Some implementations of an endovascular device include a stent graft with an expandable tubular metallic frame and a covering material disposed on at least a portion of the metallic frame. The stent graft defines a lumen therethrough. In a particular embodiment, a first balloon is disposed around an outer periphery of the stent graft, a second balloon is disposed around the outer periphery of the stent graft and spaced apart from the first balloon, and a third balloon is disposed within the stent graft lumen between the first balloon and the second balloon. The third balloon can be inflated to fully or partially occlude the lumen. The first and second balloons can be individually inflated to fully or partially shunt blood flow from a blood vessel through the stent graft. In some embodiments, sensors and an automated control unit are included to automate the operations of the endovascular device.

Assist device (10) for sclerosing treatment of varicose veins, aimed at being partially inserted into a blood vessel (20), including a tubular element (11), which has at least three ways (13, 14, 15), at least two of which (13, 14) are connected to at least one related inflatable balloon element (12, 12, 16) by at least one through hole (30, 31), and at least one remaining way (15) of said three ways (13, 14, 15) has at least one hole (32) for the passage of a sclerosing substance (17), aimed at reaching a wall (18) of said blood vessel (20), in which at least one (16) of said at least two balloon elements (12, 12, 16) has an elongated shape extending toward at least another balloon element (12, 12) and a volume comprised in the range of 30% to 99% of the space inside said blood vessel.

Assist device (10) for sclerosing treatment of varicose veins, aimed at being partially inserted into a blood vessel (20), including a tubular element (11), which has at least three ways (13, 14, 15), at least two of which (13, 14) are connected to at least one related inflatable balloon element (12, 12, 16) by at least one through hole (30, 31), and at least one remaining way (15) of said three ways (13, 14, 15) has at least one hole (32) for the passage of a sclerosing substance (17), aimed at reaching a wall (18) of said blood vessel (20), in which at least one (16) of said at least two balloon elements (12, 12, 16) has an elongated shape extending toward at least another balloon element (12, 12) and a volume comprised in the range of 30% to 99% of the space inside said blood vessel.

An adjustable flow narrow profile balloon device for use in an aorta has a catheter and an adjustable flow device comprising a scaffold having an anchored end fixed to the catheter, a movable end distal to the fixed end and support extending between the anchored end and the movable end, and a flexible tube attached to the support and at least one tension wire attached to the movable end and extending through the catheter such that the at least one tension wire is accessible to move the movable end of the balloon towards the anchored end when the catheter is positioned in the aorta. The adjustable flow device has a collapsed configuration; a fully occluded configuration in which the length of the support lies flat against the catheter and the flexible tube is inflated; and adjustable flow configurations allowing for a desired amount of fluid flow past the device.

Assist device (10) for sclerosing treatment of varicose veins, aimed at being partially inserted into a blood vessel (20), including a tubular element (11), which has at least three ways (13, 14, 15), at least two of which (13, 14) are connected to at least one related inflatable balloon element (12, 12, 16) by at least one through hole (30, 31), and at least one remaining way (15) of said three ways (13, 14, 15) has at least one hole (32) for the passage of a sclerosing substance (17), aimed at reaching a wall (18) of said blood vessel (20), in which at least one (16) of said at least two balloon elements (12, 12, 16) has an elongated shape extending toward at least another balloon element (12, 12) and a volume comprised in the range of 30% to 99% of the space inside said blood vessel.

Embodiments herein include devices and methods directed toward creating reverse flow within a vessel and thereby providing protection against embolic debris. Embodiments comprise a catheter and a plurality of occluders that are expandable and adjustable within a lumen to create low-pressure areas that reroute blood flow and embolic debris therein.

Improved methods and devices for performing an endoscopic surgery are provided. Systems are taught for operatively treating gastrointestinal disorders endoscopically in a stable, yet dynamic operative environment, and in a minimally-invasive manner. Such systems include, for example, an endoscopic surgical suite. The surgical suite can have a reversibly-expandable retractor that expands to provide a stable, operative environment within a subject. The expansion can be asymmetric around a stabilizer subsystem to maximize space for a tool and an endoscope to each be maneuvered independently to visualize a target tissue and treat the target tissue from outside the patient in a minimally invasive manner.

Interventional procedures on the carotid arteries are performed through a transcervical access while retrograde blood flow is established from the internal carotid artery to a venous or external location. A system for use in accessing and treating a carotid artery includes an arterial access device, a shunt fluidly connected to the arterial access device, and a flow control assembly coupled to the shunt and adapted to regulate blood flow through the shunt between at least a first blood flow state and at least a second blood flow state. The flow control assembly includes one or more components that interact with the blood flow through the shunt.

One disclosed embodiment comprises a method for treating lesions in the carotid artery of a mammalian body. The method comprises transcervical access and blocking of blood flow through the common carotid artery (with or without blocking of blood flow through the external carotid artery), shunting blood from the internal carotid artery and treating the lesion in the carotid artery.

A treatment system includes a guide sheath, and a catheter provided with a pressure-controlled element. The pressure-control element preferably includes an expanded configuration adapted to extend across a small feeder vessel branching from the splenic vein. The pressure-control element is positioned with the feeder vessel, and a therapeutic agent is delivered under pressure directly into the feeder vessel, where it is forced to penetrate deep into tissue. Pressure responsive elements for monitoring intravascular pressure are also provided to time delivery of the therapeutic agent for maximum uptake by the target organ.