An electrode includes separate first and second electrical contacts to contact the skin of a subject. A charge-holding structure is electrically connected between the first and second contacts. An indicator is operatively coupled to the charge-holding structure so that the indicator changes visibly in response to a change in the charge stored in the charge-holding structure. The electrode can include a rectifier across the contacts. A container for electrodes includes an electrical supply and a plurality of receptacles for electrodes so that a voltage difference is maintained across conductors of each receptacle (and contacts of an electrode therein) for at least one week. A method of making electrodes includes arranging the contacts over a support, connecting the charge-holding structure between them, arranging the indicator over the support, and charging the charge-holding structure so that the indicator has a first visual appearance.

A posture improvement device, system, and method. The system for improving posture may comprise: a sensor device; posture improvement software program, comprising a posture improvement system interface; and one or more user devices. The sensor device may be physically associated with a user and may communicate with the posture improvement software program. The sensor device may comprise: one or more sensors for monitoring positions and movements of the user. The system may calculate one or more optimum postural positions for the user, based on data communicated by the sensor device and collected information about the user. The system may monitor a conformance of the user with the optimum postural positions and may display the conformance on the posture improvement system interface. The system may detect and notify the user of one or more non-conformances, such that a user is reminded to maintain at least one optimum postural position.

Provided are a child health management system and a child health management method. A child health management system according to one embodiment of the present invention is a child health management system using a user terminal, which comprises: a storage unit for storing condition information of a child and surrounding environment information of the child, transmitted from the user terminal; a health condition analysis unit for analyzing the health condition of the child on the basis of the condition information and surrounding environment information of the child, stored in the storage unit; and a response strategy deduction unit for deducing a user's response strategy according to the analysis result from the health condition analysis unit.

The present disclosure provides an exercise monitoring device. The exercise monitoring device comprises a sensor module, a processing module, a storage module, and a user interface. The present disclosure also provides a method for estimating maximal oxygen consumption and/or future total exercise time by obtaining a person's physiological data and exercise data. The present disclosure further provides a method for calibrating the future total exercise time by environmental conditions to form an environmental specific total exercise time.

Medical system and method for operation of an active implantable medical device (IMD) and an extracorporeal device attached to a patient's skin, comprising: determining data regarding a bodily parameter of the patient by the IMD, processing the determined data and detecting a condition from a plurality of predefined conditions based on the determined data, periodically sending an intra-body communication signal representing the detected condition by the IMD to the extracorporeal device, receiving the intra-body communication signal by the extracorporeal device, providing a predefined notification signal by the extracorporeal device to the patient to motivate the patient to perform a predefined action based on the received intra-body communication signal, sending a termination signal by the extracorporeal device to the IMD, and receiving the termination signal by the IMD and subsequently terminating sending the intra-body communication signal which was initiated by the previously detected condition.

An improved analyte monitoring system having a sensor and a transceiver with improved communication and/or user interface capabilities. The transceiver may communicate with and power the sensor. The transceiver may receive one or more analyte measurements from the sensor and may calculate one or more analyte concentrations based on the received analyte measurements. The transceiver may generate analyte concentration trends, alerts, and/or alarms based on the calculated analyte concentrations. The system may also include a display device, which may be, for example, a smartphone and may be used to display analyte measurements received from the transceiver. The display device may execute a mobile medical application. The system may include a data management system, which may be web-based.

A apparatus according to an embodiment includes a processing circuitry. The processing circuitry is configured to detect whether a mobile terminal is placed at a certain position that is located outside an entrance of a room in which a magnetic resonance imaging apparatus is installed. The processing circuitry is configured to execute unlock a door of the entrance, or output information related to permission for entry into the room through the entrance, in a case in which it is detected that the mobile terminal is placed at the certain position.

An ambulatory medical device includes a sensor configured to acquire a signal indicative of a physiological condition of a patient, a controller operatively coupled to the sensor and configured to monitor the physiological signal, and to perform a diagnostic test, and a remote access manager operatively coupled to the controller and configured to monitor for a command from a remote system to perform the diagnostic test, and to cause the controller to perform the diagnostic test in response to the command. In the device, the remote access manager may be further configured to transmit data representing an operational status of the ambulatory medical device to the remote system. The operational status of the controller may result from performing the diagnostic test. The remote access manager may be further configured to send the data representing the operational status of the ambulatory medical device in real time or substantially in real time.

Delivering content based on predicted effect can include analyzing, using computer hardware, digital content before providing the digital content to a device of a user, predicting, using the computer hardware, an effect that the digital content will have on a circadian rhythm of the user, based on the predicted effect, modifying, using the computer hardware, the digital content to generate modified digital content, and providing, using the computer hardware, the modified digital content to the device of the user.

It is an object of the invention to improve a user's breathing for a specific application (e.g. diagnostic imaging, falling asleep improvement (shortening sleep onset), delivery, tinnitus control therapy, CORD, blood pressure control). This object is achieved by a breathing adaptation system configured for influencing a breathing parameter of a user's breathing pattern in order to meet a goal of decreasing or increasing the influenced breathing parameter to a certain extent in a user specific manner. The breathing adaptation system comprises a sensor, configured for monitoring a current value of the influenced breathing parameter of the user. The breathing adaptation system further comprises a feedback unit configured for providing feedback to the user about a preferred value of the influenced breathing parameter, wherein the preferred value is different from the current value of the influenced breathing parameter (310). The breathing adaptation system further comprises a control unit, comprising program code means for determining the preferred value of the influenced breathing parameter in a user specific manner by means of an intelligent agent, wherein the control unit is implemented such that the intelligent agent is rewarded (330) by means of a reward function after performing the determination of the preferred value (320) of the influenced breathing parameter, wherein the reward function is such that it balances the reward for obtaining the goal and the ability of the user to breathe according to a breathing pattern having the preferred value for the influenced breathing parameter.