A catheter assembly includes: a catheter; a catheter hub fixed to the catheter; an inner needle inserted through the catheter; a grip fixed to and holding the inner needle; a first support portion, which is a member separate from the grip and is configured to support an outer side of the catheter; and a second support portion, which is a member separate from the grip, has at least a part that is located at a position facing the first support portion, and is configured to support the outer side of the catheter. The first support portion and the second support portion are releasably engaged with each other.

Provided is a tubular member moving apparatus. A tubular member moving apparatus is configured to move a tubular member and includes a first housing through which the tubular member passes, a driving roller unit including a driving roller provided in the first housing and disposed at one side of the tubular member, a driven roller unit including a first driven roller disposed at the other side of the tubular member, a first actuator configured to provide driving power for rotating the driving roller, and a second housing separably coupled to the first housing and configured to accommodate the first actuator therein.

An intravenous catheter device may include a guidewire for actively repositioning the catheter tip. A guidewire assembly may be configured to enable a clinician to actively reposition the catheter tip by moving proximal ends of segments of the guidewire. By repositioning the catheter tip, the guidewire assembly may facilitate the collection of a blood sample or the injection of a fluid through the catheter even in instances when the catheter tip has become occluded.

A vascular access device may include a housing, which may include a distal end, a proximal end, and a lumen extending through the distal end of the housing and the proximal end of the housing. The distal end of the housing may include a connector configured to couple to a catheter assembly. The vascular access device may include a bag, which may be coupled to the proximal end of the housing. The vascular access device may include an instrument and a pincher disposed within the bag. The pincher may be configured to pinch the instrument to move the instrument distally through the lumen of the housing and into the catheter assembly.

A catheter extension set may include a housing, which may include a distal end, a proximal end, and a lumen. The catheter extension set may include a distal connector coupled to the distal end of the housing and configured to couple to a catheter assembly. The catheter extension set may include a handle, an advancement element, and an instrument. The instrument may extend through a U-shaped channel of the advancement element and may include a fixed first end and a second end. A translation feature may be disposed between the handle and the housing and within a pocket of the advancement element such that in response to distal movement of the handle a first distance, the advancement element moves distally within the lumen the first distance and the second end of the instrument advances distally a second distance. The second distance may be at least twice the first distance.

A needle assembly of a catheter system may include one or more features to facilitate flashback confirmation of catheterization while also preventing buildup of positive pressure within a flashback chamber of the needle assembly. The needle assembly may include a plug, which may include an aperture for receiving an introducer needle. A proximal opening of the introducer needle may be accessible from the proximal end of the needle hub. The plug may include a vent between an outer surface of the plug and an inner surface of the needle hub to prevent the buildup of positive pressure. The plug may include an extended distal end that reduces a volume of the flashback chamber. The plug may include a window in fluid communication with a notch of the introducer needle. Blood may flow from the notch into the flashback chamber with a reduced volume via the window of the plug.

Rapidly insertable central catheters (“RICCs”), introducers, and insertion devices including combinations and methods thereof are disclosed. For example, a RICC system can include an introducer and a RICC insertion assembly including a RICC assembly disposed in a RICC insertion device. The RICC assembly can include a RICC, an access guidewire, and a splittable casing over a catheter tube of the RICC and the access guidewire forming a longitudinal composite. The RICC insertion device can include a frame and a nose cover forming a split channel that splits away from a through channel of a nose of the frame. The RICC insertion device can be configured for advancing the RICC assembly by rolling the longitudinal composite across roller wheels disposed in the frame. The through channel can be configured for advancing the catheter tube therethrough while the split channel can be configured for both splitting and passing the splittable casing therethrough.

An optical guidewire system employs an optical guidewire (10), an optical guidewire controller (12), a guide interface (13) and an optical connector (15). The optical guidewire (10) is for advancing a catheter (20) to a target region relative to a distal end of the optical guidewire (10), wherein the optical guidewire (10) includes one or more guidewire fiber cores (11) for generating an encoded optical signal (16) indicative of a shape of the optical guidewire (10). The optical guidewire controller (12) is responsive to the encoded optical signal (16) for reconstructing the shape of the optical guidewire (10). The guidewire interface (13) includes one or more interface fiber core(s) (14) optically coupled to the optical guidewire controller (12). The optical connector (15) facilitates a connection, disconnection and reconnection of the optical guidewire (10) to the guidewire interface (13) that enables a backloading the catheter (20) on the optical guidewire (10).

Systems and methods for positioning a wire for advancement through a vessel wall, and advancing it through one or more vessel walls, generally include a delivery catheter and an alignment catheter or a receiving catheter, and a guidewire. In some variations, the systems and methods may be used to bypass an occlusion or other barrier that may prevent advancement of a wire or tools through an endoluminal space. In these variations, the systems and methods include a delivery catheter, a bypass catheter, a receiving catheter, and a guidewire. The delivery and receiving catheters each generally include a side aperture, a deflection surface, and an alignment element, and the bypass catheter generally includes two side apertures, two deflectors, and two alignment elements. In some variations, the systems and methods may assist in treatment of a patient suffering from critical limb ischemia.

The invention relates to a measurement device 1 comprising a rotatable magnetic object 4 which can oscillate with a resonant frequency if excited by an external magnetic torque. The measurement device 1 is adapted such that the resonant frequency depends on the temperature or on another physical or chemical quantity like pressure, in order to allow for a wireless temperature measurement or measurement of the other physical or chemical quantity via an external magnetic field providing the external magnetic torque. This measurement device can be relatively small, can be read-out over a relatively larger distance and allows for a very accurate measurement.