A flexible catheter is inserted into the esophagus to cool or warm the esophagus, particularly during certain procedures which can tend to change the temperature in the area of the esophagus. The catheter is inserted through the mouth and throat to a position, for example, proximate the heart, but within the esophagus. A thermally conductive gel is injected into the esophagus where it is immobilized by the one or more balloons. A coolant is pumped through a coolant tube affixed to the catheter, where it exchanges heat with the conductive gel.

A method for treatment of a brain and/or spinal cord includes inserting a flexible catheter into a cerebrospinal fluid space, the flexible catheter including two lumens adapted to allow a fluid to circulate therein in a closed loop within the flexible catheter and the flexible catheter being adapted to be connected to a device for cooling and circulating the fluid. The cerebrospinal fluid in the cerebrospinal fluid space is cooled with the flexible catheter to enable selective central nervous system cooling. The functional status of the brain and/or spinal cord is monitored, and the treatment of the brain and/or spinal cord is modified to adjust for any change in the functional status of the brain and/or spinal cord.

The invention provides a device for treating tumors at a target site, the device comprising a first balloon containing a radio isotope; a second balloon encasing the first balloon wherein the second balloon comprises structures to create a void between the first balloon and the second balloon; and optionally a third balloon encasing the second balloon, wherein the third balloon facilitates removal of material from the target site. The invention also provides a method for treating a tumor excise site, the method comprising simultaneously exposing the tumor to heat and radiation.

Methods and devices are disclosed herein that generally involve applying thermal therapy to tissue (e.g., localized cooling or heating of tissue), and in particular applying thermal therapy to the spinal canal, tissue disposed within the spinal canal, and/or nerve roots extending from the spinal canal. In some embodiments, tissue can be cooled or heated by implanting or positioning a thermal device in proximity to the targeted tissue. A number of exemplary thermal devices are disclosed, including bone anchors, inserts for use with bone anchors, K-wires, bone anchor extensions or towers, cross-connectors, spinous process plates, spinal rods, pedicle markers, bone taps, drill bits, bone plugs, bone plates, clamps, interbody or disc implants, thermal pads, and tubing loops. The thermal device can be left in place following surgery to facilitate application of post-surgical thermal therapy. In some embodiments, the thermal device can be removed post-surgery in a minimally- or non-invasive manner.

A method for conditioning an inflatable balloon of a balloon catheter prior to use inside a patient includes submerging the inflatable balloon in a liquid solution, inflating the inflatable balloon, removing any bubbles on an exterior surface of the inflated, inflatable balloon, deflating the inflatable balloon while maintaining the inflatable balloon submerged in the liquid solution, and retracting the deflated, inflatable balloon into a catheter sheath while maintaining the inflatable balloon submerged in the liquid solution.

Methods and apparatus 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.

The invention relates to a method of central nervous system pathology treatment through selective hypothermia. Brain and spinal cord cooling is achieved through a closed loop catheter system inserted directly into the cerebrospinal fluid space. The catheter comprises of a portion that dilates in a pulsatile or peristaltic fashion and facilitates circulation of the cooled cerebrospinal fluid.

A balloon catheter is used in a closed-loop heat exchange system for manipulating the temperature of a patient. The balloon catheter is positioned in the stomach of the patient, and then expanded with a heat exchange fluid delivered through a lumen formed in the shaft of the catheter. The balloon catheter comes into contact with the wall of the stomach, and the stomach substantially conforms around the expanded balloon catheter. The heat exchange fluid is allowed to flow continuously into and out of the balloon catheter. Heat is exchanged between the balloon catheter and the stomach so as to controllably alter the temperature of at least a portion of the patient. Anti-shivering mechanisms and automatic control based on temperature feedback from the patient may be used in connection with the heat exchange system.

A medical device includes: a shaft having a distal end and an associated exhaust channel; a first balloon configured to be attached to the distal end of the shaft, the first balloon having an outer surface that is substantially conformal to an inner surface of a uterine cavity; and a second balloon configured to be received within the first balloon and forming an intermediary space between the first balloon and an outer surface of the second balloon. The second balloon includes at least one rupture valve configured to rupture at a predefined pressure in the intermediary space.

An apparatus includes a shaft having a proximal end and a distal end; a stem extending from the distal end of the shaft and comprising a first cover and a second cover, the, first cover and the second cover being configured to inhibit access to fallopian tubes of a patient; and a plurality of temperature sensors disposed on the shaft and on the stem. At least one of the temperature sensors is positioned between the proximal end of the shaft and the distal end of the shaft and at least one of the temperature sensors is positioned on the stem.