A catheter adapter may include a distal end, a proximal end, a lumen extending between the distal end and the proximal end, and a side port. A central axis of a fluid path extending through the side port may be disposed at an angle with respect to a longitudinal axis of the catheter adapter. The angle may be less than 45°. Additionally or alternatively to the angle being less than 45°, the catheter adapter may include a wedge and/or an insert configured to facilitate instrument delivery to the catheter assembly via the side port.

A catheter system may include a catheter assembly, a fluid storage unit, and fluid. The catheter assembly may include a catheter hub, a catheter, an extension tube, and an adapter. The catheter hub may include a distal end, a proximal end, a lumen extending between the distal end and the proximal end, and a side port. The catheter may extend distally from the distal end of the catheter hub. A distal end of the extension tube may be coupled to the side port. The adapter may be coupled to a proximal end of the extension tube. The fluid storage unit may be coupled to the adapter and may include a reservoir, a barrier, and an actuator. The fluid may be disposed within the reservoir. In response to breach of the barrier by the actuator, the reservoir may be in fluid communication with the lumen of the catheter hub.

A catheter system may include a catheter assembly, a fluid storage unit, and fluid. The catheter assembly may include a catheter hub, a catheter, an extension tube, and an adapter. The catheter hub may include a distal end, a proximal end, a lumen extending between the distal end and the proximal end, and a side port. The catheter may extend distally from the distal end of the catheter hub. A distal end of the extension tube may be coupled to the side port. The adapter may be coupled to a proximal end of the extension tube. The fluid storage unit may be coupled to the adapter and may include a reservoir, a barrier, and an actuator. The fluid may be disposed within the reservoir. In response to breach of the barrier by the actuator, the reservoir may be in fluid communication with the lumen of the catheter hub.

Disclosed herein are devices and methods related to UV disinfection of a transfer catheter during peritoneal dialysis. The transfer catheter comprises a first and second end, the second end comprising a transfer valve. The transfer valve body comprises an inlet, outlet, and a flush hole. The valve core comprises a notch configured to allow fluid flow between the various flow paths. The valve core and body are positioned off axis with respect to the fluid flow path. The transfer catheter can allow for a small volume kill zone, which can minimize the amount of UV required to disinfect the catheter.

Systems and methods of micro-infusion of medical fluids are disclosed. Micro-infusion systems may include a pump, a patient interface, tubing between the pump and the interface, and a micro-infusion device along the tubing. A first portion of the tubing above the micro-infusion device is longer than a second portion of the tubing below the device. The micro-infusion device may include a chamber in-line with the tubing, a first valve between the chamber and the first portion of the tubing, a second valve between the chamber and the second portion of the tubing and a third valve between the chamber and a dump chamber. The second valve may be slidably disposed within the chamber. A medical fluid may be provided into the chamber that slides the second valve displacing another fluid in the chamber through the third valve into the dump chamber.

A fluid conduit has a housing with a body forming an interior and a proximal cavity within the interior. The housing has an outlet and a fluid path extending between the cavity and outlet. The conduit also has an entry channel and a contact surface. The entry channel extends through the housing distal to the cavity and has a radial longitudinal axis. The entry channel is offset from the fluid path such that the radial longitudinal axis of the entry channel does not intersect a longitudinal axis of the fluid path. This offset causes fluid entering the interior of the housing via the entry channel to initiate a swirl-like motion within the interior. A portion of the contact surface is distal to the cavity and intersects the radial longitudinal axis. The surface directs a portion of the fluid proximally into the cavity.

An introduction of medical tools to this invention that enables the improvement of flushing of sterile solutions, medications and the collection of blood specimen(s). In addition, an introduction of intravenous system whereby the healthcare provider can perform the tasks of flushing the intravenous site efficiently and collecting blood specimen using the combination of medical tools. Most importantly, these tools included in this invention preserve and protect intravenous lines from malfunctioning.

A delivery device for controllably delivering multiple implants (e.g., intravascular implants) is described herein. The delivery device may include a lockout mechanism to prevent against inadvertent implant deployment prior to initial use. The delivery device may also include a re-sheath mechanism to allow for re-sheathing of an inner core assembly prior to removal of the delivery device from an initial deployment site. The delivery device may also further include a mechanism configured to prevent against re-sheathing of a partially-deployed implant.

Disclosed herein are devices and methods related to UV disinfection of a transfer catheter during peritoneal dialysis. The transfer catheter comprises a first and second end, the second end comprising a transfer valve. The transfer valve body comprises an inlet, outlet, and a flush hole. The valve core comprises a notch configured to allow fluid flow between the various flow paths. The valve core and body are positioned off axis with respect to the fluid flow path. The transfer catheter can allow for a small volume kill zone, which can minimize the amount of UV required to disinfect the catheter.

A self-flushing connector includes a housing having a cavity, a first inlet port, a second inlet port, and an outlet port. A collapsible valve is disposed within the cavity. A first flow path extends from the first inlet port to the outlet port. The first inlet port and the second inlet port are fluidly connected through a gap defined between the body of the collapsible valve and an inner wall of the housing defining the cavity. A second flow path extends from the second inlet port to the first flow path. When the collapsible valve is in a closed state, the collapsible valve fluidly disconnects the second flow path from the first flow path while allowing fluid to flow through the first flow path. When the collapsible valve is in an open state, the second flow path is fluidly connected to the first flow path.