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 system and/or method for proactively inducing a significant drop in blood pressure during sleep is provided herein. The system includes a blood pressure monitor and a stimulating device that provides stimulation to at least a portion of the person's body. For example, the stimulating device may stimulate a portion of the person's body corresponding to the person's peripheral thermoregulatory control tissue. The stimulation increases or maintains blood flow in the person's glabrous tissue. Additionally, the stimulating device provides stimulation in response to the person's blood pressure being above a predetermined threshold.

Systems, devices, and methods for neurostimulation via vestibular stimulation are described. One example is a device for administering thermal stimulation to an ear canal of a subject. The device may include an earpiece configured to be at least partially insertable into the ear canal of the subject; a thermoelectric device thermally coupled to the earpiece and configured to heat and/or cool the earpiece to thereby heat and/or cool the ear canal of the subject; and a controller configured to administer a selected treatment plan including administering a caloric vestibular stimulation (CVS) stimulus to the ear canal of the subject in a condition-treatment effective amount during a first treatment interval. The treatment plan may be effective to produce a durable improvement in at least one symptom of the condition for a time of at least 1 week following cessation of the administering.

Various implementations include wearable devices and methods for managing respiration and user health. In some particular implementations, a wearable device includes: a mount sized to couple with a body part of a user; and a housing coupled with the mount. The housing at least partially contains: a contact element for applying pressure to the body part; and an actuator coupled with the contact element, the actuator configured to actuate the contact element in applying pressure to the body part according to a prescribed pattern. The prescribed pattern includes at least two repetitions, each repetition having: a first segment at a progressively increasing pressure; a second segment at a substantially constant pressure, following the first segment; a third segment at a progressively decreasing pressure, following the second segment; and a fourth segment at a substantially constant pressure that is less than the substantially constant pressure of the second segment.

A cooling device for removing heat from subcutaneous lipid-rich cells of a subject having skin is provided. The cooling device includes a plurality of cooling elements movable relative to each other to conform to the contour's of the subject's skin. The cooling elements have a plurality of controllable thermoelectric coolers. The cooling elements can be controlled to provide a time-varying cooling profile in a predetermined sequence, can be controlled to provide a spatial cooling profile in a selected pattern, or can be adjusted to maintain constant process parameters, or can be controlled to provide a combination thereof.

Devices and methods are provided for the treatment of pathological conditions including arrhythmias and trauma using temperature modulation via implantable or worn devices. For example, in one example embodiment this document relates to devices and methods for treating atrial or ventricular fibrillation by cooling the epicardium. The devices and methods can also be used to treat other disorders by applying heating and/or cooling to a patient in a number of different manners.

Present disclosure provides a cooling device with safety features and methods for controlling temperature of the cooling device for safe cooling of target surface.

Devices, systems and methods for removing heat from subcutaneously disposed lipid-rich cells are disclosed. In selected embodiments, suction and/or heat removal sources are coupled to an applicator. The applicator includes a flexible portion and a rigid portion. The rigid portion includes a thermally conductive plate and a frame coupling the thermally conductive plate and the flexible portion. An interior cavity of the applicator is in fluid communication with the suction source, and the frame maintains contiguous engagement between the heat removal source and the thermally conductive plate.

Headphones include a pair of cups, each housing a speaker to be positioned over an ear of a user, a processor, a cooling mechanism disposed within each of the cups to regulate environmental conditions inside of the cups to match environmental thresholds provided by a virtual reality device displaying a virtual reality environment to the user, a temperature sensor and at least one additional environmental sensor disposed within each of the cups to monitor the environmental conditions inside the cups, the processor to subsequently analyze data associated with the sensors and compare the data to the environmental thresholds and the processor to selectively activate the cooling mechanism based on the comparison.

A system for treating clogged glands of the eye includes a heated eye mask, an electrical cord, and a controller. The heated eye mask includes an outer layer of surface material, an inner layer of surface material, and a graphene heating element. The graphene heating element is disposed between the outer and inner layers of surface material in a therapeutic region of the heated eye mask. The therapeutic region of the heated eye mask extends along the Meibomian glands of the eye. The graphene heating element is encapsulated by an electrically insulating cover. A thermally conductive material evenly distributes heat across the therapeutic region of the heated eye mask. The electrical cord provides power to the heated eye mask. The controller is provided on the electrical cord for controlling the heated eye mask to heat to one of at least four pre-set temperature levels.