What is disclosed is a system for measurement and analysis of blood pressure of a test subject comprising a blood pressure measuring cuff unit; a waveform analysis subsystem coupled to said blood pressure measuring cuff unit via a network; and wherein said cuff unit acquires a digital pulse pressure waveform from a wrist of the test subject, said digital pulse pressure waveform is transmitted over said network to said waveform analysis subsystem, and said waveform analysis subsystem processes said digital pulse pressure waveform to extract one or more blood pressure parameters and hemodynamic parameters.

A blood pressure measuring device includes a curler configured to bend along a circumferential direction of a wrist of a living body, and configured to come into contact with a portion of the wrist at least between a dorsal side and a palmar side; a strap provided to a device main body, and configured to cover an outer surface of the curler; a sensing cuff arranged in a region of the wrist where arteries exist; a back plate provided on a side of the sensing cuff nearer to the curler; a rubber plate provided on a side of the back plate nearer to the curler; a pressing cuff provided between the curler and the rubber plate; and a cuff provided on a side of the curler nearer to the living body and arranged on the dorsal side of the wrist.

A non-invasive blood pressure (NIBP) measurement system that includes a blood pressure cuff and a non-invasive blood pressure monitor. The blood pressure cuff including an inner portion that is selectively inflatable and an outer portion that is rigid or semi-rigid. The outer portion reducing external stimuli on the inner portion. The inner portion connected to a sensor coupled to the NIBP monitor, the sensor sensing a pressure of the inner portion. The NIBP monitor receiving the sensor data and processing the sensor data to determine a blood pressure of a patient about which the blood pressure cuff has been placed.

A blood pressure measurement method includes wrapping a cuff around a site. The cuff includes: a first bladder that swells due to receiving fluid and is arranged at an outer surface of the site that corresponds to a first half surface where an artery is; and a second bladder that swells due to receiving fluid and is arranged at the outer circumferential surface of the measurement site that corresponds to a second half surface opposite to the first half surface. During inflation, the pressure of the second bladder is made larger than the first bladder by supplying more fluid such that the stroke amount by which the second fluid bladder swells is larger in the thickness direction. Then, the two bladders are inflated at equal rates. In the process of inflating, or in the process of deflating at rates equal to each other after inflating, blood pressure is measured.

A blood flow occlusion system includes an inflator and a pressure regulator coupled to a pressure cuff and a computing device coupled to the inflator and the regulator. The computing device comprises a memory coupled to the processor which is configured to be capable of executing programmed instructions stored in the memory to: determine brachial occlusion data based on calculating the brachial occlusion data with an occlusion regression equation using one or more input diagnostic parameters associated with a client; generate treatment parameters of a treatment program to treat the condition of the client based on the optimized brachial occlusion data and an obtained stage of the condition; generate programmed instructions of control commands to manage operation of the pressure cuff, inflator, and pressure regulator based on the treatment parameters; and initiate execution of the programmed instructions for the treatment program for treating the condition of the client when engaged.

A monitoring system configured to measure the user's health-related parameters while in a certain state is disclosed. Based on whether the user is in the certain state and/or one or more criteria being met, the monitoring system can perform a physiological measurement such as a blood pressure measurement. The monitoring system can be capable of dynamically adjusting the measurement parameters, criteria, and acquired information based one or more scalers. The criteria can be based on user states or conditions such that user disruptions can be reduced and the measurement accuracy and/or efficiency can be enhanced. The monitoring system can also measure the user's parameters during the measurement and may abort the measurement if the measurement may not have accurate information and/or to reduce any disruption to the user. Alternatively, the measurement can be annotated so that the measurement can be used during data interpretation with certain qualifiers attached.

A method of cuff storage case for an electronic blood pressure monitor includes an electronic blood pressure monitor main part, cuff, and a cuff storage case. one end of the air tube connects to a side of the electronic blood pressure monitor main part, and the other end of the air tube connects to a cuff. When the electronic blood pressure monitor main part is not in use, the cuff can place inside the cuff storage case. The Cuff storage case connects to the electronic blood pressure monitor main part through the connecting element. The structure of this invention is reasonable. The cuff storage case fixes on the electronic blood pressure monitor main part through the connecting element and will not restrict the models and shapes of the electronic blood pressure monitor. It can apply to most kinds of electronic blood pressure monitors.

The present invention provides a non-invasive portable device and method for diagnosing an occlusion in coronary arteries of a patient. The diagnostic system includes a signal processor configured to receive signals from a group of acoustic sensors attached to the torso of a patient. The diagnostic device is configured with a processor to receive and generate an output on a display using a high end algorithm.

Systems and methods are provided for a non-invasive high resolution pressure pulse waveform measurement system. The system may include a blood pressure cuff, an air pump to inflate the blood pressure cuff to specific pressure levels, high resolution pressure sensors configured to perform high sensitivity signal acquisition at a specified pressure level, high range pressure sensors configured to measure an absolute reference for the signal and to calibrate the signal, pneumatic tubing connecting the air pump and sensors with the cuff, and a hydrodynamic filter configured as an input to a reference port of the high resolution pressure sensor. The hydrodynamic filter may be configured to transmit only mean pressure by attenuating a selected frequency range of the signal.

An airbag of an electronic blood pressure monitor is provided. The airbag includes an outer wall and at least one connection wall; the outer wall includes a first wall, a peripheral side wall, and a second wall; the first wall and the second wall are disposed opposite to each other; the peripheral side wall is connected to a periphery of the first wall and a periphery of the second wall; the first wall, the side wall, and the second wall form an air chamber; the at least one connection wall is located in the air chamber; each connection wall is connected to at least two of the peripheral side wall, the first wall, and the second wall; and each connection wall is tensed when the airbag is in an expanded state. This application further provides an electronic blood pressure monitor including the airbag.