A method of delivering a medicament to a limb of a patient body includes isolating a circulatory system of the limb from a circulatory system of the patient body, wherein the limb circulatory system is substantially all limb arteries and substantially all limb veins located between an isolation region and an end of the limb. A perfusion catheter is inserted into a limb artery in an antegrade position, while a collection catheter is inserted into a limb vein in a retrograde position. The blood flow of the limb circulatory system is then circulated by collecting the blood flow with the collection catheter and delivering the blood flow with the perfusion catheter. A medicament is perfused into the limb circulatory system with the perfusion catheter.

A sensor module has an arterial catheter connection hub. The sensor module has a perfusion inflow hub coupled through an arterial/portal blood chamber to the arterial catheter connection hub. The sensor module has a venous catheter connection hub. The sensor module has an effluent outflow hub coupled through a venous blood chamber to the venous catheter connection hub. The sensor module has an arterial sensor to sense a parameter of an arterial fluid flowing through the arterial/portal blood chamber. The sensor module has a venous sensor to sense a parameter of a venous fluid flowing through the venous blood chamber. The sensor module has a processor coupled to the arterial sensor and the venous sensor to determine a relationship between the parameter of the arterial fluid sensed by the arterial sensor and the parameter of the venous fluid sensed by the venous sensor.

Devices, systems, and methods for treating a blood flow passage are discloses herein. In one example, a treatment device includes an expandable element configured to be positioned within the passage and a reinforcing element. The expandable element may have an expanded configuration in which the expandable element defines a lumen therethrough. The reinforcing element may be positioned within the lumen of the expandable element. The reinforcing element may be coupled to the expandable element such that expansion of the expandable element causes the reinforcing element to radially expand, thereby creating a perfusion lumen through the device.

An endovascular catheter combination configured to have multiple capabilities is disclosed. These capabilities include proximal and distal occlusion of a segment of a target blood vessel (such as the carotid artery) thus excluding the segment of the blood vessel from circulation for purposes such as surgical consideration. Another capability includes intravascular shunting of the blood through the excluded portion of the artery during a procedure such as an endarterectomy. Additionally, a microsensor provides a measurement of the rate/volume of blood flow through the distal end of the catheter. In one embodiment, a guidewire is provided with a filtration mesh as an anti-embolic mechanism both at the time of initial positioning of the catheter and after reversing the occlusion.

A method that includes introducing a catheter assembly to an obstructed region of a blood vessel lumen and recanalizing the obstructed region with the catheter assembly is disclosed. Prior to or during recanalization, a treatment agent may be delivered through the catheter assembly to a vessel region downstream to the obstructed region. The treatment agent may have a property that will inhibit reperfusion injury. Alternatively, a medical device may be introduced to an obstructed region of a blood vessel lumen and the obstructed region recanalized with the medical device. The treatment agent may be delivered to a vessel region downstream to the obstructed region. The treatment agent may include at least one of an immunosuppresant and an antioxidant. In other methods, a delivery cannula may be introduced to an unperfused region of an occluded vessel without disrupting the occlusion and the treatment agent having a property that will inhibit reperfusion injury may be delivered to the unperfused region through the delivery cannula. After delivering the treatment agent, the occluded vessel may be recanalized by advancing an angioplasty device into the occluded vessel.

An endovascular occlusion device. The endovascular occlusion device (300) has a balloon (306) and a catheter (304). The catheter (304) has a distal end (308), a proximal end, and a lumen (318) extending therebetween. The balloon (306) is positioned proximate to the distal end (308) of the catheter (304) and has a deflated state and an inflated state. The catheter (304) further includes a plurality of ports (314) proximate to a proximal end of the balloon (306). Each port (314) extends through a wall of the catheter (304) such that surface (316) of the catheter (304) is in fluid communication with the lumen (318) of the catheter (304). A flow restrictor (324) is positioned within, and is in sliding relation with, the lumen (318) of the catheter (304). Movement of the flow restrictor (324) is configured to close one or more ports (314) of the plurality so as to limit blood flow through the lumen (318) of the catheter (304).

A method of implanting a prosthetic heart valve includes advancing a distal end portion of a catheter shaft through a patient's vasculature. The distal end portion of the catheter shaft includes an expansion device. A prosthetic heart valve is mounted on the expansion device with the expansion device and the prosthetic heart valve in a compressed configuration. The method further includes positioning the distal end portion of the catheter shaft and the prosthetic heart valve to an implantation location and expanding the prosthetic heart valve and the expansion device to an expanded configuration. The expansion device includes a main body and a plurality of projections extending radially from the main body. The projections are spaced apart relative to each such that there are grooves extending between adjacent projections providing perfusion passageways between the expansion device and the prosthetic heart valve when the expansion device is in the expanded configuration.

A vascular occlusion catheter may be employed for at least partial occlusion of a target vessel. The vascular occlusion catheter system includes a proximal catheter shaft having at least one internal lumen, and a distal catheter shaft terminating in an atraumatic tip. An occlusion balloon is sealingly mounted to the proximal and distal catheter shafts. A central catheter shaft extends through the proximal catheter shaft, the occlusion balloon and into the distal catheter shaft. The proximal catheter shaft is secured to the central catheter shaft on a proximal side of the occlusion balloon and the distal catheter shaft is secured to the central catheter shaft on a distal side of the occlusion balloon. The occlusion balloon, the proximal catheter shaft and the distal catheter shaft have a greatest outer diameter of less than seven French (7 Fr) in an uninflated condition.

Disclosed herein are designs for improved inflatable structures for use during minimally invasive cardiovascular procedures. These inflatable structures facilitate the perfusion of blood through an anatomical structure, such as a heart valve, during the cardiovascular procedure. The inflatable structures are formed of a plurality of balloons arranged radially around a central location. The plurality of balloons form a lumen through which blood flows. Each balloon of the plurality is shaped or configured to stabilize the adjacent balloons, limiting their movement relative to each other. For example, some embodiments can feature balloons with a keystone shape that limits movement of the balloons inward toward the lumen. Some implementations can also include a support coil running through the lumen. The support coil holds enables the lumen to be open to perfusion even in the early stages of balloon inflation.

An atraumatic vessel occlusive system includes a flexible tubular member with an infusion lumen, a vessel occluder mounted at the distal end of the tubular member, and a pressure sensor located within a chamber defined by the occluder. The occluder has a braided construct provided with a fluid impermeable membrane over its proximal portion and a fluid permeable covering over its distal portion. The pressure sensor is adapted to sense pressure within the vessel through the fluid permeable membrane without being subject to the effects of turbulent flow at the exit of the infusion lumen. The accurately sensed pressure can be used to determine a dwell time for the occluder.