A system and method prevents and diagnoses deep vein thrombosis in a body limb by providing a pressure sleeve having a plurality of individually fillable cells, the pressure sleeve being configurable to be placed around a body limb. A source fills each fillable cell individually, and a pressure sensor measures a pressure in a fillable cell. A controller establishes a fill sequence of each individually fillable cell and a fill time for each individually fillable cell. The controller causes a first individually fillable cell of the pressure sleeve to be filled to a predetermined pressure and causes the pressure of first individually fillable cell of the pressure sleeve to be measured while a second individually fillable cell of the pressure sleeve is filled. The controller determines a presence of deep vein thrombosis in a body limb having the pressure sleeve therearound based upon a measured pressure change in the first individually fillable cell of the pressure sleeve.

A cuff includes a fluid bladder, an outer cover that contains the fluid bladder toward one end portion, a surface fastener, and another surface fastener. The outer cover includes, in an area of the outer cover that includes a region in which the other surface fastener is provided, a first wide portion in which the width of the outer cover is greater than a width of an area of the outer cover that includes a region in which the surface fastener is provided. The other surface fastener includes a second wide portion in which the width of the other surface fastener is greater than the width of the surface fastener. The cuff can be fitted to a measurement area with certainty.

A measuring apparatus includes a first laser light source for emitting laser light of a first wavelength, a second laser light source for emitting laser light of a second wavelength different from the first wavelength, an optical detector for receiving scattered laser light from a measured part, and a controller configured to calculate a first value based on an output of the optical detector that is based on received scattered laser light of the first wavelength, calculate a second value based on an output of the optical detector that is based on received scattered laser light of the second wavelength, and measure oxygen saturation based on a ratio of the first value to the second value.

The present invention is related to a cardiovascular monitoring device including an inflatable cuff for surrounding a limb of a user, at least a first and a second electrodes, a controlling circuitry with a processor accommodated in a housing, and a display element. The controlling circuitry is configured to perform a blood pressure measurement through controlling a pressure inside the inflatable cuff, and perform an electrocardiogram measurement by using the electrodes. The processor is also configured to provide a diastolic blood pressure and a systolic blood pressure when the blood pressure measurement is performed, and to provide a heart rhythm information when the electrocardiogram measurement is performed. Further, for achieving a better and more stable contact between the electrodes and the user's skin, the present invention provides an improved structure with electrodes arranged thereon based on the conventional blood pressure monitor.

A biometric measuring device for obtaining biometric measurements on a limb or digit, such as a finger. The biometric measuring device may include a rollable sleeve that is rollable along a longitudinal axis of the limb or digit and multiple biometric sensors attached to the rollable sleeve such that the biometric sensors are positioned on the rollable sleeve to enable the sleeve to be rolled.

The invention relates to a system for predicting the viability of a body tissue in a patient. The system comprises a computing device, and a first pressure measuring device for measuring local perfusion pressure in the body tissue of the patient. This measuring device is connected to the computing device. A second pressure measuring device is provided for measuring the systemic perfusion pressure of the patient, said second pressure measuring device being connected to the computing device. A feedback indicator is connected to the computing device and is adapted to indicate the viability of the tissue calculated by the computing device on the basis of the measured local and systemic perfusion pressures. The invention also includes a method of predicting the viability of the body tissue and to the first pressure measuring device.

A fluid bladder includes multiple segment bladders that are each formed by folding one sheet in half in a width direction X extending along an artery passing through the measurement site, welding or adhering edge portions on a side opposite to the folding location for folding in half, and welding or adhering edge portions in a lengthwise direction Y. The multiple segment bladders are stacked in a width direction orthogonal to the measurement site and integrated, and the folding locations are arranged alternatingly on opposite sides in the width direction.

A blood pressure cuff includes an alignment tab, a sleeve, and an inflatable bladder disposed within the sleeve. The inflatable bladder includes a first rectangular section having a first width, a second rectangular section having a second width, wherein the second width is larger than the first width, and a tapered section extending between the first rectangular section and the second rectangular section. The tapered section may be linearly tapered or a curved taper. A length from an edge of the alignment tab to the second end of the first rectangular section adjacent the tapered section is approximately equal to a minimum arm circumference for the blood pressure cuff.

A portable blood pressure monitoring device capable of wirelessly interacting with a secondary device, such as a cell phone, to measure blood pressure of a patient wherein the device is configurable to fold into a low profile storage configuration. The blood pressure monitoring device includes a cuff for wrapping around the limb of a subject the cuff further having a an inflatable bladder formed integrally therein, wherein the cuff is substantially rectangular in shape having a first surface, a second surface, a first end, a second end, and two sides, and a securement mechanism; one or more tubes positioned within the cuff in communication with the inflatable bladder; an exhaust valve; a displayless housing connected to one of a first end and a second end of the cuff wherein the housing includes one or more of a controller, a memory, a pump, a power supply, and a motor; and a transmitter for wirelessly transmitting blood pressure data to a second device.

A pressurizing/depressurizing section (4) performs at least one of air feeding to a cuff (20) by way of an air way (3) and air discharging by way of the air way (3) to thereby increase or decrease an internal pressure of the cuff (20). A first controlling section (5) causes the pressurizing/depressurizing section (4) to initiate the air feeding while performing the air discharging to thereby cause the internal pressure to transit from a pressure transient state to a pressure steady state or from the pressure steady state to the pressure transient state. A determining section (6) determines Whether the internal pressure has transited to the pressure steady state by way of the pressure transient state. A second controlling section (7) causes the pressurizing/depressurizing section (4) to suppress or stop the air discharging while continuing the air feeding, in accordance with determination made by the determining section (6).