A core temperature sensor and a method of using such a sensor to non-invasively measure a temperature of a core thermal compartment of a human body or other mammals. A heater of the core temperature sensor heats a peripheral area to a temperature greater than the core temperature. A skin temperature
A core temperature sensor and a method of using such a sensor to non-invasively measure a temperature of a core thermal compartment of a human body or other mammals. A heater of the core temperature sensor heats a peripheral area to a temperature greater than the core temperature. A skin temperature sensor of the core temperature sensor monitors a cooling of the peripheral area to determine the core temperature.
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1. A core temperature sensor for non-invasively measuring a temperature of a core thermal compartment of a human body or other mammal comprising: a skin temperature sensor that is adapted to be placed in conductive thermal contact with the skin over-laying a portion of the core thermal compartment;a
1. A core temperature sensor for non-invasively measuring a temperature of a core thermal compartment of a human body or other mammal comprising: a skin temperature sensor that is adapted to be placed in conductive thermal contact with the skin over-laying a portion of the core thermal compartment;a heater comprising a first surface adapted to face the skin, wherein a central region of the first surface of the heater is positioned to surround the skin temperature sensor;a layer of thermal insulation proximate a second surface of the heater and opposite the first surface of the heater facing the skin; anda controller to start and stop heat from the heater and to determine the core thermal compartment temperature, the controller configured to drive the heater to a predetermined temperature greater than the temperature of the core thermal compartment and then discontinue heating, permitting heat to rapidly diffuse into the core thermal compartment through thermal load dissipation, the controller operable to analyze a skin temperature-versus-time dissipation curve that occurs when the heat from the heater is stopped, wherein determination of the core thermal compartment temperature is established based on a slow temperature decrease portion of the curve determined by waiting for an empirically determined amount of time following the discontinuation of the heating, wherein the slow temperature decrease portion of the curve reflects a decreasing rate of change in the temperature measured by the skin temperature sensor and is indicative of reaching thermal equilibrium between the skin and the core thermal compartment. 2. A core temperature sensor for non-invasively measuring a temperature of a core thermal compartment of a human body or other mammal comprising: a skin temperature sensor that is adapted to be placed in conductive thermal contact with the skin over-laying a portion of the core thermal compartment;a heater comprising a first surface adapted to face the skin, wherein a central region of the first surface of the heater is positioned to surround the skin temperature sensor;the heater is capable of heating the skin proximate the skin temperature sensor to a skin temperature greater than the temperature of the core thermal compartment and then is capable of rapidly discontinuing heating;a layer of thermal insulation proximate a second surface of the heater and opposite the first surface of the heater facing the skin; anda controller attached to the skin temperature sensor which is correlated with time to create a skin temperature-versus-time dissipation curve when the heating is discontinued by the controller, the controller configured to drive the heater to a predetermined temperature greater than the temperature of the core thermal compartment and then rapidly discontinue heating, the controller operable analyze the skin temperature-versus-time dissipation curve to determine a slow temperature decrease portion of the curve, wherein the slow temperature decrease portion of the curve may be determined by waiting for an empirically determined amount of time following the rapid discontinuation of the heating to establish a temperature measurement of the core thermal compartment, wherein the slow temperature decrease portion of the curve reflects a decreasing rate of change in the temperature measured by the skin temperature sensor and is indicative of reaching thermal equilibrium between the skin and the core thermal compartment. 3. The core temperature sensor of claim 2, wherein the heater includes a hole in its central region and the skin temperature sensor is located within the hole. 4. The core temperature sensor of claim 2, wherein the central region of the first surface of the heater is positioned over the skin temperature sensor. 5. The core temperature sensor of claim 4, wherein the skin temperature sensor is separated from the first surface of the heater by a thin piece of thermal insulation. 6. The core temperature sensor of claim 2, wherein the heater is configured to be energized to a temperature equal to or greater than 39° C. 7. The core temperature sensor of claim 2, wherein the skin temperature sensor is one or more of a thermistor, a thermocouple, and a thermographic ink. 8. The core temperature sensor of claim 2, wherein the heater is one or more of an electrically conductive metal foil, an electrically conductive fabric, an electrically conductive film, an electrically conductive wire. 9. The core temperature sensor of claim 2, wherein the heater is one or more of a exothermic chemical reaction pad, a heated material including one or more of water, a gel, or a metal. 10. The core temperature sensor of claim 2, wherein the heater is flexible. 11. The core temperature sensor of claim 2, wherein the heater is adapted to be in conductive thermal contact with the skin over-laying the portion of the core thermal compartment, the heater operable to a temperature in the range of 2° C. to 40° C. greater than the temperature of the core thermal compartment. 12. The core temperature sensor of claim 2, wherein the layer of thermal insulation is one or more of a high loft non-woven fibrous material, a foam material, an air space. 13. The core temperature sensor of claim 2, wherein the controller is an on-off switch. 14. The core temperature sensor of claim 2, wherein the controller regulates the heater to achieve a prescribed temperature and/or time. 15. The core temperature sensor of claim 2, wherein the skin temperature sensor, the heater and the thermal insulation are enclosed in a water-proof plastic housing to form the core temperature sensor comprising the core temperature sensor, and the plastic housing includes a plastic film layer for separating the heater and skin temperature sensor from the skin. 16. The core temperature sensor of claim 15, wherein the first surface of the heater and skin temperature sensor are bonded to the plastic film layer of the plastic housing. 17. The core temperature sensor of claim 2, wherein the skin temperature sensor, the heater and the thermal insulation are enclosed in a water-proof plastic pouch to form the core temperature sensor and the plastic pouch includes a plastic film layer for separating the heater and core temperature sensor from the skin. 18. The core temperature sensor of claim 17, wherein the first surface of the heater and skin temperature sensor are bonded to the plastic film layer of the plastic pouch. 19. The core temperature sensor of claim 2, further comprising an adhesive layer. 20. The core temperature sensor of claim 19, wherein the adhesive layer is a double-faced adhesive comprised of a layer of film material with adhesive applied to both sides. 21. The core temperature sensor of claim 19, wherein the adhesive layer includes at least two different adhesive formulations, the formulation on one face is optimized for skin attachment and release and the formulation on the other face is optimized for attachment to and release from the core temperature sensor. 22. The core temperature sensor of claim 19, wherein the adhesive layer includes one or more holes cut through the film material and adhesive. 23. The core temperature sensor of claim 19, wherein the adhesive layer includes adhesive that has been applied in a stripe-like or dot pattern, wherein the space between the stripes or dots of adhesive constitutes one or more air venting channels. 24. The core temperature sensor of claim 2, further comprising a protective pouch attachment means. 25. The core temperature sensor of claim 19, wherein the adhesive layer comprises a protective pouch attachment means that includes a double-faced adhesive comprised of adhesive applied to both sides of one layer of the protective pouch. 26. The core temperature sensor of claim 19, wherein the adhesive layer includes one or more holes cut through a film material and the adhesive layer. 27. The core temperature sensor of claim 19, wherein the adhesive layer includes adhesive that has been applied in a stripe-like or dot pattern wherein the space between the stripes or dots of adhesive constitutes one or more air venting channels. 28. The core temperature sensor of claim 2, further comprising a raised ring of material near the perimeter which occludes collateral subcutaneous blood flow when pressure is applied by the core temperature sensor to the skin. 29. The core temperature sensor of claim 2, further comprising a second heater positioned on the opposite side of the thermal insulation layer from the skin heater. 30. The core temperature sensor of claim 29, further comprising a temperature sensor on the second heater and a controller wherein the controller adjusts the temperature of the second heater to approximate 37° C. 31. The core temperature sensor of claim 29, further comprising a temperature sensor on the second heater and a controller wherein the controller adjusts the temperature of the second heater to approximate the temperature of the skin as sensed by the skin temperature sensor. 32. The core temperature sensor of claim 2, wherein the controller is configured to analyze the skin temperature-versus-time dissipation curve to determine the intersection of the slopes of a rapid temperature decrease portion of the curve and of the slow temperature decrease portion of the curve. 33. The core temperature sensor of claim 2, wherein the heater is capable of heating the skin proximate the skin temperature sensor to a minimum of 2° C. greater than the temperature of the core thermal compartment and then is capable of rapidly discontinuing heating. 34. A method of non-invasively measuring a temperature of a core thermal compartment of a human body or other mammal, the method comprising: placing a skin temperature sensor in conductive thermal contact with a skin over-laying a portion of the core thermal compartment;placing a heater with a sufficiently large surface area such that a central region of a first surface of the heater is positioned to surround the skin temperature sensor and a layer of thermal insulation is proximate a second surface of the heater opposite the first surface of the heater facing the skin;energizing the heater to heat the skin to a predetermined temperature greater than the core thermal compartment temperature;de-energizing or removing the heater to stop heating the skin;monitoring with a controller, a cooling of the skin with the skin temperature sensor, and analyzing and interpreting one or more changes in the skin temperature-versus-time dissipation curve to determine the core thermal compartment temperature, wherein analyzing and interpreting one or more changes in the temperature-versus-time dissipation curve comprises waiting an empirically determined amount of time after stopping the heating of the skin to establish a temperature measurement for the core thermal compartment; andwherein analyzing and interpreting one or more changes in the temperature-versus-time dissipation curve comprises determining the slow temperature decrease portion of the curve established by a decreasing rate of change in the temperature measured by the skin temperature sensor and is indicative of reaching thermal equilibrium between the skin and the core thermal compartment. 35. The method of claim 34, further comprising energizing the heater to a temperature equal to or greater than 39° C. 36. The method of claim 34, further comprising de-energizing the heater when the skin is at a temperature greater than 39° C. 37. The method of claim 34, further comprising the controller providing instructions to enable a user of the core temperature sensor to interpret one or more changes in the skin temperature recorded by the skin temperature sensor during the steps of energizing and de-energizing the heater to determine the core thermal compartment temperature. 38. The method of claim 34, further comprising the controller analyzing one or more changes in the skin temperature recorded by the skin temperature sensor during the steps of energizing and de-energizing the heater to determine the core thermal compartment temperature, and indicating the core thermal temperature on the display. 39. The method of claim 34, further comprising the controller determining the temperature of the core thermal compartment based on an intersection point between a first slope of rapid dissipation in the skin temperature and a second slope of slow dissipation in the skin temperature. 40. A core temperature sensor for non-invasively measuring a temperature of a core thermal compartment of a human body or other mammal comprising: a skin temperature sensor that is adapted to be placed in conductive thermal contact with the skin over-laying a portion of the core thermal compartment;a heater comprising a first surface adapted to face the skin, wherein a central region of the first surface of the heater is positioned to surround the skin temperature sensor;the heater is capable of heating the skin proximate the skin temperature sensor to a skin temperature greater than the temperature of the core thermal compartment and then is capable of rapidly discontinuing heating;a layer of thermal insulation proximate a second surface of the heater and opposite the first surface of the heater facing the skin; a controller attached to the skin temperature sensor which is correlated with time to create a skin temperature-versus-time dissipation curve when the heating is discontinued by the controller, the controller configured to drive the heater to a predetermined temperature greater than the temperature of the core thermal compartment and then to discontinue heating; and the controller configured to analyze the skin temperature-versus-time dissipation curve, and to determine the slow temperature decrease portion of the curve, wherein the slow temperature decrease portion of the curve represents a decreasing rate of change in the temperature measured by the skin temperature sensor and is indicative of reaching thermal equilibrium between the skin and the core thermal compartment, wherein the slow temperature decrease portion of the curve may be determined by waiting for an empirically determined amount of time following the rapid discontinuation of the heating to establish a temperature measurement for the core thermal compartment. 41. A core temperature sensing system for non-invasively measuring a temperature of a core thermal compartment of a human body or other mammal, the system comprising: a heater adapted to be placed in thermal contact with the skin overlaying a portion of the core thermal compartment, the heater configured to heat the skin above the temperature of the core thermal compartment;a skin temperature sensor adjacent the heater, the temperature sensor adapted to be placed in thermal contact with the skin overlaying a portion of the core thermal compartment and to generate temperature data;a display; anda controller operably coupled to the heater, the skin temperature sensor and the display, the controller configured to raise the temperature of the heater to a predetermined temperature above the temperature of the core thermal compartment, and to discontinue heating the skin when a threshold skin temperature is reached, the controller further configured to determine the temperature of the core thermal compartment based on the skin temperature data and to provide an indication of the core thermal compartment temperature on the display, wherein the temperature data is a skin temperature-versus-time dissipation curve, and wherein determination of the core thermal compartment temperature is established based on a slow temperature decrease portion of the temperature-versus-time curve determined by waiting for an empirically determined amount of time following the discontinuation of the heating, wherein the slow temperature decrease portion reflects a decreasing rate of change in the temperature measured by the skin temperature sensor and is indicative of reaching thermal equilibrium between the skin and the core thermal compartment. 42. The system of claim 41, wherein the indication of the core thermal compartment temperature corresponds to an intersection point of a first slope and a second slope, wherein the first slope is a rapid temperature decrease portion of the skin temperature-versus-time dissipation curve, and the second slope is the slow temperature decrease portion of the skin temperature-versus-time dissipation curve. 43. The system of claim 41, wherein the indication of the core thermal compartment temperature on the display is a graphical depiction of the skin temperature-versus-time dissipation curve. 44. The core temperature sensor of claim 1, wherein the core temperature is determined in less than 3 minutes.
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