KR20200041585A - Electrocardiogram monitoring system capable of analyzing simultaneous motion - Google Patents

Abstract

The present invention relates to an electrocardiogram monitoring system capable of simultaneous operation analysis and, more specifically, to a technology related to an electrocardiogram monitoring system capable of simultaneous operation analysis, which may obtain additional objective information on a patient motion status at the same time since there is a case that it is ambiguous to determine whether a person is in a morbid condition using only an electrocardiogram waveform when arrhythmia is shown in a 24-hour active electrocardiogram test, which is most commonly used for arrhythmia diagnosis, and may analyze simultaneous motion for outputting whether treatment is actively recommended, by analyzing an electrocardiogram waveform and operation state information based on the obtained additional objective information.

Description

Electrocardiogram monitoring system capable of analyzing simultaneous motion

The present invention relates to an electrocardiogram monitoring system capable of simultaneous motion analysis. More specifically, it is ambiguous to determine whether or not the condition is pathological with only the ECG waveform when showing arrhythmia in a 24-hour active ECG test most commonly used for arrhythmia diagnosis. Since it exists, it is possible to obtain objective additional information on the patient's operating status at the same time, and based on this, an ECG monitoring system capable of simultaneous motion analysis that outputs whether treatment is actively recommended by analyzing the ECG waveform and the operating state information Technology.

My heart is beating all the time, but healthy normal people don't feel it. However, patients with arrhythmia may feel their heartbeat and complain of discomfort if their pulse rate is skipped or the pulse rate is abnormally too slow or too fast. Symptoms of arrhythmia vary widely, ranging from mild chest palpitation and chest pain to syncope and sudden death, depending on the type of arrhythmia and the type and severity of heart disease the patient has. When an arrhythmia occurs, an abnormal heartbeat may appear as a tingling or rattling, which may make you feel uncomfortable, and the ability of the heart to release blood decreases, resulting in a decrease in the amount of blood that is pumped out, resulting in dyspnea, dizziness, fainting, etc. You can. In addition, if malignant arrhythmias such as ventricular contraction, ventricular tachycardia, and ventricular fibrillation occur, the heart function may be completely paralyzed instantaneously, resulting in death.

When there are suspected arrhythmia symptoms, it is necessary to check whether the symptoms and abnormalities of the electrical signals of the heart are related, and this is usually confirmed by an electrocardiogram when symptoms appear.

Looking at the conventional technology for the electrocardiogram monitoring system, as shown in the Republic of Korea Patent Registration No. 10-1468057, after generating and transmitting the matrix for the normal ECG data that occurs differently depending on the individual patient or worn state For normal heart rate, the packet excluding ECG data is transmitted, and for abnormal heart rate, the packet including ECG data is transmitted, so that the monitoring device restores it using normal ECG data. And even if a human body wearable ECG measuring device is configured using a microprocessor with low data processing capability, real-time monitoring is possible, so it can be easily applied to the ubiquitous healthcare system. In particular, atrial or ventricular contraction, which is the most common abnormal heartbeat type The electrocardiogram measuring device and ECG monitoring system capable of monitoring in real time have been disclosed.

However, arrhythmia has a different clinical meaning depending on whether the patient is awakened or behaved, even with the same ECG waveform. In other words, it is often ambiguous to determine whether or not the condition is pathological only by the ECG waveform. For example, bradycardia is possible even in normal people due to the activity of the parasympathetic nerve before waking normally. Or, in the case of a vigorous exercise person, a sinus tachycardia is possible even if it is not an arrhythmia. In fact, when diagnosing arrhythmia of a patient who has been hospitalized for dyspnea, the diagnosis is completely different depending on whether the patient's electrocardiogram waveform was vigorous or resting when arrhythmia manifested.

That is, when arrhythmia is exhibited in a 24-hour active ECG, which is the most commonly used diagnostic method for diagnosing arrhythmia, it will be of course clinically useful to obtain objective additional information about the patient's motion status at the same time.

Republic of Korea Registered Patent Publication No. 10-1468057 (2014.12.02.)

The present invention has been devised to solve the problems of the prior art as described above, and an object thereof is to provide an electrocardiogram monitoring system capable of simultaneous motion analysis by recording an operation state together with an electrocardiogram waveform.

In addition, an object of the present invention is to provide an ECG monitoring system capable of simultaneous motion analysis supporting more accurate and easy arrhythmia diagnosis.

The problems to be solved by the present invention are not limited to the above-mentioned problems, and other problems to be solved by the present invention not mentioned herein are described below to those skilled in the art to which the present invention pertains. It will be clearly understood.

Electrocardiogram monitoring system capable of simultaneous motion analysis according to the present invention is attached to the user's body, a measurement unit including an electrocardiogram sensor and motion sensor for sensing the electrocardiogram and the operating state; And a monitoring unit that receives and outputs the electrocardiogram data and motion data sensed from the measurement unit, and wherein the monitoring unit includes an electrocardiogram data graph and an operation data graph in a section where the electrocardiogram data is outside a preset normal pulse range. Characterized in that the output.

In addition, in the electrocardiogram monitoring system capable of simultaneous motion analysis according to the present invention, the monitoring unit comprises: a data processing unit for processing the electrocardiogram data and motion data into an operation number assigned according to an R-R interval and an operation, respectively; A discrimination unit for generating discrimination information for discriminating the prognosis of arrhythmias using the R-R interval and the operation number; And an output unit that displays the discrimination information as a warning signal on the electrocardiogram data graph and the operation data graph.

In addition, in the electrocardiogram monitoring system capable of simultaneous motion analysis according to the present invention, the discrimination unit includes: the RR interval is 3 seconds or more and the operating state is an active posture, or the RR interval is less than 0.6 seconds and the operating state is When in a stopped posture, the output unit is characterized in that it is controlled to display a first warning signal having a high risk of highly recommending hospital treatment.

In addition, in the electrocardiogram monitoring system capable of simultaneous motion analysis according to the present invention, the discrimination unit may have a posture in which the RR interval is 3 seconds or more and the operating state is stopped, or the RR interval is less than 0.6 seconds and the operating state is When in an active posture, it is characterized in that the output unit is controlled so that a second warning signal with low risk is displayed so that it can be used as a reference for hospital treatment.

In addition, in the electrocardiogram monitoring system capable of simultaneous motion analysis according to the present invention, the monitoring unit collects the operation state data of the user sensed by the motion sensor, and ADL (Activities of Daily Living) for one day. ) It is characterized by being able to print a report.

By means of solving the above problems, the electrocardiogram monitoring system capable of simultaneous motion analysis of the present invention has an effect of improving the accuracy of arrhythmia diagnosis through simultaneous analysis of electrocardiograms and behavior patterns.

1 is a configuration diagram of an electrocardiogram monitoring system capable of simultaneous motion analysis according to the present invention.
2 is a dictionary graph for graphically showing the user's motion detected from the motion sensor of the electrocardiogram monitoring system capable of simultaneous motion analysis according to the present invention.
3 is a graph showing a user's motion detected from the motion sensor of the electrocardiogram monitoring system capable of simultaneous motion analysis according to the present invention.
4 is a view showing a graph that is enlarged by dragging a part of the operation graph of the electrocardiogram monitoring system capable of simultaneous motion analysis according to the present invention.
5 is a view showing a graph simultaneously outputting the same time vs. operation state and the electrocardiogram of the electrocardiogram monitoring system capable of analyzing the simultaneous operation according to the present invention.
6 is a diagram showing a daily life ability evaluation report of an electrocardiogram monitoring system capable of analyzing simultaneous motions according to the present invention.
7 is a view for explaining the meaning of the RR interval that is a variable for analyzing the waveform of the electrocardiogram.
8 is a diagram illustrating an algorithm for discriminating arrhythmia in an electrocardiogram monitoring system capable of simultaneous motion analysis according to the present invention.
FIG. 9 is a diagram showing an electrocardiogram-action graph of a patient in a posture in which the electrocardiogram monitoring system capable of simultaneous motion analysis according to the present invention is in a bradycardia state.
10 is a view showing an electrocardiogram-action graph of a patient in an active posture in an bradycardia state in which an electrocardiogram monitoring system capable of simultaneous motion analysis according to the present invention is performed.
11 is a diagram showing an electrocardiogram-action graph of a patient in an active posture in which an ECG monitoring system capable of simultaneous motion analysis according to the present invention is active in a sinus tachycardia state.
FIG. 12 is a diagram showing an electrocardiogram-action graph of a patient in a posture in which the ECG monitoring system capable of simultaneous motion analysis according to the present invention is in a sinus tachycardia state.

The problems to be solved for the present invention as described above, the means for solving the problems, and specific matters including the effects of the invention are included in the following embodiments and drawings. Advantages and features of the present invention, and methods for achieving them will be clarified with reference to embodiments described below in detail together with the accompanying drawings.

ECG monitoring system capable of simultaneous motion analysis according to the present invention, as shown in Figure 1, is attached to the user's body, the measurement including an electrocardiogram sensor 11 and a motion sensor 12 to detect the electrocardiogram and the operating state The unit 10 includes a monitoring unit 20 that receives and outputs electrocardiogram data and operation data sensed from the measurement unit 10. At this time, the measurement unit 10 and the monitoring unit 20 are mutually connected by wireless communication to exchange data.

First, the measuring unit 10 transmits data to the battery unit 13, the storage unit 14, and the monitoring unit 20, in addition to the ECG sensor 11, in the same manner as the conventional Holter device for monitoring ECG. It may include a transmission unit 15 for.

In particular, the measuring unit 10 includes a motion sensor 12 for detecting the user's operating state, the motion sensor 12 includes a 3-axis accelerometer, 3-axis angular accelerometer, 3-axis geomagnetic field, and lay The user's motion data can be acquired such as a standing state, a standing or standing state, a walking state, a light running state, and a running state.

At this time, since the operation data is not expressed numerically unlike the electrocardiogram data, an operation number must be assigned according to each operation state in order to show a graph. In the present invention, as shown in Figures 2 and 3, the lying state was set to 1, the sitting or standing stopped state 2, the walking state 3, the light running state 4, and the running state 5. This number is subject to change according to a person skilled in the art, and can be classified into five or more states by further subdividing the criteria recognized by each posture.

Next, the monitoring unit 20 shows and outputs the electrocardiogram data and operation data received from the measurement unit in a graph, as shown in FIG. 4, the operation state and the electrocardiogram graph together at the same time. Arrangement is made to make it easier and more accurate to determine arrhythmia.

At this time, the monitoring unit 20 is basically configured to output an operation data graph together with an electrocardiogram data graph in a section outside the normal pulse range in which the electrocardiogram data is preset. The preset normal pulse range may be preferably 40 times per minute or more and less than 150 times per minute. This configuration is intended to optimally store only the data necessary for arrhythmia diagnosis while minimizing the capacity of the measurement unit attached to the user since the capacity of the measurement unit and the monitoring unit increases because the capacity becomes too large when all measurement data is stored. .

In addition, as illustrated in FIG. 5, the monitoring unit 20 is provided with a function that can be divided into more granular times and illustrated when an interval to be examined in more detail among operation graphs is input. This ECG graph is also equipped with the same function.

In addition, as shown in FIG. 6, the monitoring unit 20 collects daily operation status data of a user sensed by the motion sensor 12 and evaluates ADL (Activities of Daily Living) for one day. ) You can print a report. The ADL report is expressed in various ways, such as the ratio of the operating state, the total amount of activity, and the amount of change per day.

In addition, the monitoring unit 20, the receiving unit 21 for receiving the electrocardiogram data and the operation data from the transmission unit 15, the received electrocardiogram data and the operation data to process the assigned operation number according to the RR interval and operation, respectively Data processing unit 22, a discrimination unit 23 for generating discrimination information for discriminating the prognosis of arrhythmias using the RR interval and the operation number, and a warning signal on the electrocardiogram data graph and the operation data graph It may include an output unit 24 and a storage unit (25).

Here, the R-R interval is an interval between R and the next R representing a peak in the ECG waveform illustrated as an example in FIG. 7 and is a variable used for heart rate evaluation.

Hereinafter, an algorithm for discriminating arrhythmias based on the measured electrocardiogram and the operating state in which the electrocardiogram monitoring system capable of simultaneous motion analysis according to the present invention will be described in detail with reference to FIG. 8.

First, the discrimination unit 23 determines whether the RR interval is 3 seconds or more (the electrocardiogram data is bradycardia) or the normal p-wave constantly appears in front of the QRS wave, and the RR interval is less than 0.6 seconds (the electrocardiogram data is the same). Grasp.

Next, the discrimination unit 23, if the electrocardiogram data is bradycardia or sinus tachycardia, the active state is lying, sitting or standing, standing posture (action number 1 ~ 2), walking, running, running, running lightly or running (action number) 3 ~ 5) Determine if it is.

Accordingly, the patient's ECG and motion data are classified into four cases. If the RR interval is 3 seconds or longer and the operation number is 1 to 2 (CASE Ⅰ), the RR interval is 3 seconds or longer and the operation number is 3 to 5 (CASE Ⅱ), the RR interval is less than 0.6 seconds and the operation number is In the case of 1 to 2 (CASE III), there will be a case where the RR interval is less than 0.6 seconds and the operation number is 3 to 5 (CASE IV).

Next, the discrimination unit 23 generates discrimination information based on a result of grasping the electrocardiogram data and the operation data.

In the case of CASE Ⅰ, asymptomatic bradycardia in a lying or resting state does not have a great clinical significance and can be regarded as a normal physiological reaction.

In the case of CASE Ⅱ, bradycardia with more than 3 seconds in active state is an indicator of severe concern for arrhythmias, and there are many indications of artificial pacemaker insertion, which can be seen as a prognosis for arrhythmias.

In the case of CASE Ⅲ, the sinus tachycardia, which is active but less than 0.6 seconds, has no clinical significance, so it can be regarded as a normal physiological reaction in which the heart rate increases with walking or jumping.

In the case of CASE IV, a sinus tachycardia less than 0.6 seconds in a sleeping or resting state is an indicator of abnormal sympathetic nerve activity and is an inappropriate sinus tachycardia, which can be seen as a prognosis for arrhythmia.

Finally, the output unit 24 graphs the ECG data of the first warning signal having a high risk of recommending hospital treatment according to the discrimination information or the second warning signal having a low risk of being used as a reference for hospital treatment. And is displayed on the operation data graph. At this time, the high-risk first warning signal should be provided in a different shape from the low-risk second warning signal.

That is, the discrimination unit 23, as shown in Figures 9 to 11, the RR interval is 3 seconds or more (electrocardiogram data is bradycardia) and the active state is active posture (motion numbers 3 to 5) or , If the RR interval is less than 0.6 seconds (electrocardiogram data is a sinus tachycardia) and the operating state is in a stopped posture, it generates a differential information in a meaningful section, and the output unit 24 has a high risk of actively recommending hospital care Control so that the first warning signal can be displayed. In addition, if the RR interval is 3 seconds or more (electrocardiogram data is bradycardia) and the operating state is a standing posture, or the RR interval is less than 0.6 seconds (electrocardiogram data is a sinus tachycardia) and the operating state is active, arrhythmia By generating discrimination information in a section with high probability of winning but meaningless, the output unit 24 is controlled to display a second low-risk warning signal to be used as a reference in hospital treatment.

It is a matter of course that the existing electrocardiogram device does not have the above-described clinical meaning since there is no operation data unlike the present invention. However, even in the electrocardiogram monitoring system capable of analyzing the simultaneous operation of the present invention, treatment is required under the clinical final judgment by comprehensively considering the drugs that the patient is eating, so the first warning signal with high risk is' to the patient immediately. Rather than urgency, it means 'recommending active hospital care'.

It will be understood that the above-described technical configuration of the present invention can be implemented in other specific forms by those skilled in the art to which the present invention pertains without changing the technical spirit or essential features of the present invention.

Therefore, the above-described embodiments are to be understood as illustrative and not restrictive in all respects, and the scope of the present invention is indicated by the following claims rather than the detailed description, and the meaning and scope of the claims It should be construed that any altered or modified form derived from the equivalent concept is included in the scope of the present invention.

10: measuring unit
11: ECG sensor
12: Motion sensor
13: battery unit
14: storage unit
15: transmitter
20: monitoring unit
21: receiver
22: data processing unit
23: discrimination unit
24: output
25: storage unit

Claims (5)

A measurement unit attached to the user's body and including an electrocardiogram sensor and an operation sensor to detect an electrocardiogram and an operation state; And
Includes; monitoring unit for receiving and outputting the electrocardiogram data and motion data sensed from the measurement unit,
The monitoring unit,
An ECG monitoring system capable of simultaneous motion analysis, wherein the ECG data is outputted together with the ECG data graph in a section outside the preset normal pulse range. According to claim 1,
The monitoring unit,
A data processing unit for processing the electrocardiogram data and the operation data into an operation number allocated according to the RR interval and operation, respectively;
A discrimination unit for generating discrimination information for discriminating the prognosis of arrhythmias using the RR interval and the operation number; And
And an output unit for displaying the differential information as a warning signal on the electrocardiogram data graph and the operation data graph. According to claim 2,
The discrimination unit,
If the RR interval is 3 seconds or more and the operating state is an active posture, or the RR interval is less than 0.6 seconds and the operating state is a standing posture,
ECG monitoring system capable of simultaneous motion analysis, characterized in that the output unit controls to display a first high-risk warning signal that is highly recommended for hospital care. According to claim 2,
The discrimination unit,
If the RR interval is 3 seconds or more and the operating state is a standing posture, or the RR interval is less than 0.6 seconds and the operating state is an active posture,
An electrocardiogram monitoring system capable of simultaneous motion analysis, characterized in that the output unit is controlled to display a second warning signal with a low risk of being used as a reference for hospital treatment. According to claim 1,
The monitoring unit,
ECG monitoring system capable of simultaneous motion analysis, characterized in that it can output the ADL (Activities of Daily Living) report for one day by collecting the user's motion state data detected by the motion sensor.

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