Systems, devices and methods for treating lymphatic congestion are disclosed. In one method, a balloon is placed at or near the veno-lymph junction. The balloon is inflated and deflation through cycles of slow inflation and rapid deflation. In another embodiment, an arteriovenous fistula is created near the veno-lymph junction. Alternate embodiments may also include axial pumps, stents, or balloons in combination with the fistula. These devices and methods create an acceleration of the blood flow past the lymphatic duct which reduces local pressure via the Venturi effect and according to the Bernoulli principle which facilitates lymph entering into the bloodstream.

The present disclosure relates to stent graft devices for endovascular repair of aneurysms. A stent graft device according to the present disclosure comprises: a membrane defining a lumen between a proximal end and a distal end of the membrane, the lumen for fluid communication distally therethrough; a plurality of fenestrations disposed on the membrane and fluidly communicable with the lumen; and a plurality of protrusions carried by the membrane, each protrusion extending inwardly into or outwardly from the lumen. Fluid communicated from the plurality of fenestrations is deflectable or deflected by the plurality of protrusions.

The invention concerns a medical device, in particular a flow diverter, having a radially self-expandable lattice structure (10) which is tubular at least in some regions and which is composed of a plurality of interwoven individual wires (11) which form meshes (12) of the lattice structure (10), wherein at least some of the individual wires (11) have an X-ray visible core material (11a) and a superelastic mantle material (11b), wherein a plurality of directly adjacent meshes (12) in the circumferential direction of the lattice structure (10) form a mesh ring (13), wherein in a fully self-expanded state, the lattice structure (10) has an expansion diameter D.sub.exp, the mesh ring (13) has a mesh number n, and the core material (11a) has a core diameter d.sub.core, and wherein for the core diameter d.sub.core, the following holds:

d.sub.core=f.Math.(D.sub.exp/n)

wherein the following holds for a visibility factor f:

0.08≤f≤0.15

The described invention provides an endovascular stent device comprising a tubular structure comprising a circumference; wherein a flow-diverting portion of the circumference is covered by a flow-diverting material; a length (l) from a proximal end to a distal end; and an inner diameter (d); wherein the flow-diverting portion of the circumference comprises a length (l′); and the flow-diverting portion of the circumference covers at least 1% to at least 100% of the endovascular stent device. According to some embodiments, the flow-diverting material is adapted to increase blood vessel wall adherence and minimize risk of an endoleak.

A flow-diverting implant includes a saddle-shaped braided mesh diverter that is sized to provide adequate blocking coverage of a neck of an aneurysm. The diverter is anchored using minimally profiled, generally circular anchors that present little to no resistance to blood flow and are unlikely to create thrombosis. A locator extends into the aneurysm to ensure the diverter is optimally positioned over the neck of the aneurysm.

A medical implant (20) includes first and second ring members (22, 24), each including a resilient framework (26) having a generally cylindrical form. A tubular sleeve (28) is fixed to the first and second ring members so as to hold the ring members in mutual longitudinal alignment, thereby defining a lumen (32) passing through the ring members. A constricting element (30) is fit around the sleeve at a location intermediate the first and second ring members so as to reduce a diameter of the lumen at the location.

An implantable device includes an outer tubular member defining a longitudinal axis and a lumen. The outer tubular member includes: an outer wall portion having a plurality of first strands defining a plurality of first openings therebetween, the outer wall portion having a first porosity; and an inner baffle portion disposed within the lumen, the inner baffle portion including a plurality of second strands defining a plurality of second openings therebetween, the inner baffle portion having a second porosity that is lower than the first porosity of the outer wall portion.

A cannula cut spiral flow inducing stent includes a plurality of spiral inducing flow diverters that each include a piece of sheet metal with a helically shaped flow surface. A proximal stent region, which includes a plurality of first struts, is joined to a proximal end of each of the spiral inducing flow diverters. A distal stent region, which includes a plurality of second struts, is joined to a distal end of each of the spiral inducing flow diverters. All of the first struts and all of the second struts share a cannula thickness, but the shaped pieces of sheet metal may have a lesser thickness.

An artificial or modified natural blood flow tubing has a helical-flow inducer to induce helical flow in such a fashion as to eliminate or reduce turbulence. One inducer is a tubular stent of expansible mesh having a helical vane.

An occlusion device that includes an inner embolic element with a proximal section and a distal section, wherein the distal section has a first stiffness and the proximal section has a second stiffness. An expandable mesh is included that is capable of being transformed between a collapsed position and an expanded position, wherein the expandable mesh is disposed over a portion of the proximal section of the inner embolic device and the first stiffness is greater than the second stiffness.