A valve for a shunt useable in treatment of hydrocephalus is described. The valve comprises an inlet in fluid communication with an outlet, a valve closure element, a mechanical biasing element configured to bias the valve closure element towards the inlet, and an electromechanical actuator configured to manipulate the mechanical biasing element. A biasing force applied to the valve closure element by the mechanical biasing element determines an operating pressure of the valve, and manipulating the mechanical biasing element by the electromechanical actuator allows for adjustment of the valve operating pressure by suitably varying the biasing force.

A method including: introducing a shunt into a vascular system, wherein the shunt includes an inlet aperture in an inlet region and an outlet aperture in an outlet region; positioning the inlet region into an epidural or intervertebral vein; with a stylet, puncturing a wall of the epidural or intervertebral vein, traversing an interstitial space, and puncturing a thecal sac, wherein the stylet includes a wire extending through the shunt; moving the shunt to cause the inlet region to extend through a wall of the epidural or intervertebral vein; moving the shunt to cause the inlet region to extend into an interstitial space; and moving the shunt to cause the inlet region to extend through the thecal sac, such that the inlet region is positioned in an intradural space, and such that the outlet region is positioned in a venous pathway.

An apparatus for loading an endovascular shunt into a delivery catheter includes a base, a boss rod connected to, and extending longitudinally across, the base, and a plurality of guide bosses slidably coupled to the boss rod. The guide bosses include a delivery catheter guide boss coupled to the delivery catheter, a malecot holding tube guide boss, wherein a malecot holding tube is connected to a first lateral side of the malecot guide boss extending towards the delivery catheter guide boss, a claw assembly guide boss, where a claw assembly is attached to a first lateral side of the claw guide boss extending towards the malecot holding tube guide boss, and a chase pin guide boss, wherein a chase pin is connected to a first lateral side of the chase pin guide boss extending towards the claw assembly guide boss.

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.

Embodiments disclosed herein provide devices, systems, and methods for reducing intraocular pressure. For example, the disclosed devices, systems, and methods are useful for reducing intraocular pressure resulting from conditions, such as acute glaucoma, on a short-term basis until a definitive surgical procedure is performed. More particularly, valved trocar cannula systems for reducing intraocular pressure resulting from conditions, such as acute glaucoma, pending surgical intervention in an operating room are disclosed. In practice, a trocar assembly is used to place a valved cannula assembly in a patient's eye, such as in the anterior chamber or pars plana, to reduce high intraocular pressure. The valved cannula is then left in the patient's eye for a period of time to continuously allow aqueous humor or liquid vitreous humor to flow therethrough, until the patient may be surgically treated in an operating room.

A method for monitoring a flowrate of cerebrospinal fluid (CSF) in a ventriculo-peritoneal (VP) shunt implanted in a human patient includes: (i) receiving, at a device external to the human patient, data sensed by a plurality of sensors within the device and positioned relative to the VP shunt to drain excess cerebrospinal fluid from the human patient's brain; (2) determining, by the device and based on the sensed data, a rate of flow of the CSF in the VP shunt; and (3) transmitting (e.g., wirelessly), by the device, data indicating the rate of flow to a computing server.

A shunt can include a primary catheter for receiving fluid, a secondary catheter for receiving fluid, and a pressure-sensitive valve to prevent flow of fluid to the secondary catheter in a first mode until the primary catheter is occluded. The pressure-sensitive valve can transition to a second mode responsive to occlusion of the primary catheter, permitting flow of fluid to the secondary catheter.

Systems and methods are provided for optically reading a setting of an implantable valve. The valve includes optical emitters that are wirelessly powered by a valve reading tool that images the emitted light to determine the valve setting.

Drainage devices for draining a fluid from a patient during treatment of a medical condition body are disclosed. The drainage devices comprise a body defining at least one conduit through the body from a distal end of the body to a proximal end of the body. The body comprises at least one carbon-based structure configured to inhibit growth of fibroblasts in the conduit when the fluid flows through the conduit. Example embodiments of the drainage device may include an ophthalmic shunt, a hydrocephalus shunt, an artificial mesh, an arteriovenous shunt, a thoracic catheter, and a central venous access device.

The present invention relates to a transcatheter method for providing fluid communication between two anatomical compartments. The present invention also relates to a transcatheter system comprising an intracorporeal connector for fluid communication between two anatomical compartments through at least one anatomical wall, wherein said connector is adapted to receive a flow regulating device, a connector, a flow regulating device and an insertion device.