Blood pressure, sometimes referred to as arterial blood pressure, is the pressure exerted by circulating blood upon the walls of blood vessels and is one of the principal vital signs. During each heartbeat, blood pressure varies between a maximum (systolic) and a minimum (diastolic) pressure. The blood pressure in the circulation is principally due to the pumping action of the heart. Differences in mean blood pressure are responsible for blood flow from one location to another in the circulation. The rate of mean blood flow depends on the resistance to flow presented by the blood vessels. Mean blood pressure decreases as the circulating blood moves away from the heart through arteries and capillaries due to viscous losses of energy.
A mobile blood pressure monitor is described that includes an integrated acoustic device, an optical sensor including at least one of a light source or a pulse oximeter device, and control circuitry coupled to the integrated acoustic device and the optical sensor. Additionally, a mobile electronic device configured to measure blood pressure is described that includes a mobile system and a mobile blood pressure monitor as disclosed above. In implementations, a process for measuring blood pressure includes sensing a heart sound with an integrated acoustic device, measuring a blood pulse rate at a peripheral site with an optical sensor, calculating a pulse wave transit time using a sensed heart sound and a measured blood pulse rate, and correlating a blood pressure using the heart sound and the blood pulse rate.
This Summary is provided to introduce a selection of concepts in a simplified form that are further described below in the Detailed Description. This Summary is not intended to identify key features or essential features of the claimed subject matter, nor is it intended to be used as an aid in determining the scope of the claimed subject matter.
The detailed description is described with reference to the accompanying figures. The use of the same reference numbers in different instances in the description and the figures may indicate similar or identical items.
Current solutions for measuring blood pressure often include using a traditional sphygmomanometer based measurement that uses a blood pressure cuff. Other solutions include using body contact sensors, such as in the case of an electrocardiogram device. Non-invasive and non-occlusive blood pressure measurement can include sensing two physiological parameters concurrently. However, using invasive or occlusive methods and/or multiple devices is inconvenient and undesirable.
Accordingly, a mobile blood pressure monitor is described that includes an integrated acoustic device, an optical sensor including at least one of a light source or a pulse oximeter device, and control circuitry coupled to the integrated acoustic device and the optical sensor. Additionally, a mobile electronic device configured to measure blood pressure is described that includes a mobile system and a mobile blood pressure monitor as disclosed above. In implementations, a process for measuring blood pressure includes sensing a heart sound with an integrated acoustic device, measuring a blood pulse rate at a peripheral site with an optical sensor, calculating a pulse wave transit time using a sensed heart sound and a measured blood pulse rate, and correlating a blood pressure using the heart sound and the blood pulse rate.
In some implementations, the mobile blood pressure monitor 102 can include an optical sensor 104 including at least one of a light source 112 or a pulse oximeter device 110. A pulse oximeter device 110 can include a medical device that indirectly monitors the oxygen saturation of a patient's blood (as opposed to measuring oxygen saturation directly through a blood sample) and changes in blood volume in the skin, producing a photoplethysmogram. An optical sensor 104 may be incorporated into a health monitor, such as the mobile blood pressure device 100 and/or mobile blood pressure monitor 102. In other implementations, the pulse oximeter device 104 can include any device capable of detecting a photoplethysmogram (PPG) signal.
The optical sensor 104 can include a light source 112 and a pulse oximeter device 110 or other detector (e.g., photodiode). In some implementations, the light source 112 can include at least one small light-emitting diode (LED) and a pulse oximeter device 110 (e.g., photodiode) through a translucent part of the patient's body (e.g., a fingertip, an earlobe, etc.). In other implementations, the light source can include a laser. In one implementation, the optical sensor 104 (e.g., both the light source 112 and the pulse oximeter device 110) is disposed on the back (e.g., the side distal from a display and/or speaker 114) of the mobile blood pressure device 100. In this implementation, the light source 112 and the pulse oximeter device 110 can, but are not required, to face each other. This configuration can allow for user convenience while holding the mobile blood pressure device 100. In these implementations, when a LED is used, one LED can be red, with a wavelength of 660 nm, for example, and another can be infrared (e.g., 905, 910, or 940 nm). The wavelength range can include about 400 nm through about 1000 nm. Absorption at these wavelengths differs significantly between oxyhemoglobin and its deoxygenated form. Therefore, the oxy/deoxyhemoglobin ratio can be calculated from the ratio of the absorption of the red and infrared light. The absorbance of oxyhemoglobin and deoxyhemoglobin is the same (the isosbestic point) for the wavelengths of 590 and 805 nm. The monitored signal fluctuates in time with the heart beat because the arterial blood vessels expand and contract with each heartbeat. Thus, detecting a pulse is essential to the operation of a pulse oximeter and it will not function without a pulse.
The mobile blood pressure device 100 includes control circuitry 118. In implementations, control circuitry 118 can include hardware, software, and/or firmware configured to correlate blood pressure using an optical sensor 104 and an integrated acoustic device 106. In an implementation, control circuitry 118 includes computing circuitry 122 (e.g., a computer processor and memory) with instructions for determining and/or correlating blood pressure from measurements (e.g., collected waveforms) received from the optical sensor 104 and the integrated acoustic device 106. In embodiments, the collected waveforms may be processed with the computer processor using backend software and can be displayed on a suitable frontend software application.
Non-invasive and non-occlusive blood pressure measurement can include sensing two physiological parameters, which can include two timing measurements of an individual's pulse across a known distance. The mobile blood pressure device 100 can include an integrated acoustic device 106 and optical sensor 104 integrated onto a mobile device (e.g., mobile blood pressure device 100) to measure the systolic blood pressure (SBP) using the pulse wave transit time (PWTT). Blood pressure can be empirically measured and accepted to be related to the time of arrival of a pulse between the aortic valve and a peripheral site (e.g., such as a finger). As shown in
As shown in
A blood pulse rate is measured (Block 204). In an implementation, measuring the blood pulse rate includes placing a finger (or other peripheral site) on an optical sensor 104, (e.g., pulse oximeter device) with a light source 112 that transmits light into the finger tissue, and the pulse oximeter device 110 detects the light reflected from the finger to the pulse oximeter device 110.
A pulse wave transit time is calculated (Block 206). In an implementation, calculating a pulse wave transit time can include using synchronization circuitry 120 and/or computing circuitry 122. As illustrated in
A blood pressure is correlated using a blood pulse rate (Block 208). In an implementation, correlating a blood pressure can include using a blood pulse rate, a heart sound, and/or control circuitry 118. The time of arrival of a pulse between the aortic valve and the peripheral site can be correlated with specific peaks in a waveform determined from the blood pulse rate and the heart sound to determine an individual's blood pressure. In a specific embodiment, computing circuitry 122 can use a measured pulse wave transit time to correlate with empirical data from a database, for example. Empirical data may be obtained from sources, such as online databases, memory that is included in control circuitry 118, etc.
Although the subject matter has been described in language specific to structural features and/or process operations, it is to be understood that the subject matter defined in the appended claims is not necessarily limited to the specific features or acts described above. Rather, the specific features and acts described above are disclosed as example forms of implementing the claims.
Number | Date | Country | |
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61875211 | Sep 2013 | US |