A method and apparatus for receiving, from a wearable sensor, current lactate level information of a user; setting, by the user, a target fatigue value; determining target lactate level information based on the target fatigue value; receiving characteristics of a physical exercise including information of an end of the physical exercise; determining adjusted characteristics of the physical exercise in order to match the current user lactate level information in the end of the physical exercise with the target lactate level information, based on the current lactate level information of the user, the target lactate level information and the characteristics for the physical exercise; and providing feedback to the user based on the adjusted characteristics of the physical exercise.

A digital processor system having one or more processors and memory obtains a time-domain signal representing brain activity, the time-domain signal having a time varying signal value. The system concurrently generates a set of acoustic parameters, including a plurality of time-varying acoustic parameters, where one or more of the plurality of time-varying acoustic parameters is modulated in accordance with at least the signal value of the time-domain signal. The system combines the concurrently generated set of acoustic parameters to produce a representation of an acoustic signal corresponding to the time-domain signal, where the acoustic signal, in audible form, manifests one or more audibly discernible variations across a plurality of stages of a brain activity event.

A method of providing audiometric feedback from a network of distributed body sensors using one or more earpieces includes receiving signals from the network of distributed body sensors at the one or more wireless earpieces, processing the signals received at the one or more wireless earpieces to determine a location of individual body sensors within the network of distributed body sensors relative the one or more earpieces, and producing audiometric feedback at the one or more wireless earpieces at least partially based on the locations of the individual body sensors relative to the one or more earpieces.

Quantitative colorimetric carbon dioxide detection and measurement systems are disclosed. The systems can include a gas conduit, a colorimetric indicator adapted to exhibit a color change in response to exposure to carbon dioxide gas, a temperature controller operatively coupled to the colorimetric indicator and configured to control the temperature of the colorimetric indicator, an electro-optical sensor assembly including a light source or sources adapted to transmit light to the colorimetric indicator, and a photodiode or photodiodes configured to detect light reflected from the colorimetric indicator and to generate a measurement signal, and a processor in communication with the electro-optical sensor assembly. The processor can be configured to receive the measurement signal generated by the electro-optical sensor assembly and to compute a concentration of carbon dioxide based on the measurement signal. Methods for using the systems are also disclosed including providing a breathing therapy to a patient or user.

System and method for determining the position and orientation (P&O) of a tool-tip relative to an eye tissue of interest. The system includes and imaging and tracking module coupled with a processor. The imaging and tracking module at least includes an imager. The imager acquires at least one image of at least one tissue-reference-marker. The imaging and tracking module further determines information relating to the P&O of the tool. The processor determines the P&O of the tissue-reference-marker according to the acquired image of the tissue-reference-marker. The processor determines the P&O of the eye tissue of interest, according to the P&O of the tissue-reference-marker, and a predetermined relative P&O between the tissue-reference-marker and the eye tissue of interest. The processor also determines the P&O of a tool-tip according to a tool-marker and determines the relative P&O between the tool-tip and the eye tissue of interest.

There is set forth herein an apparatus comprising: a non-contacting array of sensors adapted for positioning at a position spaced from and proximate a position of a patient; and a signal processing circuit in communication with the array of sensors, wherein the signal processing circuit is configured for: generating a plurality of time varying signals using the array of sensors; processing the plurality of time varying signals; and outputting one or more indicator based on the processing. The apparatus can be adapted for use in a variety of applications including emergency applications such as live birth applications in which neonate resuscitation protocols are observed.

A personal care device for modifying a keratinous surface having a sensor, a treatment element adapted to deposit a personal care composition, a feedback element, and a processor. The feedback element can be activated during deposition of the personal care composition. The personal care device can analyze a keratinous surface, identify keratinous imperfections, and then modify the keratinous imperfection by depositing a personal care composition. The feedback element can be intermittently activated during deposition and can emit a feedback signal that corresponds to the deposition of the personal care composition to alert the user as to how the personal care device is working and/or when the modification process is complete.

A probe with a blood circulation sensor and a force or pressure sensor is placed against a patient. One part of the probe applies a force to another part of the probe which is pressed against the patient at one or more locations. The variation of a measure of blood circulation is recorded as a function of the applied pressure, thereby giving the operator a specific knowledge of the Tissue Perfusion Pressure (TPP), a measure of circulatory health, at each location.

An example method is performed by a medical device and includes detecting, during a time interval, a sound indicative of cardiac activity of a subject; generating audio indicative of a pulse of the subject by analyzing the sound; and simultaneously outputting: the audio indicative of the pulse of the subject; and a visual signal indicating an additional physiological parameter of the subject detected during the time interval.

Quantitative colorimetric carbon dioxide detection and measurement systems are disclosed. The systems can include a gas conduit, a colorimetric indicator adapted to exhibit a color change in response to exposure to carbon dioxide gas, a temperature controller operatively coupled to the colorimetric indicator and configured to control the temperature of the colorimetric indicator, an electro-optical sensor assembly including a light source or sources adapted to transmit light to the colorimetric indicator, and a photodiode or photodiodes configured to detect light reflected from the colorimetric indicator and to generate a measurement signal, and a processor in communication with the electro-optical sensor assembly. The processor can be configured to receive the measurement signal generated by the electro-optical sensor assembly and to compute a concentration of carbon dioxide based on the measurement signal. Methods for using the systems are also disclosed including providing a breathing therapy to a patient or user.