Apparatus and methods are described including identifying a subject as suffering from a condition that causes the subject to have elevated central venous pressure. In response thereto, a device is placed inside the subject's vena cava, and the device is deployed inside the subject's vena cava, such that, in a passive manner, the device reduces blood pressure within the subject's renal veins relative to the subject's central venous pressure. Other applications are also described.

Apparatus and methods are described including identifying a subject as suffering from a condition that causes the subject to have elevated central venous pressure. In response thereto, a device is placed inside the subject's vena cava, and the device is deployed inside the subject's vena cava, such that, in a passive manner, the device reduces blood pressure within the subject's renal veins relative to the subject's central venous pressure. Other applications are also described.

A vascular stent, including an inner stent tube as well as a proximal support and a distal support which are arranged on an outer wall of the inner stent tube. When the vascular stent is in a compressed configuration, the proximal support and the distal support are both folded and close to the outer wall of the inner stent tube; when the vascular stent is expanded from the compressed configuration to an expanded configuration, a free end of the proximal support expands towards the distal end of the vascular stent, and a free end of the distal support expands towards the proximal end of the vascular stent. The vascular stent can be anchored to a main stent tube in a blood vessel by the proximal support and the distal support, preventing the vascular stent from shifting or becoming dislodged after being transplanted into the main stent tube.

An orientable intravascular device having a “twelve o'clock” marker on a proximal and distal end for treating an aneurysm, including a packaging catheter with an identical fixed non-round shaped inner lumen, a pusher wire having an occlusion device releasably disposed on the distal end of said pusher wire, preloaded at a fixed circumferential orientation, with corresponding markers on the outside of said packaging catheter, a hub having an inner lumen that is shaped to marry with the outer lumen of the packaging catheter to deliver a delivery wire and occlusion stent in a predicted orientation, and maintaining such orientation as the wire and stent are advanced through said delivery catheter, and while said delivery catheter is withdrawn. Methods of using same are disclosed.

An orientable intravascular device having a “twelve o'clock” marker on a proximal and distal end for treating an aneurysm, including a packaging catheter with an identical fixed non-round shaped inner lumen, a pusher wire having an occlusion device releasably disposed on the distal end of said pusher wire, preloaded at a fixed circumferential orientation, with corresponding markers on the outside of said packaging catheter, a hub having an inner lumen that is shaped to marry with the outer lumen of the packaging catheter to deliver a delivery wire and occlusion stent in a predicted orientation, and maintaining such orientation as the wire and stent are advanced through said delivery catheter, and while said delivery catheter is withdrawn. Methods of using same are disclosed.

The presently disclosed subject matter is directed to a dual stent assembly useful in treating one or more bifurcation lesions in a subject. The dual stent assembly includes a first stent and a second stent. The first stent comprises a body, proximal and distal ends, and a flare positioned at the proximal end. The first stent translates between a compressed configuration and a deployed configuration. The second stent is defined by a body comprising a sidewall, proximal and distal ends, and an orifice positioned on the body that extends through the sidewall. The second stent is translatable between a compressed configuration and a deployed configuration. The orifice is sized and shaped to align with the proximal end of the first stent when the second stent is deployed.

The presently disclosed subject matter is directed to a dual stent assembly useful in treating one or more bifurcation lesions in a subject. The dual stent assembly includes a first stent and a second stent. The first stent comprises a body, proximal and distal ends, and a flare positioned at the proximal end. The first stent translates between a compressed configuration and a deployed configuration. The second stent is defined by a body comprising a sidewall, proximal and distal ends, and an orifice positioned on the body that extends through the sidewall. The second stent is translatable between a compressed configuration and a deployed configuration. The orifice is sized and shaped to align with the proximal end of the first stent when the second stent is deployed.

The presently described stent-graft includes a stent frame forming a cavity and frame wires extending around the stent frame perimeter. The stent frame is formed such that the cavity cross sectional area decreases along a first length of a flow restricting section to a cavity minimum cross sectional area and increases along a second length of the flow restricting section. The first length extends from a cavity proximal cross sectional area to the cavity minimum cross sectional area and the second length extends from the cavity minimum cross sectional area to a cavity distal cross sectional area. When placed within a patient's aorta, the stent-graft may help the treatment of congestive heart failure by increasing blood flow to the kidneys. The provided stent-graft may also be adapted for placement within a patient's urethra to help the treatment of urinary incontinence.

The presently described stent-graft includes a stent frame forming a cavity and frame wires extending around the stent frame perimeter. The stent frame is formed such that the cavity cross sectional area decreases along a first length of a flow restricting section to a cavity minimum cross sectional area and increases along a second length of the flow restricting section. The first length extends from a cavity proximal cross sectional area to the cavity minimum cross sectional area and the second length extends from the cavity minimum cross sectional area to a cavity distal cross sectional area. When placed within a patient's aorta, the stent-graft may help the treatment of congestive heart failure by increasing blood flow to the kidneys. The provided stent-graft may also be adapted for placement within a patient's urethra to help the treatment of urinary incontinence.

A system for treating a bifurcation includes first and second delivery catheters. The first catheter has a first shaft, a first expandable member adjacent the distal end of the first shaft, an auxiliary expandable member disposed under the first expandable member, and a first radially expandable stent disposed over both the first expandable member and the auxiliary expandable member. The second delivery catheter has a second shaft, and a second expandable member adjacent the distal end of the second shaft. A portion of the second catheter is disposed under a portion of the first stent, and a portion of the second delivery catheter passes through a side hole in the first stent. The first stent is crimped over the first and second catheters such that the first stent remains attached to the first and the second catheters during advancement of the catheters through a blood vessel.