A method for displaying physiological data on a medical display device includes receiving one or more first units of physiological data from a first monitoring device. At least one of the first units of physiological data is received on a continuous basis. Each first unit of physiological data corresponds to a medical parameter being monitored by the first monitoring device. One or more second units of physiological data are received from a second monitoring device. At least one of the second units of physiological data is received on a non-continuous basis. Each second unit of physiological data corresponds to a medical parameter being monitored by the second monitoring device. The first and second units of physiological data are displayed on a single display screen of the medical display device.

An active protective circuit for a measuring amplifier of an electrical impedance tomograph includes a circuit component arrangement including an electrode input and an output and a control input for a control voltage. The output is configured for connection to a measuring amplifier for an electrical impedance tomograph. The circuit component arrangement creates a conductive connection between the electrode input of the circuit component arrangement and the output of the circuit component arrangement when the applied control voltage is within a first voltage range and does not create a conductive connection when the applied control voltage is within a second voltage range. The voltage being applied to the control input is within the second voltage range when a voltage, which is within a cut-off range, is applied to the electrode input. An electrode belt for impedance tomography has the active protective circuits associated with the electrodes.

A method for assessing a patient may involve performing a first diagnostic procedure on the patient. The first diagnostic procedure may involve securing a volumetric integral phase-shift spectroscopy (VIPS) device to the patient's head, measuring an intracranial bioimpedance with the VIPS device, and detecting an asymmetry based on the measured intracranial bioimpedance. The method may further involve performing a second diagnostic procedure on the patient using an additional diagnostic device, receiving first patient data from the first diagnostic procedure and second patient data from the second diagnostic procedure in a computer processor, processing the first patient data and the second patient data with the computer processor, and generating an assessment of the patient with the computer processor, based at least in part on the processed first patient data and second patient data.

A device for obtaining vital sign information of a living being comprises a detection unit that receives light in at least one wavelength interval reflected from at least a region of interest of a living being and that generates an input signal from the received light. A processing unit processes the input signal and derives vital sign information of the living being from the input signal by use of remote photoplethysmography. An illumination unit illuminates at least the region of interest with light, and a control unit controls the illumination unit based on the input signal and/or the derived vital sign information.

A method and a system for monitoring healthcare garments (3), wherein the method comprises the steps of: providing a temperature sensor (1) on or in a healthcare garment, sensing the temperature of the healthcare garment by means of the temperature sensor, transferring temperature data relating to the sensed temperature over at least one network (5) and a wireless interface (7) from the temperature sensor to a base station (4), and based on the transferred temperature data, determining information relating to a usage cycle of said healthcare garment.

The invention relates to a communication method, comprising the steps of: providing a patient with a control device and a display screen; executing a sequence of cognitive tests to determine a comprehension score (SCR) of the patient; selecting a communication interface as a function of the comprehension score, from a plurality of communication interfaces (EINT, SINT, CINT) having distinct respective complexities, each communication interface comprising at least one home page with selectable areas of interest using the control device; activating the selected communication interface and displaying the home page of the selected communication interface on the display screen; detecting the designation by the control device of an area of interest among the areas of interest in a page displayed on the display screen; and emitting a voice message following the detection of the designation of an area of interest.

A patient support apparatus for supporting a patient includes a plurality of pseudo-anchors that are used to determine relative position estimates with respect to an anchor affixed at a known location to a wall of a healthcare facility. From these position estimates and the knowledge of the location of the pseudo-anchors on the body of the patient support apparatus, the position and/or orientation of the patient support apparatus is determined. The pseudo-anchors may also determine the relative location of a mobile medical device with respect to the patient support apparatus. If the medical device is closely positioned to the patient support apparatus, the patient support apparatus associates the medical device with the patient support apparatus and transmits data to a server indicating the association. The medical device may include a location module and a data collection module that transmit information to the patient support apparatus for forwarding to the server.

A method and system for assisting clinicians in determining when and how to perform a lung recruitment procedure. The method includes a user configurable interface that an operator or institution can set up to correspond to best practices. Based upon the information entered into the configurable user interface, a method and algorithm automatically determines when a lung recruitment procedure should be instituted. The system can either manually or automatically enable the beginning of the lung recruitment procedure depending upon the clinician and facility preferences. The algorithm includes a plurality of process steps that are carried out in a clinically-relevant order to eliminate patient condition options and to provide the appropriate recommended actions prior to initiating the lung recruitment procedure.

A system, includes a wireless communication network that transmits data over available radio frequency channels, one or more medical sensors that are associated with a patient and that detect physiological data from the patient, and one or more communication hubs associated with the patient and that receive the detected physiological data from the one or more medical sensors and scan the available radio frequency channels around the one or more communication hubs to generate radio frequency data indicative of a measured signal strength in each available radio frequency channel of the of available radio frequency channels. The one or more communication hubs wirelessly transmit the physiological data and the radio frequency data via one or more of the of available radio frequency channels. The system further includes a processor and a memory storing instructions, such that the instruction cause the processor to receive the radio frequency data and provide communications instructions to the one or more communication hubs to communicate the physiological data over a different available radio frequency channel based on the radio frequency data.

A device and a method for the analysis of the air exhaled by a subject in order to measure basal metabolism of the subject comprise a main line for a sampling flow of the air exhaled by a subject who breathes spontaneously or a subject undergoing assisted pulmonary ventilation. A mixing mini-chamber is provided for mixing a plurality of air sampling flows exhaled by the subject within a number of respiratory cycles. Sensors for sensing the oxygen concentration and the carbon dioxide concentration respectively measure the oxygen concentration and the carbon dioxide concentration within the air flow in the main line. The device further comprises an electronic control unit which processes signals from the sensors for obtaining a measurement of metabolism of the subject within a number of respiratory cycles. The electronic control unit is further programmed for automatically starting, upon switching on the device, a self-calibration stage of the device, by connecting the main line to a calibration line while causing the calibration flow to pass through a by-pass line by-passing the mixing mini-chamber, so that the calibration can be performed immediately, without requiring a filling of the mixing mini-chamber.