The Peritoneal Conduit is a medical device composed of tubing with an integrated collar made of a flexible and non-absorbable material for surgical implantation to create a conduit for passage of a catheter between two body cavities. The Peritoneal Conduit has a hollow center that spans from one end (shorter proximal portion) to the other end (longer distal portion). The catheter that will be being placed through the Peritoneal Conduit will enter into the proximal portion and will pass through the hollow center of the Peritoneal Conduit to emerge from the distal portion. The catheter is then secured to the Peritoneal Conduit using one suture that is tied around the groove in the proximal portion of the Peritoneal Conduit. The Peritoneal Conduit itself is secured in placed using two sutures that are placed through the integrated collar at the junction of the proximal and distal portions of the Peritoneal Conduit.

Systems and methods are provided herein that generally involve shunting fluid, e.g., shunting cerebrospinal fluid in the treatment of hydrocephalus. Self-cleaning catheters are provided which include split tips configured such that pulsatile flow of fluid in a cavity in which the catheter is inserted can cause the tips to strike one another and thereby clear obstructions. Catheters with built-in flow indicators are also provided. Exemplary flow indicators include projections that extend radially inward from the interior surface of the catheter and which include imageable portions (e.g., portions which are visible under magnetic resonance imaging (MRI)). Movement of the flow indicators caused by fluid flowing through the catheter can be detected using MRI, thereby providing a reliable indication as to whether the catheter is partially or completely blocked. Systems and methods for flushing a shunt system are also disclosed herein, as are various systems and methods for opening auxiliary fluid pathways through a shunt system.

A drainage system that includes a ventricular catheter, a drainage catheter, and a positive displacement pump that can function to actively drain CSF from the ventricles of the brain of a patient. The pump can include, for example, a diaphragm pump, a piston pump, a rotor pump, a peristaltic pump, or a screw pump.

An anti-siphon drainage device having a housing forming an internal chamber, an inlet and outlet ports part of the internal chamber and fluidly connected by a primary flow path. A valve seat is associated with the primary flow path, a sloped section extends from the valve seat, and a valve element disposed in the sloped section and can seat in the valve seat to restrict a fluid flow into the primary flow path from the inlet port. A secondary flow path can have an opening near the inlet port and an orifice near the outlet port. A regulator has an aperture to selectively open and close the opening of the secondary flow path. When the valve element is seated in the valve seat and restricting the fluid flow into the primary flow path, the fluid flows into the secondary flow path.

Disclosed is a system including a flow control assembly. The system may include a flow regulating shunt system, for various purposes. The flow control assembly may be controlled according to selected parameters and methods.

An implantable body fluid drainage system includes a metering shunt having a housing with an internal chamber. A movable barrier divides the chamber into a first section and a second section, and the barrier can be displaced by a differential pressure. A first powered inlet valve providing a fill path to the first section of the chamber, and a first powered drain valve providing a drain path from the first section of the chamber. A CSF inlet conduit connects a CSF space to the first powered inlet valve. A CSF outlet conduit connects the first powered outlet valve to a discharge location. A controller opens the first powered inlet valve and close the first powered drain valve to fill the first section to a volume defined by the barrier and chamber geometry and closes the first powered inlet valve and opens the first powered drain valve to discharge the filled volume from the first section through the outlet conduit.

A cerebral spinal fluid shunt plug includes a shunt plug housing having a shunt valve recess formed therein and a window recess with an access hole. The cerebral spinal fluid shunt plug also includes a shunt valve shaped and dimensioned for positioning within the shunt valve recess of the shunt plug housing and a lucent disk shaped and dimensioned for the passage through the central access hole of the shunt plug housing. In another embodiment, a cerebral spinal fluid shunt plug includes a shunt plug housing having a shunt valve recess formed therein and an intracranial monitoring device recess with an access hole. A shunt valve is positioned within the shunt valve recess of the shunt plug housing and an intracranial monitoring device is passed through the central access hole of the shunt plug housing.

Disclosed is a system including a flow control assembly. The system may include a flow regulating shunt system, for various purposes. The flow control assembly may be controlled according to selected parameters and methods.

In one aspect, the disclosure provides a pressure sensor that wirelessly provides force/pressure data to a wireless receiver. The pressure sensor includes a first fluid-responsive membrane configured to be exposed to a region, such as a body fluid, whose pressure is being monitored. A force transducer for measuring this pressure is movable toward and away from the flexible membrane and may be oscillated, either out-of-contact with the first fluid-responsive membrane or in-contact therewith, for static/dynamic pressure sensor calibration. An actuator for displacing/oscillating the force transducer is located within the internal housing. Specific pressure transducers, fluid drainage systems, implantable devices and (at least partially) external sensing devices are disclosed. Calibration techniques, including recalibration to adjust for device drift and to clear biofouling are disclosed.

The object of providing a cerebrospinal fluid drainage system 1 which reacts precisely to changes in pressure in the cerebrospinal fluid, with ease of operation, is achieved by the present invention in that a pump 5 is used for draining the cerebrospinal fluid (liquor), wherein operating measured values supplied by sensors act as controlled variable for the operation of the pump. The pressure in the liquor line currently measured by a pressure sensor 10, the liquor pressure in the intracranial cavity being treated, measured intracorporeally by a pressure sensor, and/or the volume of liquor already pumped out, as operating measured value, can, for example, serve as the basis for operational control of the pump of the liquor drainage system. The liquor drainage system according to the invention has the advantage that the liquor is drained not only simply on the basis of the excess pressure in the intracranial cavity being treated, but is actively pumped out of the intracranial cavity in a controlled manner, in particular with constant measurement of the liquor pressure. In this way the pumping capacity can be regulated depending on requirement and the drainage pressure or the liquor pressure kept reliably within a specific pressure range.