An intravascular delivery device is disclosed comprising a delivery wire having a proximal and a distal end and an interior lumen extending there between and wherein said distal end comprises a connection interface adapted to matingly interlock with a proximal end portion of a medical implantable device, wherein said delivery device comprises a locking unit arranged to secure said connection interface in a locking position in which said medical implant is pivotably locked before a controlled release.

An example medical device for occluding the left atrial appendage is disclosed. The example medical device for occluding the left atrial appendage includes an expandable member having a first end region and a second end region. The expandable member comprises at least one inflation cavity and at least one valve member configured to selectively seal the inflation cavity. A first inflation media may be disposed within the at least one inflation cavity and a second inflation media may be disposed within the at least one inflation cavity. The second inflation media may be different from the first inflation media. The expandable member may be configured to expand and seal the opening of the left atrial appendage.

The present invention relates to a male contraception apparatus for obtaining a time-limited sterility of a male mammalian individual. The apparatus comprises a restriction device adapted to restrict the lumen of a vas deferens of the mammalian, and a controller operable to control the restriction device to restrict the lumen of the vas deferens during a controlled period to prevent sperms from reaching the urethra of the mammalian. The apparatus further comprises an implantable constriction device configured to gently constrict at least one portion of a tissue wall of the vas deferens to restrict the lumen of the vas deferens such that the flow of sperms in the vas deferens is restricted, and a stimulation device configured to stimulate the constricted wall portion of the tissue wall.

A colpotomy device includes a shaft assembly having a hollow outer shaft and an inner shaft disposed within, and rotatable and translatable relative to, the outer shaft, a handle assembly operably coupled to a proximal end of the shaft assembly, and configured to selectively rotate the inner shaft relative to the outer shaft, a colpotomy cup assembly including an outer cup and an inner cup disposed within the outer cup, wherein the inner cup is fixedly coupled to a distal end of the inner shaft, and the outer cup is fixedly coupled to a distal end of the outer shaft, and a cutting element coupled to the inner cup, such that the inner shaft the shaft assembly, inner cup, and cutting element rotate together relative to the outer shaft.

The present disclosure is directed toward drug coated balloons, and in particular to drug coated balloons having a microcrystalline structure and techniques for increasing vascular permeability for drug application and retention. Particular aspects may be directed to a medical device including a balloon having an outer surface, and a drug coating layer on the outer surface of the balloon. The drug coating layer includes microcrystals in a haystack orientation having random and a substantial absence of uniformity in placement and/or angle on the outer surface of the balloon.

The present disclosure relates to the field of delivery systems for precise navigation within and through body passages. Specifically, the present disclosure relates to delivery systems for accurate positioning and release of elements within tortuous, narrow and/or fragile passages. In particular, the present disclosure relates to a delivery system that includes a distal coil with sufficient flexibility to navigate through tortuous body passages, and which allows for controlled stretch when bent.

A release apparatus (100), a release system, a release method, and a treatment apparatus are disclosed. The release apparatus (100) uses two indicators, electric current and power comsuption, to determine whether the release process performed by the release system is successful. This reduces misjudgments, improves the accuracy of the determination of the release state. The release system also uses a self-loop structure, such that it is unnecessary to insert a conductive needle or electrode into the body of a patient, reducing the suffering of the patient.

An aneurysm treatment system can include an embolic implant, a delivery system, and a handle member that are collectively designed so that the combination of the handle member and the delivery system can be used as a deployment apparatus for the embolic implant. A proximal extension of the delivery tube can be placed inside a handle channel of handle member and the handle member can be manipulated to cause the proximal extension to bend to a predetermined angle with respect to the delivery tube, thereby separating the proximal extension from the delivery tube at a disconnection feature between the proximal extension and the delivery tube. The delivery tube includes a lumen having a pull wire that runs through the delivery tube and into the proximal extension. The proximal extension, pull wire, and handle member can be translated proximally in relation to the delivery tube to deploy the embolic implant.

An embodiment is directed to an embolic device comprised of a coil made of a first material and disposed on the inside of a tube structure made of a second material. The tube structure has micro-fabricated fenestrations formed in the tube to provide fluid communication between the lumen of the tube and the surrounding environment, thereby exposing the inner coil. The fenestrations also trip flow around the embolic device. In one embodiment, the embolic device is comprised of a tantalum coil on the inside of a polyetheretherketone (PEEK) tube. The PEEK tube has the advantage of providing a micro-machined delivery implant frame and radiopacity, while the internal tantalum coil provides radiopacity and thrombogenicity. A material other than PEEK may be used for embodiments of embolic devices without departing from the spirit of the disclosure.

Disclosed herein are detachment mechanisms for vaso-occlusive devices that allow for rapid operator-controlled release of the vaso-occlusive device into the selected site. Also disclosed are vaso-occlusive assemblies comprising these detachment mechanisms and methods of using these detachment mechanisms and vaso-occlusive assemblies.