An assembly-type device for the treatment of tricuspid regurgitation is proposed. The assembly-type device includes: a fixing member for the pulmonary artery, the fixing member installed in the pulmonary artery; a connecting tube provided with a connecting tube lumen formed therein to be movable along a connecting wire; an assembly part provided with a first assembly coupled to a lower end of the fixing member for the pulmonary artery and a second assembly coupled to an upper end of the connecting tube, wherein the fixing member for the pulmonary artery and the connecting tube are assembled together; a fixing member for inferior vena cava, the fixing member coupled to a lower end of the connecting tube and installed in the inferior vena cava; and a blocking part coupled to one side of the connecting tube and obliquely passing through a tricuspid valve to block an orifice of the tricuspid valve.

A method for transcatheter delivery to a native heart valve needing replacement. A first component is attached to the native annulus upstream of the native leaflets maintaining native leaflet function, and is held to the native annulus by barbs that are activated by a torus balloon after the first component is fully expanded. The torus balloon can be implanted along with the support frame. A limiting cable restricts further expansion of the first component and holds a second component that contains the replacement leaflets.

Prosthetic heart valves described herein can be deployed using a transcatheter delivery system and technique to interface and anchor in cooperation with the anatomical structures of a native heart valve. Some embodiments of prosthetic valves described herein include an anchor portion that couples to the anatomy near a native valve, and a valve portion that is mateable with the anchor portion. In some such embodiments, the anchor portion and/or the deployment system includes one or more prosthetic elements that temporarily augment or replace the sealing function of the native valve leaflets.

A method for mechanically capturing and removing a thrombus from a blood vessel includes contacting the thrombus with an inner catheter. A self-expanding body is advanced toward the thrombus, wherein the self-expanding body has a proximal end fixed to a distal end of an elongate catheter. The self-expanding body is preferably made from nickel-titanium and includes a tapered proximal end portion and an open distal end. The self-expanding body preferably has a mesh structure. The self-expanding body is allowed to self-expand in the blood vessel. At least a portion of the thrombus is captured by the self-expanding body and the captured thrombus is then retrieved into a lumen of an aspiration catheter. Negative pressure is applied through the lumen of the aspiration catheter during retrieval of the captured thrombus. A thrombolytic drug may be delivered into the blood vessel before capturing and removing the thrombus.

A kit for use in performing joint arthroplasty on a head of a long bone is disclosed. The kit includes: a first implant including a first implant articulating surface and an opposed first implant mounting surface having a first implant location feature; and an instrument for preparing a cavity in the head of the long bone. The instrument includes a body and a punch extending from the body. The punch includes a portion thereof having a shape similar to the first implant location surface of the implant. A method for providing joint arthroplasty is also disclosed.

There is provided herein a breast implant comprising: a base having a first diameter, the base is configured to rest against a subject's chest wall when implanted; a dome having a second diameter, the dome is configured to be positioned within breast parenchyma underneath a nipple-areola complex when implanted; and an elongated projecting structure extending between the base and the dome, wherein the implant is configured to be inserted into a subject's breast as an internal supporting skeleton and to affect the projection of breast.

An intraluminal device and method of fixation of an intraluminal device to resist distal migration in a mammalian lumen or hollow organ that is subject to peristalsis, according to an aspect of the invention, includes spaced apart wall portions connected with a connector. The wall portions are configured to the size and shape of a portion of the lumen or hollow organ and the connector is configured to be positioned against a wall of the lumen or hollow organ. The intraluminal device is positioned in a mammalian lumen or hollow organ that is subject to peristalsis. The device is fixed in the lumen or hollow organ against distal migration, wherein tissue lining the lumen or hollow organ bridges over the connector. The device is explanted after tissue bridges over the connector including separating the connector from one or both of the wall portions and withdrawing the connector axially from the tissue bridging over the connector.

A device for retrieval of a vena cava filter is provided. The retrieval device has, approximately, an umbrella shape and consists of a central shaft; a plurality of frame struts, attached to frame strut attachment points on the central shaft and disposed radially about the central shaft; and a plurality of snare wires. The retrieval device has a collapsed configuration for insertion and removal from a blood vessel of a patient and an expanded state for capturing an intravascular filter in the blood vessel of the patient. The plurality of snare wires provides multiple points at which a vena cava filter, particularly one that has become misaligned during deployment or treatment, can be caught. The frame struts can be substantially sinusoidal in shape and made of shape memory metal, such as Nitinol. The snare wires can be made of a biocompatible material such as silk, polyester, polypropylene, or nylon.

A vascular filter system and method are disclosed. In one embodiment, the filter system comprises a dispensing needle, a guidewire and a catheter releasably attached to a filter dispenser which stores a length of filter wire. The filter wire dispenser has a guide tube which guides the filter wire into the catheter and then into a vein during surgical implantation. The filter wire is configured to form into a predetermined shape as it is deployed from the needle. The shape of the filter wire captures blood clots in the blood stream. The filter wire may be configured with a perforated section and a non-perforated section. Perforations are in fluid communication with an inner hollow lumen in the filter wire.

The invention is a method for reducing regurgitation through a mitral valve. The device and method is directed to an anchor portion for engagement with the heart wall and an expandable valve portion configured for deployment between the mitral valve leaflets. The valve portion is expandable for preventing regurgitation through the mitral valve while allowing blood to circulate through the heart. The expandable valve portion may include apertures for reducing the stagnation of blood. In a preferred configuration, the device is preferably configured to be delivered in two-stages wherein an anchor portion is first delivered and the valve structure is then coupled to the anchor portion. In yet another embodiment, the present invention provides a method of forming an anchor portion wherein a disposable jig is used to mold the anchor portion into a three-dimensional shape for conforming to a heart chamber.