The present invention provides a system for enriching a flowing liquid with a dissolved gas inside a conduit. The system comprises two or more capillaries, each capillary delivering a stream of a gas-enriched liquid to the flowing liquid. The first ends of the capillaries are positioned to form an intersecting angle with respect to the effluent streams such that these streams of gas-enriched liquid collide with each other upon exit from the first ends of the capillaries, effecting localized convective mixing within the larger liquid conduit before these gas-enriched streams are able to come into close contact with the boundary surfaces of the conduit, whereby the gas-enriched liquid mixes with the flowing liquid to form a gas-enriched flowing liquid. In the preferred embodiment, no observable bubbles are formed in the gas-enriched flowing liquid. Methods of making and using such system are also provided.

A hemodialysis device which includes a main tube, a first linking tube, a second linking tube and a third linking tube is disclosed. The main tube includes a central tube, an annular tube, a plurality of dialysis holes, a first end and a second end. The central tube includes a blood passage. The annular tube includes a waste passage which surrounds the central tube. The plurality of dialysis holes are located on the central tube, wherein the blood passage is connected to the waste passage via the plurality of dialysis holes. The first end and the second end are the two opposite ends of the main tube. The first linking tube is connected to the first end and to the central tube. The second linking tube is connected to the second end and to the central tube.

A fluid conduit includes a first portion having a first porosity, a second portion disposed immediately adjacent to the first portion, the second portion having a second porosity that is greater than the first porosity, and a third portion of the fluid conduit disposed immediately adjacent to the second portion, the third portion having a third porosity that is less than the second porosity. Each of the first portion, the second portion, and the third portion may be integrally formed as a single, continuous piece defining the fluid conduit. The fluid conduit may be incorporated into a system configured for implantation into a patient. For example, an implantable fluid conduit system may feature a drain in fluid communication with the fluid conduit that is connectable to the patient's bladder, and a pump that controls filtrate flow from the fluid conduit to the drain.

A catheter (100) for treating hypervolemia in a patient includes a luminal ingress (112) joined to a luminal egress (114) at a distal end portion (116) of the catheter having a closed distal end (102). The distal end portion is configured to at least temporarily reside within a vessel of the patient, the distal end portion including a semipermeable membrane. The luminal ingress is designed to convey an influent having a first osmotic concentration to the distal end portion. The semipermeable membrane is configured to pass blood-borne water from the vessel into the distal portion. The blood-borne water is absorbed by the influent to produce an effluent having a second osmotic concentration lower than the first osmotic concentration. Systems (200) with the catheter and methods for treating hypervolemia are also disclosed.

A dialysis device implantable in a patient for dialysis includes a filtration unit. The filtration unit includes at least one dialysis chamber for containing and/or circulating dialysate; and at least one blood chamber for containing and/or circulating blood of the patient, disposed on at least one dialysis chamber and being in communication with the at least one dialysis chamber. Each of the at least one dialysis chamber and the at least one blood chamber comprise at least one inlet for circulating fluid into and/or out of the at least one dialysis chamber and the at least one blood chamber. The at least one dialysis chamber and the at least one blood chamber are configured such that the blood in the at least one blood chamber and the dialysate in the at least one dialysis chamber operably interact with each other for dialysis.

The present invention provides a system for enriching a flowing liquid with a dissolved gas inside a conduit. The system comprises two or more capillaries, each capillary delivering a stream of a gas-enriched liquid to the flowing liquid. The first ends of the capillaries are positioned to form an intersecting angle with respect to the effluent streams such that these streams of gas-enriched liquid collide with each other upon exit from the first ends of the capillaries, effecting localized convective mixing within the larger liquid conduit before these gas-enriched streams are able to come into close contact with the boundary surfaces of the conduit, whereby the gas-enriched liquid mixes with the flowing liquid to form a gas-enriched flowing liquid. In the preferred embodiment, no observable bubbles are formed in the gas-enriched flowing liquid. Methods of making and using such system are also provided.

The invention concerns the field of medical devices, more particularly devices for joint extraction, within an organism, of at least one metal cation and at least one target molecule. In order to do this, the device comprises: a) at least one ligand exhibiting specific affinity for the target molecule; b) at least one means for extraction of the metal cation, said means being a perfusion fluid comprising at least one chelating agent, the perfusion fluid being contained in a dialysis or microdialysis system. The use of these devices makes it possible, for example, to prevent and/or treat pathologies linked to dysregulation of the homeostasis of metals and/or target molecules in the organism, for example neurological diseases and/or proteinopathies.

Hemofilters for in vivo filtration of blood are disclosed. The hemofilters disclosed herein provide an optimal flow of blood through the filtration channels while maintaining a pressure gradient across the filtration channel walls to enhance filtration and minimize turbulence and stagnation of blood in the hemofilter.

Treatment of cardiac tissue via an implantable heart treatment device is described. A device embodiment includes, but is not limited to, a substrate configured for implantation within a body; an electromagnetic signal generator coupled to the substrate and configured to generate one or more electric signals configured to stimulate one or more tissues of a heart within the body; and an energy-carrier molecule delivery device coupled to the substrate and configured to supply one or more non-oxygen cellular energy sources to one or more tissues of the heart within the body.

Treatment of cardiac tissue via an implantable heart treatment device is described. A device embodiment includes, but is not limited to, a substrate configured for implantation within a body; an electromagnetic signal generator coupled to the substrate and configured to generate one or more electric signals configured to stimulate one or more tissues of a heart; and an oxygenator coupled to the substrate and configured to supply one or more oxygenated molecules to one or more tissues of the heart, the oxygenator including a blood inlet portion, a blood outlet portion, and an oxygen exchange portion positioned between the blood inlet portion and the blood outlet portion, the oxygen exchange portion including a high surface area oxygen exchanger configured to transfer one or more oxygenated molecules from the high surface area oxygen exchanger to blood passing from the blood inlet portion to the blood outlet portion.