Devices and methods for treating vascular defects, such as, for example, balloon-type aneurysms, are described herein. In one embodiment, an apparatus includes an insertion portion and an expandable implant. The expandable implant is configured to be deployed in an aneurysm and is coupled to the insertion portion. The expandable implant has a first portion and a second portion coupled to the first portion. The expandable implant is movable between a first configuration in which the first portion and the second portion are substantially linearly aligned and a second configuration in which the second portion at least partially overlaps the first portion.

An embodiment of the invention includes an expandable implant to endovascularly embolize an anatomical void or malformation, such as an aneurysm. An embodiment is comprised of a chain or linked sequence of expandable polymer foam elements. Another embodiment includes an elongated length of expandable polymer foam coupled to a backbone. Another embodiment includes a system for endovascular delivery of an expandable implant (e.g., shape memory polymer) to embolize an aneurysm. The system may include a microcatheter, a lumen-reducing collar coupled to the distal tip of the microcatheter, a flexible pushing element detachably coupled to an expandable implant, and a flexible tubular sheath inside of which the compressed implant and pushing element are pre-loaded. Other embodiments are described herein.

A vascular remodeling device has a plurality of sections, sized for deployment in a blood vessel, that is radially expandable from a collapsed state to an expanded state. Each section has a plurality of interconnected struts that define a waist, a proximal face, and a distal face. Each face comprises (i) a plurality of distal strut portions extending proximally from a distal side of the face, (ii) a plurality of proximal strut portions extending distally from a proximal side of the face, and (iii) a plurality of sub-struts, wherein, from each proximal strut portion, two of the sub-struts each extend to a different one of the distal strut portions.

An intrasaccular flow diverter includes a wire structure (e.g., a braided wire or a laser-cut hypotube), a thin-film mesh placed over the wire structure, and crimps fixing the thin-film mesh to the wire structure at each crimp. The wire structure and the thin-film mesh between adjacent crimps are expanded radially to form thin-film covered spheroid structures. When deployed in an aneurysm, the spheroid structures may volumetrically fill the aneurysm sac. An intrasaccular flow diverter with an umbrella structure includes a wire structure with a plurality of crimps along the wire structure, and a thin-film covered umbrella structure at one end of the wire structure. The wire structure between adjacent crimps is expanded radially to form a spheroid structure. When deployed in an aneurysm, the thin-film covered umbrella structure may cover the aneurysm neck.

An occlusion clip is disclosed herein. The occlusion clip comprises a resilient base strip including a plurality of base strip segments defining a hexagonal profile that represents an open state of the occlusion clip. A plurality of housing segments is provided on each of the base strip segments. A core element is disposed and extends within the housing segments defining a half of the hexagonal profile, wherein the core element is configured for linear movement within the housing segments. An actuator cable extends from each of the core elements, wherein in an actuated state, the core element is pulled via the actuator cable, and the pulling facilitates relative movement between the housing segments and the core elements causing the core element to make the housing segments collinear, thereby defining a closed configuration of the occlusion clip.

Systems and methods related to polymer foams are generally described. Some embodiments relate to compositions and methods for the preparation of polymer foams, and methods for using the polymer foams. The polymer foams can be applied to a body cavity and placed in contact with, for example, tissue, injured tissue, internal organs, etc. In some embodiments, the polymer foams can be formed within a body cavity (i.e., in situ foam formation). In addition, the foamed polymers may be capable of exerting a pressure on an internal surface of a body cavity and preventing or limiting movement of a bodily fluid (e.g., blood, etc.).

Magnetic anastomosis devices constructed from magnetic segments coupled together with members that help the devices spontaneously transform from a linear delivery configuration to a polygonal deployment configuration. When two devices are joined together over tissue(s), the compressive force causes the tissue(s) to necrose and form an anastomosis. By altering the arrangement of the magnetic poles of the magnetic segments in the devices, the magnetic interaction between paired devices can be altered. This property gives surgeons flexibility in choosing how much attractive force the devices will experience during a procedure.

Devices, methods and systems are provided for occluding a left atrial appendage. In one embodiment, a medical device includes a cover portion and a foam anchor portion with a flexible member coupled therebetween. The cover portion is configured to be positioned over an ostium of the left atrial appendage. The foam anchor portion extends between a proximal end and a distal end to define a length and an axis defined along the length of the foam anchor portion. The foam anchor portion defines a curved external surface radially extending relative to the axis such that the curved external surface extends between the proximal and distal ends of the foam anchor portion. The foam anchor portion is configured to self-expand to provide an outward biasing force from the curved external surface such that a circumferential surface area of the curved external surface biases against tissue of the left atrial appendage.

A vascular implant configured for occluding a vasculature of a patient having a biocompatible polymeric structure formed of a plurality of filaments spaced to maintain surface porosity and an inner radiopaque coil positioned within the longitudinally extending opening of the polymeric structure and attached to the polymeric structure. The polymeric structure and radiopaque coil are attached forming a joint at the distal end.

Embodiments of the present invention provide devices and methods for treating various target sites, such as vascular abnormalities. For example, a medical device according to one embodiment includes at least one layer of a fabric of braided strands having proximal and distal ends and a central axis extending therebetween. The medical device has an expanded configuration a generally frustroconical shaped portion at each end. The medical device is configured to be constrained to a reduced configuration for delivery through a diagnostic catheter and to at least partially return, when unconstrained, towards the expanded configuration.