A fluid delivery Y-site is described that is configured to receive and control delivery of two or more fluid flows. Fluid flow is controlled within a chamber by a valve and float. Flow of a primary fluid into the chamber is reduced or halted by the movement of a valve. The valve may occlude a first flow port into the chamber in response fluid flowing from a second flow port into the chamber. A float is moveably disposed within the chamber and configured to engage the valve in response a fluid flow into the chamber from the second flow port. As fluid flow from the second flow port into the chamber is reduced or ceases, the valve and float allow the flow from the first flow port to once again enter the chamber and exit from an outlet port.

A valve with an internal member is disclosed which allows exhaled carbon dioxide to escape from a breathing circuit when the circuit gas pressure drops below a threshold pressure. The valve operates by occluding one or more ports under a relatively high pressure and opening the one or more ports under a relatively low pressure. The internal member is attached to the body of the valve at two or more locations on the internal member. The internal member moves in a direction perpendicular to the gas flow through the valve.

A disclosed antimicrobial medical device includes a fluid transfer device configured to couple between a patient and a fluid reservoir, a fluid pathway extending through the fluid transfer device, a first electrode coupled to the fluid transfer device, and a second electrode coupled to the fluid transfer device and spaced apart from the first electrode. The first electrode includes a first conductive material and the second electrode includes a second conductive material different from the first conductive material. The second electrode is configured to form a galvanic cell with the first electrode.

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.

A collapsible valve comprising a first portion with at least one dimple in a side thereof, and a second portion, the second portion being narrower than the first portion and arranged along an axial dimension of the first portion, the second portion including a cut therein.

Some embodiments disclosed herein relate to a medical connector having a backflow resistance module configured to prevent fluid from being drawn into the connector when a backflow inducing event occurs. In some embodiments, the backflow resistance module can include a variable-volume chamber configured to change in volume in response to a backflow-inducing event and a check valve configured to resist backflow. In some embodiments, the medical connector can include a fluid diverter configured to direct fluid flowing through the medical connector into the variable volume chamber to prevent fluid stagnation therein. In some embodiments, the medical connector includes a body member, a base member, a seal member, a support member, and a valve member.

A medical connector can include a body having a fluid path with an inlet port, an outlet port, a luer portion, and a post extending through a fluid path. An arm having a latch member is coupled to the body to engage a ridge or thread on an exterior surface of a reciprocal connector. The arm may also include an extension. When the connector is in an open position, the latch member restricts retraction of the reciprocal connector from the outlet port. A seal is coupled to the body and includes a flap extending across the outlet port or a bellows to compress along an axis. In a closed position, the post restricts flow through the luer portion. In an open position, the post permits flow through the luer portion.

A fluid delivery Y-site is described that is configured to receive and control delivery of two or more fluid flows. Fluid flow is controlled within a chamber by a valve and float. Flow of a primary fluid into the chamber is reduced or halted by the movement of a valve. The valve may occlude a first flow port into the chamber in response fluid flowing from a second flow port into the chamber. A float is moveably disposed within the chamber and configured to engage the valve in response a fluid flow into the chamber from the second flow port. As fluid flow from the second flow port into the chamber is reduced or ceases, the valve and float allow the flow from the primary flow port to once again enter the chamber and exit from an outlet port.

The present disclosure relates to a reinfusion tube system that includes a reinfusion fluid tubing with a pre-pump loop section, a post-pump loop section, and a pump loop section; and one of

a check valve positioned at an end or between the ends of the reinfusion fluid tubing such that it is provided to block fluid flow through the check valve in a direction from the post-pump loop section to the pre-pump loop section, and a check valve adapter including a check valve. The check valve adapter can be configured to be connected to an end or to be positioned between the ends of the reinfusion fluid tubing such that the check valve is provided to block fluid flow through the check valve in a direction from the post-pump loop section to the pre-pump loop section.

A disclosed antimicrobial medical device includes a fluid transfer device configured to couple between a patient and a fluid reservoir, a fluid pathway extending through the fluid transfer device, a first electrode coupled to the fluid transfer device, and a second electrode coupled to the fluid transfer device and spaced apart from the first electrode. The first electrode includes a first conductive material and the second electrode includes a second conductive material different from the first conductive material. The second electrode is configured to form a galvanic cell with the first electrode.