Systems and methods for improving or preventing a condition, such as the treatment of pain syndromes and migraine headaches are disclosed. A method for treating pain can include one or more of the steps including identifying a region of the patient comprising glabrous tissue; positioning the region of the patient comprising glabrous tissue into an enclosed chamber; adjusting the relative humidity of the enclosed chamber sufficient to create a physiologic effect. The method need not involve altering the temperature within the enclosed chamber.

Methods and devices for preventing a change in the core body temperature of a mammal under cold conditions are provided. In the subject methods, a requirement for thermal energy input in said mammal is first detected. In response to the detection of this requirement for thermal energy input, a surface of a portion of the mammal is contacted with a warm temperature medium under negative pressure conditions for a period of time sufficient to introduce thermal energy into the core body of the mammal. The subject devices include at least a means for detecting a requirement for thermal energy input and a means for contacting a surface of the mammal with a warm temperature medium under negative pressure conditions. The subject methods and devices find use in a variety of applications, and are particularly suited for use in maintaining the core body temperature of a mammal substantially constant under cold conditions for an extended period of time.

A method and apparatus in accordance with a particular embodiment of the present invention includes applying adhesive onto skin of a human subject. An applicator is then brought into contact with the adhesive such the adhesive is disposed between the applicator and the subject's skin. The applicator is activated to cool a tissue region via the subject's skin, via the heat-transfer surface of the applicator, and via the adhesive. While the tissue region cools, the adhesive also cools, thereby reversibly strengthening adhesion between the subject's skin and the heat-transfer surface and forming a strong bond therebetween. The strengthened adhesion inhibits any movement of the applicator relative to the skin. After cooling the tissue region, the adhesive is warmed, thereby weakening the adhesion which allows the heat-transfer surface of the applicator to be easily separated from the skin.

Methods and devices for preventing a change in the core body temperature of a mammal under cold conditions are provided. In the subject methods, a requirement for thermal energy input in said mammal is first detected. In response to the detection of this requirement for thermal energy input, a surface of a portion of the mammal is contacted with a warm temperature medium under negative pressure conditions for a period of time sufficient to introduce thermal energy into the core body of the mammal. The subject devices include at least a means for detecting a requirement for thermal energy input and a means for contacting a surface of the mammal with a warm temperature medium under negative pressure conditions. The subject methods and devices find use in a variety of applications, and are particularly suited for use in maintaining the core body temperature of a mammal substantially constant under cold conditions for an extended period of time.

Apparatus and methods are provided for treating a human condition by providing an appendage chamber having a thermal exchange member. Negative pressure may be applied to a human appendage when placed within the appendage chamber. Blood flowing through the arteriovenous anastomosis (AVA) of the appendage may be heated or cooled at the thermal exchange member for therapeutic application of thermal energy to adjust blood viscosity in the human to alleviate symptoms associated with a number of autoimmune, circulatory, neurological, lymphatic, and endocrinal maladies. A load sensor may be coupled to the thermal exchange member and configured to measure a force of the appendage applied to the thermal exchange member. In addition, a negative pressure sensor may measure pressure within the appendage chamber.

Systems and methods for improving or preventing a condition, such as the treatment of pain syndromes and migraine headaches are disclosed. A method for treating pain can include one or more of the steps including identifying a region of the patient comprising glabrous tissue; positioning the region of the patient comprising glabrous tissue into an enclosed chamber; adjusting the relative humidity of the enclosed chamber sufficient to create a physiologic effect. The method need not involve altering the temperature within the enclosed chamber.

One aspect of the invention provides a cooling device including a cooling unit and a control unit. The control unit is programmed to control operation of the cooling unit in order to cool one or more sebaceous glands within a local region for a period of time and to a temperature sufficient to disrupt function of the one or more sebaceous glands without permanently injuring epidermal tissue or cooling subcutaneous adipose tissue to 25 C. or below 25 C.

Systems and methods for a medical device configured to provide cooling to a tissue region are provided. The medical device may be configured to noninvasively cool the tissue region to a predetermined operating temperature via a two-phase heat transfer process. In some aspects, the medical device can be configured to be in communication with a vacuum to provide a suction to the medical device. In some aspects, the medical device can be adapted to a medical device to noninvasively cool the tissue region near a fractional treatment area.

The present invention relates to methods for use in the selective disruption of lipid-rich cells by controlled cooling. The present invention further relates to a device for use in carrying out the methods for selective disruption of lipid-rich cells by controlled cooling.

A method for treating wounds, comprised of the application of reduced pressure to a wound site and alteration of the temperature over said wound. A system for wound healing, comprising: a substantial impermeable drape sized to cover and enclose the wound creating a reservoir and adapted to maintain reduced pressure at the site of the wound; a sterilizable porous cooling pad incorporated into a wound sponge adapted to provide localized cooling to said wound, said cooling pad located between said wound and said cover or over the drape; a reduced pressure supply mechanism capable of providing subatmosphere pressure over said wound site.