A system configured to determine a characteristic of a patient includes a plurality of sensors, wherein each sensor of the plurality of sensors is configured to noninvasively determine a respective parameter of the patient, and wherein the parameter determined by each sensor is different from parameters determined by remaining sensors of the plurality of sensors. Such a system also includes a connector having a passage configured to direct pressurized fluid therethrough, wherein the plurality of sensors is connected to the connector.

A blood pressure measuring apparatus with a cuff comprises a cuff, an inflation unit, a deflation unit, a pressure sensor, a signal record and storage unit, and an operation and analysis unit. The operation and analysis unit is used to control the inflation unit and the deflation unit to increase the pressure within the cuff to a first pressure, maintain the pressure at the first pressure for a specified interval, then increase the pressure to a second pressure, and decrease the pressure. The blood pressure measurement is accordingly finished. The operation and analysis unit calculates an arteriosclerosis index based on a pulse waveform signal when the adjustable pressure unit maintains the pressure at the first pressure.

Disclosed herein are in vivo non-invasive methods and devices for the measurement of the hemodynamic parameters, such as blood pressure, cardiac output, stroke volume and vascular tone, of a subject, and the mechanical anelastic in vivo properties of the subject's arterial blood vessels. An exemplary method requires obtaining the peripheral pulse volume waveform (PVW), the peripheral pulse pressure waveform (PPW), and the peripheral pulse velocity wavefcirm. (PUW) from the same artery; calculating the time phase shift between the PPW and FM, and the plot of pulse pressure versus pulse volume; and determining the blood pressures and power law components of the anelastic model from the waveforms PPW and PVW, the cardiac output from the waveforms PPW and PUW, and the quality factor of the artery based. upon the calculations. The disclosed methods and devices can be used to diagnose and treat cardiovascular disease in a subject in need thereof.

A wearable sensing device having a first and second opening, a first semipermeable membrane having a first surface and a second surface, and a second semipermeable membrane having a third and fourth surface, a ketone body sensor, and a void. The first opening is juxtaposed to the first surface and the second opening is juxtaposed to the third surface. The space between the first and second openings is the void and wherein the ketone body sensor is positioned within the void. Gasses may permeate through the first opening and into the void to contact the sensor and exit the void through the second opening. The sensor may be in direct skin contact with vapor dissipation being enabled through ventilation. Ventilation will be facilitated by microgrooves on the sensor surface or through vent openings in the encasement.

A wearable device and the accompanying method for the determination of continuous pulsatile BP are described. The absolute values can be obtained in the initial phase and how a transfer function can transform the BP-signal obtain at the finger or wrist to correct BP-values corresponding to the brachial artery and at heart level. The wearable device contains an orthostatic level-correcting element, which can measure the vertical distance between heart level and finger/wrist level, where the actual measurement takes places. The wearable device may be in the form of a ring, a watch, or a bracelet. Further, the wearable device has elements for wirelessly transmitting signals to host devices such as a smart phone, tablet or other computers.

A mammography apparatus includes a support plate for supporting a breast of a patient, a compression plate movable toward and away from the support plate for compressing the breast against the support plate, and a controller configured to control movement of the compression plate toward and away from the support plate. The controller is configured to adjust at least one of a rate of compression and a pressure applied to the breast based on a measurement of at least one of a diastolic pressure and a systolic pressure of the patient taken during at least one of a compression phase and a clamping phase of the mammography apparatus.

Disclosed is a method and an arrangement implementing the method for continuously estimating blood pressure. The method includes receiving an electrocardiography signal and a first photoplethysmography signal measured from the person, extracting values of a timing parameter set based on timings of the electrocardiography signal and the photoplethysmography signal, and calculating at least two intermediate estimates of the blood pressure of the person with linear regression models that model are based on different timing parameter subsets of the timing parameter set. At least one final estimate is then calculated on the basis of the intermediate estimates.

A device is configured for tracking e.g. the diastolic blood pressure in a patient. The device applies a pressure to a body part, e.g. by use of an inflatable cuff. By performing repeated and alternating pressure changes in the cuff, a specific feature of a signal that relates to the diastolic blood pressure can be tracked and possibly measured. The device may have particular use in conjunction with cardiopulmonary resuscitation devices.

A health monitoring device is provided. The health monitoring device includes a wearable component, an optical monitoring module and an air-bag positioning assembly. The wearable component is worn on a body part of a subject and is contacted with a skin tissue. The optical monitoring module is disposed inside the wearable component and includes a driving controller, an optical sensor and at least one light-emitting element. A light source emitted by the light-emitting element irradiates on the skin tissue. The optical sensor receives a reflection light and generates a sensing signal accordingly. The driving controller converts the sensing signal into health data information and outputs the health data information. By the air-bag positioning assembly, the wearable component is securely worn on the body part of the subject, and the optical sensor is attached on the skin tissue of the subject for accurately monitoring the health data information.

A blood pressure estimating apparatus is provided. The blood pressure estimating apparatus may include: a sensor configured to measure a bio-signal waveform; and a processor configured to obtain a first feature based on a first area under the bio-signal waveform in a first time interval, obtain a second feature based on a second area under the bio-signal waveform in a second time interval which is different from the first time interval, and estimate blood pressure based on the first feature and the second feature.