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.

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.

Embodiments related to methods and wearable medical detecting systems for detecting disease states and/or treatment states of a subject are described. In one embodiment, a wearable structure may include one or more radiation detectors use to detect a time varying radiation signal emitted from a labeled compound within a body portion of interest. The radiation signal may be analyzed to determine one or more signal characteristics that may be compared to one or more predetermined standard characteristics associated with known disease and/or treatment states to determine a current disease and/or treatment state of a subject.

A heat conduction device includes a heat source portion, a temperature control surface, and heat transfer portions. The heat source portion is configured to generate at least hot heat or cold heat. The temperature control surface is sectioned into a plurality of temperature control sections, and at least some of the plurality of temperature control sections are disposed away from the heat source portion. The plurality of heat transfer portions connect the heat source portion and the plurality of the temperature control sections to transfer heat between the heat source portion and the plurality of temperature control sections. The plurality of temperature control sections are separated from each other based on a distance from the heat source portion.

A tissue stimulation device comprising: a source; a control unit; a decoupled output stage circuit connected to the source and the control unit; a signal generator connected to the input of the decoupled output stage circuit and the control unit; an analog demultiplexer connected to the output stage circuit decoupled by a PE signal and an out signal, the analog demultiplexer is connected to the control unit, and a transducer array is connected to the output of the analog demultiplexer; wherein the control unit selects the output of the analog demultiplexer that allows switching of the PE and out signals to activate the transducers in the transducer array to stimulate tissue.

A temperature therapy system and a method for temperature control for such a temperature therapy system are disclosed. According to one embodiment, a temperature therapy system has a retention mechanism and a plurality of temperature modulation systems attached to the retention mechanism, wherein each of the plurality of temperature modulation systems comprises a thermoelectric cooler. The wearable personal temperature therapy system may have a plurality of temperature sensors and a plurality of conductive flags, wherein each of the plurality of conductive flags is adhered to a respective thermoelectric cooler and a respective temperature sensor. The wearable personal temperature therapy system may have a control module electrically coupled to each of the plurality of temperature modulation systems and each of the plurality of temperature sensors, wherein each of the temperature modulation systems is controlled based on a control voltage applied to the thermoelectric cooler of the respective temperature modulation system.

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.

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.

The present invention relates to an orthopedic brace including therein a thermal treatment system useful for treating joint injuries and musculoskeletal disorders, such as osteoarthritis.

A temperature modulation assembly and a multi-layer retention mechanism for such a temperature therapy device are disclosed. According to one embodiment, a temperature modulation assembly for a temperature therapy device has a heat spreader and a mounting plate coupled to a bottom portion of a spacer, wherein the heat spreader is disposed between the mounting plate and the spacer. The temperature modulation assembly has a heatsink and a fan coupled to a top portion of the spacer, wherein the heatsink is disposed between the top portion of the spacer and the fan. The temperature modulation assembly further includes a heating and/or cooling device disposed within a central opening of the spacer, wherein the heating and/or cooling device is located between the heatsink and the heat spreader.