HU221390B1 - Apparatus for monitoring and signalling cardiac pulse rate - Google Patents

Abstract

The device has a signal-forming amplifier unit, and its essence is that it has a signal provider design with a polarity and width corresponding to the polarity and width of the main wave or waves of the action potential change detected at the output of the signal-forming amplifier unit (10), and it also has a signal-forming circuit (20), which the signal-forming amplifier unit (10) first is connected to its output, it also has a clock signal generator (32) with a control input, LED displays (41, 43, 44, 45, 50) connected to specific outputs from the parallel outputs of the first counter (30) which counts output signals and has parallel outputs, the signal shaping circuit (20) its output is connected to the other terminal of the LED displays (41, 43, 44, 45, 50) directly or through the interposition of a drive circuit (36), and on the other hand, through the interposition of a start circuit (34) to the enable input of the first counter (30) and the synchronizing input of the clock signal generator (32). ŕ

Description

BACKGROUND OF THE INVENTION The present invention relates to a device for monitoring and signaling heart rhythm, which can be used both as a device for general and medical use, mainly as a diagnostic aid or, in some cases, as a medical instrument. The device according to the invention has a signal amplifier unit with inputs that can be connected to a sensor electrode and a display.

Heart contraction is known to be triggered by action currents. In healthy people, the action potential changes that trigger action currents occur almost periodically in succession. The frequency with which action potential changes occur depends on the cardiac load condition, the average heart rate is moderate, at rest, in stress, physiological load, etc., and the heart rate becomes steadily faster or slower according to blood supply requirements. If the periodicity changes, or one period is significantly different from the expected one, for example, it increases or decreases by 0.25 s, then there is a characteristic symptom of cardiac dysfunction, arrhythmia, which, unless specifically observed, he does not notice me.

Therefore, monitoring the periodicity of cardiac function may be used to predict abnormal heart rhythm and thus provide a method of preventing a disease. Consequently, it may be desirable, for the sake of maintaining health, to monitor the periodicity of heart rate and the frequency of heart rate changes in some individuals, and the extent of the change in period length in the case of altered heart rate.

A known device for monitoring and signaling heart function is the so-called ECG device. The ECG plots the temporal changes in action potentials that trigger cardiac function, reports heart rate, current myocardial status, blood supply, etc. A further feature of the device is that, for a more accurate measurement of heart rate, it measures a specific number of periods of at least four, depending on the manufacturer, and displays the average of the four measurements obtained as a value over a period of time. while keeping the former average. This has the disadvantage that the change in the length of a period does not significantly affect the displayed average value, so that arrhythmic function and its extent may not always be directly determined from the displayed heart rate numerical value. The structure of the device is complicated, its effective use requires specialized knowledge, due to the accurate and large amount of information it provides, it is only used in specialist and hospital care and its price is very high.

Also known is the so-called Holter device, which senses and measures action potentials with three or four electrodes placed in the right place. The device compares the measured values with the values of the ideal ECG signal stored in its memory and, if it finds a difference greater than a certain amount, stores the different readings, virtually arrhythmic cardiac period values, with the time of the measurement. The stored values can be read by a so-called reading device at an evaluation time. The device is not capable of displaying short heartbeat at the same time, even with most features built in, it only shows the difference at the same time, meaning more information than the alarm, such as what was the difference, what to do, etc. does not give.

The disadvantages of the described devices are that they are either very costly and need to be used professionally or are not suitable for signs of subsequent complaints such as pain, shortness of breath, heart attack, etc., intermittent changes in the length of one period or a specific wave, mainly to detect malfunctions (subjective complaints), mainly due to R and / or S wave distortions, due to their rarity and brevity, and to prevent and avoid later expected complaints.

The need for monitoring and displaying the heart rate, and the shortcomings of known devices for this purpose, have made it necessary to develop a device capable of monitoring and displaying the heart rate, most of which occur at rarer intervals above the normal limit and but at the same time simple to use, inexpensive to use, the device requires essentially no expertise and can thus be widely used as both a general and medical device, mainly as a diagnostic aid or in some cases as a medical instrument. It is also desirable for the device to be capable of providing data not only to the person concerned, but also to a person within a few meters of the supervisor. There was also a need for the device to be capable of controlling the operating frequency range of a healthy heart.

The present invention is based on the discovery that the object is met by a device which measures the length of time between the onset of the main electrical pulses generated by the heart, preferably the R waves, and indicates the measured value while also indicating that the period of time was normal or not, thus giving the person less familiar with such knowledge without the need for a separate evaluation of the information displayed, and at the same time providing the device with both a diagnosis and provides sufficient information for healing or rehabilitation.

SUMMARY OF THE INVENTION The object of the present invention is to provide a signal amplifier unit with a sensor electrode connected to a sensor electrode, a signal forming circuit connected to a first output thereof, and a display device for monitoring and signaling heart rate. The essence of the device is that the main wave of the action potential change detected at the output of the signal amplifier unit (R)

EN 221 390 has a design for providing a signal of polarity and width corresponding to polarity and width of R or S, and a clock generator having a synchronizing input, a first counter having a plurality of parallel outputs and a first counter having parallel outputs It has LED displays, the output of the signaling circuit being connected directly to the other terminal of the LED displays, either directly or via a drive circuit, to the enable input of the first counter and to the synchronization input of the clock generator.

In a preferred embodiment of the apparatus, a first oscillator is connected to the output of the signal-forming circuit to which a speaker is connected, directly or indirectly. In a preferred embodiment of this embodiment, the first oscillator is coupled to a signal output circuit output via a first switch.

A preferred embodiment is that the first counter has an overflow output and an overflow display connected thereto.

The general purpose embodiment of the device according to the invention has an OR function circuit, an AND function circuit connected to its output and a second counter connected to its output, wherein each input of the OR function circuit is connected to each output of the first counter, preferably to its outputs. , and the second input of the AND function circuit is connected to the output of the signal generating circuit. In another embodiment of this embodiment, which detects distortion of the other polarity wave (S), the signal amplifier unit has a second output, which second output is coupled to the input of the second counter.

Preferably, an embodiment is provided wherein a second oscillator is connected to the output of the second counter, preferably a second oscillator tuned to a frequency other than the frequency of the first oscillator, and the output of the second oscillator is connected to the speaker input and the output of the second counter. More effective acoustic signaling is achieved by an embodiment wherein the output of the first oscillator and the output of the second oscillator are connected to one of the inputs of the summing circuit and the output of the summing circuit is connected to the input of the speaker.

Another preferred embodiment has a timer generator, the output of the timer generator being connected to the wiper input of the second counter. In this embodiment, the timer generator has on / off switch timer members, preferably timer capacitors.

It is desirable to have a design wherein the overflow output of the first counter is coupled to the second input of the second oscillator. An embodiment of this embodiment for producing a highly alert tone is wherein the output of the timer generator is coupled to a control of the second counter wiper input, the control input of the first counter being connected to the overflow output of the first counter.

An embodiment having a manual switch, preferably a push button, coupled between the reset input of the second counter and / or the timer generator and a terminal having a corresponding potential is preferred.

The signaling amplifier unit of the device according to the invention has an input differential amplifier connected to the inputs of the sensor inputs, a leveling amplifier coupled to its output via an amplifier and a disconnecting capacitor, a leveling amplifier output via a filter, preferably an active filter, where the outputs of the dual signal forming circuit form the outputs of the signal forming amplifier unit.

The essence of the device according to the invention will now be described in more detail with reference to a preferred embodiment, with reference to the accompanying schematic drawing, wherein

Figure 1 is a schematic block diagram of the construction of a wide range of service features of the device,

Fig. 2 shows an exemplary preferred block diagram of the device signaling amplifier unit,

3. a. Fig. 4A is a graph showing the shape of a signal in a cardiac arrhythmia;

3. b. Figure 3.a. FIG. 2B, when detecting a signal of the shape shown in FIG

4. a. FIG. 4A is a graph showing the shape of a signal in a first type of abnormal heart; FIG.

4. b. Figure 4.a. FIG. 4A is a representation of the shape of the signal appearing on the first outputs of the signal generating unit, FIG

5. a. Fig. 4A is a graph showing the shape of a signal perceptible to a second type of abnormal heart function;

5b Figure 5a. 5a, the signal shape shown on the first outputs of the signaling amplifier unit and FIG

5c Figure 5a. 5A, the signal output at the second output of the signal generating unit is detected.

As shown in Figure 1, the device has a sensor amplifier unit 10 with detector electrodes 10, with inputs 1, 2 and 3 for attachment to sensor body electrodes, in particular silver-silver chloride electrode pins. The first output of the signal generating amplifier 10, an exemplary embodiment of which is illustrated in FIG. 2, is coupled to a signal forming circuit 20 implemented by a Schmitt trigger. The first branch of the output of the signal forming circuit 20 is coupled to the input of a starter circuit 34, in this example a differentiating circuit connected to the synchronization input of the clock generator 32 and the enable counter 30 of the first counter.

HU 221 390 Bl

The output of the clock generator 32 is connected to the input of the counter 30. An exemplary form of the clock generator 32 outputs a clock every 200 ms, which is counted by the counter 30. The counter 30 is configured such that at its parallel outputs from one to ten according to the number of pulses counted, the corresponding serial number output is activated. On the specific parallel outputs of the counter 30, in this embodiment, each of the ten LEDs 41 ... 43, 44, 45 ... 50 is connected, of which a preferred output, in this example, is the fourth output, which is connected 44 The LED is green, while the other outputs, which are unsignificant outputs, are connected with a red LED. The other terminal of the LEDs 41 to .50 is coupled to the output of a drive circuit 36 connected to a first branch of the output of the signal forming circuit 20.

Counter 30 has an overflow output to which overflow indicator 38 is connected.

A second oscillator 24 is connected to a second branch of the output of the signal forming circuit 20 via a manually operated first switch 22, the output of which oscillator 24 is connected to a speaker input 28 via a summing circuit 26.

Of the parallel outputs of the counter 30, the non-preferred outputs are branched to one of the inputs of a 52 OR function circuit, in this example an OR gate circuit, which is connected to one of the inputs of an AND function circuit 54, in this example. A third branch of the output of the signal forming circuit 20 is connected to the other input of the AND function circuit 54.

The output of the AND function circuit 54 is connected to a second input 60 of a counter 60 which is connected to its self-counting input itself and to the first input of a second oscillator 70. The output of the oscillator 70 is connected to the other input of the summing circuit 26.

The apparatus further comprises a timer generator 66, the output of which generator 66 is connected via a controlled switch 56 to the counter wiper input 60. The control input of switch 56 is connected to the output of counter overflow 30.

The timer generator 66 has a variable timer design, a timer-defining first timer capacitor 64 and a second timer capacitor 65, one of which can be set by inserting a timer generator 66 into the circuit of the timer generator.

The output of counter overflow 30 is also connected to the second input of oscillator 70.

The apparatus further comprises a push-button switch 58, which in the present embodiment is coupled between the timer generator 66 and the reset input of the second counter 60 and a terminal of suitable potential.

2 is a block diagram of an exemplary embodiment of the signaling amplifier unit 10. As shown, the signal amplifier unit 10 has an input differential amplifier 11 connected to the inputs 1,2, 3 of the sensor and a level amplifier 14 coupled to its output via an amplifier 12 and a disconnecting capacitor 13. A dual signal forming circuit 18 is connected to the output of the leveling amplifier 14 via a narrowband active filter 15, preferably an active hole filter, a sintering amplifier 16 and a capacitor 17. The dual signal forming circuit 18 has two high gain amplifiers, one for amplifying one of the polarity signal components and one for the other polarity signal components, and having separate positive output and separate negative output outputs, which are also outputs of the signal amplifier unit 10. form.

In the operation of this embodiment, the sensor detects a change in the electrical signal generated by the heart at the inputs 1, 2, and 3 at a level of 1-2 mV according to the P-Q-R-S-T curve. The signal received together with the superimposed interference signals is amplified by differential amplifier 11 and amplifier 12, and the isolating capacitor 13 filters out the smooth component. By adjusting the leveling amplifier 14, the signal can be set to zero. The active filter 15 isolates the interference signals from the signal varying according to the P-Q-R-S-T curve and amplifies the resulting signal to a 2-3 V amplitude level. The filtered signal thus amplified to the appropriate level is further amplified by the signal-forming circuit 18 by overcontrolled gain. The first output of the signal generating circuit 18, which is also the first output of the signal amplifier unit 10, displays a trapezoidal signal of a width corresponding to the wavelength R, and the second output, which is also the second output of the signal amplifier unit 10, For the PQRST curve. If there is an abnormality in the heart function that results in an increase in the S wave, a second trapezoidal signal with a trapezoidal width corresponding to the width of the S wave will also appear on the second output.

From the signal output at the first output of the signal generating amplifier unit 10, the comparator and hysteresis signal forming circuit 20, in this embodiment, generates a signal proportional to the width of the wave R from the Schmitt trigger circuit, from which the output circuit 34, in this embodiment, differentiates. The signal on the one hand allows the counter 30 to reset and start counting live, and on the other hand starts the clock generator 32 synchronously. The output signals of the clock generator 32 are counted by the counter 30 until the signal from the next R wave is reset and re-counted. At normal heart rate, the next R wave will arrive after about 800 ms, during which the clock generator 32 will output four clock signals, so the counter 30 will count to four, respectively, its fourth parallel output, causing the green LED 44 to be connected to this preferred output. the diode receives the forward bias and due to the bias provided by the power amplifier 36, this green LED 44 flashes to indicate that the last measured heart rate period is within the set range. If the heart rate is not normal, the counter 30 may or may not have been counting, depending on whether the heart rate was faster or slower, so that the non-dedicated output of the counter 30 is activated and the red color connected to it, for example 43 or 45, is activated. LED

221 flashes to indicate that the heart rate is abnormal.

The device can be set to acoustically display any electrical signal that causes heart contraction, practically a heartbeat. Then, by closing the first switch 22, the signal at the output of the signal forming circuit 20, which is adapted to the width of the wave R, actuates the first oscillator 24, thereby providing the speaker 28 with a specified first frequency audio signal.

If, after a wave R, the device does not detect another wave R for a long period of time determined by the capacity of the counter 30 and the frequency of the clock generator 32, the counter 30 will overflow. The device indicates the absence of the R wave by actuating the overflow detector 38 by an additional LED diode and by switching on the second oscillator 70 connected to the output of the counter overflow 30 and set to the second frequency via the oscillator 70 at the second frequency. operation, thereby emitting another type of continuous beep.

If the device generates a wave interruption signal R, which is a continuous signal, while the wave 22 is re-detected and the switch 22 is turned on, the speaker 28 will be the first and second frequency oscillators by the summing circuit 26 for the duration of the wave R Outputs a third frequency display from its output signal, indicating that the heart will continue to function after the outage.

The frequency of the cardiac dysfunction is counted by the second counter 60 of the device. The OR function circuit 52, connected to one of the inputs of counter 30, collects a signal from one of the non-specific outputs of the counter 30 that is activated during the abnormal length period, and signals of this period disorder are output to the output signal circuit 54 of the signal generator. which counts as an abnormal event.

A signal appears at the second output of the signal generator 10 when the wave S is distorted, so-called ST. This output signal as an indication of the occurrence of an abnormal event is written directly into the counter 60.

The output of counter 60 for occurring abnormal events is coupled to the first input of oscillator 70, so that after the number of abnormalities has reached the value determined by or through the counter 60, the device emits a continuous tone and actuates the counter 60 and its contents. deletion is disabled by loopback of its output.

To monitor the incidence of malfunctions, it is possible to set a monitoring or test period for the device. The timing time of the timer generator 66 can be set by the timer generator 66 selected and inserted by the timer capacitor 64 or capacitor 65. At the end of the timing time, the erase signal output by the generator 66 via the controlled switch 56, unless the erase is disabled by the feedback, erases the contents of the counter 60. The apparatus further comprises a push-button switch 58 coupled to an appropriate potential to reset the counter 60 to eliminate the oscillator signal 70 and to restart the generator 66. The control input of the switch 56 is connected to the output of the counter overflow 30, which, in the case of cardiac action during the test period and not restarted within the test period, allows the number of abnormal events to occur to be determined.

3.a. Fig. 4A shows the time course of the normal shaped signals. As shown, the tracking period of the signals varies, in the case of the figure, the first period is normal, the second period is longer than normal, and the third period is shorter than normal.

3.b. FIG. 3A shows the output signals of the signal forming circuit 20 in FIG. Figs. For such periodic signals, at the end of the first period, the device will first flash a green LED 44, a red LED 45 for the next detected signal, and a red LED 43 for the next detected signal.

4.a. Fig. 4A shows a waveform indicating an abnormal operation, the so-called ST wave raised. 4.b. FIG. 4A shows the output signals of the signal forming circuit 20 in FIG. Figs. Due to the widening of the R-wave, the light and acoustic signal given by the device are not consistent with each other, and the LEDs, due to their pre-tension for the duration of the R-wave, show abnormally faster heart rate, even though heart rate has not changed.

5.a. Fig. 4A shows another waveform indicating a malfunction, the so-called ST wave subsided. 5.b. 5a shows the output signals of the signal forming circuit 20 in FIG. FIG. As shown in the figure, due to the relatively normal shape of the R wave, the LED displays indicate normal period operation. 5.c. FIG. 6A shows a waveform at the second output of the signal generating and amplifying unit 10, which is a broad pulse, unlike zero at normal operation. The device detects a waveform indicative of this disorder at the counter 60.

One of the main advantages of the device according to the invention is that it is capable of providing meaningful information to both the person using the device and / or the person observing the user.

A further advantage is that the sensor electrodes of the device can be placed anywhere on the body surface, such as the limb, chest, and the device provides a valuable result with each placement.

Another great advantage of the device is that it measures and displays the time of each heartbeat period, so that it always displays the current status of the heart and provides it with light, sound or alarm as needed. As a result, we are ready

The appendix is particularly well-suited for monitoring the current working capacity of the heart at any time in both healthy and ill or cured users, and thus provides a greater opportunity to prevent it and to monitor the effectiveness or improvement of post-treatment.

Claims (14)

PATENT CLAIMS A device for monitoring and signaling a heart rate, comprising a signaling amplifier unit having a sensor electrode-connected inputs, a signaling circuit connected to a first output thereof, and a display, characterized in that the main wave of the action potential change detected at the output of the signaling amplifier unit a wave generator (32), a first counter (30) having parallel outputs and a first counter (30) having parallel outputs, and a clock generator (32) having a synchronizing input, and a first counter (30) having parallel outputs; The output of the signal generating circuit (20) directly or via a drive circuit (36) to the other terminal of the LED displays (41 ... 50) connected to the enable input of the first counter (30) and the synchronization input of the clock generator (32) via an intermediate circuit (34). Apparatus according to claim 1, characterized in that a signal oscillator (24) is connected to the output of the signal forming circuit (20) to which the output (28) is connected, directly or indirectly. Device according to Claim 2, characterized in that the first oscillator (24) is connected to the output of the circuit (20) of the signal shapes via a first switch (22). 4. Device according to any one of claims 1 to 3, characterized in that the first counter (30) has an overflow output and a connected overflow indicator (38). 5. Apparatus according to any one of claims 1 to 4, characterized by an OR function circuit (52), an AND function circuit (54) associated with its output and a second counter (60) coupled to its output, wherein the OR function circuit (52) has a single input the first counter (30) being connected to one of its outputs, preferably its outputs, and the second input of the AND function circuit (54) being coupled to the output of the signal generating circuit (20). Apparatus according to claim 5, characterized in that the signal forming amplifier unit (10) has a second output, the second output being connected to the input of the second counter (60). Apparatus according to claim 5 or 6, characterized in that a second oscillator (70) is coupled to the output of the second counter (60), preferably a second oscillator (70) tuned to a frequency different from the frequency of the first oscillator (24). the output of the second oscillator (70) is connected to the input of the speaker (28) and the output of the second counter (60) is connected to the input of the counting bar. Device according to claim 7, characterized in that the output of the first oscillator (24) and the output of the second oscillator (70) are connected to one of the inputs of the summing circuit (26) and the output of the summing circuit (26) is 28) connected to its input. 9. Device according to any one of claims 1 to 3, characterized in that a timer generator (66) is provided, the output of which timer generator (66) is connected to the wiper input of the second counter (60). Apparatus according to claim 9, characterized in that the timer generator (66) has on / off timer members, preferably timer capacitors (64, 65), with a time switch (62). 11. Device according to any one of claims 1 to 3, characterized in that the overflow output of the first counter (30) is connected to the second input of the second oscillator (70). 12. A 7-11. Device according to any one of claims 1 to 3, characterized in that the output of the timer generator (66) is connected to a wiper input of the second counter (60), the control input of the controlled switch (56) having an overflow output. connected. 13. A 9-12. Device according to any one of claims 1 to 3, characterized in that it has a manual, preferably push-button, switch (58) connected between the reset input of the second counter (60) and / or the timing generator (66) and a terminal of appropriate potential. 14. Apparatus according to any one of claims 1 to 3, characterized in that the differential amplifier (11) connected to the inputs of the signaling amplifier unit (10) connected to the inputs of the sensor inputs (1,2, 3) is leveled via an amplifier (12) and a disconnecting capacitor (13). an amplifier (14) having a dual signal forming circuit (18) coupled to the output of the leveling amplifier (14) via a filter (15), preferably an active filter, preferably an active hole filter, a sinter (16) and a capacitor (17), The outputs (18) form the outputs of the signaling amplifier unit (10).