Abstract: A smart face mask comprising a mask body; a temperature sensor; a respiration sensor; and a transmitter for transmitting information from the temperature sensor, the respiration sensor and a geotracker to a smart phone or smart watch.

Abstract: A handheld device for sonifying electrical signals obtained from a subject is provided. The device can utilize at least one of several operations including (but not limited) digitizing signals from electrodes, adjusting the signals based on accelerometer input, filtering the signals, conditioning the signals according to conditioning parameters, modulating the signal according to sound synthesis parameters, and generating sound from the representations of the signals to accomplish sonification. The device can include an analog-to-digital (A/D) converter to digitize the one or more electrical signals and a processor that receives the one or more digitized electrical signals and produces a representation of an acoustic signal. The device further includes a speaker system that sonifies the representation of the acoustic signal.

Abstract: A catheter and guide wire assembly for measurement of blood pressure in a living body, including a tubular shaft, which is connected to a tubular extension, which is connected to a permeable helical coil, which has a distal end that is secured in a distal tip, and a core member, which is attached in a distal portion of the tubular shaft and extends through the tubular extension and the helical coil, and is secured in the distal tip. The catheter and guide wire assembly has an outer diameter of about 0.35 mm and an open, inner lumen, which includes the tubular shaft, the tubular extension, the helical coil, and the core member. The catheter and guide wire assembly has a total flow-resistance index less than about 1.2×106 mm?3, and more preferably less than about 1.0×106 mm?3, and even more preferably less than about 0.7×106 mm?3.

Abstract: A method (200) of deriving systolic blood pressure and/or diastolic blood pressure of a subject is disclosed. The method comprises: (i) receiving (202) data related to at least one cardiac cycle of a bio-signal from the subject; (ii) calculating (208) a rise time and a fall time of the at least one cardiac cycle based on the received data; (iii) calculating (208) a parameter derived from a function of the rise time and fail time; and (iv) determining (210) the systolic blood pressure and/or diastolic blood pressure of the subject based on the calculated parameter. A related apparatus is also disclosed.

Abstract: A biological sound analyzing apparatus is provided with: an obtaining device configured to obtain first information regarding biological sounds in a first period; and an outputting device configured to output second information, which indicates a ratio of a generation time in which sounds indicating abnormality of a living body and included in the biological sounds are generated, with respect to the first period, on the basis of the first information. According to the biological sound analyzing apparatus, it is possible to preferably analyze information regarding the sounds indicating the abnormality because it can output the ratio of the generation time of the sounds indicating the abnormality and included in the biological sounds.

Abstract: A bag-shaped structure for a blood pressure monitor cuff that is wrapped around a living body and is inflated by supplying a fluid to an internal space to apply a pressure to the living body, includes an inner wall portion that is positioned on the living body's side, has a Shore A hardness of 15 to 75, and has a thickness of 0.10 mm to 0.40 mm, an outer wall portion that faces the inner wall portion, and a pair of side wall portions that are provided in a manner to be continuous with the inner wall portion and the outer wall portion, have a Shore A hardness equal to the Shore A hardness of the inner wall portion, and have a thickness that falls within a range of 0.15 mm to 0.60 mm and is equal to or greater than a thickness of the inner wall portion.

Abstract: A noninvasive method of sensing an arterial pulse on a paw pad includes providing an instrument having a probe; placing the probe housing a tactile transducer and a reflective optical coupler comprising an infrared emitter and an infrared detector on a subject's metatarsal or metacarpal pad; emitting infrared light from the emitter; detecting infrared light with the detector; maintaining a linear direct current bias of the detector; converting a signal emitted by the infrared detector into a digital pulse that drives the tactile transducer to emit tactile pulses; and counting the tactile pulses over a predetermined time. An arterial pulse detection system includes a probe. The probe contains an optical sensor and a tactile transducer to which instrumentation is electrically connected. The optical sensor includes an infrared emitter and an infrared detector.

Abstract: A device (250) for estimating the risk of a future hypoglycemic event for a subject with a standing insulin regimen (206), wherein the standing insulin regimen comprises one or more types of insulin medicament dosage regimen (208), wherein each of the one or more types of insulin medicament dosage regimen (208) comprises a type of insulin medicament (210) defining one or more types of insulin medicaments. Using the evaluation of a glucose concentration, a first time derivative and an insulin on board for the subject in a current metabolic state, and the evaluation of a glucose concentration, a first derivative and a historical insulin on board to estimate a hypoglycemic risk measure.

Abstract: A method for contextually aware determination of respiration includes obtaining, by an electronic device, context information and selecting, by the electronic device, a set of sensor data associated with respiratory activity of a subject, based on the context information. The method further includes selecting, based on the selected set of sensor data, an algorithm from a plurality of algorithms for determining a respiration rate of the subject, and determining, by applying the selected algorithm to the selected set of sensor data associated with respiratory activity of the subject, the respiration rate for the subject.

Abstract: The present invention relates to physiological signal processing, and in particular to methods and systems for processing physiological signals to predict a fluid responsiveness of a patient. A medical monitor for monitoring a patient includes an input receiving a photoplethysmograph (PPG) signal representing light absorption by a patient's tissue. The monitor also includes a perfusion status indicator indicating a perfusion status of the PPG signal, and a fluid responsiveness predictor (FRP) calculator programmed to calculate an FRP value based on a respiratory variation of the PPG signal. The FRP calculator applies a correction factor based on the perfusion status indicator.

Abstract: A microcirculation detection system including a heating device, a photosensitive array and a processing unit is provided. The heating device is used to heat a skin area. The photosensitive array is used to detect outgoing light from the skin area, and output a plurality of brightness variation signals respectively at different time points within a heating period. The processing unit is used to calculate a change of an array energy distribution varied within the heating period according to the plurality of brightness variation signals to accordingly identify a microcirculation state.

Abstract: A device for collecting exhalation gas and aiding measurement of a trace component in the exhalation gas and the usage method thereof are disclosed. The device comprises an alveolar air bag for storing alveolar air collected from the breath of a subject, a cavity channel air bag for storing cavity channel air from the subject, a three-way pipe, and a mouthpiece. The three-way pipe comprises a first branch pipe, second branch pipe, and third branch pipe communicating with each other. The first branch pipe and the second branch pipe respectively extend in opposing directions along the same axis. The third branch pipe extends along a radial direction of the first branch pipe and the second branch pipe. The mouthpiece communicates with the first branch pipe. An air hole of the cavity channel air bag communicates with the second branch pipe.

Abstract: A bag-shaped structure excellent in both creep resistance and flexibility is provided. Provided is a bag-shaped structure (122) including a layer (122a) made of a thermoplastic elastomer foam. Also provided are a cuff for a blood pressure monitor and a blood pressure monitor each including the bag-shaped structure (122).

Abstract: Disclosed is apparatus for collecting a breath sample from a human subject, the apparatus comprising at least a mask portion which, in use, is positioned over the subject's mouth and nostrils so as to collect breath exhaled from the subject, the apparatus further comprising movement detection means for detecting movement of the mask portion, and an alarm signal generator, which alarm signal generator generates an alarm signal if the subject's head is outside a predetermined range of acceptable orientations during collection of a breath sample, but only after the subject's head has been outside the predetermined range of acceptable orientations for a defined or measurable period of time.

Abstract: To provide a bag-shaped structure that can suppress expansion of the side wall portion and improve the vascular compression property. A bag-shaped structure used in a cuff for a blood pressure monitor configured to be wrapped around a living body, inflate when a fluid is supplied to an internal space, and compress the living body includes: an inner wall portion provided on a living body side; an outer wall portion facing the inner wall portion; and a pair of side wall portions continuous with the inner wall portion and the outer wall portion and including a bent portion bent toward the internal space; and a reinforcing member provided on each of the pair of side wall portions, having a higher hardness than the side wall portion, and having shape followability in a direction of wrapping around the living body.

Abstract: A biological information analysis device including: an indicator extraction unit that is configured to extract, from time-series data regarding blood pressure waveforms consecutively measured by a sensor that is configured to be worn on a body part of a user and to be capable of non-invasively measuring a blood pressure waveform for each heartbeat, data regarding blood pressure waveforms corresponding to a period of time in which a change in blood pressure occurs, and extract an indicator that is related to the functionality of respiratory organs of the user, based on characteristics of the blood pressure waveforms corresponding to the period of time; and a processing unit that performs processing that is based on the indicator thus extracted.

Abstract: A physiological detection system including an array sensor and a processing unit is provided. The array sensor is configured to output array PPG signals. The processing unit is configured to construct a 3D energy distribution according to the array PPG signals to accordingly identify different microcirculation states.

Abstract: In some examples, devices, systems, and techniques are configured to compensate for changes in sensed blood pressure due to issues such as blood pressure sensor movement. For example, processing circuitry of a device may determine a difference value between a first blood pressure value representative of a blood pressure at a first time and a second blood pressure value representative of the blood pressure at a second time. Responsive to determining that the difference value is greater than or equal to a threshold value, the processing circuitry may generate updated blood pressure values by applying an offset value to the second blood pressure value and subsequently received blood pressure values that compensates for the difference value between the first blood pressure value and the second blood pressure value.

Abstract: A catheter for measuring a pressure distal of a stenosis includes a shaft including a housing in a distal portion of the shaft. A flexible printed circuit board is coupled to the housing. A pressure sensor is coupled to the flexible printed circuit board and is suspended within the housing. An aperture enables blood flow into the housing and into contact with the pressure sensor.

Abstract: A biological sound analyzing apparatus is provided with: an obtaining device configured to obtain biological sound information, which indicates a change in biological sounds with time; a first calculating device configured to calculate first information, which indicates a variation degree based on a first reference value of the biological sounds in a first period, on the basis of the biological sound information; a second calculating device configured to calculate second information, which indicates a variation degree based on a second reference value of the biological sounds in a second period, on the basis of the biological sound information, wherein the second period is longer than the first period; and an outputting device configured to output noise information, which indicates noise included in the biological sounds, on the basis of the first information and the second information. This makes it possible to preferably analyze the noise included in the biological sounds.