A transcranial fastening device (1) for a drainage catheter (3), comprising an external body (5) being equipped with a passage (P), the passage (P) being equipped with blocking means (9) of the drainage catheter (3) adapted to allow a sliding of the drainage catheter (3) through the passage (P) along a first movement direction (M1) and to prevent a sliding of the drainage catheter (3) through the passage (P) along a second movement direction (M2).

A hydrocephalus shunt arrangement for draining cerebrospinal fluid (CSF) in a patient includes a ventricle catheter, a first drainage line, a control valve, a second drainage line, and an intracranial device. The ventricle catheter is inserted into a ventricle space of the brain of a patient. The first drainage line is connected to the ventricle catheter. The control valve is connected to the first drainage line and controls the drainage of CSF from the cranium of the patient through the second drainage line into a drainage area inside an abdominal cavity of the patient. The intracranial device is implanted under the skin of the patient in or at the cranium and connected to the ventricle catheter or the control valve. The intracranial device includes a corrugated metal membrane covering a chamber disposed within a rigid housing. The control valve produces a desired, controlled, drainage of excess CSF.

A carrier device and methods of use, for implanting in biological tissue and releasing a medical payload in the biological tissue according to remote ultrasound trigger pulses. The carrier device includes at least one internal resonant element with a resonance frequency in the ultrasound range. When an ultrasound pulse at the resonance frequency is sent through the tissue, the resonant element vibrates at high amplitude and raises the internal pressure of the carrier and releases the payload. In some embodiments, payload release can be started, stopped, and restarted at a later time or place. Individual carrier devices can be selectively triggered by providing different resonance frequencies, and external resonant elements can provide propulsion and navigation capabilities.

Drug delivery systems and methods are disclosed herein. In some embodiments, a drug delivery system can be configured to deliver a drug to a patient in coordination with a physiological parameter of the patient (e.g., the patient's natural cerebrospinal fluid (CSF) pulsation or the patient's heart or respiration rate). In some embodiments, a drug delivery system can be configured to use a combination of infusion and aspiration to control delivery of a drug to a patient. Catheters, controllers, and other components for use in the above systems are also disclosed, as are various methods of using such systems.

A device and system for flushing a shunt catheter utilizes the available cerebrospinal fluid (CSF) to flush a blocked catheter. The CSF is pressurized to a predetermined amount and then allowed to suddenly, rapidly and forcefully purge any occlusions. The rapid release of CSF produces flow jets from the catheter pores into the ventricle. This impulse, or cough, will push and divert choroid plexus and/or other blockages away from the pores. The device and system may then be allowed to refill at a slow rate, thus reducing the possibility of rapid suction of fluid back into the system and the attendant possibility of drawing the choroid plexus back into the pores. The catheter at the proximal end may also include back-up pores that can be opened to restart flow from the ventricle should the primary pores remain blocked after a flushing attempt.

Systems and methods for treating biologic fluids are disclosed. Some disclosed embodiments may be used to filter cerebrospinal fluid (CSF) from a human or animal subject, heat CSF to a target temperature, cool CSF to a target temperature, apply light treatment to CSF, separate cells via their dielectric properties, apply spiral and/or centrifugal separation, introduce additives to target particles, and/or apply combinations thereof. The method may include the steps of withdrawing fluid comprising CSF, treating the fluid, and returning a portion of the treated fluid to the subject. During operation of the system, various parameters may be modified, such as flow rate.

Systems and methods for filtering materials from biologic fluids are discussed. Embodiments may be used to filter cerebrospinal fluid (CSF) from a human or animal subject. In an example, CSF is separated into a permeate and retentate using a tangential flow filter. The retentate is filtered again and then returned to the subject with the permeate. During operation of the system, various parameters may be modified, such as flow rate and waste rate.

A shunt device for shunting cerebrospinal fluid (CSF) from a CSF containing space to a sinus system cavity comprises a tubular inlet element, a flow restricting part, and a tubular outlet element having an outlet end with an outlet opening for insertion in the sinus system cavity, and a one-way valve preventing flow in a direction from the outlet opening to the inlet opening. The shunt device further comprises a distancer, said distancer being provided at the outlet end of the tubular outlet element.

A shunt device for shunting cerebrospinal fluid (CSF) from a CSF containing space to a sinus system cavity comprises a tubular inlet element, a flow restricting part, and a tubular outlet element having an outlet end with an outlet opening for insertion in the sinus system cavity, and a one-way valve preventing flow in a direction from the outlet opening to the inlet opening. The shunt device further comprises a distancer, said distancer being provided at the outlet end of the tubular outlet element.

This disclosure describes devices and methods used to inject or aspirate fluid into or from various regions of the human body, such as the anterior chamber of the eye. The disclosed devices and methods provide improvements over conventional devices and methods in that an operator can perform a procedure using the disclosed device without an assistant. The disclosed devices and methods allow one-handed injection or aspiration of fluid into or from body tissue, and provide means for controlling the volume of injected or aspirated fluid.