A treatment device for removing heat from subcutaneous lipid-rich cells of a subject having an actuator that provides mechanical energy to the tissue. The mechanical energy provided may include a vibratory component that can range between low and ultra-high frequencies, and such energy may include various combinations of two or more frequencies tailored to produce the desired effect on the subcutaneous tissue. Disruption of adipose tissue cooled by an external treatment device may be enhanced by applying mechanical energy to cooled tissue. Furthermore, such mechanical energy may impart a vibratory effect, a massage effect, a pulsatile effect, or combinations thereof on the tissue.

A device for enhancement of visual appearance including a first applicator to be coupled to a first area of a body region, with a first magnetic field generating device and a first radiofrequency electrode, a second applicator to be coupled to a second area of the body region, with a second magnetic field generating device. The device further includes a first energy storage device, a second energy storage device, and a first switching device to discharge energy from the first energy storage device to the first magnetic field generating to generate a first time-varying magnetic field to cause muscle contraction, and a second switching to discharge energy from the second energy storage device to the second magnetic field generating device to generate a second time-varying magnetic field. The first radiofrequency electrode may provide first radiofrequency waves causing heating of tissue within the first area of the body region.

In methods for treating a patient, a time varying magnetic field is applied to a patient's body and causes a muscle contraction. The time-varying magnetic field may be monophasic, biphasic, polyphasic and/or static. The method may reduce adipose tissue, improve metabolism, blood and/or lymph circulation. The method may use combinations of treatments to enhance the visual appearance of the patient.

A personal heating and cooling system comprising a chair, a pad comprising a length of flexible tubing and at least one heating element housed in an interior area of the pad, a pump configured to pump a volume of coolant (e.g., water) through the length of the flexible tubing, an intake trunk coupled to the pump and configured to deliver a volume of water from a reservoir (e.g., from a thermal insulated cooler) and a battery pack operably engaged with the pump and the at least one heating element. In certain embodiments, the pad may be integral to the chair and comprise seat and back portions of the chair. In certain embodiments, the pad may be removably coupled to the chair or other seating surface or may be laid flat.

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.

An organ can be cooled to minimize ischemic tissue damage from a vascular occlusion by a thrombus or dissection. A catheter including a thermal member can be used to introduce cold fluid downstream from an arterial occlusion to cool tissue affected by the occlusion. This is particularly useful to minimize neurologic damage from a thrombotic stroke.

The present disclosure provides a device and a method for cooling living tissues for a medical purpose and other purposes. The cooling device includes a cooling medium contacting the living tissues to be cooled. The cooling medium comprises: a first fluid medicine reservoir configured to be installed outside a main body that couples with a medical cooling device and to move into the main body, wherein the first fluid medicine reservoir stores a first fluid medicine to be injected through a hole at a tip of the main body.

A therapeutic device includes a substrate, a seal to couple the substrate to a surface, and at least one port defined in the substrate through which a therapeutic fluid is introduced between the surface and the substrate such that the therapeutic fluid directly contacts the surface.

Please delete the current abstract and add the following new paragraph as the abstract. A head cooler improves sleep quality without overcooling the head of a sleeping person. A head cooler includes a main body, a pillow, and a connector. The main body sends out a liquid for circulation between the main body and the pillow through the connector. The main body includes a temperature adjuster that adjusts a temperature of the liquid, a pump that sends out the liquid toward the pillow, and a controller that controls the temperature adjuster and the pump to adjust a temperature of the pillow at a first target temperature of 22 to 24° C. until an elapsed time from start of cooling reaches a target time of 200 to 250 minutes.

A cold and/or hot compress system, comprising a water bag (101), an air bag (102), a water circulation assembly (2) in fluid communication with the water bag (101) and a pneumatic assembly (3) in fluid communication with the air bag (102). In the cold and/or hot compress system, the water circulation assembly (2) is independent from the pneumatic assembly (3). Therefore, during the delivery of a cooling or heating therapy, the independent pneumatic assembly (3) can be driven by an air pressure waveform defined by parameters pre-stored in a control panel (402) to cause the water bag (102) to apply cold/hot compress to a region of interest of a patient's body. Independent water and air circulation paths in the system avoid interference between water and air flows therein, allowing the system to applied more stable compress with minimized pressure errors. Moreover, a more constant water flow rate and a more uniform temperature distribution across the surface of the water bag are achievable.