A method for administering chemotherapy medicament, which comprises providing a closed-system drug administration kit, performing sterile catheterization on a patient by placing at least the distal tip of the catheter into the patient's bladder to drain the bladder, inserting a syringe containing the medicament into a safety adapter at a proximal end of the catheter to prevent leakage during attachment, injecting the medicament into the bladder with the injector through the adapter and the drain lumen without leakage of the medicament from the patient into an environment while assessing a pain level of the patient, removing the syringe and closing the catheter to hold the medicament in the bladder for a given treatment time, and, after the given treatment time, draining the medicament out of the bladder with a medicament pressure reservoir through the catheter and into the medicament pressure reservoir for disposal of the kit.

In one aspect, a valve includes a valve body rotatable about a central axis of the valve body, an interior channel adjacent the valve body for permitting a fluid to flow through an axial opening of the interior channel, and a plug within the interior channel that is movable between a first axial position at the axial opening and a second axial position spaced apart from the axial opening. In the first axial position, the plug closes the axial opening to prevent the fluid from flowing through the axial opening in a first direction and to prevent the fluid from flowing through the axial opening in a second direction that is opposite to the first direction. In the second axial position, the plug permits the fluid to flow through the axial opening into the interior channel in the first direction.

A two-component rotary valve for controlling the fluid flow through a fluid conduit, the rotary valve being injection-moulded in two steps with no need for assembly after the injection moulding procedure. The rotary valve comprises a valve house with a plug inside it, and the rotary valve has sealing means in the form of local variations in the radius of the plug and house along their lengths. Thereby, a rotary valve is obtained which does not require a viscous sealant, such as silicone, to eliminate the risk of leakage, when the valve is open.

An aspiration system exhibits an accelerated drop in negative pressure at the distal end of an aspiration catheter from the time of opening a valve. The system includes an aspiration pump in communication with a first chamber, and an aspiration catheter configured for placement into fluid communication with the first chamber by way of an elongate aspiration tube. A second chamber is provided between the aspiration tube and the catheter, and a valve is provided between the second chamber and the aspiration catheter. Upon opening of the valve with negative pressure at equilibrium in the first and second chambers, resistance to fluid flow between the second chamber and the distal end of the catheter is less than the resistance to fluid flow between the second chamber and the first chamber, causing a rapid aspiration into the second chamber.

Bubble traps for use in medical fluid lines and medical fluid bubble trap systems are disclosed herein. In some embodiments, the bubble trap is configured to trap gas (e.g., air) that flows into the bubble trap from a fluid line. In some embodiments, the bubble trap includes an inlet and an outlet and a chamber between the inlet and the outlet. For example, in some embodiments, the bubble trap is configured to inhibit gas from flowing into the outlet once gas flows into the chamber from the inlet. In some embodiments, the bubble trap is in fluid communication with a source container, a destination container, and/or a patient.

A fluid injection system includes a valve device and a valve actuation device. The valve device has a valve member and a valve member coupling. The valve member has an open position that permits fluid to pass through and a closed position that prevents fluid from passing through. The valve member coupling is configured, when actuated, to transition the valve member between the open and closed positions. The valve actuation device having a valve actuation coupling and a drive mechanism. The valve actuation coupling is coupled to the valve member coupling and drive mechanism. The valve actuation coupling is movable independent of the drive mechanism to couple the valve actuation coupling to the valve member coupling. And, the valve actuation coupling is movable with the drive mechanism to actuate the valve member coupling to transition the valve member between the open and closed positions.

An infusion set (1) includes a first flow channel (10) constituted by a pliable tube (10a) and including a spike (11) provided at one end thereof, a second flow channel (20) constituted by a pliable tube (20a) and including a lock connector (50) provided at one end thereof, the lock connector (50) including a lock mechanism (60) that is brought into engagement with a female connector (200), a third flow channel (30) constituted by pliable tubes (30a, 30b and 30c) and including a male connector (31) provided at one end thereof, and a three-way stopcock (40) to which another end of the first flow channel, another end of the second flow channel and another end of the third flow channel are connected. The three-way stopcock includes a handle (41) that can be switched between a first position that brings the first flow channel and the third flow channel into communication with each other and a second position that brings the second flow channel and the third flow channel into communication with each other.

A medical check valve includes a main body with an inlet and an outlet. A poppet valve base in the main body may include a first conduit to enable fluid flow between the inlet and the outlet in a normal operating position and a second conduit to enable fluid flow between the outlet and a top portion of the poppet valve base in a bypass operating position. A poppet cap with a neck portion inserted into the poppet valve base may be moved between an open position and a closed position. In the open position, fluid flow is permitted into an aperture in the cap, e.g., via a syringe, in the bypass operating position such that the fluid in the syringe is delivered to the outlet. In the closed position, and fluid flow is disabled, preventing possible splash back events.

An infusion system comprises an infusion pump that comprises an input unit and a display unit. The input unit is adapted for adjusting a value of at least one parameter for controlling operation of the infusion pump and/or an infusion process, and the display unit displays the value of the at least one parameter. The input unit comprises at least one slide bar adapted to be touched by a user's finger and moved along its length to change the value of the parameter, wherein movement in a first direction increases the value of the parameter and in a reversed, second direction decreases the value. The slide bar is adapted so that the rate of change of the parameter value correlates with the speed of the finger movement and in an idle mode is decelerated in a similar way as under influence of an inertia load and/or a friction.

The present invention relates to a stopcock for use in intravenous catheter apparatus and infusions of intravenous fluid to a patient. An intravenous catheter apparatus (10) comprising: an integrated three-way stopcock assembly (12), and a catheter hub assembly (14) having a proximal end (30a) configured to be connected to a needle hub (28) having a needle (18), and having a distal end (32a) configured to be connected to a catheter tube (16), wherein a straight needle (18) is capable of passing through said proximal end (30a) and distal end (32a) of the catheter hub assembly (14), in a ready position of the intravenous catheter apparatus (10), said catheter hub assembly (14) includes: a wing housing (36) at the distal end (32a), a housing (38) at the proximal end (30a), and a body portion (40) in between housing said three-way stopcock assembly (12); wherein said body portion (40) comprises an entry port (44) in communication with said housing (38), an exit port (46) in communication with said wing housing (36), wherein the entry port (44) and the exit port (46) extend along a horizontal line in an axial direction (A), and an injection port (48), wherein all of these ports (44, 46, 48) are confluent at a central chamber (50) configured within the body portion (40); wherein said three-way stopcock assembly (12) has a top portion (52a) and an opposing bottom portion (54a), both along a vertical line perpendicular to the horizontal line, as well as a handle (56) configured in said top portion (52a), wherein the handle (56) has a first portion (58) parallel to the horizontal line and a second portion (60) parallel to the injection port (48), in the ready position, and wherein the three-way stopcock assembly (12) has rotation capabilities relative to the body portion (40) of the catheter hub assembly (14).