A hollow probe enabling insertion and accommodation of endoscopic and other instruments advancing within a lumen includes a central valve unit featuring a central bore and at least one valve for controlling the introduction and withdrawal of fluid into the central bore. A sliding tubular sheath is movably disposed inside the central valve unit. An impermeable flexible sleeve is sealingly anchored to the central valve unit and folds over to cover both the inside and outside of the sheath to sealingly envelop the sheath and contain the fluid, together with the valve unit, while allowing sliding of the sleeve-covered-sheath. An endoscope adapter is mountable to the proximal end of the sleeve-covered-sheath, for allowing insertion of the endoscope through the adapter into the sleeve-covered-sheath, includes at least one gasket for sealing at least one gap between the endoscope and the sleeve-covered-sheath for withholding fluids from escaping.

An everting balloon system is disclosed that can be used for the placement of an IUD within the uterine cavity of a female patient. The everting balloon system with IUD can be used to access a uterine cavity at specific locations in the fundus. A one-handed IUD delivery system for placement with an everting catheter is disclosed. An IUD loading system for placement within an everting catheter is disclosed. The everting catheter with an IUD can simplify the process of IUD placement within the uterine cavity.

Mechanical thrombectomy apparatuses including an inverting, rolling conveyor region (“tractor”) at the distal end that are configured to grab and remove thrombus material. In particular, described herein are mechanical thrombectomy apparatuses that are adapted to prevent premature deployment of the tractor, e.g., by including a tractor hold (e.g., a housing, a lock, a clamp, etc.) or the like to secure the outer end of the tractor against and/or relative to the elongate inversion support.

Systems for providing access across a site of obstruction and methods for manufacturing and using such systems are provided. Such systems may include a cannula having a lumen, an everting member coupled to the cannula, and a push assembly having a pathway. The push assembly may be slidably disposed within the lumen of the cannula and connected to a proximal end of the everting member to move the everting member from an inverted position inside the cannula to an everted position outside the cannula. The systems may also include a hard tube having a passageway, the hard tube slidably disposed on or within the pathway of the push assembly. The hard tube being designed to create and opening within and traverse and obstruction within a structure.

A device for catheterization is disclosed. Such a device includes a hollow catheter, a cylindrical sheath, and a flange through which the catheter passes. Before insertion, the sheath begins at a first opening near the catheter tip and extends into the catheter to a first circumferential fold, then back towards the catheter tip to a second circumferential fold about the tip to the exterior surface, and ends at a second opening attached to the flange. As the device is inserted up to a length, the flange abuts the cavity opening, and a corresponding length of the sheath deploys from the catheter interior, around the first and second circumferential folds, to the catheter outer surface. Once fully inserted, all, or a substantial portion, of the sheath initially positioned within the catheter has been deployed to the outer surface, thereby forming a protective barrier between the catheter and the surrounding tissues.

A catheter delivery system (10) includes: (i) an introducer sheath (12); (ii) a catheter (14) disposed at least partially within the introducer sheath and movable axial along the introducer sheath; (iii) an invaginating tube (16) sealably secured at or near a first axial end (16a) of the invaginating tube to the introducer sheath at or near a first axial end (12 a) of the introducer sheath; (iv) a runner (28) slidably connected to the catheter; (v) the invaginating tube being sealably secured at or near a second axial end (16b) of the invaginating tube to the runner, such that the runner with inavaginating tube secured thereto is sealably connected to the catheter and movable axially along at least a portion of the catheter; and (vi) means for pressurising the annular space defined between the introducer sheath, the catheter and the invaginating tube.

An invaginating device includes an inner elongate member and an outer flexible tube with invaginated axial ends. The outer flexible tube is: disposed at a first axial end of the inner elongate member; concentric with the inner elongate member; sized to provide a radial gap there between; sealably connected at the axial ends of the outer flexible tube to the inner elongate member, with the axial spacing between such sealed axial ends being less than the axial length of the outer tube; and extendable to protrude from the first axial end of the inner elongate member and retractable to reduce such protrusion from the first axial end of the inner elongate member. Fluid contained within the radial gap defined between the inner elongate member and the outer flexible tube is either pressurized or a non-compressible fluid. An actuator is: movable relative to the inner elongate member; and engageable with the outer flexible tube to extend the outer flexible tube relative to the first axial end of the inner elongate member.

The present disclosure provides an introducer device including an outer tube defining a first lumen, and an inner tube defining a second lumen, and a sheath coupled thereto. The first end of the inner tube is positioned in the first lumen of the outer tube, and the inner tube is configured to translate within the first lumen in a direction towards the first end of the outer tube from a first position to a second position. The first end of the sheath is coupled to the first end of the outer tube, and the second end of the sheath is coupled to the first end of the inner tube. The introducer device further includes an inlet port in fluid communication with the inner surface of the outer tube, and one or more steering wires coupled to the sheath that are configured to bias a direction of a leading edge of the sheath as the sheath everts from a retracted position to an extended position.

Mechanical thrombectomy apparatuses including an inverting, rolling conveyor region (“tractor”) at the distal end that are configured to grab and remove thrombus material. In particular, described herein are mechanical thrombectomy apparatuses that are adapted to prevent premature deployment of the tractor, e.g., by including a tractor hold (e.g., a housing, a lock, a clamp, etc.) or the like to secure the outer end of the tractor against and/or relative to the elongate inversion support.

Aspects of this disclosure relate to catheter assemblies, that include an inner tube component, an outer tube component that fits over the inner tube component, and a disposable layer of film that isolates the otherwise fluid-exposed portions of the catheter from the fluid it drains. This disposable film can be removed at regular intervals and obviates the need for catheter exchanges as the isolating disposable film, rather than the catheter itself, is removed. The principal characteristic of the disposable film is that it is relatively impermeable to fluid, for example, bodily fluids.