The disclosed systems and methods are configurable central nervous system (CNS) delivery solutions for therapeutics, such as genetic medicines. The systems and methods first infuse a therapeutic bolus within intrathecal space and subsequently infuse a flush fluid to move the therapeutic bolus rostrally toward a target area and achieve a desired spread in the spine and/or brain. The second location can be at a location caudal to the delivery location of the therapeutic bolus.

The disclosed systems and methods are configurable central nervous system (CNS) delivery solutions for therapeutics, such as genetic medicines. The systems and methods first infuse a therapeutic bolus within intrathecal space and subsequently infuse a flush fluid to move the therapeutic bolus rostrally toward a target area and achieve a desired spread in the spine and/or brain. The second location can be at a location caudal to the delivery location of the therapeutic bolus.

The present invention relates to a system for flushing a medical device, comprising a multi-port valve for controlling the delivery of flushing fluids, the multi-port valve connected to a source of pressurised flushing gas; a fluid outlet for coupling flushing fluids to the medical device; and, a gas-driven pump connected to the fluid outlet, wherein, in a first configuration, the multi-port valve couples a flow of gas from the source of pressurised flushing gas to the fluid outlet, and wherein, in a second configuration, the multi-port valve couples a flow of gas from the source of pressurised flushing gas to the gas-driven pump to drive the gas-driven pump thereby to provide a flow of flushing liquid to the fluid outlet.

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.

An administration line for use with a fluid injector system includes a fluid verification module configured to be in operative communication with a housing of the fluid injector system such that the fluid injector system can determine a status of the administration line. The fluid verification module includes a body defining an inlet port, an outlet port, and a fluid channel extending from the inlet port to the outlet port; a first tubing section connected to the inlet port; and a second tubing section connected to the outlet port.

A fluid delivery device comprising a fluid reservoir; a transcutaneous access tool fluidly coupled to the fluid reservoir; and a drive mechanism for driving fluid from the reservoir, the drive mechanism comprising a plunger received in the reservoir; a leadscrew extending from the plunger; a nut threadably engaged with the leadscrew; a drive wheel; and a clutch mechanism coupled to the drive wheel, wherein the clutch mechanism is configured to allow the nut to pass through when disengaged and is configured to grip the nut when engaged such that the drive wheel rotates the nut to advance the drive rod and the plunger into the reservoir.

A percutaneous transluminal angioplasty (PTA) catheter may be configured to perform vein expansion and occlusion. A infusion port located proximal to the occlusion feature can be used to inject contrast enhancement agent as well as other substances. The catheter can be used especially advantageously in vascular regions associated with hemodialysis access.

An intradermal fluid delivery device that uses a processor controlled electromechanical delivery mechanism is provided. An air pump pushes fluid containing medication or saline from a fluid compartment through a microneedle array into a person's skin. The processor repeatedly turns the air pump on or off, for the fluid to gradually be injected into the person's skin. The processor may be configured to control the total fluid delivery time as well as the granularity of the fluid delivery. The total fluid delivery time may be set to T, and the time period T may be divided into smaller periods t.sub.1 to t.sub.n, where the fluid may be administered in a period t1, the fluid delivery may then be stopped for a period t2, followed by another fluid delivery period, etc. The periods t1 to tn may be the same or of different lengths.

An intravenous (IV) fluid delivery system include an IV bag and a fluid delivery device. The IV bag is made of many fluidic channels that keep the fluid distributed across the bag such that the bag may be easily and comfortably wrapped around the arm and shoulder of a person. The fluid delivery device includes a processor controlled electromechanical delivery mechanism that controls a positive displacement pump. The pump moves the fluid into a tube and a needle that is connected to a person's vein. The processor repeatedly turns the pump on or off to gradually transfer the fluid from the IV bag into the person's vein. The processor controls the granularity of the fluid delivery, where the fluid may be administered in a fluid delivery period, the fluid delivery may then be stopped in a subsequent fluid stoppage period, followed by other fluid delivery periods.

An adapter configured to couple to a catheter assembly. The adapter may include a first proximal port, a second proximal port, and a distal port. An infusion fluid pathway may extend between the first proximal port and the distal port. A blood withdrawal fluid pathway may extend between the second proximal port and the distal port. The adapter may include a one-way septum disposed in the first proximal port and configured to open to allow fluid flow in a distal direction at a pressure differential across the one-way septum. The one-way septum is disposed within the infusion fluid pathway. The adapter may include a two-way septum disposed in the second proximal port. The two-way septum may be disposed within the blood withdrawal fluid pathway.