Disclosed herein is an indwelling urinary catheter having a guidewire anchoring mechanism. The indwelling urinary catheter includes a catheter tube having a proximal opening, a distal opening, a catheter tube lumen with the catheter tube having a first wall thickness. The guidewire anchoring mechanism is configured to transition between an insertion state and an anchored state. The guidewire anchoring mechanism can include a proximal portion having a top cap, a collapsible section having a second wall thickness less than the first wall thickness, and a distal portion including a holder cap coupled to a holder. The holder can be coupled to the catheter tube, the distal portion can be in communication with the proximal portion, and a guidewire can be coupled to the proximal portion, the guidewire extending through the catheter tube lumen to the distal portion.

The disclosure relates to the area of medicine and surgery, in particular it pertains to a drainage catheter (100) that comprises a high capacity drain comprising a radiological guide (110a) with a suction mesh (110b), a safety control opening/closing system (160), an internal pneumatic clamping system (140) and/or an external adhesive skin protection system (150). A reservoir for the administration of local anesthetics and antibiotics may be additionally provided. The disclosed catheter system optimizes flow surface, facilitates procedures for handling and removal of drainage, reduces the risk of occlusions, pain, injuries and infections of the surrounding skin and maintains sufficient structural strength to prevent collapses, among others.

Some embodiments of a medical device anchor system includes an anchor sleeve and a catheter (or other medical instrument) to advance though a working channel of the anchor sleeve. The anchor sleeve may have a subcutaneous cuff device arranged along an outer surface. In such circumstances, the embedded cuff device can inhibit the migration of infection from outside the skin and into the blood stream.

Expandable sheaths are disclosed herein. In some embodiments, a braided layer is positioned radially outward from a first polymeric layer. The braided layer includes a plurality of filaments braided together. A second polymeric layer is positioned radially outward of the braided layer, such that the braided layer is encapsulated between the first and second polymeric layers. In some embodiments, a braided layer is adhered to a sealing layer that is impermeable to blood flow. Methods of making and using the devices disclosed herein are also disclosed, as are crimping devices that may be used in methods of making the devices disclosed herein.

A peritoneal dialysis catheter includes: a catheter tube defining a lumen for carrying peritoneal dialysis fluid to at least one aperture located at or near a distal end of the lumen; at least one cuff located along the outside of the catheter tube; an access site proximally spaced from the at least one cuff, the access site allowing an antimicrobial agent to be introduced into the catheter tube; a reservoir operable with the catheter tube and in fluid communication with the access site, the reservoir storing an amount of the antimicrobial agent received from the access site after an antimicrobial agent introducer is removed from the access site; and a delivery area of the catheter tube in fluid communication with the reservoir, the delivery area positioned so as to target delivery of the antimicrobial agent to the at least one cuff or other desired location along the catheter tube.

A medical delivery device for delivering a medical device includes a navigable elongated member, a deployment bay, and a compression mechanism. The deployment bay may be configured to house the medical device as the medical device is navigated to the target site. The deployment bay may be at a distal end of the delivery device and may include a distal opening through which the medical device may be deployed. The compression mechanism is configured to longitudinally compress in response to a predetermined force such that the elongated member and deployment bay are relatively closer together along a longitudinal axis of the delivery device.

A delivery catheter system includes a guide catheter, an anchor catheter, a collapsible and expandable anchor, a balloon formed from a portion of the positioning catheter, and a needle. The anchor may be for anchoring a prosthetic heart valve in a native heart valve. The anchor may be configured to be received within the anchor catheter. The balloon may be inflated or deflated and provide mechanical support to enable the needle to pierce a ventricle wall. A metallic guide wire can simultaneously be inserted through the aorta to outline the heart when viewed through fluoroscopic imaging.

An anchor strain relief member provides resistance to disengagement from a hemostatic valve due to forces tending to force the catheter in a proximal direction. The anchoring strain relief member is distal to a hub, joined to the catheter outer surface, and comprises a sealing portion that has at least one ridge that has a ridge tip and a ridge height defined by a distance from the ridge tip to the catheter central axis. Methods of forming a nested catheter system are described using a catheter with an anchor strain relief as the inner catheter for the nested catheter set. Systems of a hemostatic valve and a suitable catheter with an anchor strain relief member can provide for desired assemblies of components.

An operation device is configured to remotely operate a medical device including a movement mechanism configured to move an elongated body to be inserted into a living body forward and backward along the longitudinal direction of the elongated body, and includes an endless linear member. The medical device is operated based on a forward and backward movement of the linear member in the endless axis direction along an endless axis.

A catheter used for percutaneous endovascular procedures is described. The catheter is configured to be used for engagement and treatment of obstructive lesions in a patient's vasculature. The catheter includes a tube having a leading edge that is configured to score or cut a lesion in a vasculature. The tube may be an expandable outer tube, and placed around an inflatable inner tube, such that inflation of the inner tube expands the outer tube. Expansion of the inner tube may connect or laterally lock the inner tube to the outer tube, allowing both tubes to move in unison through the vasculature. The leading edge can score or cut lesions as it moves in the vasculature.