A blood pressure measurement system comprises: a pressure sensor guide wire comprising a pressure sensor located in a distal region of the pressure sensor guide wire; a transceiver unit communicatively coupled to the pressure sensor guide wire, the transceiver unit comprising: a housing adapted to be used external to the human body, a sensor signal adapting circuitry configured to process a signal representing a pressure reading sensed by the pressure sensor to create a processed pressure reading, and a first Bluetooth transceiver configured to wirelessly transmit a signal representing the processed pressure reading; and a second Bluetooth transceiver configured to wirelessly receive the signal representing the processed pressure reading transmitted from the first Bluetooth transceiver, wherein the second Bluetooth transceiver is connected with a personal computer that is configured to display a value representing the processed pressure reading.

Embodiments described herein relate to an implantable device that include an inductor coil, a storage capacitor, active circuitry, and a sensor, but doesn't include an electrochemical cell, and methods for use therewith. During first periods of time, the storage capacitor accumulates and stores energy received via the inductor coil from a non-implanted device. During second periods of time, interleaved with the first periods of time, and during which energy is not received from the non-implanted device, the active circuitry of the implantable device is powered by the energy stored on the storage capacitor and is used to perform at least one of a plurality of predetermined operations of the implantable device, including, e.g., obtaining a sensor measurement from the sensor of the implantable device, transmitting a communication signal including a sensor measurement to the non-implanted device, and/or receiving a communication signal from the non-implanted device.

A method includes, in a living organ (28) in which an ambient pressure varies as a function of time, sensing the ambient pressure using a pressure sensor (36, 90, 174), which has a capacitance that varies in response to the ambient pressure, so as to produce a time-varying waveform. A calibration voltage, which modifies the capacitance and thus the time-varying waveform, is applied to the pressure sensor. The time-varying waveform is processed so as to isolate and measure a contribution of the calibration voltage to the waveform. A dependence of the capacitance on the ambient pressure is calibrated using the measured contribution of the calibration voltage.

A sensor assembly which includes a first physiological parameter sensor configured to sense a physiological parameter and a first reactance sensor connected to the first physiological parameter sensor. The first reactance sensor provides a signal corresponding to a position of a tissue relative to the first reactance sensor and corresponding to the first physiological parameter sensor.

Medical device systems and methods for making and using medical device systems are disclosed. An example medical device system may include a guidewire. A pressure sensor assembly may be disposed within the guidewire. The pressure sensor assembly may include a pressure sensor and a first optical fiber coupled to the pressure sensor. The first optical fiber may have a first outer diameter. A cable may be coupled to the guidewire. The cable may include a second optical fiber. The second optical fiber may have a second outer diameter greater than the first outer diameter.

Intravascular devices, systems, and methods are disclosed. In some embodiments, the intravascular devices include at least one pressure sensing component within a distal portion of the device. In that regard, one or more electrical, electronic, optical, and/or electro-optical pressure-sensing components is secured to an elongated member and the system includes components to process the output signals according to various calibration parameters.

A method, including pressing a distal end of a medical probe against a wall of a body cavity, and receiving from the probe first measurements of a force exerted by the distal end on the wall. The method also includes receiving from the probe second measurements indicating a displacement of the wall in response to the force. The method further includes estimating a thickness of the wall based on the first and the second measurements.

A smart personal portable blood pressure measuring system comprises a smart blood pressure measuring base, and a portable blood pressure measuring apparatus comprising a metal electrode detecting unit for detecting an electrocardiography (EKG) signal, a photoplethysmography detector for detecting a photoplethysmography (PPG) signal, a storage unit, a first central processor, a first power supply, and a first coupling interface unit. The storage unit stores a plurality of blood pressure values and a blood pressure algorithm. The first central processor performs a calculation according to the EKG signal, the PPG signal and the blood pressure algorithm. The first power supply provides the necessary power for operating the portable blood pressure measuring apparatus. The first coupling interface unit is coupled to the smart blood pressure measuring base so that the smart blood pressure measuring base is capable of transmitting data to the portable blood pressure measuring apparatus.

An apparatus for calibration of a bio-information estimation model includes a sensor configured to obtain a bio-signal from an object in a reference interval; a feature extractor, implemented by at least one processor, configure to extract a reference feature value from the bio-signal; and a calibrator, implemented by the at least one processor, configured to determine whether a condition is satisfied based on at least one of the reference feature value and an offset value, and based on determining that the condition is satisfied, configured to calibrate the bio-information estimation model based on the reference feature value and the offset value.

The present invention provides automatic zeroing and electronic level adjustment of pressure transducer in relation to patient, applied to vital signs monitors, where the automatic zeroing of circuit of pressure consists of circuit and software able to remove the value of the virtual ground voltage from the pressure calculation, and the electronic level adjustment of transducer in relation to patient consists of compensating, through software, the value in mmHg related to level difference in cmH.sub.2O informed by the user by means of monitor interface.