DE4439253A1 - Human pulse waveform measurement device with pressure cuff - Google Patents

Abstract

The appts. for measuring human pulse waveforms consists of a pressure cuff (1) fitted to an appropriate body part, and filled with a medium to detect pressure variations due to a pulse signal, and a pressure measurement sensor (2) to convert the pressure variations to an electrical signal. The pressure in the cuff (1) is supplied by a device (8) connected by a valve (20) and piping. The sensor is a piezoelectric device mounted on a membrane, or a strain gauge, capacitive sensor, optoelectronic, inductive or other suitable style.

Description

The present invention relates to a device for measuring the signal curve of the human pulse.

The human pulse arises from a pressure wave in the blood caused by the Heart muscle is created when it pumps blood through your veins. In general In language use, only the frequency of this pressure wave is often referred to as a pulse. In the places of the human body where the arteries are just under the skin run, such as B. on the wrists or on the neck, the pulse rate and blood pressure can also be measured easily. Known devices work on it the basis of acoustic sensors. However, it is not with these devices possible to the signal curve, i.e. amplitude and phase of the human pulse measure up.

European patent application EP 0 032 159-A1 discloses an electronic one Diagnostic device for pressure-dependent pulse measurement and recording using piezoelectric pulse probes. These pulse probes work as pressure sensors and enable the measurement and recording of the pulse shapes, i.e. H. the pulse waveform. The pulse probes have the shape of flat, round plates and are placed on the spots of the human body on which the pulse shape is to be measured, ie e.g. B. on the radial artery on the wrists. The fixation of the pulse probes during the measuring process takes place by means of an inflatable pressure cuff with which the pulse probes are pressed onto the measuring point.

The disadvantage of this known device is that the point on the body where the pulse to be measured must first be carefully felt. The pulse probe must then can be placed exactly at this point and is allowed when putting on and inflating the The pressure cuff does not change its position. Furthermore, during the Measurement process be very carefully made sure that the patient at least that Do not move the part of the body that is being measured, otherwise the pulse probe will slip  can and the measurement must be repeated. The measurement is therefore very susceptible to interference and can only be carried out by experienced specialists.

Accordingly, the object of the present invention is to provide a device for Measuring the waveform of the human pulse to create the inexpensive to manufacture simply constructed, easy to use and insensitive to external influences.

This object is achieved by a device according to the preamble of claim 1 solved the present invention, which is characterized by a pressure cuff to put on a corresponding part of the body filled with a medium is, the pressure changes generated by the pulse signal, and one with the Pressure cuff connected pressure measuring device, which from the pulse in the Pressure cuff generated and by means of the medium in the pressure measuring device passed pressure changes converted into electrical signals.

The advantage of this device is that a through the pressure cuff large area of attack is available for the pulse to be measured, but not with it must be searched for a long time and cumbersome. The large pressure area of the Pressure cuff enables the application and operation of the invention Device itself by a layperson not medically trained.

The device according to the invention can either be in the pressure cuff be integrated what z. B. is advantageous in outpatient use, or by a hose connected to it. The second possibility has the advantage that the Pressure chamber with the piezoelectric membrane from the measuring point to the Hose length is removed and the pressure chamber together with the electronics for Processing the measurement signals can be arranged in a housing or the like can. This part of the measuring device can thus be safe and protected from external influences protected while the pulse shape of a Patient is measured.

The pressure sleeve overlaps the point of the wire at which the pressure is measured should be, e.g. B. on the wrist and there z. B. by means of a Velcro fastener attached. It is particularly advantageous for the quality of the measurements if the pressure of the medium in the pressure cuff, the hose and the Pressure measuring device is greater than the external or ambient pressure. The medium can e.g. B. be gaseous or liquid.  

The pressure cuff, the hose and the pressure measuring device thus form either a tight, closed system, the internal pressure z. B. by suitably solid Applying the pressure cuff to the body part to be measured can be increased. The another possibility is a device for generating pressure, such as a handball or to connect an electric pump to the device according to the invention. The has the advantage that the pressure of the medium can be adjusted and regulated as desired. These Device for generating pressure is either with the pressure measuring device, the Pressure cuff, or preferably with the hose between the two connected. A device such as. B. a valve to regulate of the pressure.

The exact location of the vein at which the pulse can best be measured does not have to be be searched for a long time because the pressure cuff with a large inner surface on appropriate part of the body. The pressurized medium in the The cuff picks up the pressure changes generated by the pulse and passes them on the hose into the pressure measuring device. This preferably comprises one Pressure chamber in which a pressure sensor is arranged. Here, for. B. a wall of Pressure chamber have a membrane that carries the pressure sensor and the Changes in pressure into electrical signals.

The use of a piezoelectric pressure sensor has been particularly advantageous proved, because such sensors because of the almost pathless measurement, that associated short response time and their high natural frequency very good for one dynamic use. Add to that the simple, robust construction and the high pressure resistance of piezoelectric sensors. Another advantage is that this Sensors are active elements because they have no bias or the like supply pressure proportional electrical signal. This offers the Possibility of a stationary preload, such as. B. the increased internal pressure of the Cuff system, short-circuit charges generated, so that the full Resolving power of the piezoelectric sensor also for the measurement very small Fluctuations is available.

The use of a piezoelectric has proven to be particularly effective and cheap Ceramic layer proven. Such layers find z. B. as speaker membranes Versatile application of all sizes, but can also be used according to the invention  are and are very cheap as mass articles with sufficient sensitivity producible.

Another promising option is to use a Strain gauge as a pressure sensor for the present invention. Here are u. a. because of their inexpensive mass production semiconductor strain gauges, however metal foil, thin film or thick film strain gauges are also suitable.

Other suitable pressure sensors are inductive, capacitive or optoelectric Pressure sensors.

Disturbances can occur during the measurement of a patient's pulse signal curve occur when the patient has the part of the body where the pressure cuff is located emotional. The pressure changes resulting from the movement are forwarded together with the pulse signals to the pressure measuring device and in electrical signals implemented. To compensate for such a movement caused pressure changes, a second pressure measuring device can be provided his. You can e.g. B. consist of a pressure sensor that is simply on or near the point at which the pulse is measured is put on. The second Pressure measuring device can also, for. B. over a hose with the Pressure cuff connected. The pressure cuff is two in this case Connected pressure measuring devices, both of which measure the pressure changes caused by the pulse and caused by the movement. By means of suitable Filter devices become the signals from the second pressure measuring device Pulse signals filtered out, so that only the movement signals remain. These Signals are then used to compensate for the movement signals of the first Pressure measuring device used.

The second pressure measuring device has the same structure as the first Pressure measuring device, optionally one of those described above Pressure sensors are used, but preferably a semiconductor Strain gauges.

The pressure cuff can e.g. B. in the event that the patient is seriously injured and if possible, his condition should not be disturbed or impaired by a Mattress, a pillow or the like. On which the patient is placed. These Mattress is also corresponding with a gaseous or liquid medium  filled, which are triggered by the pulse signal or the heartbeat of the patient Record changes in pressure and forwards to the pressure measuring device or devices.

The high advantages of the device according to the invention are to be emphasized Efficiency, the high sensitivity, and the great speed, which can be detected dynamic sizes is important.

Also noteworthy are the very low manufacturing costs, especially since the pressure chamber or the pressure chambers of the pressure sensor or sensors directly on the PCB of an integrated circuit can be built.

The present invention will hereinafter be described with reference to a preferred one Exemplary embodiment described with reference to the accompanying drawings, where show:

Fig. 1 is a schematic representation of the structure of a device according to the invention for measuring the signal curve of the human pulse, and

Fig. 2 shows the structure of a pressure measuring device according to the invention.

Fig. 1 shows a pressure cuff 1 , which is connected by a hose 15 to the pressure measuring device 2 . The pressure cuff 1 is a conventional pressure cuff, such as z. B. is used in blood pressure measurements or the like. The pressure cuff 1 , the hose 15 and the pressure measuring device 2 are filled with a medium which, for. B. can be gaseous or liquid. The pressure measuring device 2 comprises a pressure chamber with a pressure sensor which converts the pressure changes caused by the pulse into electrical signals.

A second pressure measuring device 16 is connected to the pressure cuff 1 by a hose 17 and, using suitable filter devices (not shown), serves to compensate for signals caused by movements of the corresponding part of the body. For this purpose, the measurement signals of the first pressure measuring device 2 are freed of movement artifacts by the compensation signals of the second pressure measuring device 16 in an operational amplifier 18 , converted in an A / D converter 19 and passed on to further evaluation, storage and display units 22 .

An electric pump or a handball serves as a device for generating pressure 8 and is connected to the pressure cuff 1 via a hose with an adjustable valve 20 . This valve 20 , the device 8 for generating pressure, the operational amplifier 18 and the A / D converter 20 are regulated by a central control unit 21 .

FIG. 2 shows a preferred exemplary embodiment of the first and second pressure measuring devices 2 and 16 with a pressure chamber 3 . One wall of the pressure chamber 3 has a membrane 4 with a pressure sensor 10 , which can be formed by a piezoelectric layer or by a strain gauge. The membrane 4 is supported between two rubber rings 5 in the example shown. The two rubber rings 5 are clamped between two plates 6 , 7 , the z. B. are attached to each other by screws, soldered wires or the like under mutual pressure. The outer edge of the membrane 4 is held between the rubber rings, while the inner part of the membrane 4 , on which the piezoelectric layer is applied, can vibrate easily.

The plate 6 located on the side of the pressure chamber 3 has an opening 12 through which the pressure chamber 3 is connected to the pressure sleeve 1 via the hose 15 . In the exemplary embodiment shown, the plate 6 also has a second opening 13 , which is connected via a hose to a device 8 for generating pressure. This device 8 consists in the embodiment shown from a handball z. B. made of rubber, with which the pressure of the medium in the pressure chamber 3 and the pressure cuff 1 can be increased before the measurement process. The other plate 7 has an opening 14 through which a pressure equalization to the external pressure takes place so that the membrane 4 can oscillate freely.

The membrane 4 is preferably made up of several layers in the case of the use of a piezoelectric ceramic. The first layer 9 is a carrier layer, by means of which the membrane 4 is held between the rubber rings 5 . The second layer 10 is the piezoelectric layer, which is preferably made of ceramic. The voltage changes on the piezoelectric layer 10 generated by the pressure changes of the pulse are removed via a metallic coating 11 , fed to the measuring electronics and evaluated there.

Claims (19)

1. Device for measuring the signal curve of the human pulse,
marked by
a pressure cuff ( 1 ) for application to a corresponding point on the body, which is filled with a medium which absorbs pressure changes generated by the pulse signal,
and
means connected to said pressure cuff (19) The pressure measurement device (2), generated by the pulse in the pressure cuff (1) and converts (2) forwarded pressure changes into electrical signals by means of the medium in the pressure measurement device. 2. Device according to claim 1, characterized in that the pressure measuring device ( 2 ) with the pressure cuff ( 1 ) is connected by a hose ( 15 ) through which the pressure changes generated by the pulse in the pressure cuff ( 1 ) by means of the medium to the pressure measuring device ( 2 ) be directed. 3. Device according to claim 1 or 2, characterized in that a device ( 8 ) for generating pressure with the pressure measuring device ( 2 ), the hose ( 15 ) or the pressure cuff ( 1 ) is connected, through which the pressure of the medium can be changed . 4. Device according to one of claims 1 to 3, characterized in that the pressure measuring device ( 2 ) has a pressure chamber ( 3 ) which contains a pressure sensor ( 4 ). 5. The device according to claim 4, characterized in that the pressure sensor ( 4 ) has a piezoelectric element ( 10 ). 6. The device according to claim 5, characterized in that the piezoelectric element ( 10 ) consists of a piezoelectric ceramic. 7. The device according to claim 4, characterized in that the pressure sensor ( 4 ) has a strain gauge. 8. The device according to claim 7, characterized, that the strain gauge is made of a semiconductor material. 9. The device according to claim 4, characterized in that the pressure sensor ( 4 ) is a capacitive pressure sensor. 10. The device according to claim 4, characterized in that the pressure sensor ( 4 ) is an inductive pressure sensor. 11. The device according to claim 4, characterized in that the pressure sensor ( 4 ) is an optoelectric pressure sensor. 12. Device according to one of the preceding claims, characterized in that a second pressure measuring device ( 16 ) for compensating for the pressure changes caused by a movement of the corresponding body part in the pressure cuff ( 1 ) is provided. 13. The apparatus according to claim 12, characterized in that the second pressure measuring device ( 16 ) comprises a pressure sensor ( 4 ) which can be applied to or in the vicinity of the body site at which the pressure cuff ( 1 ) rests. 14. The apparatus according to claim 12, characterized in that the second pressure measuring device ( 16 ) with the pressure cuff ( 1 ) is connected by a hose ( 17 ) through which the pressure changes generated in the pressure cuff ( 1 ) by means of the medium to the second pressure measuring device ( 16 ). 15. The apparatus according to claim 12 or 14, characterized in that the second pressure measuring device ( 16 ) has a pressure chamber ( 3 ) which contains a pressure sensor ( 4 ). 16. The apparatus according to claim 13 or 15, characterized, that the pressure sensor has a piezoelectric element. 17. The apparatus according to claim 13 or 15, characterized in that the pressure sensor ( 4 ) has a strain gauge. 18. The apparatus according to claim 17, characterized, that the strain gauge is made of a semiconductor material. 19. Device according to one of the preceding claims, characterized in that the pressure cuff ( 1 ) can be formed by a cushion which receives pressure changes generated by the pulse signal or heartbeat of a patient resting on it.