An apparatus adapted to be worn at or near an ear of a subject includes at least one battery, a plurality of electrodes configured to contact the ear and to sense physiological information from the subject, at least one motion sensor configured to monitor subject body motion, at least one analog-to-digital convertor configured to convert analog sensor signals from the plurality of electrodes into digitized information, at least one speaker configured to supply sound to the subject, at least one digital memory device configured to store at least one algorithm for signal processing, at least one signal processor configured to process data from the plurality of electrodes and the at least one motion sensor using the at least one algorithm to monitor physiological information from the subject, and at least one transceiver configured to enable wireless communication between the apparatus and a remote device.

Wearable apparatus for monitoring various physiological and environmental factors are provided. Real-time, noninvasive health and environmental monitors include a plurality of compact sensors integrated within small, low-profile devices, such as earpiece modules. Physiological and environmental data is collected and wirelessly transmitted into a wireless network, where the data is stored and/or processed.

Wearable apparatus for monitoring various physiological and environmental factors are provided. Real-time, noninvasive health and environmental monitors include a plurality of compact sensors integrated within small, low-profile devices, such as earpiece modules. Physiological and environmental data is collected and wirelessly transmitted into a wireless network, where the data is stored and/or processed.

Wearable apparatus for monitoring various physiological and environmental factors are provided. Real-time, noninvasive health and environmental monitors include a plurality of compact sensors integrated within small, low-profile devices, such as earpiece modules. Physiological and environmental data is collected and wirelessly transmitted into a wireless network, where the data is stored and/or processed.

Methods are disclosed for analyzing representations of one or more in situ structures in the body of a subject (e.g., a human subject or other animal subject) to glean information about the health of the subject. Methods are disclosed for diagnosing, staging, grading, and monitoring diseases. Methods also are disclosed for targeting treatments and screening, validating therapies based on the analysis of in situ patters (e.g., individual structural features or distributions), and monitoring the effectiveness of therapies.

A local positioning system (LPS) is provided. The LPS includes at least three local position tracking devices, each further including one or more of: a clock synchronized to the clock in each of the other devices; a transmitter transmitting signals over time synchronized to the clock; and a receiver receiving the signals over time from the other devices. The LPS further includes a processor operatively coupled to at least one of the devices and that is configured to: obtain for each of the signals a location of the device that transmitted that signal; produce one or more representations of at least a part of a living body based on at least one of one or more of the locations and one or more further representations of the at least the part of the living body, each of the representations including one or more temporal frames; and to provide output.

Systems and methods are disclosed for locating the parathyroid. In one aspect, temporal variation among a plurality of images is evaluated and at least one image is enhanced according to the temporal variation. The image may be enhanced to one or both of reduce conspicuity of the thyroid gland and enhance conspicuity of the parathyroid gland. Some of the plurality of images may be adjusted in order to align representations of a target portions. Adjustments may be based locations of one or more organs or one or more artificial markers affixed to a living body in the plurality of images. A local positioning system (LPS), GPS, or other locating system may be used to position a living body, align the plurality of images, or to guide the positioning of objects relative to the living body. An elastomeric gel marker for imaging applications is also disclosed.

The present invention relates to a sampling device, a sampling system and a method of sampling, and in particular a method of analysis, for application to a living entity.

An earpiece module includes a physiological sensor, an external energy sensor, a transceiver, a communication module, a data storage component, and a power source. The communication module includes a microphone, a speaker, and a signal processor. The signal processor processes audio information received from a remote source via the transceiver and communicates the processed audio information to a subject via the speaker. The signal processor processes information in real time from the physiological sensor and the external energy sensor, and the signal processor provides biofeedback to the subject based on signals produced by the physiological sensor. The data storage component includes a plurality of algorithms. At least one algorithm focuses processing resources on extracting physiological information from the physiological sensor, at least one algorithm is configured to be modified or uploaded wirelessly via the transceiver, and at least one algorithm is a compression/decompression (CODEC) algorithm.

A method for analyzing biological specimens by spectral imaging to provide a medical diagnosis includes obtaining spectral and visual images of biological specimens and registering the images to detect cell abnormalities, pre-cancerous cells, and cancerous cells. This method eliminates the bias and unreliability of diagnoses that is inherent in standard histopathological and other spectral methods. In addition, a method for correcting confounding spectral contributions that are frequently observed in microscopically acquired infrared spectra of cells and tissue includes performing a phase correction on the spectral data. This phase correction method may be used to correct various types of absorption spectra that are contaminated by reflective components.