Systems and methods for Endovascular Perfusion Augmentation for Critical Care (EPACC) are provided. The system may include a catheter having an expandable aortic blood flow regulation device disposed on the distal end of the catheter for placement within an aorta of a patient. The system may also include a catheter controller unit that causes the expandable aortic blood flow regulation device to expand and contract to restrict blood flow through the aorta. The system may also include one or more sensors for measuring physiological information indicative of blood flow through the aorta, and a non-transitory computer readable media having instructions stored thereon, wherein the instructions, when executed by a processor coupled to the one or more sensors, cause the processor to compare the measured physiological information with a target physiological range associated with blood flow through the aorta such that the catheter controller unit automatically adjusts expansion and contraction of the expandable aortic blood flow regulation device to adjust an amount of blood flow through the aorta if the measured physiological information falls outside the target physiological range.

A method of producing an arteriovenous (AV) fistula includes producing an anastomosis between a primary blood vessel (e.g., a vein) and a secondary blood vessel (e.g., an artery). A collateral (or competing) blood vessel in fluid communication with one of the primary blood vessel or the secondary blood vessel is identified. A reversible flow restrictor is then applied to the collateral blood vessel to reduce a blood flow rate through the collateral blood vessel. In some embodiments, the anastomosis can be produced percutaneously. In some embodiments, the reversible flow restriction (or a portion thereof) can be removed from the collateral blood vessel. In other embodiments, the reversible flow restriction (or a portion thereof) can be adjusted to allow increased blood flow therethrough while within the collateral blood vessel.

Systems and methods for partial aortic occlusion are provided. The system may include a catheter having an expandable aortic blood flow regulation device disposed on the distal end of the catheter for placement within an aorta of a patient, and a catheter controller unit that causes the device to expand and contract to restrict blood flow through the aorta. The system also may include sensors for measuring blood pressure distal and proximal to the expandable device. The system further may include non-transitory computer readable media having instructions stored thereon, wherein the instructions, when executed by a processor coupled to the sensors, cause the processor to estimate aortic blood flow based on the measured blood pressures and corresponding waveforms, compare the estimated aortic blood flow with a target aortic blood flow range, generate an alert if the estimated aortic blood flow falls outside the target aortic blood flow range, and cause the catheter controller unit to adjust expansion and contraction of the expandable device to adjust an amount of blood flow through the aorta if the estimated aortic blood flow falls outside the target aortic blood flow range.

Systems and methods for blood flow control are described herein. In some variations, a blood flow control system may comprise a blood flow control device. The blood flow control device may be placed within a body of a patient and may comprise an expandable member and a sensor. The sensor may be configured to measure at least one of a physiologic condition of the patient and a pressure associated with the expandable member. The blood flow control system may include at least one controller communicably coupled to the sensor to: receive data indicative of at least one of the physiologic condition of the patient and the pressure associated with the expandable member from the sensor, compare the received data with target data, identify at least one error based on the comparison, and in response to identifying the error, inhibit at least one function of the blood flow control system.

Temporary vascular occlusion devices and methods for use thereof are described which provide temporary vascular occlusion while maintaining distal perfusion along with vascular access. The temporary vascular occlusion device may include a multiple layer scaffold covering having proximal and distal attachment zones separated by an unattached scaffold covering zone where the scaffold covering is adjacent to but not attached directly to the scaffold frame. Devices for a vascular procedure may access the vasculature using a guide catheter in the shaft of the occlusion device. The occlusion device may then be used to provide protection from contrast media used during the vascular procedure conducted using the access provided by the occlusion device.

The present technology relates to power management for interatrial shunting systems. In some embodiments, the present technology includes a system for shunting blood between a left atrium and a right atrium of a patient. The system can include a shunting element and a plurality of active electronic components operably coupled to the shunting element. At least some of the active electronic components have different power consumption characteristics. The system also includes a plurality of energy storage components, with some of the energy storage components have different characteristics. During operation, the system is configured to receive a signal indicating that an active electronic component is to be operated, and select an energy storage component associated with power output characteristics capable of accommodating the power consumption characteristics of the active electronic component. The system is further configured to instruct the selected energy storage component to power operation of the active electronic component.

Various devices, systems, and methods that can be used in the treatment of obesity and related illnesses are disclosed. In some instances, the cecum of an obese patient is distended to a pathophysiological size for a therapeutically effective period. The distention may be achieved by introduction of an object that is of foreign origin relative to the body of the patient into the cecum of the patient. In some instances, the distention is achieved by a medical device that transitions from an undeployed state, in which the medical device is introduced into the cecum of the patient, to an expanded state in which the medical device distends the cecum by an amount sufficient to trigger a colo-gastric brake in the patient.

A method of providing retrograde perfusion of a patient's brain includes occluding a jugular vein of a subject at a jugular occlusion location, and passively shunting arterial blood from an artery of the subject to a location in the jugular vein distal to the jugular occlusion location.

Devices and methods of the disclosure use an intravascular catheter with deployable sealing elements to create a fluid trap around an outlet of a lymphatic duct and drain lymph passively to a collection vessel that may be pressurized to a predetermined pressure or a partial vacuum. Due to the fixed pressure, the device creates a low-pressure area at the lymphatic duct, which drains lymph passively without any mechanical pump or impeller. In certain aspects, a device includes a catheter for insertion into a vein of the venous angle of a patient, with proximal and distal sealing elements deployable to seal the vein to thereby define a fluid trap around the lymphatic outlet. A port within the fluid trap opens to a drainage lumen extending along the catheter to a collection vessel. The device may be configured such that the drainage lumen passively drains the fluid trap into the collection vessel.

Temporary vascular occlusion devices and methods for use thereof are described which provide temporary vascular occlusion while maintaining distal perfusion. The temporary vascular occlusion device may include a multiple layer scaffold covering having proximal and distal attachment zones separated by an unattached scaffold covering zone where the scaffold covering is adjacent to but not attached directly to the scaffold frame.