Disclosed is a drug injection device that is implanted between the skull and the subcutaneous layer of an animal. The disclosed drug injection device includes: a main body that is positioned on the skull and implanted and fixed in the subcutaneous layer; a guide member that guides a trocar such that the drug is injected into brain parenchyma inside the skull of the animal; a cover member that is installed inside the main body and connected to the guide member in the center and has a hole for guiding drug injection trocar so as to be inserted; and a sealing member that is installed between the main body and the cover member and prevents reverse flow of drugs and the introduction of foreign substances.

A material includes a metallic, nanoporous structure having a plurality of nanopores having a porosity that allows passage of insulin but not IgG. The metallic nanoporous structure includes titanium, 316L stainless steel and may have a textured nano-sericeous surface. A nanoporous bicontinuous structure can be integrated with nanopores.

Fluid communication devices and supporting structures may be provided for use with intraosseous devices. Apparatus and methods may also be provided to communicate fluids with an intraosseous device.

Rapidly insertable central catheters (“RICCs”), RICC insertion assemblies, and methods are disclosed. For example, a RICC insertion assembly can include a RICC, an introducer, and an access guidewire. An introducer needle can include a needle shaft having a longitudinal gap extending from a proximal portion of the needle shaft through a needle tip. An introducer sheath can include a splittable sheath hub coupled to a splittable sheath body. The introducer sheath can be disposed over the introducer needle with the sheath body sealing the needle shaft for drawing a vacuum through the introducer needle. The access guidewire can extend along an entirety of a primary lumen of the RICC, through a splittable valved port of the sheath hub, along a sheath body-covered needle channel of the needle shaft, and to a location in the introducer proximal of the needle tip in a ready-to-operate state of the RICC insertion assembly.

An arteriovenous dialysis access graft configured to be implanted in a subject includes: at least one flexible conduit having first and second end portions, wherein the first end portion is configured to connect to an artery of the subject and the second end portion is configured to connect to a vein of the subject such that blood flows through the at least one conduit from the first end portion to the second end portion; and at least one cannulation chamber positioned between the first end portion and the second end portion of the at least one conduit. The chamber includes: an elongated housing having an inlet at a first end thereof and an outlet at a second, opposed end thereof, a posterior wall, a pair of sidewalls, and an open anterior portion defining a cannulation port; a self-sealing material extending across the cannulation port; and a longitudinal passageway defined by the housing and the self-sealing material that extends from the inlet to the outlet of the housing. The housing of the at least one chamber is formed of a substantially rigid material such that, when a dialysis needle is inserted through the self-sealing material and the cannulation port, the needle is inhibited or prevented from extending through the posterior or the side walls of the housing.

A system for facilitating instrument delivery through a peripheral intravenous catheter may include a catheter adapter having a proximal end, a distal end, and a lumen extending there through. The catheter adapter may include a side port. The system may include an extension tube extending from the side port. The system may include a blood control valve disposed in the lumen of the catheter adapter. The system may include a peripheral intravenous catheter extending distally from the catheter adapter.

An introducer assembly includes a plurality of selectable side holes through which a fluid can be delivered. In some examples, an introducer assembly includes an outer elongated body defining a plurality of outer body side holes and an inner elongated body defining a plurality of inner body side holes. The inner elongated body is configured to rotate relative to the outer elongated body between a first rotational orientation in which a first subset of outer body side holes aligns with a first subset of inner body side holes and the inner elongated body blocks fluid flow out of the outer elongated body through a second subset of outer body side holes, and a second rotational orientation in which the second subset of outer body side holes aligns with a second subset of inner body side holes and inner elongated body blocks fluid the first subset of outer body side holes.

A low-profile access port for subcutaneous implantation within a patient. The access port can include a set of receiving cups which can be placed in fluid communication with a catheter. The set of receiving cups can provide a greater skin surface with which to access the port to avoid repeated penetrations at a single locus, such as during consecutive dialysis treatments. The access port can alternatively include needle penetrable arms or elongate chambers that also have a slim, low profile. The access port can include a needle guide to direct subsequent needle access to different insertion points to permit healing at the previous insertion points. The access port can be formed of a modular construction with a first conduit, a second conduit, and an outer shell. The outer shell can include a proximal portion and a distal portion. The access port can include a stem assembly and a locking member.

An external end device has a casing (4), including a base (5), in which a distal opening (12) is formed which receives a funnel-shaped septum (14) having a tube trunk (140). Inside the tube trunk (140) the catheter (3) is connected to the distal section (16) of the fitting (15). A tubular coating (2) has a proximal end adapted to be grafted onto the tube trunk (140) and a distal end coaxially adhering to the catheter (3). A pair of bands (90, 91) of tissue-ingrowth material is fixed on the tubular coating (2), and an anchor ring (92), equipped with anchoring means, is sandwiched between the bands (90, 91).

A skin surface indwelling device for guiding punctures includes: an indwelling tube (13) having an inside tunnel (P) substantially extending along the longitudinal direction of the indwelling tube (13), the tunnel (P) is used for guiding needle (N), the indwelling tube (13) has a proximal end positioned above the skin surface (S) and a distal end positioned under the skin surface (S) in indwelling state; a support (11) having a bottom surface on its bottom that directly or indirectly contacts with the skin surface (S), the support (11) supports and fixates the indwelling tube (13); and a sealing elements (141,142) configured to seal the tunnel (P). The skin surface indwelling device for guiding punctures can shorten the time of establishing a puncture tunnel in the buttonhole puncture method, and help to build the puncture tunnel. In addition, the skin surface indwelling device can also guide the puncture needle (N) when puncturing, and protect the immature puncture tunnel.