An implant including an open end and a pinched end can have a predetermined shape. When in the predetermined shape, the tubular braid can include a proximal inversion and two segments, and the braid can be composed of one or more wires. The first segment can extend from the open end of the tubular braid to the proximal inversion. The second segment can be at least partially surrounded by the open end and extend from the proximal inversion to the pinched end. The tubular braid can also include at least one corrugated fold. The one or more corrugated folds can be located within the first segment, second segment, or both. The corrugated folds can be configured to assist in anchoring the example device when in the implanted shape within an aneurysm in a similar manner to stent struts to help the tubular braid hold its shape.

A delivery system employs a hold-release structure to deploy an implant at a target site in the vasculature of a patient. The hold-release structure may include two or more grasping members configured to close and exert an inward clamping force to hold the implant when the grasping members are constrained in a tubular member. The grasping members can open when unconstrained allowing the implant to be released. Alternatively, the hold-release structure may include two or more radially expandable members configured to exert an outward radial force when constrained by the tubular member allowing the hold-release structure to hold the implant against the tubular member. The radially expandable members can be configured to create a friction force on the implant allowing the hold-release structure to move the implant relative to the tubular member.

An endovascular system employs a lever structure to deploy an embolic device at a target site in the vasculature of a patient. The endovascular system comprises an elongate tubular member provided with a lever structure and an elongate detachment wire to assert an effort to the proximal portion of a lever member outwardly, thereby generating a load to the distal portion of the lever member inwardly to allow the lever structure to engage and secure the embolic device. The elongate detachment wire is disengageable from the lever structure to remove the effort asserted to the proximal portion of the lever member, thereby removing the load off the distal portion of the lever member to allow the lever structure to disengage and release the embolic device.

Disclosed are implantable medical devices for the occlusion of a bodily lumen, cavity, vessel, or organ, as well as methods for manufacturing such occlusion devices, and methods for treating a subject using the occlusion devices. The devices generally include a wire having shape memory properties and a flexible membranous material disposed about the wire. Some embodiments include a lateral fringe on the membranous material. Some embodiments include a fluid capture cup affixed to the wire.

A device for occluding a patient's left atrial appendage (LAA) device includes a self-expanding closure disc and an anchor. The self-expanding closure disc has an atrial side, an appendage side, and a peripheral edge configured to engage tissue on both an atrial side and an appendage side of an opening between the left atrium and the left atrial appendage. The self-expanding anchor extends from the appendage side of the self-expanding closure disc, and an annular sealing skirt extends about at least a portion of the appendage side of the self-expanding closure disc. the annular sealing skirt is more compliant than the self-expanding closure disc to seal over the left appendage side of the opening after implantation of the device in the LAA.

Implantable therapeutic devices and methods for endovascular placement of devices at a target site, such an opening at a neck of an aneurysm, are disclosed. Selected embodiments of the present technology have closures that at least partially occlude the neck of an aneurysm to stabilize embolic or coagulative treatment of the aneurysm.

Vaso-occlusive apparatuses, including implants, and methods of using them to treat aneurysms. For example, described herein are expandable vaso-occlusive implants that include one or more soft and expandable braided member coupled to a pushable member such as a coil that maybe inserted and retrieved from within an aneurism using a delivery catheter. In particular, the expandable implants described herein are configured to allow relatively soft and elongate implants to be pushed out of a cannula without binding up within the cannula.

The present disclosure relates to a braid for treating an aneurysm. The braid can include a proximal expandable portion for positioning inside the aneurysm and sealing across a neck of the aneurysm. The braid can also include a distal expandable portion distal of the proximal expandable portion, the distal expandable portion for filling the aneurysm.

Systems and methods for treating an aneurysm in accordance with embodiments of the present technology include intravascularly delivering an occlusive member to an aneurysm cavity via an elongated shaft and transforming a shape of the occlusive member within the cavity. The method may include introduction of an embolic element to a space between the occlusive member and an inner surface of the aneurysm wall. In some embodiments, the elongated shaft is detachably coupled to a distal portion of the occlusive member.

Expandable devices are disclosed herein. Several of the embodiments are directed towards an expandable device comprising a mesh configured to be expanded at a blood vessel bifurcation of a human patient. The mesh may comprise a tubular body portion and one or more circumferentially discontinuous articulating portions. The mesh may be expanded such that the one or more articulating portions are positioned at an angle to the tubular body portion.