Abstract: A bio-surveillance system monitors symptoms or groups of symptoms experienced by people in a geographical area. The system tracks symptoms reported by calls to an emergency service dispatcher. The bio-surveillance system monitors the symptoms and associates the geographical location with the symptoms. Various triggers are programmed and stored in the system to look for certain types of threats. Each trigger is set based on a statistical variation of the historical data relating to the symptoms within a predetermined time in a predefined geographical area. When the reported symptoms exceed one of the triggers, an alert is activated to provide an indication of a potential biological or chemical terrorist attack.

Abstract: Biometric monitoring devices, including various technologies that may be implemented in such devices, are discussed herein. Additionally, techniques for utilizing altimeters in biometric monitoring devices are provided. Such techniques may, in some implementations, involve recalibrating a biometric monitoring device altimeter based on location data; using altimeter data as an aid to gesture recognition; and/or using altimeter data to manage an airplane mode of a biometric monitoring device.

Abstract: This invention relates to method of diagnosing the presence and/or severity of a liver pathology and/or of monitoring the effectiveness of a curative treatment against a liver pathology in an individual, leading to a score, comprising the combination, of at least one blood test and of at least one data issued from a physical method of diagnosing liver fibrosis, said data being selected from the group consisting of medical imaging data and clinical measurements, said combination being performed through a mathematical function. This invention also relates to a method wherein the combination through a mathematical function, of at least one blood test and of at least one data issued from a physical method of diagnosing liver fibrosis, is performed at least twice and the at least two resulting scores are combined in an algorithm based on the diagnostic reliable intervals.

Abstract: The present invention is related to a compact, portable, user-friendly sleep disorder diagnosis and screening device. The present invention is further related to a single-ended respiratory inductance plethysmography belt used to monitor certain parameters of a subject's respiration while at the same time serving to position and mechanically stabilize a compact data acquisition system about a subject's thorax or abdomen. In one application of the present invention to screen for sleep disorders, the single-ended respiratory inductance plethysmography belt is worn by the subject and a compact data acquisition unit is attached to the belt to which appropriate additional sensors and components such as a pulse oximeter and a nasal cannula are connected. Data is then collected using the belt, compact data acquisition unit, and sensors and is used to determine whether the subject has, or is at risk of having, a sleep disorder.

Abstract: A surgical instrument may be configured to sense a light re-emitting probe to resolve tissue oxygenation, the surgical instrument including: an optical emitter configured to excite the light re-emitting probe within an absorption band of the light re-emitting probe; an optical detector configured to receive the re-emitted light from the probe; and a signal processor configured to resolve the tissue oxygenation based on the received light. The surgical instrument can be a surgical stapler anvil or a flexible substrate having a tissue interfacing surface. Further, a monitoring device may be configured to map oxygenation of a tissue containing a light re-emitting probe, the monitoring device including: an optical emitter configured to excite the light re-emitting probe; at least one optical detector configured to receive the re-emitted light from the probe; and a signal processor that is configured to resolve the tissue oxygenation at multiple points to generate an oxygen map.

Abstract: The present invention suggests the use of independent, wireless, smart and therefore self-contained sensors (3, 4, 5) in a patient monitoring system (1). The sensors (3, 4, 5) provide their own communication system for transmitting acquired signals to a patient monitor (8) etc. Furthermore a patient identifier (26) is associated to the communication. This approach introduces a patient-related concept, where all communication is personalized and assigned to the patient (2).

Abstract: Dietary intake regulating devices that can assist a user in measuring his or her dietary intake and optionally his or her physical activity are disclosed.

Abstract: A patient monitoring system for monitoring vital signs, comprises: one or more sensors, wherein the sensors measure vital signs; a monitor station; and one or more portable monitoring devices, wherein monitored data based on the measured vital signs is wirelessly transmitted from the sensors to the monitor station, wherein the monitor station issues one or more alarms to certain ones of the portable monitoring devices as a function of the monitored data, and wherein a portion of the monitored data that pertains to the alarms is wirelessly transmitted to the certain ones of the portable monitoring devices and displayed by the certain ones of the portable monitoring devices.

Abstract: A computationally implemented method includes, but is not limited to: acquiring data indicative of an inferred mental state of an authoring user in connection with at least a particular item of an electronic message, and associating the data indicative of the inferred mental state of the authoring user with the particular item. In addition to the foregoing, other method aspects are described in the claims, drawings, and text forming a part of the present disclosure.

Abstract: An apparatus and method for measuring a person's biometric data as well as associated data and for using that data to determine the person's talents and well-being state, as well as predicting an optimal career path for the person. Biometric data is measured using a sensor, a memory configured to store the biometric signals, a database configured to store and retrieve profiles, and a processor configured to compare biometric data as well as associated data with anonymous profiles stored in the database and create a profile for the person.

Abstract: In a patient monitoring system (10), shorter interval physiological parameters and longer interval clinical data are collected from a monitored patient (12). A composite acuity score generator (70) generates or updates a composite acuity score indicative of wellbeing of the patient (12) based at least on the sensed physiological parameters and the longer interval data. A monitor (22, 56) displays current values of at least one of selected sensed physiological parameters, longer interval data, and the composite acuity score.

Abstract: A computationally implemented method includes, but is not limited to: acquiring a result of an observation of an authoring user; acquiring a result of an observation of a receiving user; comparing the result of the observation of the authoring user with the result of the observation of the receiving user; and presenting data indicative of an extent of congruity between the result of the observation of the authoring user and the result of the observation of the receiving user based at least in part on said comparing. In addition to the foregoing, other related method/system aspects are described in the claims, drawings, and text forming a part of the present disclosure.

Abstract: Systems and methods for automated on-boarding of a new-hire are provided. A sensor may monitor a response of the new-hire. A reference index may correlate the response to a known condition. A processor device may detect the known condition or a threshold number of known conditions. The processor may relate the known condition to feedback. A feedback mechanism may provide the feedback to the new-hire. The feedback may be provided based on the known condition. The feedback may be configured to provide the new-hire with directions, a policy reminder or any other suitable information. The feedback may be based on the threshold number.

Abstract: A device is provided for the output of medical data with an output device (1) for the output of medical data in a first output mode or in a second output mode different therefrom. The device includes a detection device (3, 4) for detecting an ambient parameter and an automatic switchover device for the output of medical data in the first output mode if the ambient parameter detected by the detection device is in a first range of values, and for the output of medical data in a second output mode if the ambient parameter detected by the detection device is in a second range of values different from the first range of values.

Abstract: A muscle assessment method utilizing a computing system, surface electromyometry (sEMG) sensors, and other sensors to gather data for one or more subjects engaged in an activity through operably coupling the one or more sensors to the computing system, and directing a computing system to select one or more muscle assessment protocols related to a number of different metrics. For a user subject engaged in a physical activity, assessing muscle condition, the muscle activity, and statistically related averages provide information to the user and about muscle and whole body fitness.

Abstract: A variety of methods, devices, systems and arrangements are implemented for stimulation of the peripheral nervous system. Consistent with one embodiment of the present invention, method is implemented in which light-responsive channels or pumps are engineered in a set of motor units that includes motor units of differing physical volumes. Optical stimuli are also provided to the light-responsive channels or pumps at an optical intensity that is a function of the size of motor units to be recruited. In certain implementations, the intensity of the optical stimuli is increased so as to recruit increasingly larger motor units.

Abstract: A physiological condition monitor can provide substantially real-time feedback to an individual being monitored. The feedback can be in the form of graphical displays of real-time trends. Both audible and visual warnings can be provided to the individual in response to results of trend analysis.

Abstract: A system and method for the wearable mini-size intelligent healthcare system, comprising one or multiple vital signal sensors, activity sensors, a real-time detection and analyzing module for continuous health monitoring, adjustable user setting mode with the adaptive optimization, data-collecting capability to record important health information, smart audio outputs of audio beep and speech advice to the user through audio path and audio interface, preset and user confirmable alarm conditions via wireless communications network to the appropriate individual for prompt and necessary assistance. The system uses noninvasive monitoring technology for continuous, painless and bloodless health state monitoring. The system also works through the short range RF link with carry-on PDA or cell phone for displaying health information, making urgent contact to support center, doctor or individual, or for information transmission with a healthcare center.

Abstract: A system and method of tracking activity includes a motion sensor, a light source and a light detector. The light detector is configured to capture an amount of the light that is reflected back to the light detector, at least a first portion of the light reflected back to the light detector is reflected from a blood vessel disposed under a skin of a user when the user places the skin over the heart rate monitor location on the housing. A processor is in communication with the motion sensor and the light detector and can process the reflected light to identify heart beats of the user and produce an indication of a heart rate. The indication of the heart rate can be displayed on the display screen as an option, in addition to the metrics that quantify the motion data.

Abstract: Various methods and apparatuses for measuring a state parameter of an individual using signals based on one or more sensors are disclosed. In one embodiment, a first set of signals is used in a first function to determine how a second set of signals is used in one or more second functions to predict the state parameter. In another embodiment, first and second functions are used where the state parameter or an indicator of the state parameter may be obtained from a relationship between the first function and the second function. The state parameter may, for example, include calories consumed or calories burned by the individual. Various methods for making such apparatuses are also disclosed.