavity containing a magnetic body (13′), the magnetic body being arranged downstream from a point at which the shaft (25) exits the catheter (24) which it surrounds with respect to the direction of flow of the fluid through the catheter.

Systems, methods, and apparatuses for irrigating a tissue site are described. The system can include a tissue interface and a sealing member configured to be placed over the tissue site to form a sealed space, and a negative-pressure source fluidly coupled to the sealed space. The system includes an irrigation valve having a housing, a piston disposed in the housing, a fluid inlet to fluidly couple a fluid inlet chamber to a fluid source, and a fluid outlet to fluidly couple a fluid outlet chamber to the sealed space. A piston passage extends through the piston and fluidly couples the fluid inlet chamber and the fluid outlet chamber, and a biasing member is coupled to the piston to bias the irrigation valve to a closed position. The negative-pressure source is configured to move the piston between the closed position and an open position to draw fluid to the sealed space.

Apparatus and methods of dispensing fluid intravenously to a subject, and of flushing a line of an intravenous fluid administration apparatus, are provided. The apparatus may include a chamber including a plurality of connector ports and be configured to operate in fluid communication with an upstream source via a first connector port and, during operation, pass therethrough to downstream tubing, under a first pressure condition, first fluid from the upstream source via a second connector port. A third connector port may be configured to connect to an end of tubing or a valve connector such that, during operation, the chamber is configured to, under a second, higher pressure condition, pass therethrough to the downstream tubing a second fluid from a second fluid source via the third and second connector ports, prevent first fluid flow into the downstream tubing, and prevent second fluid flow through the first connector port.

Apparatus and methods of dispensing fluid intravenously to a subject, and of flushing a line of an intravenous fluid administration apparatus, are provided. The apparatus may include a reservoir pump configured to operate in fluid communication with an upstream source of a first fluid and a downstream pressure-operated valve. The apparatus may also include a port connector configured to operate in fluid communication with at least the pressure-operated valve. The reservoir pump may also be configured to, during operation, automatically refill itself with the first fluid from the first upstream source. The downstream pressure-operated valve may be configured to operate in fluid communication with the reservoir pump and a second fluid source upstream of the pressure-operated valve, and to, during operation, dispense the first fluid to tubing downstream of the pressure-operated valve based on a pressure condition within the pressure-operated valve exceeding a threshold pressure.

A stopcock for a liquid channel of a medical endoscope, having a housing, a spring element and a plug rotatably mounted in the housing, wherein the plug in a working position lies with its conical surface against a seal surface of the housing and can be placed in a medium access position in which the conical and the seal surface have no contact and the housing and the plug remain connected, characterized in that the plug includes one or more transverse grooves, in the outer wall of a conical piece, running transversely to the longitudinal axis of the conical piece and having straight groove bottoms, and the spring element in the medium access position engages with one or more transverse grooves. A medical endoscope having at least one liquid channel, characterized in that it includes at least one stopcock, by which the liquid flow through the channel can be regulated.

A valve assembly embodiment includes first and second valve devices and a coupling mechanism. Each of the first and second valve devices can include first and second fluid pathways and first and second valve members respectively positioned at the first and second fluid pathways. Both the first and second valve members can have an open position that permits fluid flow and a closed position that prevents fluid flow along the first and second fluid pathways past the first and second valve members. The coupling mechanism can couple to each of the first and second valve members. When the valve assembly is actuated, the coupling mechanism can be configured to transition one or both of the first and second valve members between the open and closed positions.