KR102552577B1 - Apparatus for monitoring AI respiration patient - Google Patents

Abstract

Touch screen screen where input and display are made; EIT biometric data measurement unit for measuring EIT biometric data of a respiratory patient through electrical impedance tomography (EIT); a bio-biological data measurement unit for measuring bio-biometric data including electrocardiogram, body temperature, blood pressure, and oxygen/carbon dioxide saturation of a respiratory patient; and a control unit that synchronizes the measured EIT biometric data and the biometric biometric data in time and displays them together on the touch screen screen.

Description

AI respiratory patient monitoring device {Apparatus for monitoring AI respiration patient}

The present invention relates to an AI respiratory patient monitoring device, which monitors a respiratory patient having a respiratory disease such as Corona 19.

If the timing of the appearance of viruses expressing respiratory diseases is getting faster, an explosive increase in respiratory patients due to this can happen anytime from now.

The increase in respiratory patients requires special equipment and facilities such as ventilators, ECMO, and negative pressure wards. In addition, the higher the proportion of severely ill patients, the more experienced medical staff are needed. However, not only Korea but also the world lacks such special equipment and facilities, and the number of medical staff is also very insufficient.

If a respiratory patient has lung abnormalities, there is no other way to safely and continuously observe the lungs, which breathe 12 to 20 times per minute on average, except through EIT technology. However, the appearance of the lungs observed in EIT is a simple image, and it is up to the medical staff to judge by looking at it.

Observing the lungs of respiratory patients in real time through EIT technology is very important data, but ECG, body temperature, blood pressure, and oxygen/carbon dioxide saturation measured by basic monitoring equipment are also very important data. However, there is an inefficient problem in that each equipment cannot be interlocked and the medical staff has to check each equipment and check the patient's condition.

Korean Patent Registration No. 10-1132595

The technical problem of the present invention is to integrate several medical devices into one device to gather the dispersed biometric data into one device to enable accurate and fast customized treatment for respiratory patients through the latest medical AI technology.

An embodiment of the present invention is a touch screen screen made of input and display; EIT biometric data measurement unit for measuring EIT biometric data of a respiratory patient through electrical impedance tomography (EIT); a bio-biological data measurement unit for measuring bio-biometric data including electrocardiogram, body temperature, blood pressure, and oxygen/carbon dioxide saturation of a respiratory patient; and a control unit that synchronizes the measured EIT biometric data and the biometric biometric data in time and displays them together on the touch screen screen.

The control unit calculates patient treatment guide information including a ventilator parameter setting value, drug dosage, and drug administration timing of a respiratory patient based on the measured EIT biometric data and biometric data, and displays it on the touch screen screen. there is.

Calculating patient treatment guide information based on the measured EIT biometric data and biometric data can be displayed on the touch screen screen, characterized in that it is calculated through artificial intelligence learning analysis.

The AI respiratory patient monitoring device includes a main body provided with the touch screen screen, an EIT biometric data measurement unit, a bio biometric data measurement unit, and a control unit; a cradle supporting the main body and provided with an external battery and storage; A trolley supporting the cradle and capable of moving wheels may be included.

an alarm light provided on the top of the main body and notifying the patient's condition through color light emission; It may include a rotary provided at the lower end of the main body to receive numerical values or screen adjustments displayed on the touch screen screen.

The EIT biometric data measurement unit includes an EIT measurement cushion on which a person can lie down, and the EIT measurement cushion has a strip-shaped line groove, and an EIT sensor belt is attached to the bottom of the line groove. there is.

According to an embodiment of the present invention, based on biometric data obtained through EIT equipment and patient biometric data obtained through existing patient monitoring equipment, medical staff can help in patient treatment through AI technology.

In addition, according to an embodiment of the present invention, it can help to prepare more rapid and flexible countermeasures in the appearance of COVID-19 and respiratory disease outbreak viruses that may occur in the future.

In addition, according to an embodiment of the present invention, it is possible to help patients to be treated more quickly and accurately based on AI medical technology, thereby efficiently operating the insufficient number of hospital beds, medical equipment, and medical staff.

Current EIT equipment shows only real-time monitoring images of the lungs, but according to an embodiment of the present invention, the best treatment method can be suggested to medical staff by analyzing real-time measured images.

In addition, according to an embodiment of the present invention, biometric data required for treatment of a respiratory patient can be quickly observed on one screen.

In addition, according to an embodiment of the present invention, unnecessary trauma can be minimized in the process of receiving treatment while a patient is lying on a bed.

1 is a perspective view of an AI respiratory patient monitoring device according to an embodiment of the present invention.
Figure 2 is a block diagram of the configuration of the AI respiratory patient monitoring device according to an embodiment of the present invention.
3 is a perspective view of an EIT measurement cushion according to an embodiment of the present invention;

Hereinafter, embodiments according to the present invention will be described with reference to the accompanying drawings. In adding reference numerals to components of each drawing, it should be noted that the same components have the same numerals as much as possible even if they are displayed on different drawings. In addition, in describing an embodiment of the present invention, if it is determined that a detailed description of a related known configuration or function hinders understanding of the embodiment of the present invention, the detailed description will be omitted. In addition, embodiments of the present invention will be described below, but the technical idea of the present invention is not limited or limited thereto and can be modified and implemented in various ways by those skilled in the art.

1 is a perspective view of an AI respiratory patient monitoring device according to an embodiment of the present invention, Figure 2 is a block diagram of the AI respiratory patient monitoring device according to an embodiment of the present invention, Figure 3 is according to an embodiment of the present invention It is a perspective view of the EIT measurement cushion.

If there is existing patient monitoring equipment in the hospital, AI respiratory patient monitoring equipment can only use the function of measuring the patient's lungs with EIT. All biometric data of the patient that can be obtained are displayed together.

At this time, the present invention does not simply show each biometric data as one machine screen, but presents guidelines for the ventilator parameter setting values in the treatment of respiratory patients through AI based on each data, The amount of drug administered to the patient and the timing of administration can be guided to the medical staff.

To this end, the AI respiratory patient monitoring device according to an embodiment of the present invention, as shown in FIGS. The main body 100 equipped with the control unit 140, the cradle 200 supporting the main body 100 and having an external battery and storage cabinet, the trolley 300 supporting the cradle 200 and having wheels movable, , Includes an alarm light provided at the top of the main body 100 to inform the patient's condition through color light emission, and a rotary provided at the bottom of the main body 100 to receive numerical values displayed on the touch screen screen 110 or screen adjustment. can do. It will be detailed below.

The cradle 200 is a support that supports the main body 100 and is equipped with an external battery and a storage cabinet. The external battery provides driving power to the touch screen screen 110, the EIT bio data measurement unit 120, the bio bio data measurement unit 130, the control unit 140, and the like. In addition, the external battery can be interlocked with other equipment, and the storage cabinet can be implemented in various structural forms.

The trolley 300 is a means for supporting the cradle 200 and enabling wheel movement. The trolley 300 is used when movement is required according to the patient. If not used as a mobile type, the trolley 300 is not required and the cradle 200 may be fixedly attached to a place such as a pendant.

The main body 100 is implemented in a panel shape, and as shown, it is not limited to a rectangular panel shape and may have various shapes such as a circular panel, a triangular panel, and a pentagonal panel.

As shown in FIG. 2 , the main body 100 includes a touch screen screen 110, an EIT biometric data measuring unit 120, a bio-biometric data measuring unit 130, and a control unit 140.

The touch screen screen 110 is not only a screen display means, but also a screen on which input and display are performed by detecting a touch by a touch means such as a touch pen or a finger, and a graphical user interface (GUI; Graphic User Interface) for communication with a user. interface). Here, the work screen refers to various operation screens such as a standby screen, a picture screen, a video screen, an application screen, and a control screen. Therefore, when the measurement is made, patient information such as age, height, weight, and gender of the patient can be input through the touch screen screen 110 .

The bio-biometric data measuring unit 130 performs a function of measuring bio-biometric data including electrocardiogram, body temperature, blood pressure, and oxygen/carbon dioxide saturation of the respiratory patient. Accordingly, an electrocardiogram measurement sensor, an invasive/non-invasive body temperature measurement sensor, and an oxygen/carbon dioxide measurement sensor are connected and provided through a connection port on the back of the main body 100. For reference, in the case of measuring body temperature and blood pressure, both invasive and non-invasive measurement methods are possible, and it is possible to simultaneously measure vesicular saturation and carbon dioxide saturation, and only oxygen saturation sensor can be attached to the patient to monitor only oxygen saturation.

The EIT biometric data measuring unit 120 measures EIT biometric data of a respiratory patient through electrical impedance tomography (EIT).

As is known, EIT (Electrical Impedance Tomography) is a technique for generating EIT biometric data in the form of an image through electrical impedance tomography. To this end, the EIT biodata measuring unit 120 includes a plurality of electrodes for current injection and voltage sensing, and chest electrodes (EIT sensors) attached along the circumference of the chest of a respiratory patient to be measured.

Here, the chest electrode is formed with a plurality of electrodes for current injection and voltage sensing, and is attached along the circumference of the chest of a respiratory patient to be measured. The plurality of electrodes are at least one of simple electrodes and composite electrodes, and may be arranged on one surface of a base plate made of a flexible elastic material and attached to the chest. In addition, the plurality of electrodes may be EIT electrodes attached along the chest of a respiratory patient to measure impedance data for the inside of the lungs. The EIT electrode is used to inject a relatively low current that the respiratory patient cannot detect, for example, a high-frequency current of 1 mA or less and measure the induced voltage, and the current-voltage data measured through the EIT electrode is used for imaging the chest ( lungs) during obstruction, it can be used to detect structural changes that contribute to its shape and obstruction.

Therefore, the EIT biodata measuring unit 120 can image the inside of the chest from the impedance data by selectively supplying current to at least one selected electrode pair among the plurality of electrodes and measuring the voltage through the non-selected electrodes. there will be

To this end, the EIT biometric data measurement unit 120 may include a current injection module, a voltage measurement module (not shown), an image generation module (not shown), and an EIT control module (not shown).

The current injection module may inject currents having a plurality of frequency ranges through at least one selected electrode pair among a plurality of electrodes attached to the chest of a respiratory patient.

According to the embodiment, the current injection module selects a selected electrode pair and frequency, generates a voltage signal according to the selected frequency, converts it into a current, and injects the converted current into the chest of a respiratory patient through the selected electrode pairs. .

According to another embodiment, the current injection module converts the voltage signal into two currents with different phases, corrects the two currents so that the amplitude and frequency are the same, and sends the two currents calibrated to the chest of a respiratory patient through a selected electrode pair. can also be injected.

The voltage measurement module may measure an induced voltage according to a current injected from non-selected electrodes among a plurality of electrodes. For example, the voltage measurement module removes noise included in the detected voltage based on the slope of the measured voltage, and when the slope of the detected voltage exceeds a preset threshold, a section exceeding the threshold is detected. The voltage may be replaced with a preset voltage value.

The image generation module may image the inside of the chest by measuring impedance data from the chest based on the measured voltage. For example, the image generation module may obtain a voltage difference signal induced by an injected current through non-selected electrodes among a plurality of electrodes, and obtain impedance data according to the circumference of the chest of a respiratory patient and electrode positions. .

Thereafter, the image generation module may reconstruct the conductivity and permittivity images of the chest of the respiratory patient using the measured impedance data values to image the chest image. In detail, the image generation module may control sensitivity and resolution according to the position of the chest electrode by having a measurement protocol of a plurality of electrodes for imaging the chest of a respiratory patient. Using the measured values using these multiple measurement protocols or their combination and the sensitivity matrix improved from the 3D modeling image generated through the chest electrode, the conductivity and permittivity image of the chest of a respiratory patient, that is, the chest image, which is an impedance image can create

The EIT control module controls the selection of at least one or more electrode pairs from a plurality of electrodes, controls the selection of non-selected electrodes, and controls the selection of non-selected electrodes, based on the respiration parameter input from the respiration measurement unit 120, the global variable (global variable) can be controlled to be obtained. The EIT control module may control the current injection module to measure impedance data of the respiratory patient's chest.

The control unit 140 synchronizes the measured EIT biometric data and biometric data in time and displays them together on the touch screen screen 110 . Here, the time synchronization refers to synchronizing the measurement time periods of the EIT biometric data and the biometric data, which may have different measurement time periods, to be displayed on one screen.

In detail, in the case of electrocardiogram measurement, a method of measuring using 3 leads is selected, and when there is a problem with the patient's electrocardiogram, it is possible to measure the patient's electrocardiogram more precisely through the function of using 6 leads. However, the principle of electrocardiogram measurement and the principle of observing the patient's lungs through EIT technology are the same principle, and each measurement is not perfectly performed due to the close proximity of the action site. Therefore, when observing the patient's lungs simultaneously through 6-Leads ECG measurement and EIT technology, the ratio of the measured time is different based on 1 minute (Ex. ECG: EIT 2: 1 / min). In this way, it is possible to adjust the rate of lung observation and measure more ECGs when an abnormality is detected in the ECG of a respiratory patient by not affecting each sensor.

Furthermore, the control unit 140 calculates patient treatment guide information including the respiratory patient's ventilator parameter setting value, drug dosage, and drug administration timing based on the measured EIT biometric data and biometric data, and displays it on the touch screen screen. can be displayed Therefore, rather than simply showing each biometric data as one machine screen, based on each data, guidelines are presented for the ventilator parameter setting values in the treatment of respiratory patients through AI, and It will be possible to guide the medical staff on the amount of the drug and when to administer it.

Here, calculating the patient treatment guide information based on the EIT biometric data and the biometric data can be calculated using a pre-registered database (DB). Alternatively, patient treatment guide information can be calculated by applying EIT biometric data and biometric data to artificial intelligence learning analysis pre-learned by deep learning.

On the other hand, the AI respiratory patient monitoring device is provided at the top of the main body 100, an alarm light that informs the patient's condition through color light emission, and a numerical value displayed on the touch screen screen 110 provided at the bottom of the main body 100 A rotary for receiving an input of screen adjustment may be additionally provided. Therefore, the most critical alarms are displayed in red, and the next most critical alarms are displayed in orange and yellow. Also, in case of a general alarm, it can be warned in green.

On the other hand, in the case of medical devices that monitor the patient's lungs through currently produced EIT technology, the patient's skin is often injured due to the sensor belt attached to the patient's chest. In order to prevent such trauma to the patient, the present invention allows the patient to lie down on a cushioned back and create an empty space where the EIT sensor belt can pass. In addition, a separately made disposable adhesive bandage should be used so that the medical staff can attach such a cushiony assistive device to the patient's body if necessary.

To this end, the EIT biometric data measurement unit 120 includes an EIT measurement cushion on which a person can lie down, as shown in FIG. 3 . That is, the EIT measurement cushion is intended to prevent the EIT sensor belt of the EIT equipment from injuring the patient's skin, and is spread from the head to the patient's thigh to have a cushion feeling. Therefore, in the EIT measurement cushion, a strip-shaped line groove is formed, and the EIT sensor belt is attached to the bottom surface of the line groove. Here, the EIT sensor refers to the above-described chest electrode, and the EIT sensor belt is a belt in which chest electrodes are arranged and refers to a belt wrapped around the chest to measure the lungs of a respiratory patient when measuring EIT biometric data. This EIT sensor belt is connected behind the main body 100 .

As described above, the optimum embodiment has been disclosed in the drawings and specifications. Although specific terms have been used herein, they are only used for the purpose of describing the present invention and are not used to limit the scope of the present invention described in the claims. Therefore, those of ordinary skill in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical scope of protection of the present invention should be determined by the technical spirit of the appended claims.

110: touch screen screen
120: EIT biometric data measuring unit
130: bio biometric data measuring unit
140: control unit

Claims (6)

Touch screen screen where input and display are made;
EIT biometric data measurement unit for measuring EIT biometric data of a respiratory patient through electrical impedance tomography (EIT);
a bio-biological data measurement unit for measuring bio-biological data including electrocardiogram, body temperature, blood pressure, and oxygen/carbon dioxide saturation of a respiratory patient;
a control unit that time-synchronizes measured EIT biometric data and biometric data and displays them together on the touch screen;
a main body provided with the touch screen screen, EIT biometric data measuring unit, bio-biometric data measuring unit, and control unit;
a cradle supporting the main body and provided with an external battery and storage;
a trolley supporting the cradle and having wheels movable;
an alarm light provided on the top of the main body and notifying the patient's condition through color light emission;
A rotary provided at the bottom of the main body to receive numerical values displayed on a touch screen or screen adjustment;
The EIT biometric data measurement unit includes an EIT measurement cushion on which a person can lie down,
The EIT measurement cushion has a strip-shaped line groove, and an EIT sensor belt is attached to the bottom of the line groove,
The control unit calculates patient treatment guide information including a ventilator parameter setting value, drug dosage, and drug administration timing of a respiratory patient based on the measured EIT biometric data and biometric data, and displays it on the touch screen screen,
Calculating patient treatment guide information based on the measured EIT biometric data and biometric data is an AI respiratory patient monitoring device that is calculated through artificial intelligence learning analysis. delete delete delete delete delete

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