This document describes techniques for, and systems that enable, in-ear health monitoring. The techniques described herein enable early detection of health conditions (e.g., contagious disease) through use of an in-ear health-monitoring and audio device. These techniques prompt a user, often through the user's smart phone, to listen to audio content through the device, which also takes the user's temperature. Through repetitive use, the techniques are capable of determining a temperature differential for the user, which aids in early detection of a contagious disease or other malady.

A medical thermometer including a curved mirror and a radiation sensor is disclosed. The radiation sensor is disposed relative to the mirror in a configuration whereby the mirror reflects away from the sensor radiation that passes through the radiation entrance and that is oriented outside a range of angles relative to the mirror, and reflects toward the sensor radiation that passes through the radiation entrance and that is oriented within a range of angles relative to the mirror.

This document describes techniques for, and systems that enable, in-ear health monitoring. The techniques described herein enable early detection of health conditions (e.g., contagious disease) through use of an in-ear health-monitoring and audio device. These techniques prompt a user, often through the user's smart phone, to listen to audio content through the device, which also takes the user's temperature. Through repetitive use, the techniques are capable of determining a temperature differential for the user, which aids in early detection of a contagious disease or other malady.

A medical thermometer including a curved mirror and a radiation sensor is disclosed. The radiation sensor is disposed relative to the mirror in a configuration whereby the mirror reflects away from the sensor radiation that passes through the radiation entrance and that is oriented outside a range of angles relative to the mirror, and reflects toward the sensor radiation that passes through the radiation entrance and that is oriented within a range of angles relative to the mirror.

A protective cover for an insertion probe of a medical instrument. The cover contains a flexible tubular body that compliments the probe geometry and a radially disposed flange that surrounds the proximal end of the body. A series of snap-on fasteners removably connect the cover to the instrument. A camming surface is located on the outer face of the flange which coacts with a cam follower that is movably mounted upon the instrument to flex the cover sufficiently to open the fastener and release the cover from the instrument and move the cover axially toward the distal end of the tip.

An earbud includes a housing, a thermometer module and a speaker module. The housing defines a passageway having a passageway opening. The thermometer module is disposed in the housing, and receives infrared radiation from an eardrum via the passageway. The speaker module is disposed in the housing, and is operable to generate sound waves that travel through the passageway toward the eardrum. The speaker module cooperates with the housing and the thermometer module to define an infrared radiation path and a sound wave path within the passageway that are separated from each other and that are for the infrared radiation from the eardrum and the sound waves generated by the speaker module to respectively travel therethrough.

Embodiments include a thermometer for measuring a temperature of a living being, including inside a cavity or on an external surface of the living being. The thermometer includes a temperature sensing probe coupled to the proximal end of the housing, a power source, light source, and processor. The light source can be configured to illuminate a portion of the housing near the temperature sensing probe. In some embodiments, the light source is configured to emit light in a plurality of colors. At least one of the plurality of colors may be indicative of a pre-measurement state. Some of the plurality of colors can be indicative of a specific temperature range. In some embodiments, the processor is operatively coupled to the power source, the temperature sensing probe, and the light source.

A method of determining a temperature of a patient includes determining a temperature associated with a measurement site of the patient with a temperature device, and without contacting the patient with the device. The method also includes estimating a temperature of the patient based at least in part on the temperature associated with the measurement site. The temperature device includes a sensing element configured to determine the temperature associated with the measurement site, an imaging device, and a controller configured to estimate the temperature of the patient based on the temperature associated with the measurement site.

A temperature measurement system includes a temperature probe including a temperature sensor. The system also includes a reader, and a controller in communication with the temperature sensor and the reader. The system further includes a container housing a plurality of probe covers associated with the temperature probe. The container includes an information feature providing information related to the plurality of probe covers. The reader is configured to read the information and direct a signal to the controller indicative of the information.

An apparatus for measuring body core temperature includes a light guide with an internally reflective tube. The light guide is coupled to an earpiece, and has a lens or an aperture positioned at one of its ends. A sensor is positioned at the other end of the light guide, and a processor is coupled to the sensor. The sensor senses infrared radiation from an infrared source at the end of the light guide, and the processor determines a temperature of the infrared source at the end of the light guide via a transfer function that correlates a measure of the infrared radiation observed by the sensor and an effect of radiation of the light guide.