CN211796425U - Device and system for synchronously monitoring dynamic body temperature and dynamic electrocardiogram - Google Patents

Abstract

The utility model discloses a device of synchronous monitoring developments body temperature and developments heart electrograph, its including first electrode and the second electrode that is used for measuring the heart electrograph, be used for measuring human skin surface temperature's temperature sensor, wherein first electrode with temperature sensor assembles together, the second electrode through the wire with first electrode is connected. The utility model discloses the size is small and exquisite, and portable is fit for wearing for a long time to thereby be applicable to internet of things and be favorable to implementing long-range physiology index monitoring.

Description

Device and system for synchronously monitoring dynamic body temperature and dynamic electrocardiogram

Technical Field

The utility model belongs to the field of medical equipment, concretely relates to synchronous monitoring developments body temperature and dynamic electrocardiogram's device especially relates to a portable body temperature and an electrocardiogram synchronous monitoring device and a synchronous monitoring developments body temperature and dynamic electrocardiogram's system based on thing networking.

Background

Many infectious diseases and acute infections such as novel coronavirus pneumonia COVID-19, SARS (atypical pneumonia), avian influenza, influenza A and the like are easy to cause a large number of infected people, especially infected people with basic diseases such as hypertension, diabetes, coronary heart disease and the like, can cause myocardial damage, malignant arrhythmia and even endanger life. Fever is one of the important clinical manifestations of most infections, which can be detected early by body temperature monitoring; while malignant arrhythmia can be detected early by electrocardiographic monitoring. Therefore, in the process of isolating and observing infection and epidemic situation, the body temperature and the change of electrocardiogram are urgently needed to be monitored synchronously.

The body temperature and the electrocardiogram change are dynamically, synchronously and continuously monitored, the physiological correlation between the electrocardiogram signal and the temperature signal is found, the fever condition of a potential infected patient and the malignant arrhythmia dangerous event in the infection process are found as soon as possible, the success rate of diagnosing and rescuing the malignant arrhythmia in the acute infection process is improved, and the death rate of the malignant arrhythmia is reduced.

However, the conventional dynamic body temperature monitoring device and the dynamic electrocardiogram monitoring device are both devices which are used independently and are separated from each other, and no dynamic synchronous body temperature and electrocardiogram monitoring device which integrates the dynamic body temperature monitoring device and the dynamic electrocardiogram monitoring device is reported. The existing dynamic body temperature monitoring device comprises: a body temperature test patch (a battery, a temperature sensor, an MCU and an ISM communication module) and a handheld terminal. Through pasting body temperature test paster in patient's body surface, the temperature-sensing ware passes through ISM communication module wireless transmission with data to handheld terminal after the start. There is a portable electrocardiogram measuring system such as one disclosed in patent document CN201611079081.4, which includes a measuring device including a first electrode group having at least one electrode and a second electrode group having at least two electrodes, and stores unique ID information, and a mobile terminal. Because the second electrode group in the portable electrocardiogram measuring system disclosed in CN201611079081.4 has at least two electrodes, which are in contact with two fingers of a user and simultaneously collect the electrocardiographic potentials of the two fingers, when data collected by one electrode in the group of electrodes has fluctuation and error, the error signal is processed by the common mode suppression circuit in the processing and transmission unit, so as to effectively filter out the interference signal; the electrocardiogram data is transmitted to the mobile terminal in a wireless mode. But the electrocardiograph device does not have an integrated temperature sensor. The measurement precision of the infrared sensor is lower than that of the thermosensitive sensor. The thermosensitive sensor needs to be attached to the surface of human skin, and is difficult to realize, and the problem that the sensor does not correspond to the temperature gradient of the human body exists.

On the other hand, the body temperature and the heart function of the infectious disease patient or the epidemic situation isolator can change along with the progress of the disease course and the treatment time, and a doctor can generally adjust the treatment scheme according to the treatment course, so that the body temperature and electrocardiogram synchronous monitoring device is necessary to be combined with the internet of things technology, so that the doctor can monitor the disease course and the rehabilitation effect of the patient or the epidemic situation isolator in real time, the patient and family members thereof can also receive the treatment result and the adjustment of the treatment scheme in time, timely feedback and further treatment guidance are obtained from the doctor, and accurate medical treatment is implemented for the patient or the epidemic situation isolator.

SUMMERY OF THE UTILITY MODEL

In order to overcome the defects that the conventional dynamic body temperature monitoring device and the conventional dynamic electrocardiogram monitoring device are mutually independent in use, are mutually separated in space, are complex and inconvenient to operate and are difficult to realize synchronous dynamic monitoring, the dynamic body temperature monitoring device and the dynamic electrocardiogram monitoring device are skillfully combined, and a brand-new intelligent monitoring device for synchronously monitoring the dynamic body temperature and the dynamic electrocardiogram is designed and manufactured. Particularly, the utility model comprises the following technical scheme.

A device for synchronously monitoring dynamic body temperature and dynamic electrocardiogram comprises a first electrode and a second electrode for measuring electrocardiogram and a temperature sensor for measuring the surface temperature of human skin, wherein the first electrode is assembled with the temperature sensor, and the second electrode is connected with the first electrode through a lead.

The first electrode and the second electrode form an electrocardiosignal sensor, and are connected with a data concurrency processor together with the temperature sensor.

The first electrode is preferably a shell, and the first electrode internally comprises an electrocardiosignal collector, a temperature signal collector, a data concurrency processor, a communication module and a power supply module. The electrocardiogram signal collector, the data concurrent processor and the communication module can be the existing functional circuit in the existing electrocardiograph. The temperature signal collector, the data concurrent processor and the communication module can be the existing functional circuit in the existing thermodetector. The method for acquiring and processing the electrocardiosignals by the electrocardiosignal acquisition device and the method for acquiring and processing the temperature signals by the temperature signal acquisition device can adopt the conventional methods.

The temperature sensor (or called temperature signal sensor, temperature sensor, heat-sensitive sensor) comprises a temperature sensing probe and a telescopic lead, and the temperature sensor extends out of the first electrode shell through the telescopic lead.

Preferably, the temperature sensor protrudes from a surface (i.e., a front surface) of the first electrode case on the electrode pad side; or from the surface (i.e., the back) of the first electrode case on the side opposite to the electrode sheet; or from the side of the first electrode housing.

Alternatively, the temperature sensing probe of the temperature sensor may be fixed on the surface of the first electrode shell on one side of the electrode plate in a planar manner. For example, the temperature sensing probe can be annular hoop cover and fix at the casing surface in electrode slice periphery, and this kind of structure makes temperature sensor and first electrode integrate into the whole that a shape is fixed, uses and operates the utility model discloses the time is more convenient, swift.

In order to be attached to the surface of a human body for long-time body temperature and electrocardiogram monitoring, the first electrode is generally a flat shell and can be square or round, and the electrode plate can be a traditional round metal sheet; the second electrode may be generally square or circular and the electrode sheet may be a conventional circular metal sheet. One end of a lead connecting the second electrode and the first electrode can be fixed on the second electrode, and the other end can be inserted on the first electrode through a joint or fixed on the first electrode.

When the temperature sensor is used, the probe of the temperature sensor and the electrode plate of the first electrode are jointly positioned on the surface of the skin of the human body covered by the electrode patch, or the probe of the temperature sensor is fixed on the surface of the skin of the human body separately without being covered by the electrode patch.

In one embodiment, the first electrode and the temperature sensor can be attached to the left axilla (the second intercostal level of the axillary midline) of a patient or an epidemic person by a medical electrocardiogram electrode patch, and the second electrode is attached to the fourth intercostal of the left edge of the sternum by the medical electrocardiogram electrode patch.

The communication module in the first electrode is used for communication (communication) connection with a mobile terminal such as a mobile phone or a portable computer, and/or for communication connection with a cloud platform data management center, or for communication with a traditional electrocardiograph). In this case, the device for synchronously monitoring the dynamic body temperature and the dynamic electrocardiogram can be called a "host unit" or a "host", and is a portable electronic device.

When combined with a mobile terminal, such as a mobile phone or a portable computer, a second aspect of the present invention provides a portable temperature and electrocardiogram synchronous measurement system.

As another alternative, the communication module may include a data connection interface, including but not limited to a standard USB interface, a micro USB interface, a USB type-C interface, a Lightning interface, and an earphone interface, for connecting with the mobile terminal through a wire (data exchange line) or connecting with the electrocardiograph, so as to upload the body temperature and electrocardiograph data to the mobile terminal or the electrocardiograph.

Preferably, the communication module is a bluetooth communication module, and is configured to wirelessly transmit the body temperature and the electrocardiogram data to the outside through the bluetooth communication module.

The mobile terminal can be a mobile phone or a portable computer such as an iPad.

The power module in the first electrode may be a rechargeable power supply or a button cell, preferably a rechargeable power supply. The power module is used for providing power for the host unit, can be a storage battery such as a lithium secondary battery, and can be charged through a wire interface.

Optionally, the communication module further includes an internet connection port for uploading data via bluetooth, so that the device for synchronously monitoring the dynamic body temperature and the dynamic electrocardiogram is suitable for an internet of things system.

Based on internet of things, the utility model discloses a second aspect provides a system of synchronous monitoring dynamic body temperature and dynamic electrocardiogram, and it includes foretell synchronous monitoring dynamic body temperature and dynamic electrocardiogram's device, but also includes cloud platform data management center, user app and doctor app, communicates through wiFi/cellular network between them.

The utility model discloses according to body temperature and heart electrograph check out test set's medical standard method, on portable developments heart electrograph monitoring devices is like the basis of the portable heart electrograph measurement system that CN201611079081.4 discloses, loading temperature sensor realizes dynamic body temperature and the synchronous data acquisition function of developments heart electrograph to through bluetooth wireless transmission data to mobile terminal, finally reach user dynamic synchronization monitoring body temperature and heart electrograph by oneself. The utility model discloses the size is small and exquisite, and portable is fit for wearing for a long time. Through inciting somebody to action the utility model discloses a synchronous monitoring developments body temperature and developments heart electrograph's device combines with internet of things, is favorable to realizing accurate medical treatment for hospital and patient or epidemic situation isolation person family members can long-range participation and trail patient or epidemic situation isolation person's course of illness and treatment process.

Drawings

Fig. 1 is a schematic structural diagram of a front surface (a surface on which an electrode sheet is located) of an embodiment of the present invention, in which a temperature sensor extends from the front surface of a first electrode.

Fig. 2 is a schematic structural diagram of a front surface (a surface on which an electrode sheet is located) of another embodiment of the present invention, wherein a temperature sensing probe in a temperature sensor is fixed on a front surface of a first electrode in a planar manner.

Fig. 3 is a rear view of the embodiment of fig. 1 in use.

Fig. 4 is a schematic diagram illustrating the connection relationship of the main modules of the present invention.

Fig. 5 is a work flow diagram showing an embodiment of the present invention.

Fig. 6 is a flowchart showing the operation of an embodiment of the internet of things of the present invention.

Detailed Description

The technical solution of the present invention will be described below with reference to the accompanying drawings. It is to be understood that the described embodiments are merely a few embodiments and not all embodiments of the present application; and the structural and logical relationships shown in the drawings are merely schematic and do not represent physical objects. It should be noted that all other embodiments obtained by those skilled in the art based on the embodiments of the present invention belong to the protection scope of the present application.

The utility model discloses according to body temperature and heart electrograph check out test set's medical standard method, on portable developments heart electrograph monitoring devices's basis, loading temperature sensor realizes dynamic body temperature and the synchronous data acquisition function of developments heart electrograph to through bluetooth wireless transmission data to mobile terminal, finally reach user's dynamic synchronization monitoring body temperature and heart electrograph by oneself.

On the other hand, the development of the internet of things technology is complied with, the dynamic body temperature and dynamic electrocardiogram synchronous monitoring device can be applied to medical treatment of the internet of things, a dynamic body temperature and dynamic electrocardiogram synchronous monitoring system based on the internet of things is established, a doctor is helped to remotely monitor physiological indexes of a patient or an epidemic situation isolator, a treatment scheme of the patient is perfected, and accurate medical treatment is realized; the system can help family members of patients to know the course of disease at any time, guarantee the right of knowledge of the family members of the patients or epidemic situation isolators, and reduce medical disputes so as to guarantee social harmony.

The utility model discloses a portable dynamic body temperature and dynamic electrocardiogram synchronous monitoring system can realize long-range dynamic body temperature and dynamic electrocardiogram synchronous data acquisition to the automatic monitoring mode outside the institute to through wireless transmission to high in the clouds server or mobile terminal, finally realize that the automatic dynamic synchronous monitoring body temperature and the heart electrograph change in infecting, epidemic situation isolation observation process, discover potential infection patient's the condition of generating heat and the malignant arrhythmia danger event of infection process early.

For the sake of convenience of description, the "device for synchronously monitoring body temperature and electrocardiography" is sometimes referred to herein simply as "synchronous body temperature and electrocardiography monitoring device", "host unit" or "host", which are used interchangeably, to mean the same.

For simplicity of description, the "system for simultaneously monitoring dynamic body temperature and electrocardiogram (ecg)" is sometimes referred to herein simply as "internet of things system" or "system", which are used interchangeably in the same sense.

In this context, the term "connected" includes electrical and/or communication, fixed and/or movable connections. One skilled in the art can determine whether to electrically or communicatively couple, fixedly couple, or movably couple, depending on the context of use of the term. When "connected" means communicatively connected (i.e., communicatively connected), it includes wired connections and wireless connections.

Referring to fig. 1, fig. 2, fig. 3 and fig. 4, the device 100 for synchronously monitoring dynamic body temperature and dynamic electrocardiogram provided by the present invention mainly comprises a first electrode 1 and a second electrode 2 for measuring electrocardiogram, and a temperature sensor 3 for measuring the skin surface temperature of a human body. Fig. 1 is a schematic view of the front surfaces (surfaces on which the electrode pads 18 and 28 are located) of the first electrode 1 and the second electrode 2, and fig. 2 is a rear surface view in use. Wherein the first electrode 1 is assembled with the temperature sensor 3; the second electrode 2 is connected to the first electrode 1 by a wire 4. The first electrode and the second electrode form an electrocardiosignal sensor 10, and are connected with a data concurrency processor 13 together with the temperature sensor 3. Each of them is specifically described below.

A first electrode 1 and a second electrode 2

The first electrode 1 and the second electrode 2 may be collectively referred to as an "electrocardiographic signal sensor 10", wherein the first electrode 1 may be a casing, and in order to facilitate long-term attachment to a surface of a human body for monitoring body temperature and electrocardiogram, the first electrode 1 is a substantially flat casing, and may be a square casing as shown in fig. 1 to 3, or a circular casing or other shapes, and the electrode sheet 18 may be a conventional circular metal sheet. The second electrode 2 may be generally square or circular and the electrode pad 28 may be a conventional circular metal pad. The lead 4 connecting the second electrode 2 and the first electrode 1 may have one end fixed to the second electrode 2 and the other end insertable to the first electrode 1 through the connector 41 or fixed to the first electrode 1.

The material of the casing of the first electrode 1 may be a polymer material such as engineering plastic. The first electrode 1 mainly comprises the following components in the shell: an electrocardiosignal collector 11 for collecting and processing the electrocardiosignals obtained from the electrocardiosignal sensor 10; a temperature signal collector 12 for collecting and processing a temperature signal obtained from the temperature sensor 3; a data concurrency processor 13, or host chip 13, for processing the digital information transmitted from the electrocardiosignal collector 11 and the temperature signal collector 12; a communication module 14 for transmitting the information transmitted from the data concurrent processor 13 to the outside; and the power supply module 15 is used for supplying electric energy to the dynamic body temperature and dynamic electrocardiogram synchronous monitoring device 100.

The electrocardiographic signal acquisition unit 11, the data concurrency processor 13 and the communication module 14 are all functional circuits existing in the conventional electrocardiograph. The temperature signal collector 12, the data concurrency processor 13 and the communication module 14 may also be the existing functional circuit in the existing temperature measuring instrument. The method for acquiring and processing the electrocardiosignals by the electrocardiosignal acquirer 11 and the method for acquiring and processing the temperature signals by the temperature signal acquirer 12 can adopt the conventional methods.

It is to be noted that the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

For example, the first electrode 1 may further include a signal amplifier, a power switch, an indicator light, a buzzer, a wire reel, and other electronic and mechanical components, which are not shown.

Temperature sensor 3

The temperature sensor 3, which may also be referred to as a temperature signal sensor 3, a temperature sensor 3, a heat-sensitive sensor 3, etc., includes a temperature sensing probe 31 of small volume and a retractable wire 32, through which the temperature sensor 3 extends out of the housing of the first electrode 1.

The temperature sensor 3 may protrude from the surface (i.e., the front surface) of the first electrode 1 on the side of the electrode sheet 18 on the casing, as shown in fig. 1 and 3; or may protrude from the surface (i.e., the back surface) of the casing of the first electrode 1 opposite to the electrode sheet 18; but also from the side of the housing of the first electrode 1. Preferably, the surface of the temperature sensing probe 31 is made of a flexible material to avoid causing skin discomfort.

The first electrode 1 and the temperature sensor 3 are assembled together, so that the size of the dynamic body temperature and dynamic electrocardiogram synchronous monitoring device 100 can be remarkably reduced, discomfort of a wearer caused by hanging and winding underwear on the electric wires and the parts when the parts are placed respectively is avoided, and the dynamic body temperature and dynamic electrocardiogram synchronous monitoring device is suitable for being worn for a long time.

When the dynamic body temperature and dynamic electrocardiogram synchronous monitoring device 100 is used, the probe 31 of the temperature sensor 3 and the electrode sheet 18 of the first electrode 1 can be co-located on the skin surface of the human body covered by the electrode patch 5, as shown in fig. 3; the probe 31 of the temperature sensor 3 may not be covered by the electrode patch 5, but may be separately fixed to the skin surface of the human body, for example, by adhering the probe 31 to the skin surface of the human body with an adhesive tape.

As another alternative, the temperature sensing probe 31 of the temperature sensor 3 may be fixed on the surface of the first electrode 1 on the side of the electrode sheet 18 in a flat manner. For example, the temperature sensing probe 31 may be in the form of an annular hoop that is sleeved around the electrode sheet 18 and fixed on the surface of the casing, as shown in fig. 2. This structure makes the temperature sensor 3 and the first electrode 1 integrated into a fixed shape, and is more convenient and faster to use and operate the electrocardiographic synchronous monitoring device 100.

In one mode of use, when the device 100 for monitoring body temperature and electrocardiogram data is used, the first electrode 1 and the temperature sensor 3 can be attached to the left underarm (the second level between the axillary midline and the rib) of a patient or an epidemic isolation person through the medical electrocardiogram electrode patch 5, and the second electrode 2 can be attached to the fourth rib between the left edge and the fourth rib of the sternum through the medical electrocardiogram electrode patch 5.

Communication module 14

The communication module 14 in the first electrode 1 is used for communication connection with a mobile terminal 6 such as a mobile phone 6 or a portable computer 6; or is used for communication connection with the cloud platform data management center 7; for communicative connection with a conventional electrocardiograph (not shown). In this case, the device 100 for synchronously monitoring the dynamic body temperature and the dynamic electrocardiogram may be referred to as a "host unit 100" or a "host 100", and is a portable electronic device.

As another alternative, the communication module 14 may include a data connection interface, including but not limited to a standard USB interface, a micro USB interface, a USB type-C interface, a Lightning interface, and an earphone interface, for connecting with the mobile terminal 6 through a wire (data exchange line) or with an electrocardiograph (not shown) in order to upload the body temperature and electrocardiograph data to the mobile terminal 6 or with the electrocardiograph.

The communication module 14 may be a bluetooth communication module, and is used for wirelessly transmitting the body temperature and the electrocardiogram data to the outside through the bluetooth communication module.

Optionally, the communication module 14 may further include an internet connection port for uploading data via bluetooth, so that the ambulatory body temperature and ambulatory electrocardiogram synchronous monitoring device 100 is suitable for an internet of things system.

Power supply module 15

The power module 15 in the first electrode 1 may be a rechargeable power supply or a button cell, preferably a rechargeable power supply. The power module 15 is used to provide power to the host unit 100, and may be a storage battery such as a lithium secondary battery, which may be charged through a wire interface (not shown).

Portable temperature and electrocardiogram synchronous measurement system 101

When the dynamic body temperature and dynamic electrocardiogram synchronous monitoring device 100 is combined with the mobile terminal 6, such as the mobile phone 6 or the portable computer 6, a portable temperature and electrocardiogram synchronous measuring system 101 is formed, which comprises the host unit 100 and the mobile terminal 6. Fig. 5 shows a structural mode and a work flow chart of a portable temperature and electrocardiogram synchronous measurement system 101.

Internet of things system 102 for synchronously monitoring dynamic body temperature and dynamic electrocardiogram

The utility model discloses a developments body temperature and developments heart electrograph synchronous monitoring device 100 still is applicable to internet of things. Fig. 6 shows the structural mode and the work flow diagram of an internet of things system 102 for synchronously monitoring dynamic body temperature and dynamic electrocardiogram, which includes a host unit 100, a cloud platform data management center 7, a user app 6 and a doctor app 8, which communicate with each other through a WiFi/cellular network.

The internet of things system 102 can help the doctor 8 to remotely monitor physiological indexes of the patient or the epidemic situation isolater, improve the treatment scheme of the patient and realize accurate medical treatment; the family members 6 of the patients can be helped to know the course of the disease at any time, the right of knowledge of the patients or the family members of the epidemic situation isolators is guaranteed, the body temperature and the electrocardiogram change are automatically and dynamically and synchronously monitored in the infection and epidemic situation isolation observation processes, the fever condition of the potential infected patients and the malignant arrhythmia dangerous events in the infection process are discovered as soon as possible, and the medical disputes are reduced, so that the social harmony is guaranteed.

Use examples

When the portable temperature and electrocardiogram synchronous measurement system 101 is used, the following steps can be performed:

1. the first electrode 1 and the second electrode 2 are connected together by a lead 4, the first electrode 1 is attached to the left armpit (the second level between the axillary midline) of the patient by a medical electrocardiogram electrode patch 5, and the second electrode 2 is attached to the fourth intercostal of the left edge of the sternum;

2. open host computer 100 switch on first electrode 1, then open APP software and bluetooth in the mobile terminal 6, treat APP display device 6 and connect after successful, click the collection key, carry out long-range developments body temperature and heart electrograph synchronous monitoring.

3. And (3) displaying data: collecting and storing electrocardiogram data at a fixed frequency of 200Hz, and displaying the data in real time; the body temperature data is collected and stored at the frequency of 1Hz, and the body temperature data is displayed at intervals of 10 minutes after the start-up measurement is carried out for 20 minutes until the temperature measurement is stable.

The above embodiments are only used to illustrate the technical solutions of the present invention, and not to limit the same. Those of ordinary skill in the art will understand that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the present invention in its essence.

Claims (10)

1. The device for synchronously monitoring the dynamic body temperature and the dynamic electrocardiogram is characterized by comprising a first electrode and a second electrode for measuring the electrocardiogram and a temperature sensor for measuring the surface temperature of the skin of a human body, wherein the first electrode is assembled with the temperature sensor, and the second electrode is connected with the first electrode through a lead.

2. The device of claim 1, wherein the first electrode is a shell, and comprises an electrocardiosignal collector, a temperature signal collector, a data concurrency processor, a communication module and a power module inside the shell.

3. The device of claim 2, wherein the temperature sensor comprises a temperature sensing probe and a retractable wire, the temperature sensor being retractable out of the first electrode housing through the wire; or the temperature sensing probe is fixed on the surface of one side of the electrode plate on the first electrode shell in a plane.

4. The device of claim 1, wherein the temperature sensor extends from a surface of the first electrode casing on a side of the electrode pad, or from a surface of the first electrode casing on a side opposite the electrode pad, or from a side of the first electrode casing.

5. The apparatus of claim 2, further comprising a communication module configured to communicatively couple with a mobile terminal or a cloud platform data management center.

6. The device of claim 5, wherein the communication module comprises a data connection interface for connecting with a mobile terminal through a wire or with an electrocardiograph.

7. The apparatus of claim 5, wherein the mobile terminal is a mobile phone or a laptop.

8. The apparatus of claim 2, wherein the power module is a rechargeable power source or a button cell.

9. The device of claim 5, wherein the communication module further comprises an internet connection port for data uploading, so that the device for synchronously monitoring the ambulatory body temperature and the ambulatory electrocardiogram is suitable for an internet of things system.

10. A system for synchronously monitoring dynamic body temperature and dynamic electrocardiogram, which comprises the device for synchronously monitoring dynamic body temperature and dynamic electrocardiogram according to any one of claims 1-9, and further comprises a cloud platform data management center, a user app and a doctor app, which communicate with each other through a WiFi/cellular network.

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