Method and apparatus are disclosed for esophageal heat transfer devices and methods for cardiac tissue ablation procedures. An exemplary method includes collecting esophageal data via one or more sensing elements of an esophageal heat transfer device positioned within an esophagus of the patient. The exemplary method includes determining, based on the esophageal data and/or operator selected power setting, a temperature setting and/or a flow rate setting for fluid flowing through the esophageal heat transfer device to maintain a target temperature of esophageal tissue adjacent to the ablation site via a heat transfer region. The exemplary method includes adjusting, via the controller, a fluid source to provide the fluid to the esophageal heat transfer device at the temperature setting and/or a flow rate setting.

Compositions and formulations for use with devices and systems that enable tissue cooling, such as cryotherapy applications, for alteration and reduction of adipose tissue are described. Aspects of the technology are further directed to methods, compositions and devices that provide protection of non-targeted cells (e.g., non-lipid-rich cells) from freeze damage during dermatological and related aesthetic procedures that require sustained exposure to cold temperatures. Further aspects of the technology include systems for enhancing sustained and/or replenishing release of cryoprotectant to a treatment site prior to and during cooling applications.

A method in accordance with a particular embodiment of the present invention includes increasing a concentration of a modified or unmodified saccharide within a subject's skin, applying an applicator to the subject's skin, and cooling the subject's skin via a heat-transfer surface of the applicator. The saccharide within the subject's skin can enhance a resistance of at least some cells within the subject's skin to damage associated with the cooling. A corresponding system includes the applicator, the saccharide, and an energy-delivery device. The energy-delivery device can be configured to apply ultrasound, optical, thermal, or another type of energy to the subject's skin to drive the saccharide into the subject's skin. The system can also include a penetration enhancer configured to enhance penetration of the saccharide into the subject's skin. The penetration enhancer can be applied with the saccharide or separately.

Method and apparatus are disclosed for esophageal heat transfer devices and methods for cardiac tissue ablation procedures. An exemplary method includes collecting esophageal data via one or more sensing elements of an esophageal heat transfer device positioned within an esophagus of the patient. The exemplary method includes determining, based on the esophageal data and/or operator selected power setting, a temperature setting and/or a flow rate setting for fluid flowing through the esophageal heat transfer device to maintain a target temperature of esophageal tissue adjacent to the ablation site via a heat transfer region. The exemplary method includes adjusting, via the controller, a fluid source to provide the fluid to the esophageal heat transfer device at the temperature setting and/or a flow rate setting.

Provided is a neuroprotection apparatus including a scalp temperature measurement acquisition device for acquiring scalp temperature measurements at a plurality of locations on a patient's scalp during an induced hypothermia and a neuroprotection processor for processing the scalp temperature measurements for determining real time patient temperature information for display on a human head image on a display device during the induced hypothermia.

Compositions and formulations for use with devices and systems that enable tissue cooling, such as cryotherapy applications, for alteration and reduction of adipose tissue are described. Aspects of the technology are further directed to methods, compositions and devices that provide protection of non-targeted cells (e.g., non-lipid-rich cells) from freeze damage during dermatological and related aesthetic procedures that require sustained exposure to cold temperatures. Further aspects of the technology include systems for enhancing sustained and/or replenishing release of cryoprotectant to a treatment site prior to and during cooling applications.

A method and apparatus are disclosed for regulating a temperature of an esophagus when heat or cold is delivered to a left atrium, the method including altering a heat exchange device from an insertable configuration to a heat exchanging configuration which conforms and corresponds with a cross-section of an inside of the esophagus such that the esophagus is maintained in its natural shape and location. In some embodiments the heat exchange device has a heating/cooling balloon which is inflated to be in the heat exchanging configuration. Some alternative embodiments includes altering the configuration of the balloon to conform to or correspond with the cross section of an esophagus by means other than inflation.

Treatment systems, methods, and apparatuses for treating acne, hyperhidrosis, and other skin conditions are described. Aspects of the technology can include cooling a surface of a patient's skin and detecting changes in the tissue. The tissue can be cooled a sufficient length of time and to a temperature low enough to affect glands or other targeted structures in the skin.

The present invention generally relates to improved medical devices, systems, and methods. In many embodiments, devices, systems, and methods for locating and treating a target nerve with integrated cold therapy and electrical stimulation systems are provided. For example, nerve stimulation and cryoneurolysis may be delivered concurrently or alternately with the cryo-stimulation device. In some embodiments, the device may be operated by a single operator or clinician. Accordingly, embodiments of the present disclosure may improve nerve targeting during cryoneurolysis procedures. Improvements in nerve localization and targeting may increase treatment accuracy, physician confidence in needle placement during treatment, and clinical efficacy and safety. In turn, such improvements may decrease overall treatment times, the number of repeat treatments, and the re-treatment rate. Further, additional improvements in nerve localization and targeting may reduce the number of needle insertions, applied treatment cycles, and may also reduce the number of cartridge changes.

The present invention generally relates to improved medical devices, systems, and methods. In many embodiments, devices, systems, and methods for locating and treating a target nerve with integrated cold therapy and electrical stimulation systems are provided. For example, nerve stimulation and cryoneurolysis may be delivered concurrently or alternately with the cryo-stimulation device. In some embodiments, the device may be operated by a single operator or clinician. Accordingly, embodiments of the present disclosure may improve nerve targeting during cryoneurolysis procedures. Improvements in nerve localization and targeting may increase treatment accuracy, physician confidence in needle placement during treatment, and clinical efficacy and safety. In turn, such improvements may decrease overall treatment times, the number of repeat treatments, and the re-treatment rate. Further, additional improvements in nerve localization and targeting may reduce the number of needle insertions, applied treatment cycles, and may also reduce the number of cartridge changes.