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.

A protective dressing includes an outer dressing and an adhesive layer. The outer dressing includes an opening and a cavity sized to receive a phase-change material (PCM) insert inserted through the opening. The adhesive layer is configured to adhere to a patient's skin surrounding an anatomic site. When adhered to the patient's skin, the PCM insert modifies the patient's skin at the anatomic site. The PCM insert may be removed and replaced with another PCM insert. For example, a warm PCM insert may be replaced with a refrigerated PCM insert. The opening of the outer dressing may be self-sealing. The opening of the outer dressing may be sealed with an upper layer dressing coupled to the PCM cooling insert.

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.

Methods and apparatuses for manipulating the temperature of a surface are provided. Devices of the present disclosure may include a thermal adjustment apparatus, such as a controller in electrical communication with one or more thermoelectric materials, placed adjacent to the surface of skin. The device may generate a series of thermal pulses at the surface, for providing an enhanced thermal sensation for a user. The thermal pulses may be characterized by temperature reversibility, where each pulse includes an initial temperature adjustment, followed by a return temperature adjustment, over a short period of time (e.g., less than 120 seconds). The average rate of temperature change upon initiation and upon return may be between about 0.1° C./sec and about 10.0° C./sec. In some cases, the average rate of the initial temperature adjustment is greater in magnitude than the average rate of the return temperature adjustment.

A vestibular neurostimulation device, which may include first and second electrodes; first and second thermoelectric devices thermally coupled, respectively, to first and second earpieces that are configured to be insertable into respective ear canals of a patient; and a controller comprising a waveform generator. The waveform generator may be is configured to deliver a modulated electric signal to the patient through galvanic vestibular stimulation (GVS) using the first and second electrodes and to deliver a time varying thermal waveform to the patient through caloric vestibular stimulation (CVS) using the first and second earpieces simultaneous with the delivery of the modulated electrical signal through GVS. The CVS and/or GVS may be configured to increase a passage of insulin-like growth factor 1 (IGF-1) through a blood-brain-barrier.

Disclosed are systems, pads, and methods for targeted temperature management. A pad can include a multilayered pad body, a pad inlet connector, and a pad outlet connector. The pad body can include a plurality of separable longitudinal portions, wherein each longitudinal portion of the longitudinal portions includes a conduit, a patient-interfacing layer over the conduit, and an insulation layer over the conduit opposite the patient-interfacing layer. The conduit can be configured to convey a temperature-controlled fluid as a supply fluid from a hydraulic system or convey a return fluid back to the hydraulic system. The patient-interfacing layer can include a thermally conductive medium configured for placement on a patient’s body. The insulation layer can include an insulative foam. The pad inlet connector can be configured for charging the pad with the supply fluid while the pad outlet connector can be configured for discharging the return fluid from the pad.

An eye compress assembly includes two thermally adjustable heating and cooling device and a bridge connecting the two devices is provided. The thermally adjustable device is configured to apply thermal treatment against the eye region. Within the thermally adjustable heating and cooling device the thermoelectric element is powered by a battery. A power input port is provided in the bridge to connect into a power supply in order to recharge the battery.

Thermal management devices and associated systems and methods are disclosed herein. In some embodiments, a representative device can comprise (i) thermoelectric components (TECs) each including a first side configured to be operated at a desired temperature and a second side opposite the first side, and (ii) a heat transfer system including an array of fluid distribution networks, an inlet passage coupled to the fluid distribution networks, and an outlet passage coupled to the fluid distribution networks. In operation, a working fluid flows through the fluid distribution networks from the inlet passage to the outlet passage, and absorbs heat from the fluid distribution networks. The inlet and outlet passages can be fluidically coupled to individual fluid distribution networks such that pressure drop and/or temperature drop of the working fluid across the individual fluid distribution networks is about the same as one another.

Provided are systems and methods for reducing pain during an injection or an insertion of an object into the skin of a subject.

A cooling device for removing heat from subcutaneous lipid-rich cells of a subject having skin is provided. The cooling device includes a support having a first portion and a second portion. A first cooling element having a first heat exchanging surface is located at the first portion of the support. A second cooling element having a second heat exchanging surface is located at the second portion of the support. At least one of the first and second cooling elements is movable along the support and is configured to rotate for adjusting an angle between the first and second heat exchanging surfaces.