A device to change the temperature of a localized volume of material. A workable device includes at least one heat transfer mechanism having an external surface for direct contact with an exposed surface of the material. A working fluid is directed by input and output conduits to contact an internal surface of the heat transfer mechanism. The heat transfer mechanism exchanges heat between the working fluid and the material. Temperature of the working fluid may be regulated by a thermal system disposed at a remote location. An optional temperature sensing element may monitor a local temperature of the heat transfer mechanism or otherwise infer a temperature of a portion of the material. Sometimes, a device includes a cooperating anchoring arrangement to facilitate holding the heat transfer mechanism in a desired spot. Certain devices may be plastically deformed to a desired device shape.

A catheter configured to provide a delivery system for standard interventional devices and for rapid localized deep cooling to organs at risk of ischemia-reperfusion injury during procedures such as intracranial thrombectomy or emergency thrombectomy. The catheter is comprised of an insulative shaft with a multi-component braided outer lumen and an internal floating inner lumen with a plurality of structures configured to minimize contact and resulting heat transfer between the two lumens.

Thermal therapy systems, devices, and methods of using the same disclosed. A localized hypothermia of the pancreas with a delivery and placement procedure in the stomach of a patient comprising a cooling balloon system is disclosed that can be used for the treatment of pancreatitis in a patient. The cooling balloon system can have mechanisms for affecting the pancreas without impacting or inducing hypothermia in the patient in a systemic fashion. The localized hypothermia system can have a simplified delivery system and can be intended to reduce patient discomfort while reducing the metabolic activity of the inflamed pancreas of the patient.

Thermal therapy systems, devices, and methods of using the same disclosed. A localized hypothermia of the pancreas with a delivery and placement procedure in the stomach of a patient comprising a cooling balloon system is disclosed that can be used for the treatment of pancreatitis in a patient. The cooling balloon system can have mechanisms for affecting the pancreas without impacting or inducing hypothermia in the patient in a systemic fashion. The localized hypothermia system can have a simplified delivery system and can be intended to reduce patient discomfort while reducing the metabolic activity of the inflamed pancreas of the patient.

Methods and system are provided for thermally-induced renal neuromodulation. Thermally-induced renal neuromodulation may be achieved via direct and/or via indirect application of thermal energy to heat or cool neural fibers that contribute to renal function, or of vascular structures that feed or perfuse the neural fibers. In some embodiments, parameters of the neural fibers, of non-target tissue, or of the thermal energy delivery element, may be monitored via one or more sensors for controlling the thermally-induced neuromodulation. In some embodiments, protective elements may be provided to reduce a degree of thermal damage induced in the non-target tissues. In some embodiments, thermally-induced renal neuromodulation is achieved via delivery of a pulsed thermal therapy.

An automated therapy system having an infusion catheter; a sensor adapted to sense a patient parameter; and a controller communicating with the sensor and programmed to control flow output from the infusion catheter into a patient based on the patient parameter without removing fluid from the patient. The invention also includes a method of controlling infusion of a fluid to a patient. The method includes the following steps: monitoring a patient parameter with a sensor to generate a sensor signal; providing the sensor signal to a controller; and adjusting fluid flow to the patient based on the sensor signal without removing fluid from the patient.

A catheter is provided comprising a flexible heat transfer element provided on an outer surface of the catheter, a conduit arranged to supply an inflation fluid for inflating the flexible heat transfer element so as to form an inflated balloon, a guide wire lumen for receiving a guide wire, and an elongate cooling element arranged to cool said inflation fluid for inflating the balloon. Said cooling element and said guide wire lumen are arranged inside the flexible heat transfer element such that, when inflated the cooling element is substantially central within the balloon and said guide wire lumen is parallel to and radially offset from the cooling element.

A macerating and aspiration tool for removing blood masses from the brain.

Closed loop heat exchange catheters having bi-directional flow heat exchange regions and their methods of manufacture and use. The heat exchange region may be formed of expandable or non-expandable tubular conduit(s) that are configured in a series of loops or coiled configuration defining a supply flow path and a return flow path through which heat exchange medium is circulated. The individual loops of convolutions of the coiled configuration may be the same or different size. In some embodiments, the tubular conduit(s) may be passed through generally transverse bore holes formed in a catheter shaft so that the loops or convolutions of protrude from the catheter shaft.

A process and related assemblies for delivering slush through a tube towards a patient. Obtaining an elongated container partially filled with slush with a port end that has a first port and a second port. Placing the first port in fluid communication with tubing for delivery of slush towards the patient. Placing the second port in fluid communication with a source of gas which may be air. Subjecting the elongated container to automated repetitive movements so that the slush in the partially filled elongated container moves against interior surfaces within the elongated container. Ideally, two different forms of repetitive motion are used to impose complex movement upon the slush within the elongated container. Applying a pressure gradient to cause slush to flow out of the first port towards the patient. The elongated container may be made from a slush bottle with a reversibly engaged cap with the two ports.