DE102015012351A1 - Device for measuring pulse wave velocity on a single small patch over an artery - Google Patents

Abstract

Hypertension is one of the most common diseases. The conventional measurement of blood pressure with a sphygmomanometer is problematic. In the device according to the invention, a highly sensitive sensor detects the pressure fluctuations of a near-surface artery at a measuring field which is 20-150 cm away from the heart. The first pressure fluctuation in the time course of a pulse is the first heart sound with power maxima in the frequency range between 3-300 Hz. Far later the actual pulse wave reaches the pressure transducer as elastic deformation of the vessel wall with typical frequencies of under 3 Hz. From the time delay between heart sound and arrival time of the Pulse wave, the device calculates the pulse wave transit time and pulse wave velocity as well as the blood pressure. The invention allows the production of light, small, barely perceptible, on the body continuously portable measuring devices suitable for trouble-free measurement during sleep.

Description

Hypertension is one of the major risk factors for cardiovascular diseases such as heart attack and stroke. High blood pressure is also one of the most common diseases and affects about one third of the population over 25 years. The measurement of blood pressure is usually made with a so-called sphygmomanometer. It is with a pressure cuff a pressure in the tissue z. B. generated on the upper arm or wrist, which exceeds the arterial blood pressure. This pressure is varied and the restriction of blood flow in the artery is evaluated acoustically or oscillometrically. This form of measurement is problematic for several reasons. The short-term measurement often does not reflect the resting blood pressure, as patients respond to the investigation with an increase in blood pressure (so-called white-coated hypertension). Measurement over a long period of time is difficult and uncomfortable because the pressure cuff is noticeable and annoying. Finally, the measurement itself, which is perceived by the patient as squeezing, generates a possibly unconscious disturbance of the resting state and thus an increase in pressure as an alarm reaction. A measurement during sleep, where the resting pressure can best be determined, without disturbing the night's sleep is not possible. For these reasons, the usual blood pressure measurement has a very poor specificity: in about one third of patients, a high blood pressure is falsely diagnosed with significant consequences, such as. B. Lifelong medication intake including side effects. Also, the sensitivity of the diagnostic described is not good, about 20% of hypertensive patients are not recognized with the usual individual measurements.

For this reason, other less disturbing gauges have recently been developed. The most promising method is to determine the pulse wave transit time or pulse wave velocity. The time of the beginning of the cardiac contraction is determined (for example, from an ECG signal). In addition, the arrival time of the pulse wave is measured at a body site at a known distance from the heart. From this the pulse wave velocity can be calculated. This measurement does not require disturbing compression of tissue. The pulse wave velocity is essentially dependent on the elasticity of the arterial walls and is therefore a function of blood pressure: the higher the pressure, the stronger the tension and stiffness of the arterial wall, and the faster the pulse wave velocity. The blood pressure can be calculated from the pulse wave velocity after reference measurements. However, even without conversion, the pulse wave velocity itself is already a good indicator of cardiovascular risks.

The main disadvantage of the pulse wave velocity measurement is the previous need to detect signals at two different points in the body: the beginning of the pulse wave is best determined electrically or acoustically near the heart, while the delayed arrival of the pulse wave is most accurate as far as possible Heart can be picked up remotely. This dilemma has hitherto prevented the development of light, small, barely noticeable, body-wearable pulse wave velocity gauges, such as a fitness bracelet, headband, or other "wearable".

The WO 2008007361 describes a bracelet in which a grid of pressure transducers is arranged so that the transducers on the radial artery are a few mm to cm different distances from the heart. With the time difference of the pulse wave arrival, the pulse wave velocity is to be determined. This arrangement has two major disadvantages: The small distance difference causes an extremely small time difference and thus large measurement inaccuracy. In addition, the pulse wave velocity is determined only in a short section of the A. radialis, while the clinically relevant cardiac artery tree including aorta is not detected.

DE 10 2008 042 115 describes a device that evaluates the shape of the pressure waveform of the pulse wave and from the typical reflections of the pulse wave z. For example, the pulse wave velocity is determined at the bifurcation of the aorta into the femoral arteries. These devices have the disadvantage of blurring the typical form of reflected pulse waves in the elderly, and therefore the method can not be reliably applied to the age group with the highest cardiovascular risk.

The US 2015/0073239 A1 describes a device that contains a microphone and a computing unit similar to a mobile phone. The device should - taken near the chest - record the heart sounds. The first heart sound is caused by the compression of the blood column in the heart muscle and indicates the beginning of the pulse wave. A pressure sensor in the periphery, z. B. on the wrist, then transmits the arrival time of the peripheral pulse wave to the device. The disadvantage of this invention is the need to record readings at two different points in the body. This invention therefore does not allow the construction of a small, barely noticeable, non-irritating, wearable device.

The invention described here describes a single, small, hardly noticeable, non-irritating, permanently portable device with low weight for detecting the pulse wave velocity and thus solves all the disadvantages listed. The In particular, the invention makes it possible to record measured values only at one point on the body surface and to reliably determine the pulse wave velocity in all age groups. A connection between spaced sensors, z. B. with a cable, is not required. The sensor can be very small and easily realized and integrated, for example, in a bracelet. This ensures a continuous measurement, recording and transmission of the pulse wave velocity which does not disturb the patient, also and especially during sleep.

The device according to the invention described here achieves these tasks in the following manner: These objects are achieved with regard to the measuring device having the features of claim 1 and with regard to the measuring method having the features of claim 9. Advantageous developments of the invention are specified in the subclaims. All combinations of at least two features disclosed in the description, the claims and / or the figures fall within the scope of the invention. In order to avoid repetition, features disclosed in accordance with the device should also be regarded as disclosed according to the method and be able to be claimed. Likewise, according to the method disclosed features should be considered as device disclosed and claimed claimable.

The heart sounds are usually heard with a stethoscope or microphone on the chest, so in the immediate vicinity of the heart. Surprisingly, it is possible with a sensitive sensor to record and measure heart sounds also at a great distance from the heart over a peripheral artery. In the device according to the invention, a highly sensitive sensor detects the pressure fluctuations of a near-surface artery at a measuring field which is 20-150 cm away from the heart. The first pressure fluctuation in the time course of a pulse is the first heart sound with power maxima in the frequency range between 10-300 Hz. The first heart sound results from the compression of the blood column in the cardiac muscle at the beginning of the contraction together with the closure of the mitral and tricuspid valve. This acoustic wave is propagated in the arterial blood column at a speed of approximately over 1400 m / s, similar to a longitudinal sound wave in water. With a known distance of the sensor from the heart so that the time of the beginning of the pulse wave can be calculated. Much later, the actual pulse wave reaches the sensor as an elastic deformation of the vessel wall, as it is propagated at typical frequencies of less than 3 Hz at a much lower speed of typically 10-15 m / s. This type of conduction is an interaction between elastic vessel wall and pressure around the interior of the blood vessel and is comparable to a wave on a water surface. From the time delay between the start time of the pulse and the arrival time of the pulse wave, the device calculates the pulse wave transit time and pulse wave velocity. Using calibration data, the device also calculates systolic and diastolic blood pressure. The measurement can be done continuously for each pulse. The data obtained may be stored, displayed on a display, associated with visual and / or audible alarms, and transmitted wirelessly or by cable to another computing device.

The arrival time of the first heart sound may alternatively or additionally also be detected or verified optically, as with an optical microphone, similar to the pulse wave, similar to a pulse oximeter, by measuring the hemoglobin concentration in the skin. The identification of the first heart sound may be performed by analysis of the frequency range, and / or the time in the time frame of several consecutive pulses, and / or by a plausibility analysis of the calculated pulse wave velocity.

Brief description of the drawings

Further advantages, features and details of the invention will become apparent from the drawings. These show in:

1 : a schematic representation of a measuring device,

2 : a schematic diagram explaining the measuring principle of the pulse wave velocity.

Embodiments of the invention

In the figures, like elements and elements having the same function are denoted by the same reference numerals.

1 shows a measuring device 1 for measuring the velocity of human pulse waves. The measuring device 1 includes funds 2 for fastening the measuring device 1 on the human body. By way of example, a section through the forearm near the wrist is shown. Furthermore, the measuring device comprises one or more sensors 3 and one or more agents 5 for the acoustic and / or mechanical and / or optical coupling of the sensors to the peripheral artery 6 , The means 2 and 5 can put a slight pressure on the skin surface 4 To exert compression of elastic tissue and thereby achieve a better coupling to the arterial wall and its deflection.

2 explains the measuring principle. The contraction of the heart muscle over the blood filling, together with the closure of the mitral and Tricuspid valve the first heart sound. This is propagated at high speed through the blood column as a longitudinal acoustic wave and reaches the sensors as a first wave 7 , Furthermore, the pressure increase in the heart generates a pulse wave 8th which is propagated substantially as a surface wave of the elastic vessel wall at a lower speed and therefore the sensors to wave 7 achieved delayed. The time delay 9 is determined with knowledge of the distance covered by the waves for calculating the pulse wave velocity and the blood pressure. The heart sound is typically detected in a frequency band of 10-300 Hz 10 , The pulse wave 8th In contrast, has typical performance maxima 11 below 3 Hz.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• WO 2008007361 [0004]
• DE 102008042115 [0005]
• US 2015/0073239 A1 [0006]

Claims (10)

Single small, easily wearable device for measuring pulse wave velocity by measuring on a single measurement field on a near-surface human or animal artery, consisting of a. One or more sensors for detecting movement or acceleration in different frequency ranges for detecting the heart sounds, in particular the first heart sound b. One or more sensors for detecting movement or acceleration in different frequency ranges for detecting the pulse wave c. Device for coupling the transducer to the skin surface d. Single, small, light, barely noticeable, non-irritating, wearable attachment e. Electronic device for data processing and calculation f. Device for analyzing frequency bands typically from 0.01 Hz to 3 Hz and from 3 Hz to 300 Hz G. Device for detecting the time of the first heart sound H. Device for detecting the time of arrival of the pulse wave i. Apparatus for calculating the pulse wave transit time j. Apparatus for calculating systolic and diastolic blood pressure k. data storage l. display m. Optical indicators n. Acoustic indicators o. Device for wireless data transmission p. Device for wired data transmission q. energy r. charging The device in 1, wherein the attachment d) is a bracelet, headband, collar, body jewelry, underwear, or a similar element Device in 1, wherein c) is a liquid- or gel- or gas-filled, deformable and or optically transparent and or reflective cushion Device in 1, wherein a) are realized as one or more pressure transducers, microphones, in particular structure-borne sound microphones Device in 1, wherein a) as one or more optical pickup, such as phototransistors or fields of phototransistors or CMOS image sensors are realized and contain one or more lighting units such as LEDs Device in 1, wherein a) are implemented as one or more accelerometers and / or motion sensors Device in 1, wherein a) as one or more electrical impedance sensors, in particular with electrode pairs are realized Device in 1, where e) includes an apparatus for detecting and identifying an individual, by analyzing the patterns of collected data, and ensuring data security, such as access rights to the collected data. A method for the diagnosis of cardiovascular diseases and risks, in particular for determining the pulse wave transit time and / or pulse wave velocity and the systolic and diastolic blood pressure, wherein the measurement is made on a single measurement field on a human or animal surface near the artery, and wherein the time of the first heart sound and the arrival time of the pulse wave are detected, and from these times the aforesaid quantities are calculated. Method in 9, wherein the distinction between heart sound and pulse wave by analysis of the frequency range, and / or the time in the time frame of several successive pulses, and / or by a plausibility analysis of the calculated pulse wave velocity is made.

Images