JP2021065419A - Electrocardiogram monitor system, electrocardiogram monitor system actuation method, and transmission processing program - Google Patents

Abstract

To provide a system to allow efficient transmission and management of electrocardiogram data of a subject, in order to promote the enhanced efficiency of remote diagnosis in a home medical care.SOLUTION: An electrocardiogram monitor system comprises: a portable electrocardiograph for acquiring electrocardiogram data of a subject; a transmission processing terminal which receives the electrocardiogram data from the portable electrocardiograph; and a server for storing the electrocardiogram data transmitted from the transmission processing terminal, which includes data transmission means for transmitting electrocardiogram data configured as data for each predetermined unit time to the server.SELECTED DRAWING: Figure 1

Description

The present invention relates to a system for monitoring an electrocardiogram of a subject, a method of operating the system, and a transmission processing program.

In recent years, the need for home medical care has been increasing against the background of the progress of the aging society. Home medical care is medical care that enables elderly people living in the community to receive high-quality medical care or long-term care support while living in a familiar place with peace of mind, and is closely related to the comprehensive community care system. However, it is developing. In addition, as it is also called pediatric home medical care, there is an increasing need for home medical care for children and the like who need medical equipment on a daily basis.

On the other hand, in Japan, there is a serious problem of a shortage of doctors, and there is a demand for more efficient medical care for patients. Against this background, efforts to build a telemedicine system utilizing ICT (Information and Communication Technology) are becoming more widespread.

In particular, for those who have or are suspected of having heart disease, various electrocardiogram monitoring systems are known for measuring the electrocardiogram for a certain period of time while living a daily life and evaluating the presence or absence of findings such as heart disease. ing.

For example, Patent Document 1 discloses an electrocardiogram monitoring system for the purpose of centrally monitoring the electrocardiograms of a plurality of patients in real time.

Further, Patent Document 2 discloses a biometric data transmission / reception system for the purpose of efficiently and quickly transmitting / receiving biometric data on the premise that it is applied to emergency medical care that requires urgency.

Japanese Patent No. 3831701 Japanese Patent No. 4172543

In Patent Document 1, it is possible to monitor the patient's electrocardiogram in real time, but in home medical care, it is naturally assumed that the diagnosis is performed not only in real time but also on a date and time different from the electrocardiogram measurement date. Will be done. It is also envisioned that a healthcare professional may wish to refer to ECG data at a particular time zone when making such a later diagnosis.

Further, in Patent Document 2, it is possible to store the electrocardiogram data at intervals of 1 second and to acquire the electrocardiogram data at a specified time. However, this is intended for the rapid and efficient transfer of the electrocardiogram data necessary for emergency medical care, and is not intended for the case of acquiring the electrocardiogram data for a long period of time.

As described above, a system for efficiently processing electrocardiogram data is disclosed for the case of monitoring the electrocardiogram in real time or the case of transferring the electrocardiogram data in a relatively short time such as when transporting a patient. There has been no known system capable of efficiently transmitting and managing electrocardiogram data in both real-time and later diagnosis on the premise of remote monitoring of electrocardiogram.

In addition, although the portable electrocardiograph itself for continuously monitoring the electrocardiogram for a long period of time has been known from the past, a method of collectively transferring the measured data offline has been adopted, so that it is used for data transfer. There are problems such as time-consuming or time-consuming display of data in a desired time zone, and a solution has been sought.

In view of such a background, the present invention has been made for the purpose of solving the problem of the conventional portable electrocardiograph, and in order to support the efficiency of remote diagnosis in home medical care, the subject The purpose is to provide a system that enables efficient transmission and management of electrocardiogram data.

The present invention that solves the above problems
A portable electrocardiograph that acquires the electrocardiogram data of the subject,
A transmission processing terminal that receives the electrocardiogram data from a portable electrocardiograph, and
A server for storing electrocardiogram data transmitted from the transmission processing terminal is provided.
The transmission processing terminal is an electrocardiogram monitoring system characterized by having a data transmission means for transmitting electrocardiogram data configured as data for each predetermined unit time to the server.

According to the present invention having such a configuration, it is possible to efficiently transmit and manage the electrocardiogram data of the subject.

In a preferred embodiment of the present invention, the transmission processing terminal has a transmission success data deleting means for deleting the transmission success data stored in the transmission processing terminal when the electrocardiogram data is successfully transmitted to the server. It is characterized by.

With such a configuration, the electrocardiogram data that has been successfully transmitted to the server is sequentially deleted, so that unnecessary data is not accumulated and the processing speed can be improved.

In a preferred embodiment of the present invention, the transmission processing terminal has a re-execution means for re-transmitting the transmission failure data to the server after a lapse of a predetermined time when the transmission of the electrocardiogram data to the server fails. The re-execution means is characterized in that the transmission process is repeated until the transmission of the transmission failure data to the server is successful.

With such a configuration, the electrocardiogram data that failed to be transmitted to the server due to a problem such as a communication error is automatically retransmitted until the transmission is successful, so that the measured data can be managed without omission. it can.

In a preferred embodiment of the present invention, the re-execution means transmits the transmission failure data and the electrocardiogram data accumulated until the transmission of the transmission failure data to the server is successful to the server. And.

With such a configuration, measurement data other than the data whose transmission to the server has failed can be managed without omission while maintaining continuity.

In a preferred embodiment of the present invention, the transmission processing terminal is characterized by comprising a round slice data conversion means for converting the electrocardiogram data into electrocardiogram data at predetermined unit times.

With such a configuration, the continuously acquired electrocardiogram information is converted into round-cut data for each predetermined unit time, and the electrocardiogram data of the subject can be transmitted and managed more efficiently.

In a preferred embodiment of the present invention, the predetermined unit time is 1 minute to 6 hours.

With such a configuration, the electrocardiogram data is divided into the above-mentioned data for each predetermined unit time. Therefore, the viewability and manageability of the data are further improved.

In a preferred embodiment of the present invention, the transmission processing terminal is characterized in that the electrocardiogram data is converted into DICOM format data and transmitted to a server.

Today, medical data and the like related to various test results are generally stored in a data format compliant with the DICOM (Digital Imaging and Communications in Medicine) standard. Therefore, it is preferable that the electrocardiogram information according to the present invention is converted into DICOM format data and then transmitted to the server.

Further, in a preferred embodiment of the present invention, the server is a cloud server, and the cloud server analyzes the electrocardiogram data to detect irregular beats.

Conventionally, the electrocardiogram data stored in a server such as a cloud server has generally been downloaded via the Internet or taken offline from a terminal in which the electrocardiogram data is stored for analysis.

However, according to the present invention, since it is possible to analyze desired data directly on the cloud server, the efficiency of data analysis is further improved.

The present invention includes an information acquisition process for acquiring electrocardiogram data of a subject by a portable electrocardiograph, and
An information transmission process for transmitting the electrocardiogram data acquired by the portable electrocardiograph to a transmission processing terminal, and
A data transmission step of transmitting the electrocardiogram data received by the transmission processing terminal to a server is included.
The data transmission step also relates to a method of operating an electrocardiogram monitoring system, which comprises transmitting electrocardiogram data configured as data for each predetermined unit time to the server.

Further, the present invention is a transmission processing program for transmitting the electrocardiogram data of a subject acquired via a portable electrocardiograph to a server.
The present invention also relates to a transmission processing program characterized in that a computer functions as a data transmission means for transmitting the electrocardiogram data to the server as electrocardiogram data configured as data for each predetermined unit time.

According to the present invention, a system that enables efficient transmission and management of electrocardiogram data of a subject is provided, and remote diagnosis in home medical care can be made more efficient.

It is a figure which shows the outline of the electrocardiogram monitoring system which concerns on embodiment of this invention. It is a functional block diagram which shows the functional structure example of the electrocardiogram monitoring system which concerns on embodiment of this invention. This is a display example of a browsing screen of the electrocardiogram monitoring system according to the embodiment of the present invention. It is a flowchart which shows the flow of processing of the electrocardiogram data in the electrocardiogram monitoring system which concerns on embodiment of this invention. It is a flowchart which shows the flow of processing of the electrocardiogram data in the electrocardiogram monitoring system which concerns on embodiment of this invention.

Hereinafter, the electrocardiogram monitoring system according to the present invention will be described with reference to the drawings. The embodiments shown below (including the Graphical User Interface) are examples of the present invention, and the present invention is not limited to the following embodiments.

In the present embodiment, the configuration, operation, and the like of the electrocardiogram monitoring system will be described, but devices, computer programs, methods, and the like having the same configuration also have the same effects. Further, the program may be stored in a recording medium. Using this recording medium, for example, a program can be installed on a computer. The recording medium in which the program is stored may be a non-transient recording medium such as a CD-ROM.

In the present invention, the "electrocardiogram information" is an electrocardiogram signal detected as an action potential or an action current of the myocardium acquired from the body surface via a portable electrocardiograph.
Further, the "electrocardiogram data" is digital data in which the temporal change of the electrocardiogram information is recorded as a waveform, and is generally also referred to as an electrocardiogram or ECG (Electrocardiogram).

FIG. 1 is a diagram showing an outline of an electrocardiogram monitoring system 1 according to the present invention.
As shown in FIG. 1, the electrocardiogram monitoring system 1 transmits an electrocardiogram data acquired via a portable electrocardiograph 2 mounted on the chest of a subject and a portable electrocardiograph 2 to a server 4. It includes a terminal 3, a server 4, and a browsing terminal 5.

The portable electrocardiograph 2 performs wireless communication with the transmission processing terminal 3. Further, the transmission processing terminal 3 and the server 4, and the server 4 and the browsing terminal 5 are connected to each other so as to be able to communicate with each other via the network NW. Further, the server 4 is preferably a cloud server, but is not limited to this.

The viewing terminal 5 includes a communication unit that is an interface for communicating with an external device, an input unit such as a touch panel and a physical key, an output unit such as a display, and an audio input / output unit that inputs / outputs audio. It can also be an information communication terminal such as a personal computer, a smartphone equipped with a touch panel, a tablet terminal, a portable information terminal such as a PDA (Personal Digital Assistant), or the like. It is preferable that the viewing terminal 5 stores a dedicated program for displaying the electrocardiogram data.

Although not shown in the present specification, the portable electrocardiograph 2 includes a main body unit, a power supply unit, an input unit including an electrode pad, an amplification unit for amplifying input electrocardiogram information, and an amplified electrocardiogram. A conversion unit that digitally converts information, a storage unit that stores electrocardiogram data after digital conversion, a wireless transmission unit for wireless communication with the transmission processing terminal 3, and an external device such as the transmission processing terminal 3. It includes a connection unit having a USB terminal for connecting and charging.

The connection portion of the portable electrocardiograph 2 may include not only a USB terminal but also an AV terminal such as a Lightning terminal, a VGA terminal, and the like, depending on the embodiment.

As described above, the portable electrocardiograph 2 has a configuration capable of wirelessly communicating with the transmission processing terminal 3 by the wireless transmission unit. As the wireless communication standard, various wireless communication standards such as wireless communication standards such as Bluetooth (registered trademark) and Zigbee (registered trademark), mesh network format, and P2P (Peer to Peer) format can be adopted. ..

Further, the portable electrocardiograph 2 may be connected to the transmission processing terminal 3 by wire using a USB terminal, depending on the usage environment and the like.

The subjects who wear the portable electrocardiograph 2 according to the electrocardiogram monitoring system 1 of the present invention and monitor the electrocardiogram are roughly classified into three patterns as follows. The first subject is a person who has no subjective symptoms or signs such as heart disease. In this case, the purpose is to screen for diseases (preventive medicine). The second subject is a person who has subjective symptoms or signs such as heart disease. In this case, the purpose is to detect a fatal arrhythmia and promptly treat the subject. The third subject is a preoperative and / or postoperative patient. In this case, the purpose is to manage the patient's perioperative period and confirm the therapeutic effect.

The target person is not limited to the above three patterns. For example, in addition to this, the present invention can also be applied to patients with a certain risk of developing cerebral infarction based _{on the CHADS 2} score, which scores the risk of developing cerebral infarction in patients with atrial fibrillation.

In addition, there are a certain number of cerebral infarctions whose cause is unknown, but by using the portable electrocardiograph 2 of the present invention, whether or not the cause of such cerebral infarction is cardiogenic. It can also help in diagnosing.

The number of days for wearing the portable electrocardiograph 2 and monitoring the electrocardiogram can be appropriately determined according to the above-mentioned purpose of use, but as a guide, it is 1 to 10 days, more preferably 2 to 7 days.

The portable electrocardiograph 2 can be attached to the subject's chest via a gel pad. The mounting position of the portable electrocardiograph 2 can be specified based on the instructions of the medical staff according to the required waveform, but from the viewpoint of reducing the influence of noise and myoelectricity, it is mounted in the center of the chest. Is preferable. In this case, the direction of the portable electrocardiograph 2 is more preferably such that the longitudinal direction of the main body is perpendicular to the ground.

In the portable electrocardiograph 2, an electrocardiogram signal (electrocardiogram information) is acquired by an input unit, a conversion unit converts this analog signal into digital data (electrocardiogram data), and a storage unit stores this. Then, the obtained electrocardiogram data is transmitted to the transmission processing terminal 3 via the wireless transmission unit or the connection unit.

The biological information acquired by the portable electrocardiograph 2 is not necessarily limited to the electrocardiogram data, and may be configured to acquire other biological information such as body surface temperature, if desired.

As shown in FIG. 2, the transmission processing terminal 3 includes a data storage means 31, a round slice data conversion means 32, a round slice data storage means 321, a data transmission means 33, a transmission success data deletion means 34, and a re-execution means. 35 and. The functions of the transmission processing terminal 3 described below are also applicable to the description of the transmission processing program of the present invention.

Further, the transmission processing terminal 3 of the present invention may be further provided with a marking means for recording the time, symptomatism, etc. when the subject becomes aware of the irregular pulsation during the measurement period of the electrocardiogram data.

The transmission processing terminal 3 may be configured to have a data communication function, and a smartphone terminal or a tablet terminal can be adopted. Further, these terminals include a computing device (CPU (Central Processing Unit)) and a main storage device (RAM (Random Access Memory)) as a working memory as hardware components. In addition, communication such as OS (Operating System), application program, auxiliary storage device such as HDD, SSD, flash memory, etc. that rewritably stores various information (including data), communication control unit, NIC (Network Interface Card), etc. It includes an interface (IF) unit, a display control unit, a display unit, and the like.

The data storage means 31 is configured to temporarily store continuous electrocardiogram data transmitted from the portable electrocardiograph 2. The round slice data conversion means 32 is configured to convert the stored electrocardiogram data into electrocardiogram data for each predetermined unit time.

The above-mentioned "predetermined unit time" is preferably in units of 1 minute to 6 hours, more preferably in units of 1 minute to 3 hours, more preferably in units of 5 to 60 minutes, still more preferably in units of 5 to 45 minutes, and particularly preferably in units of 5 to 45 minutes. It is in units of 5 to 30 minutes.
By setting the predetermined unit time as described above, the viewability and manageability of data are improved.

In a preferred embodiment of the present invention, the electrocardiogram data converted as data for each predetermined unit time by the round slice data conversion means 32 is stored in the transmission processing terminal 3 by the round slice data storage means 321, and the server 4 is stored by the data transmission means 33. Will be sent to.

Further, in another embodiment of the present invention, the portable electrocardiograph 2 may be configured to generate electrocardiogram data for each predetermined unit time. In this case, the electrocardiogram data is stored by the round slice data storage means 321 and transmitted to the server 4 by the data transmission means 33.

Further, in a preferred embodiment of the present invention, the data transmission means 33 automatically transmits the electrocardiogram data for each predetermined unit time stored in the round slice data storage means 321 every time the predetermined unit time elapses. Send to.

With such a configuration, for example, when the predetermined unit time is set to 15 minutes, the medical staff can monitor the electrocardiogram data of the subject every 15 minutes, that is, in substantially real time. it can.

Further, even when the monitoring is not performed in substantially real time, that is, when the diagnosis is performed at a later date and time, all the electrocardiogram data of the subject measured during the observation period are accumulated in the server 4 as data in units of 15 minutes. Therefore, the medical staff can quickly and easily access the desired data.

Further, the present invention is a data storage means which includes the above-mentioned data transmission means 33, but stores the electrocardiogram data stored in the round slice data storage means 321 for each predetermined unit time without automatically transmitting the electrocardiogram data to the server 4. It can also be configured to include. In this case, the electrocardiogram data stored in the round slice data storage means 321 is stored in the transmission processing terminal 3 without being deleted by the transmission success data deletion means 34 described later. The accumulated electrocardiogram data can be viewed as electrocardiogram data for each predetermined unit time through the display unit of the transmission processing terminal 3.

With such a configuration, the present invention can be applied even when, for example, the transmission processing terminal 3 and the server 4 are not in a communicable environment. The electrocardiogram data stored in the data storage means is configured to be transmitted to the server 4 by the manual transmission means that manually transmits the electrocardiogram data to the server 4 when the transmission processing terminal 3 and the server 4 can communicate with each other. You can also do it.

Further, the present invention provides the above-mentioned data transmitting means 33, but does not convert the continuous electrocardiogram data transmitted from the portable electrocardiograph 2 into the electrocardiogram data at predetermined unit times, but instead sends the continuous electrocardiogram data to the server 4. It can also be configured to include a real-time transmission means for transmission.

With such a configuration, it is possible to monitor ECG data in real time for a subject who requires intensive management or observation.

As described above, the present invention further includes not only the data transmission means 33 that automatically transmits the electrocardiogram data for each predetermined unit time to the server 4, but also the data storage means, the manual transmission means, and the real-time transmission means. it can. Therefore, the target person or the medical worker can appropriately select the transmission mode of the electrocardiogram data according to the purpose.

Each of these functions can be switched by the target person himself or a related person such as the target person's family by changing the setting of the transmission processing terminal 3.

The transmission success data deletion means 34 automatically deletes the electrocardiogram data for which the transmission was successful when the electrocardiogram data stored in the round slice data storage means 321 for each predetermined unit time is successfully transmitted to the server 4. It is a configuration to do.

When the transmission success data deletion means 34 receives a notification indicating that the server 4 has succeeded in normally receiving the electrocardiogram data from the notification means 43 described later, it determines that the transmission of the electrocardiogram data has been successful, and the transmission is successful. It is preferable that the data is deleted from the transmission processing terminal 3.

More specifically, in the transmission success data deleting means 34, after the electrocardiogram data is transmitted to the server 4 by the data transmitting means 33 and a certain time has elapsed after the receiving means 41 described later receives the electrocardiogram data. Upon receiving the notification, it is determined that the transmission of the electrocardiogram data has been successfully completed, and the transmission success data is deleted from the transmission processing terminal 3. The above-mentioned "constant time" will be described later.

Further, as will be described later, whether the notification means 43 has successfully completed the transmission of the received electrocardiogram data to the server 4 depending on whether or not the received electrocardiogram data is stored in the server 4 by the storage means 42 within a certain time. It can be determined whether or not.

When the re-execution means 35 fails to transmit the electrocardiogram data stored in the round slice data storage means 321 for each predetermined unit time to the server 4, the re-execution means 35 automatically transmits the electrocardiogram data for which the transmission fails after the elapse of the predetermined time. This is a configuration for retransmitting to the server 4.

When the re-execution means 35 receives a notification indicating that the server 4 has failed to normally receive the electrocardiogram data from the notification means 43 described later, the re-execution means 35 determines that the transmission of the electrocardiogram data has failed, and receives the notification. It is preferable to perform the transmission process again after a lapse of a predetermined time.

More specifically, in the re-execution means 35, the electrocardiogram data is transmitted to the server 4 by the data transmission means 33, and the notification means is notified after a certain time has elapsed since the receiving means 41 described later receives the electrocardiogram data. When the notification that the transmission has failed is received from 43, it is determined that the transmission of the electrocardiogram data has failed, and after a predetermined time has elapsed, the transmission failure data is retransmitted.

The predetermined time can be arbitrarily set, but within a predetermined unit time, which is a unit for rounding the electrocardiogram data, preferably once or more, more preferably two times or more, still more preferably three times or more, again. It is preferable to set the time during which the transmission process of

More specifically, the predetermined time is preferably 1 to 100 minutes, more preferably 3 to 60 minutes, still more preferably 5 to 30 minutes, and particularly preferably 5 to 15 minutes. More specifically, when the electrocardiogram data for each predetermined unit time is set as the data for each 15 minutes, the predetermined time is preferably 5 minutes.

With such a configuration, even if a certain 15-minute unit ECG data fails to be transmitted to the server 4, the transmission is performed by the time the next 15-minute unit ECG data is accumulated in the transmission processing terminal 3. You will have the opportunity to resend the failed data three times.

Therefore, by removing the factor that caused the transmission failure during this period, it is possible to prevent the ECG data in units of 15 minutes from being excessively accumulated in the transmission processing terminal 3, and the transmission efficiency to the server 4 can be improved. improves.
From such a viewpoint, it is preferable to set the predetermined time to a time during which the transmission process can be performed again at least the above number of times.

Further, the re-execution means 35 repeatedly executes the transmission process until the transmission of the transmission failure data to the server 4 is successful. Then, similarly to the above, the re-execution means 35 succeeds in receiving the notification of whether or not the server 4 has succeeded in normally receiving the electrocardiogram data from the notification means 43, which will be described later, by the re-transmission process. Determine if the data transmission is complete. Then, when the notification means 43 notifies that the transmission has failed, the re-execution means 35 performs the transmission process again after the same time as the predetermined time has elapsed.

On the other hand, when the notification means 43, which will be described later, notifies that the transmission has been successful, the re-execution means 35 ends the repeated transmission process. Then, the transmission success data deleting means 34 deletes the electrocardiogram data from the transmission processing terminal 3.

When the transmission failure of the electrocardiogram data to the server 4 by the re-execution means 35 lasts for a certain long time, the electrocardiogram data for each predetermined unit time following the transmission failure data is stored in the server in the transmission processing terminal 3. It will be accumulated without being transmitted to 4.

Even in such a case, in order to improve the transmission efficiency of the electrocardiogram data, the re-execution means 35 together with the electrocardiogram data related to the transmission failure, the electrocardiogram data accumulated until the transmission failure data to the server 4 is successful. It is preferable that the data is also transmitted to the server 4.

For example, in the case where the electrocardiogram data for each predetermined unit time is set to the electrocardiogram data for each 15 minutes, when the predetermined time until the re-transmission processing is performed again by the re-execution means 35 is set to 5 minutes, the re-transmission processing is performed. If all three failures occur, the next 15-minute unit electrocardiogram data is accumulated in the transmission processing terminal 3. In such a case, the transmission efficiency of the electrocardiogram data is improved by configuring the configuration in which the next 15 units of electrocardiogram data are transmitted to the server 4 together with the transmission failure data.

It is more preferable that the transmission processing terminal 3 is provided with DICOM conversion means for converting ECG data into DICOM format data.

Conventionally, images related to inspections by radiation equipment such as CT (Computed Tomography), CR (Computed Radiography), MR (Magnetic Resonance), and XA (X-Ray Angiography) are managed by the DICOM server in the facility as DICOM format data. It was common to be done.

On the other hand, one-dimensional waveform data related to physiological tests such as electrocardiogram, electroencephalogram, and respiratory waveform are stored in a data format different from DICOM format, and are managed differently from DICOM data even within the same facility. It was.

Therefore, by converting the electrocardiogram data according to the present invention into DICOM format data, the electrocardiogram data of the subject can be centrally managed by the DICOM server together with other medical data.

It should be noted that converting the electrocardiogram data into DICOM format data is not necessarily limited to the transmission processing terminal 3. The server 4, which will be described later, may have the same function.

Next, the server 4 will be described. The server 4 includes a receiving means 41, a storage means 42, a notification means 43, a transmitting means 44, and an analysis means 45.

The receiving means 41 is configured to receive the electrocardiogram data transmitted from the transmission processing terminal 3. Then, after the receiving means 41 receives the electrocardiogram data of the target person, the storage means 42 stores the electrocardiogram data in the server 4.

The storage means 42 stores the transmitted electrocardiogram data in a facility unit, a device unit (target person unit), and a date unit. By storing the electrocardiogram data in such a data structure, it is possible to efficiently manage the data related to a plurality of target persons.

The notification means 43 is configured to notify the transmission processing terminal 3 whether or not the receiving means 41 has normally received the electrocardiogram data after a certain period of time has elapsed from the reception of the electrocardiogram data. The notification means 43 determines that the transmission has failed when the electrocardiogram data is not stored in the server 4 by the storage means 42 within a certain time after the receiving means 41 receives the electrocardiogram data. Notify the transmission processing terminal 3 to that effect.

On the other hand, the notification means 43 notifies the transmission processing terminal 3 that the transmission is successful when the electrocardiogram data is stored in the server 4 by the storage means 42 and a certain time elapses.

The above-mentioned "constant time" can be arbitrarily set as long as the effect of the present invention is not hindered, but is preferably 1 to 10 minutes after the receiving means 41 receives the electrocardiogram data, more preferably. Is preferably 1 to 5 minutes, more preferably 1 to 3 minutes, and particularly preferably 30 to 60 seconds.

By setting the above time, the transmission processing terminal 3 can quickly determine whether the transmission of the electrocardiogram data to the server 4 is successful or unsuccessful, and the transmission successful data deletion means 34 or re-execution The processing by the means 35 can be executed more efficiently.

The transmission means 44 is configured to transmit the electrocardiogram data stored in the storage means 42 to the viewing terminal 5 in response to a request from the viewing terminal 5.

As shown in FIG. 3, a list of portable electrocardiographs 2 registered in the facility is displayed on the display unit of the browsing terminal 5 via a dedicated program. When the medical worker selects the portable electrocardiograph 2 related to the target person who wants to view the electrocardiogram data, the date list and the file list are displayed.

The medical staff can download all the electrocardiogram data measured by the portable electrocardiograph 2 from the server 4 by pressing the "download" button located on the left side of the upper part of FIG. Further, if necessary, only specific electrocardiogram data can be downloaded from the server 4 by pressing the "acquire only selected files" button located on the right side of the upper part of the figure.

Further, by pressing the "acquire all unacquired files" button located on the right side of the upper part of the figure, only the electrocardiogram data related to the portable electrocardiograph 2 that has not been downloaded can be downloaded.

Furthermore, the medical staff can press the "Automatic data acquisition for the last 2 days" button located on the left side of the upper part of the figure to measure the data for the last 2 days with all the portable electrocardiographs 2 registered in the facility. It is also possible to check the electrocardiogram data at predetermined unit times and automatically download the unacquired data.

The above-mentioned ECG data download is an embodiment in which the server 4 and the viewing terminal 5 are communicably connected via the network NW, and the present invention has such an embodiment. While assuming the form, it is also possible to download the electrocardiogram data offline.

In this case, the transmission processing terminal 3 and the viewing terminal 5 are connected by a Lightning cable or the like, and the electrocardiogram data stored in the round slice data storage means 321 of the transmission processing terminal 3 is duplicated in the viewing terminal 5. The electrocardiogram data duplicated on the viewing terminal 5 can be manually deleted from the transmission processing terminal 3.

The medical worker can browse the electrocardiogram data acquired in this way through the browsing terminal 5 and diagnose the presence or absence of an arrhythmia event in the subject by himself / herself.

In addition, the medical staff specifies the electrocardiogram data measured by a specific portable electrocardiograph 2 in a specific time zone, requests an external specialist to analyze it, and refers to the result of the analysis. It is also possible to diagnose the subject.

The analysis means 45 is configured to analyze the electrocardiogram data on the server 4 in response to a request from the viewing terminal 5. The medical worker can access the dedicated website from the browsing terminal 5 via a web browser and browse the electrocardiogram data stored in the server 4.

On the website, all the electrocardiogram data measured by the portable electrocardiograph 2 registered in the facility can be displayed in the same way as the browsing terminal 5 displays through the dedicated program. Therefore, the medical staff can browse arbitrary electrocardiogram data on the website without downloading to the browsing terminal 5 of the facility by the dedicated program.

The analysis means 45 automatically detects the presence or absence of an arrhythmia event in the electrocardiogram data designated by the medical staff. The type of arrhythmia to be detected is not particularly limited, but diagnostic names include, for example, atrial fibrillation, ventricular tachycardia, ventricular fibrillation, paroxysmal supraventricular tachycardia, extrasystole, sinus tachycardia, and atrioventricular. Block, sinus dysfunction syndrome, etc. can be mentioned.

The automatic analysis of the presence or absence of an arrhythmia event can be executed by designing an algorithm according to the type of arrhythmia to be detected. Such an algorithm can have the same configuration as that conventionally installed and used in an information processing terminal such as a PC as an electrocardiogram automatic analysis program.

As described above, according to the present invention, the analysis means 45 makes it possible to browse all the electrocardiogram data of the subject, preferably on the cloud server, and further automatically analyze the arbitrary electrocardiogram data to improve the work efficiency of the medical staff. Not only will it improve, but it will also enable diagnostic support.

FIG. 4 is a flowchart showing the flow of processing in the electrocardiogram monitoring system 1 of the present embodiment from the portable electrocardiograph 2 to transmitting the electrocardiogram data to the server 4 via the transmission processing terminal 3.

In FIG. 4, in step S1, the portable electrocardiograph 2 acquires the electrocardiogram data of the subject and transmits it to the transmission processing terminal 3. Then, in the following step S2, the data storage means 31 stores the electrocardiogram data transmitted from the portable electrocardiograph 2.

The electrocardiogram data stored here is converted into electrocardiogram data for each predetermined unit time by the round slice data conversion means 32, and then stored in the transmission processing terminal 3 by the round slice data storage means 321 (step S3).

As step S4, the electrocardiogram data for each predetermined unit time is transmitted to the server 4 by the data transmitting means 33, and the receiving means 41 accepts this. As a result, the electrocardiogram data successfully transmitted to the server 4 is automatically deleted from the transmission processing terminal 3 by the transmission success data deleting means 34 (step S5).

On the other hand, the electrocardiogram data that has failed to be transmitted to the server 4 is repeatedly transmitted to the server 4 by the re-execution means 35 until the transmission to the server 4 is successful after a lapse of a predetermined time (step S6). ). The electrocardiogram data successfully transmitted to the server 4 by the re-execution means 35 is deleted from the transmission processing terminal 3 by the transmission success data deleting means 34.

FIG. 5 is a flowchart showing a processing flow from the transmission of the electrocardiogram data from the transmission processing terminal 3 to the server 4 in step S4 in FIG. 4 until the server 4 determines the success or failure of the transmission of the electrocardiogram data. ..

In step S41, the receiving means 41 of the server 4 receives the electrocardiogram data transmitted from the transmission processing terminal 3. Then, in step S42, the storage means 42 executes the storage process of the electrocardiogram data in the server 4.

The notification means 43 determines whether or not the electrocardiogram data has been successfully transmitted to the server 4 depending on whether or not the electrocardiogram data is stored in the server 4 by the storage means 42 within a certain time.

As a result, when the storage process is completed within a certain time, the notification means 43 determines that the normal reception of the electrocardiogram data has been completed, and holds the stored electrocardiogram data in the server 4. Then, as step S43, the notification means 43 notifies the transmission processing terminal 3 that the transmission of the electrocardiogram data has been successful. On the other hand, if the storage process is not completed within a certain time, the notification means 43 notifies the transmission processing terminal 3 that the transmission of the electrocardiogram data has failed.

When the transmission of the electrocardiogram data fails, the re-execution means 35 of the transmission processing terminal 3 executes the re-transmission processing of the electrocardiogram data whose transmission has failed after a predetermined time has elapsed from the notification, and the receiving means 41 , The electrocardiogram data reception process is performed again (step S41). When the transmission fails, the series of processes is repeatedly executed until the transmission of the electrocardiogram data is successfully completed.

The present invention can be applied to ECG monitoring of a subject in home medical care.

1 ECG monitoring system 2 Portable electrocardiograph 3 Transmission processing terminal 31 Data storage means 32 Round-cut data conversion means 321 Round-cut data storage means 33 Data transmission means 34 Transmission success data deletion means 35 Re-execution means 4 Server 41 Reception means 42 Storage means 43 Notification means 44 Transmission means 45 Analysis means 5 Browsing terminal NW In-hospital network

Claims (10)

A portable electrocardiograph that acquires the electrocardiogram data of the subject,
A transmission processing terminal that receives the electrocardiogram data from a portable electrocardiograph, and
A server for storing electrocardiogram data transmitted from the transmission processing terminal is provided.
The transmission processing terminal is an electrocardiogram monitoring system comprising a data transmission means for transmitting electrocardiogram data configured as data for each predetermined unit time to the server. The transmission processing terminal is characterized in that, when the electrocardiogram data is successfully transmitted to the server, the transmission processing terminal has a transmission success data deleting means for deleting the transmission success data stored in the transmission processing terminal. The electrocardiogram monitoring system described. When the transmission of the electrocardiogram data to the server fails, the transmission processing terminal has a re-execution means for re-transmitting the transmission failure data to the server after a lapse of a predetermined time, and the re-execution means The electrocardiogram monitoring system according to claim 1 or 2, wherein the transmission process is repeated until the transmission failure data is successfully transmitted to the server. The re-execution means according to claim 3, wherein the re-execution means transmits the electrocardiogram data accumulated until the transmission failure data to the server is successful together with the transmission failure data. ECG monitoring system. The electrocardiogram monitoring system according to any one of claims 1 to 4, wherein the transmission processing terminal includes a round slice data conversion means for converting the electrocardiogram data into electrocardiogram data at predetermined unit times. The electrocardiogram monitoring system according to any one of claims 1 to 5, wherein the predetermined unit time is in units of 1 minute to 6 hours. The electrocardiogram monitoring system according to any one of claims 1 to 6, wherein the transmission processing terminal converts the electrocardiogram data into DICOM format data and transmits the electrocardiogram data to a server. The electrocardiogram monitoring system according to any one of claims 1 to 7, wherein the server is a cloud server, and the cloud server analyzes the electrocardiogram data to detect irregular pulsations. .. The information acquisition process for acquiring the subject's electrocardiogram data with a portable electrocardiograph,
An information transmission process for transmitting the electrocardiogram data acquired by the portable electrocardiograph to a transmission processing terminal, and
A data transmission step of transmitting the electrocardiogram data received by the transmission processing terminal to a server is included.
The data transmission step is a method of operating an electrocardiogram monitoring system, which comprises transmitting electrocardiogram data configured as data for each predetermined unit time to the server. It is a transmission processing program for transmitting the electrocardiogram data of the subject acquired via the portable electrocardiograph to the server.
A transmission processing program characterized in that a computer functions as a data transmission means for transmitting the electrocardiogram data to the server as electrocardiogram data configured as data for each predetermined unit time.

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