An attachment for a catheter assembly may include a platform, which may include an upper surface and a bottom surface. The bottom surface may be configured to contact skin of a patient. At least a portion of the upper surface may be configured to support the catheter assembly. The upper surface may support the catheter assembly at an angle with respect to skin of the patient that is approximately equal to an insertion angle of a catheter of the catheter assembly. The attachment may include snap feature coupled to the upper surface of the platform. The attachment may include a blunt cannula extending distally from the snap feature. The blunt cannula and the portion of the upper surface may provide a generally straight pathway for an instrument inserted distally through the attachment into the catheter assembly.

A needle set includes a needle guard and a winged needle. The needle guard has upper and lower jaws, each of the upper and lower jaws defining a channel and coming together at a hinge. The upper and lower jaws are separated by slots in sides of the needle guard, which slots divide the sides into upper and lower side walls, respectively. The winged needle can be inserted between the upper and lower jaws, with wings of the winged needle passing through the slots. The hinge has an opening and a tube connected to the winged needle passes through the opening.

An infusion device includes a base for removably coupling to a fluid deliver device, a needle hub supporting an introducer needle and a catheter for delivering a substance to a patient. The infusion device includes a needle shield for covering the introducer needle after inserting the catheter into the patient. The needle shield includes a leg with a latching tab to couple to the coupling of the base until the legs spring outward to release the coupling. The legs have inwardly extending overlapping arms with an aperture receiving the introducer needle. A spring guard is formed on the needle shield and is spring biased inwardly toward the introducer needle to contact the arms. The introducer needle is retracted to release the arms allowing the arms to spring outwardly to disengage from the coupling of the base and to enable spring guard to spring inwardly to cover the tip of the introducer needle.

A fluid control component configured for controlling fluid flow through the hub of a catheter assembly during and after placement into the patient is disclosed. In one embodiment, the fluid control component comprises a body disposed within a cavity of the hub, the body being movable between a first position and a second position, wherein the body does not pierce a valve disposed in the hub when in the first position and wherein the body pierces the valve when in the second position. The body includes a conduit to enable fluid flow through an internal portion of the body when the body is in the second position, and a plurality of longitudinally extending ribs disposed on an exterior surface of the body. The ribs provide at least one fluid flow channel between the valve and an external portion of the body when the body is in the second position.

The present disclosure provides for a safety catheter assembly comprising a needle hub, a catheter hub, a tip protector housing. Various embodiments can comprises a push-off tab extending radially from the tip protector housing or a portion thereof, and/or structure can be added or removed to affect compliance between a catheter assembly and a catheter insertion device.

Rapidly insertable central catheters (“RICCs”) including catheter assemblies and methods thereof are disclosed. For example, a RICC assembly includes a RICC and an introducer. The RICC includes a catheter tube, a catheter hub, and one or more extension legs coupled in the foregoing order. The catheter tube includes a side aperture that opens into an introducing lumen that extends from at least the side aperture to a distal end of the RICC. The introducer includes a retractable-needle device, a syringe, and a coupling hub that couples the retractable-needle device and the syringe together proximal of the side aperture in a ready-to-deploy state of the RICC assembly. The retractable-needle device includes an introducer needle. A needle tip in a distal-end portion of a shaft of the introducer needle extends beyond the distal end of the RICC when the RICC assembly is in the ready-to-deploy state of the RICC assembly.

A catheter assembly is disclosed, which includes a catheter; a catheter hub fixed to a base end portion of the catheter; an inner needle having a needlepoint, inserted into the catheter; a needle hub coupled to the inner needle; a needle support portion configured to support the inner needle through the catheter on a leading end side beyond the catheter hub, the needle support portion having a pair of support arms openable and closeable in a lateral direction; a restraining portion capable of restraining the pair of support arms in a closed state and releasing a restraint of the pair of support arms; and wherein the restraining portion is movable with respect to the pair of support arms by a distal movement of the catheter hub relative to the inner needle, which releases the restraint with respect to the pair of support arms.

Provided are a catheter device and a catheter package which are capable of preventing a bend from being formed in a catheter body.

The catheter body includes a wire state discrimination portion which discriminates a protruding state and a non-protruding state, in which the wire state discrimination portion includes a stopper which allows a transition from the protruding state to the non-protruding state, and blocks a transition from the non-protruding state to the protruding state.

Intravascular devices and methods for intramural delivery of dissection fluids and infusates are disclosed herein. In some embodiments, the systems include an infusion assembly that can access a vessel wall at a depth within a layer of the vessel wall and advance a tissue manipulation component at approximately the same depth within the vessel wall to create an intramural space within the vessel layer. The infusion assembly can further deliver an infusate that includes a therapeutic drug or other agent into the intramural space.

Manual insertion device has retraction spring (202) and hollow septum configuration (224) implemented using barrel-shaped guides (108, 110) and a guiding boss (210) in insertion device housing (106), and provides a fluid path through alignment of septum openings, side-port openings and catheter openings upon complete catheter insertion. Button (200) causes manual insertion of introducer needle (204) and catheter (220) of a first barrel (108) into a skin surface, and loading of retraction spring (202) disposed in an adjacent second barrel (110). Once introducer needle (204) and catheter (220) are fully inserted, the introducer needle hub (206) is released and automatically retracted by release of the retraction spring (202), leaving the catheter (220) in the user's body. Septums (218, 224) and side-port openings (216, 228) in the button (200) and introducer needle (204) are thus aligned, creating an uninterrupted fluid path between a reservoir or pump and catheter (220).