Devices and methods for draining excess lymph fluid are disclosed. The device can be fixed to the blood vessel adjacent to the thoracic duct. The device can have a port for withdrawing lymph fluid exiting the thoracic duct. The device can have a cannula and/or subcutaneous port to draw the lymph fluid away from the thoracic duct and reduce hemostatic pressure in the lymphatic system.

A sheath for producing a fully sealed access to the interior of a vessel of an animal or human body comprises a base sheath having a tubular body defining a pass-through channel. The base sheath is adapted to be inserted into the vessel through a vessel aperture. The sheath further comprises an expansion device which is adapted to cooperate with the base sheath such that the outer diameter of the sheath increases in the region of the vessel aperture with the sheath in a stationary position in the vessel and upon actuation of the expansion device.

Surgical access ports useful in minimally invasive surgical procedures are provided. The access ports comprise a cannula that defines a passageway for one or more surgical instruments through a tissue tract and a dome extending from the cannula to provide an expanded diameter for receiving one or more surgical instruments.

A graft system may be provided. The graft system may include a graft, a hemostasis valve operably coupled to a proximal end of the graft, and a clamp disposed around the proximal end of the graft and configured to hold the hemostasis valve in place relative to the graft. The graft may include a woven or knitted fabric. The clamp may be removably, or permanently, attached to the graft. The hemostasis valve may include a slit membrane disposed within a housing. The hemostasis valve may include an introducer sheath coupled to the housing. The housing may include two portions coupled together along two axial seams, each axial seam extending from a proximal end to a distal end of the hemostasis valve. A grommet may be coupled to an end of the graft.

An access closure device for closing an opening in tissue is provided. The access closure device may comprise an implant delivery system and a sealant delivery mechanism. The implant delivery system may comprise a suture, a procedural sheath, a delivery tube, an deployable implant and a suture attached to the implant. The sealant delivery mechanism may comprise a sealant deliverable over a suture through the procedural sheath, configured to settle proximal an implant located in an access track.

A method of implanting a cardiac device featuring the insertion of an inner seal member through an opening in a pericardium about a living human heart. The inner seal member has a first sealing lip disposed inside the pericardium and surrounding an aperture through the inner seal member. An outer seal member is aligned with the inner seal member. The outer seal member has a second sealing lip disposed outside the pericardium, surrounding an aperture through the outer seal member. The inner seal member is secured to the outer seal member. The firsts sealing lip is engaged against an inner surface of the pericardium. The second sealing lip is engaged against an outer surface of the pericardium. A cardiac device is inserted into the pericardium through the apertures of the inner and outer seal members.

An access closure device for closing an opening in tissue is provided. The access closure device may comprise a balloon delivery system and a sealant delivery system. The balloon delivery system may comprise a suture, a delivery shaft, an inflatable balloon, and a balloon segment releasably attached to the delivery shaft. The sealant delivery system may comprise a sealant delivery shaft, an ejection tube, and a snare wire configured to snare a suture of the delivery system.

In one embodiment, an expandable access sheath including a planar sheet of material that is configured to be rolled up around an inflatable balloon, the sheet comprising an inner surface, an outer surface, a leading edge, a trailing edge, a proximal edge, and a distal edge, the sheet further including at least one locking tab that extends from either the inner surface or the outer surface of the sheet, wherein the leading edge of the sheet is configured to interface with the locking tab to lock the access sheath in a predetermined configuration in which the access sheath forms an inner working channel having a predetermined cross-sectional dimension after the access sheath has been expanded by the inflatable balloon.

A method of deploying a stent is disclosed. The delivery device includes: an outer sheath including a stent located within, the stent making frictional contact with and exerting outward force on an inner surface of the outer sheath. A first wire located coaxially within the lumen and the stent. The first wire has a distal end extending distally of the outer sheath, and a proximal end. extending proximally of the outer sheath. A filter is disposed within the outer sheath and coupled to the first wire and distally of the stent and a distal tip detachably coupled to the distal end of the outer sheath. The method includes separating the outer sheath from the distal tip and withdrawing to deploy the stent and the filter. The method further includes withdrawing the distal tip to collapse the filter. as well as withdrawing the filter and the distal tip through the stent.