Combined methods for treating a patient using time-varying magnetic field are described. The treatment methods combine various approaches for aesthetic treatment. The methods are focused on enhancing a visual appearance of the patient.

Devices and systems for providing cooling and compression to a site needing hemostasis can include a compression member having a component that can be inflated with one or more fluids, including a coolant solution. Cooling can be initiated and maintained by securing such a device to the site and optionally equipping the device with the coolant solution. A system can include materials for equipping the device with a coolant solution.

Relatively non-invasive devices and methods for heating or cooling a patient's body are disclosed. Devices and methods for treating ischemic conditions by inducing therapeutic hypothermia are disclosed. Devices and methods for inducing therapeutic hypothermia through esophageal cooling are disclosed. Devices and methods for operative temperature management are disclosed.

A method, including receiving diagnostic information, relating to a potential traumatic brain injury of a person; based on the received diagnostic information, determining a Glascow Coma Scale for the person; upon determining that the Glascow Coma Scale is above a threshold value, instructing use of a cooling system to manage a temperature of the person's head, wherein the cooling system includes: an insulated cap having one or more fluid conduits extending through the cap; a cooling control unit, a fluid line disposed between the cap and the cooling unit that tethers to cap and the cooling unit to one another; and one or more temperatures sensors configured to measure a temperature of the person's head.

An eye treatment system can comprise a roller with a handle, a power source, control circuitry coupled to the power source, an axle, coupled to the handle, a heating element within the roller, a cylinder configured to rotate about the axle, a temperature sensor adjacent to a surface of the cylinder, with the temperature sensor spaced apart from the heating element, and one or more arms of the roller that couple a first end of the handle to the axle, wherein at least one of the one or more arms houses first wiring through which power is supplied from the power source to the heating element and houses second wiring connecting the temperature sensor to the control circuitry. The treatment system might also comprise an eye pad comprising a heat-retaining material and sized to be applied to an eyelid of a user when warmed. The eye pad could be gel-filled.

A thermal control unit for controlling a patient's temperature includes a fluid outlet for delivering temperature-controlled fluid to a patient, a pump, a heat exchanger, and a controller that automatically pauses thermal treatment of the patient prior the patient reaching a target temperature. During the pause, the controller assesses a reaction of the patient and changes a temperature of the fluid only inside the thermal control unit if the patient is likely to reach the target temperature without further thermal treatment. However, if the patient is unlikely to reach the target temperature without further thermal treatment, the controller restarts the thermal treatment. The controller may pause thermal treatment again prior to reaching the target temperature and assess the patient's reaction. In some embodiments, the controller may selectively include and exclude a fluid reservoir in a circulation channel within the thermal control unit.

The invention relates to a thermal skin treatment device comprising a skin contact component with a skin contact surface; a thermal energy component in thermal contact with the skin contact component; a temperature control circuit electrically connected to the thermal energy component and comprising a user interface; and an energy source electrically connected to said thermal energy component for energy supply. Said temperature control circuit is adapted to control an amount of energy supplied from said energy source to said thermal energy component such that a first predetermined temperature is maintained at the skin contact surface for a first duration, or a second predetermined temperature is maintained at the skin contact surface for a second duration, wherein said first predetermined temperature is in a range of 40° C.+/−2° C., and wherein said second predetermined temperature is in a range of 19° C.+/−2° C. The temperature control circuit is adapted to maintain for a predetermined duration, during operation, only said first predetermined temperature or said second predetermined temperature at the skin contact surface. The invention further relates to a method for non-therapeutic treatment of a human eye region by means of a thermal skin treatment device according to the invention.

Devices, systems, and methods herein relate to cooling a head of a patient. These systems and methods may comprise a cooling cap assembly comprising a heat exchanger configured to be wrapped around a head of a patient and a compression assembly releasably coupled to the heat exchanger. The compression assembly may comprise an enclosure and an inflatable member coupled to an internal surface of the enclosure. When coupled, the inflatable member may be positioned between the enclosure and the heat exchanger. The heat exchanger may be separate from and moveable relative to the inflatable member.

A method is provided for in-situ cooling of biological tissue within the body, the biological tissue being selected from the group consisting of organ tissue, blood vessel tissue and combinations thereof. The method comprises establishing a heat-conducting contact between a heat absorption zone of a cooling unit of a device for in-situ cooling of biological tissue and the biological tissue within the body, transporting thermal energy from the heat absorption zone of the cooling unit via a substance for transporting thermal energy, which is arranged within a hollow tube of the device for in-situ cooling of biological tissue, to a cooling device of the device for in-situ cooling of biological tissue, and releasing the thermal energy via the cooling device. The method allows protecting biological tissue within the body in a location-selective manner from cancer-therapy-caused damage during cancer therapy in a simple, cost-effective and low-risk manner.

A mask, according to an embodiment, comprises: a first wiring disposed on a first base layer; a piezoelectric element disposed on the first wiring; a second wiring disposed on the piezoelectric element; a second base layer disposed on the second wiring; a protective layer disposed between the first and second base layers and surrounding the first wire, the second wire, and the piezoelectric element; and a control unit which controls a driving frequency of the piezoelectric element. The control unit controls the driving frequency of the piezoelectric element in a frequency band defined as a first range, and the temperature of the piezoelectric element changes by means of the control of the driving frequency of the control unit.