KR102567385B1 - Apparatus and method for monitoring anesthesia and sleep based on brainwave - Google Patents

Abstract

It relates to an EEG-based anesthesia and sleep monitoring device and method capable of monitoring the patient's anesthesia depth and sleep phase based on the patient's EEG signal, an EEG measuring unit for measuring the patient's EEG signal, based on the measured EEG signal anesthesia and sleep information generation unit for generating anesthesia depth information and sleep stage information of the patient, a user input unit for requesting generation of the anesthesia depth information or sleep stage information, and a control unit for controlling the anesthesia and sleep information generation unit. wherein the control unit controls the anesthesia and sleep information generation unit to generate depth of anesthesia information of the patient when generation of the anesthesia depth information is requested from the user input unit, and when generation of the sleep stage information is requested from the user input unit The artificial respiration environment of the patient may be adjusted based on the generated sleep stage information by controlling the anesthesia and sleep information generator to generate the sleep stage information.

Description

EEG-based anesthesia and sleep monitoring device and method {APPARATUS AND METHOD FOR MONITORING ANESTHESIA AND SLEEP BASED ON BRAINWAVE}

The present invention relates to an anesthesia and sleep monitoring device, and more particularly, to an EEG-based anesthesia and sleep monitoring device and method capable of monitoring a patient's anesthesia depth and sleep stage based on the patient's EEG signal.

In general, when medical activities such as surgery and treatment are performed, it is important for the patient to properly maintain the patient's anesthesia and depth of consciousness.

This is because if the anesthesia is shallow, you may wake up during surgery and suffer from pain, and if the anesthesia is too deep, you may have a heart attack, complications, or death.

In particular, it is a bigger problem that the patient cannot properly express his/her intention even if breathing is difficult during the procedure after anesthesia.

Accidents caused by such anesthesia can happen to an unspecified number of people unexpectedly, and can lead to the death of a patient immediately, so prevention is the best option.

In order to prevent such an accident, it is necessary to quantitatively evaluate anesthesia and depth of consciousness. However, the current depth of anesthesia is determined by the experience and knowledge of anesthesiologists and pain medicine clinicians who control the concentration of anesthetic solution by grasping the patient's condition. .

Therefore, a device capable of objectively measuring the depth of anesthesia is required.

In addition, when a patient has a sleep disorder, a sleep monitoring device for monitoring the patient's sleep state is required.

By monitoring the patient's sleep state through the sleep monitoring device, ventilation efficiency of the lungs may be improved by injecting air into the patient through a ventilator.

However, existing monitoring devices measure the patient's depth of anesthesia and sleep stage by independently calculating the depth of anesthesia and sleep stage of the patient. provided.

Therefore, in the future, it is possible to simultaneously measure the patient's depth of anesthesia and sleep stage based on the patient's brain wave signal without unnecessary equipment replacement, and by adjusting the patient's artificial respiration environment corresponding to the measured depth of anesthesia and sleep stage, the patient Development of an anesthesia and sleep monitoring device capable of providing an optimal artificial respiration environment is required.

Republic of Korea Patent Registration No. 10-1079785 (October 28, 2011)

A technical problem to be achieved by an embodiment of the present invention is to measure the patient's depth of anesthesia and sleep stage together based on the patient's brain wave signal and adjust the patient's artificial respiration environment corresponding to the patient's depth of anesthesia and sleep stage. Its purpose is to provide an anesthesia and sleep monitoring device and method that can provide an optimal artificial respiration environment.

In addition, the present invention selectively measures the depth of anesthesia and the sleep stage of the patient based on the patient's brain wave signal through the user input unit or the acquired location information according to the location, so that it is convenient without replacing the equipment for measuring the depth of anesthesia and the sleep stage. An object of the present invention is to provide an anesthesia and sleep monitoring device and method capable of reducing measurement time and providing user convenience.

The technical problems to be achieved in the present invention are not limited to the technical problems mentioned above, and other technical problems not mentioned will be clearly understood by those skilled in the art from the description below. You will be able to.

In order to solve the above technical problem, an anesthesia and sleep monitoring device according to an embodiment of the present invention includes an EEG measurement unit for measuring an EEG signal of a patient, and depth of anesthesia information of the patient based on the measured EEG signal. and an anesthesia and sleep information generating unit generating sleep stage information, a user input unit receiving input from a user to generate the anesthesia depth information or the sleep stage information, and a control unit controlling the anesthesia and sleep information generating unit, wherein the controller controls the anesthesia and sleep information generation unit to generate anesthesia depth information of the patient when the generation of anesthesia depth information is input from the user input unit, and generates the sleep stage information when generation of the sleep stage information is input from the user input unit The anesthesia and sleep information generator controls the anesthesia and sleep information generation unit to generate, and then stores the parameter value of the mixed gas of the patient corresponding to any one of the anesthesia depth information and sleep stage information generated by the anesthesia and sleep information generation unit in the memory unit. The artificial respiration environment of the patient may be adjusted based on the extracted parameter value of the mixed gas of the patient.

In an alternative embodiment of the anesthesia and sleep monitoring device, the user input unit may include a first user input button for receiving generation of the anesthesia depth information, and a second user input button for receiving generation of the sleep stage information. can

In an alternative embodiment of the anesthesia and sleep monitoring device, the control unit, when the anesthesia depth information and the patient's sleep stage information are generated from the anesthesia and sleep information generation unit, the generated patient's anesthesia depth information and the The patient's sleep stage information may be displayed on the display screen.

In an alternative embodiment of the anesthesia and sleep monitoring device, the control unit, when the patient's sleep stage information is generated from the anesthesia and sleep information generator, the artificial respiration environment of the patient based on the generated patient's sleep stage information can be adjusted.

In an alternative embodiment of the anesthesia and sleep monitoring device, the control unit, when adjusting the patient's artificial respiration environment, based on the patient's sleep stage information, the flow rate and pressure of the mixed gas of air and oxygen supplied to the patient , It is possible to control the artificial respiration environment of the patient by controlling at least one parameter of the volume.

In an alternative embodiment of the anesthesia and sleep monitoring device, the control unit may generate alarm information when the patient's sleep stage information generated by the anesthesia and sleep information generation unit is a wakeup stage.

In particular, in an alternative embodiment of the anesthesia and sleep monitoring device, the device further includes a location information module for acquiring current location information, wherein the control unit is configured to obtain depth of anesthesia information and The anesthesia and sleep information generator may be controlled to selectively generate sleep stage information.

In an alternative embodiment of the anesthesia and sleep monitoring device, the control unit controls the anesthesia and sleep information generation unit to generate depth of anesthesia information of the patient if the current location is an operating room, and the sleep information if the current location is an intensive care unit. The anesthesia and sleep information generation unit may be controlled to generate step information.

Meanwhile, a method for monitoring anesthesia and sleep according to an embodiment of the present invention includes the steps of confirming whether information input through a user input unit is an anesthesia depth information generation request or a sleep stage information generation request; controlling, by the controller, the anesthesia and sleep information generation unit to generate depth of anesthesia information of the patient based on the brain wave signal of the patient when the information input through the user input unit is a request for generating depth of anesthesia information; controlling, by the controller, the anesthesia and sleep information generation unit to generate sleep stage information of the patient based on the brain wave signal of the patient, if the information input through the user input unit is the request for generating the sleep stage information; The control unit extracts, from a data table stored in the memory unit, a parameter value of the gas mixture of the patient corresponding to any one of the depth of anesthesia information and the sleep stage information generated by the anesthesia and sleep information generation unit, and extracts the Adjusting the artificial respiration environment of the patient based on the parameter value of the mixed gas of the patient, wherein the control unit controls the patient according to the current location information obtained from the location information module of the anesthesia and sleep monitoring device. Controlling the anesthesia and sleep information generator to selectively generate depth of anesthesia information and sleep stage information of Controlling the anesthesia and sleep information generating unit; If the current location is in an intensive care unit, the control unit controlling the anesthesia and sleep information generating unit to generate the sleep stage information; may further include.

The effects of the anesthesia and sleep monitoring apparatus and method according to the present invention are described as follows.

The present invention provides an optimal artificial respiration environment for the patient by measuring the patient's depth of anesthesia and sleep stage together based on the patient's brain wave signal and adjusting the patient's artificial respiration environment corresponding to the patient's depth of anesthesia and sleep stage. can do.

In addition, the present invention selectively measures the depth of anesthesia and the sleep stage of the patient based on the patient's brain wave signal through the user input unit or the acquired location information according to the location, so that it is convenient without replacing the equipment for measuring the depth of anesthesia and the sleep stage. Measurement time can be shortened and user convenience can be provided.

A further scope of the applicability of the present invention will become apparent from the detailed description that follows. However, since various changes and modifications within the spirit and scope of the present invention can be clearly understood by those skilled in the art, it should be understood that the detailed description and specific examples such as preferred embodiments of the present invention are given as examples only.

1 is a block diagram illustrating an anesthesia and sleep monitoring device according to an embodiment of the present invention.
FIG. 2 is a block diagram illustrating the user input unit of FIG. 1 .
3 is a diagram showing a display screen displaying depth of anesthesia information.
4 is a diagram showing a display screen displaying sleep stage information.
5 is a flowchart illustrating an anesthesia and sleep monitoring method according to a first embodiment of the present invention.
6 is a flowchart illustrating an anesthesia and sleep monitoring method according to a second embodiment of the present invention.

Hereinafter, the present invention will be described in more detail with reference to the drawings.

The suffixes "module" and "unit" for components used in the following description are simply given in consideration of the ease of writing the present specification, and the "module" and "unit" may be used interchangeably.

Furthermore, embodiments of the present invention will be described in detail below with reference to the accompanying drawings and the contents described in the accompanying drawings, but the present invention is not limited or limited by the embodiments.

The terminology used in this specification has been selected as a general term that is currently widely used as much as possible while considering the function in the present invention, but it may vary according to the intention or custom of a person skilled in the art or the emergence of new technology. In addition, in a specific case, there is also a term arbitrarily selected by the applicant, and in this case, the meaning will be described in the description of the invention. Therefore, it should be clarified that the terms used in this specification should be interpreted based on the actual meaning of the term and the overall content of this specification, rather than simply the name of the term.

1 is a block diagram illustrating an anesthesia and sleep monitoring device according to an embodiment of the present invention.

As shown in FIG. 1, the anesthesia and sleep monitoring device 100 of the present invention includes an EEG measurement unit 110 that measures the patient's EEG signal, the patient's anesthesia depth information and sleep stage based on the measured EEG signal. An anesthesia and sleep information generator 120 that generates information, a user input unit 130 that receives an input from a user to generate anesthesia depth information or the sleep stage information, and a controller that controls the anesthesia and sleep information generator 130 ( 140) may be included.

Here, the EEG measurement unit 110 may include a plurality of sensors attached to a predetermined region of the patient's body to sense the EEG signal of the patient, but is not limited thereto.

In addition, when generating depth of anesthesia information of the patient, the anesthesia and sleep information generating unit 120 may generate the depth of anesthesia information by calculating the depth of anesthesia of the patient by analyzing a frequency signal corresponding to the brain wave of the patient.

In addition, the anesthesia and sleep information generating unit 120, when generating the patient's sleep stage information, pre-processes the patient's brain wave signal to remove noise, extracts the features of the brain wave signal, and sleep stage corresponding to the extracted features. It is possible to determine and generate sleep stage information corresponding to the determined sleep stage.

Subsequently, the user input unit 130 may include a first user input button for receiving generation of anesthesia depth information and a second user input button for receiving generation of sleep stage information, but is not limited thereto.

In addition, the control unit 140 controls the anesthesia and sleep information generation unit 120 to generate the patient's depth of anesthesia information when generation of the depth of anesthesia information is requested from the user input unit 130, and the user input unit 130 determines the sleep stage. When information generation is requested, the patient's artificial respiration environment may be adjusted based on the generated sleep stage information by controlling the anesthesia and sleep information generation unit 120 to generate sleep stage information.

In addition, the present invention may further include a display unit 150 that displays at least one of anesthesia depth information and sleep stage information.

Next, when the patient's sleep stage information is generated from the anesthesia and sleep information generation unit 120, the controller 140 may control the display unit 150 to display the generated patient's sleep stage information on the display screen.

Here, the controller 140, when displaying the patient's sleep stage information on the display screen, wakes up (WAKEUP) step, the non-REM (NONREM) sleep stage including the first to fourth sleep stages, and It can be expressed as a rapid eye movement (REM) sleep stage including the fifth sleep stage.

For example, the controller 140 divides the first and second sleep stages among non-REM (NONREM) sleep stages into light sleep stages, and the third and fourth sleep stages among non-REM (NONREM) sleep stages as deep sleep stages. and the fifth sleep stage of the REM sleep stage can be divided into a dream sleep stage.

In addition, when the patient's sleep stage information is generated from the anesthesia and sleep information generation unit 120, the control unit 140 may adjust the patient's artificial respiration environment based on the generated patient's sleep stage information.

Here, the controller 140 controls at least one parameter of the flow rate, pressure, and volume of the mixed gas of air and oxygen supplied to the patient based on the patient's sleep stage information when adjusting the patient's artificial respiration environment. The patient's artificial respiration environment can be controlled.

In some cases, the control unit 140 may generate alarm information notifying the patient's waking state in the first wake-up stage of the patient's sleep stage information generated by the anesthesia and sleep information generation unit 120. can

In some cases, the present invention may further include a memory unit 160 in which a data table including parameter values of a mixed gas of air and oxygen corresponding to a patient's sleep stage is stored.

Here, the controller 140, when adjusting the patient's artificial respiration environment, when the patient's sleep stage information is generated, extracts the parameter value of the mixed gas of air and oxygen for the patient's sleep stage from the data table and extracts the extracted air and oxygen. At least one of the flow rate, pressure, and volume of the mixed gas of air and oxygen supplied to the patient may be varied based on the parameter value of the mixed gas.

In addition, the controller 140 may generate alarm information when the patient's sleep stage information generated by the anesthesia and sleep information generation unit 120 is a wakeup stage.

For example, when the controller 140 generates alarm information, the first alarm information for visually displaying information informing of the patient's awake state on the display screen and the information informing of the patient's awake state are audibly delivered to the speaker At least one of the second alarm information to be generated may be generated.

In addition, the controller 140 may control the display unit 150 to display the generated patient anesthesia depth information on the display screen when the patient's anesthesia depth information is generated from the anesthesia and sleep information generation unit 120 .

For example, the controller 140 may quantify and display a bispectral index (BIS) when displaying information on the depth of anesthesia of the patient on a display screen.

Then, when the anesthesia and sleep information generating unit 120 generates the patient's depth of anesthesia information, the controller 140 may adjust the patient's artificial respiration environment based on the generated depth of anesthesia information.

Here, the control unit 140, when adjusting the patient's artificial respiration environment, maintains or changes the parameter of the mixed gas of air and oxygen supplied to the patient based on the patient's depth of anesthesia information, or changes the patient's artificial respiration environment. can be adjusted

In some cases, when adjusting the patient's artificial respiration environment, the controller 140 controls at least one parameter among the flow rate, pressure, and volume of the mixed gas of air and oxygen supplied to the patient based on the patient's depth of anesthesia information. It can also control the artificial respiration environment of the patient.

As another case, the present invention may further include a memory unit 160 storing a data table including parameter values of a mixed gas of air and oxygen corresponding to the depth of anesthesia of the patient.

Here, the control unit 140, when adjusting the patient's artificial respiration environment, when the patient's anesthesia depth information is generated, extracts the parameter value of the mixed gas of air and oxygen for the patient's anesthesia depth from the data table and extracts the extracted air and oxygen. At least one of the flow rate, pressure, and volume of the mixed gas of air and oxygen supplied to the patient may be varied based on the parameter value of the mixed gas.

Next, the present invention may further include a communication unit 170 that obtains current location information.

Here, the control unit 140 acquires the current location information from the communication unit 170, and operates the anesthesia and sleep information generation unit 120 to generate anesthesia depth information and sleep stage information of the patient corresponding to the obtained current location information. You can control it.

For example, the controller 140 controls the anesthesia and sleep information generation unit 120 to generate anesthesia depth information of the patient when the current location is an operating room, and generates anesthesia and sleep stage information when the current location is an intensive care unit. The information generator 120 may be controlled.

In some cases, when acquiring current location information from the communication unit 170, the control unit 140 acquires the current location information from the communication unit 170 at the start point of the EEG measuring unit 110 measuring the patient's EEG signal. can do.

For example, the communication unit 170 may be at least one of a global positioning system (GPS) module, a wireless fidelity (WiFi) module, and a beacon module, but is not limited thereto.

The communication unit 170 of the present invention may include a location information module. The location information module is a module for obtaining the location (or current location) of the anesthesia and sleep monitoring device 100, for example, GPS ( There are Global Positioning System) module, WiFi (Wireless Fidelity) module, and beacon module.

For example, the anesthesia and sleep monitoring device 100, when using a GPS module, obtains its own position using a signal sent from a GPS satellite, corresponding to the acquired current position, the patient's depth of anesthesia information and sleep stage Information can be automatically generated and displayed.

As another example, the anesthesia and sleep monitoring device 100, when utilizing the Wi-Fi module, based on the information of the Wi-Fi module and wireless AP (Wireless Access Point) that transmits or receives a wireless signal to its location By acquiring, the patient's depth of anesthesia information and sleep stage information may be automatically generated and displayed corresponding to the acquired current position.

As another example, the anesthesia and sleep monitoring device 100 acquires its own position by receiving non-audible sound waves in a specific area using a microphone, thereby obtaining the patient's depth of anesthesia information and sleep stage corresponding to the acquired current position. Information can be automatically generated and displayed.

As such, the present invention measures the patient's depth of anesthesia and sleep stage together based on the patient's brain wave signal and adjusts the patient's artificial respiration environment corresponding to the patient's depth of anesthesia and sleep stage, thereby providing optimal ventilation for the patient. environment can be provided.

In addition, the present invention selectively measures the depth of anesthesia and the sleep stage of the patient based on the patient's brain wave signal through the user input unit or the acquired location information according to the location, so that it is convenient without replacing the equipment for measuring the depth of anesthesia and the sleep stage. Measurement time can be shortened and user convenience can be provided.

FIG. 2 is a block diagram illustrating the user input unit of FIG. 1 .

As shown in FIG. 2 , the user input unit 130 includes a first user input button 132 for receiving generation of anesthesia depth information and a second user input button 134 for receiving generation of sleep stage information. It may include, but is not limited to.

For example, the user input unit 130 is for receiving information from a user, and when information is input through the user input unit 130, the control unit 140 controls the operation of the anesthesia and sleep monitoring device to correspond to the input information. You can control it.

The user input unit 130 is a mechanical input means (or a mechanical key, for example, a button located in the anesthesia and sleep monitoring device 100, a dome switch, a jog wheel, a jog switch) etc.) and a touch input means.

As an example, the touch input means consists of a virtual key, a soft key, or a visual key displayed on a touch screen through software processing, or on a part other than the touch screen. It may be made of a touch key that is disposed.

Meanwhile, the virtual key or visual key can be displayed on the touch screen while having various forms, for example, graphic, text, icon, video, or any of these can be made in combination.

3 is a diagram showing a display screen displaying depth of anesthesia information.

As shown in FIG. 3 , the anesthesia and sleep monitoring apparatus of the present invention can display the patient's anesthesia depth information on the display screen 152 of the display unit 150 when the patient's anesthesia depth information is generated. .

For example, in the present invention, when anesthesia depth information of a patient is displayed on the display screen 152, a bispectral index (BIS) 154 may be digitized and displayed.

In addition, according to the present invention, the patient's electroencephalography (EEG) signal 155 may be measured in real time and displayed on the display screen 152, or the bi-spectral index waveform 165 for each time may be displayed.

4 is a diagram showing a display screen displaying sleep stage information.

As shown in FIG. 4 , the anesthesia and sleep monitoring apparatus of the present invention can display the generated patient's sleep stage information on the display screen 152 of the display unit 150 when the patient's sleep stage information is generated. .

Here, the anesthesia and sleep monitoring device of the present invention, when displaying the patient's sleep stage information on the display screen 152, includes a wakeup stage in an awake state and first to fourth sleep stages. (NONREM) sleep stages and REM (Rapid Eye Movement, REM) sleep stages including the fifth sleep stage may be displayed as the waveform type 158 .

For example, the present invention divides the first and second sleep stages among non-REM (NONREM) sleep stages into light sleep stages, and divides the third and fourth sleep stages among non-REM (NONREM) sleep stages into deep sleep stages, , The fifth sleep stage of the REM sleep stage can be classified as a dream sleep stage.

In addition, the present invention may display the patient's sleep state by time in the form of a graph 159 .

5 is a flowchart illustrating an anesthesia and sleep monitoring method according to a first embodiment of the present invention.

As shown in FIG. 5 , the present invention may receive a user input (S10).

Further, the present invention may check whether the user input is a request to generate depth of anesthesia information or a request to generate sleep stage information (S20).

Subsequently, in the present invention, when the user input is confirmed as a sleep stage information generation request (S60), the patient's sleep stage information can be generated based on the patient's EEG signal (S70).

Here, the present invention can pre-process the EEG signal of the patient to remove noise, extract features of the EEG signal, determine a sleep stage corresponding to the extracted feature, and generate sleep stage information corresponding to the determined sleep stage. there is.

Also, according to the present invention, when the patient's sleep stage information is generated, the generated patient's sleep stage information may be displayed on the display screen.

Subsequently, the present invention may adjust the patient's artificial respiration environment based on the sleep stage information (S80).

Here, the present invention may control at least one parameter of the flow rate, pressure, and volume of the mixed gas of air and oxygen supplied to the patient based on the patient's sleep stage information to adjust the patient's artificial respiration environment.

In some cases, the present invention, when the patient's sleep stage information is generated, extracts the parameter value of the mixed gas of air and oxygen for the patient's sleep stage from the data table stored in the memory. At least one of the flow rate, pressure, and volume of the mixed gas of air and oxygen supplied to the patient may be varied based on the above.

In addition, according to the present invention, when the patient's sleep stage information is generated, it may be checked whether the generated patient's sleep stage information is a wakeup stage, and if it is a wakeup stage, alarm information may be generated.

For example, according to the present invention, at least one of first alarm information for visually displaying information informing of the patient's waking state on a display screen and second alarm information for audibly transmitting information informing of the patient's waking state to a speaker of alarm information can be created.

In addition, according to the present invention, when the user input is confirmed as a request for generating depth of anesthesia information (S30), depth of anesthesia information of the patient may be generated based on the brain wave signal of the patient (S40).

Here, the present invention may generate depth of anesthesia information by analyzing a frequency signal corresponding to a patient's brain wave.

In addition, according to the present invention, when the patient's depth of anesthesia information is generated, the generated depth of anesthesia information of the patient may be displayed on the display screen.

Next, the present invention may adjust the patient's artificial respiration environment based on the depth of anesthesia information (S50).

Here, according to the present invention, the artificial respiration environment of the patient may be adjusted by maintaining or changing the parameters of the mixed gas of air and oxygen supplied to the patient based on the generated depth of anesthesia information of the patient.

In some cases, the present invention may control the patient's artificial respiration environment by controlling at least one parameter among the flow rate, pressure, and volume of the mixed gas of air and oxygen supplied to the patient based on the patient's depth of anesthesia information.

As another case, the present invention, when the information on the depth of anesthesia of the patient is generated, extracts the parameter value of the mixed gas of air and oxygen for the depth of anesthesia of the patient from the data table stored in the memory. At least one of the flow rate, pressure, and volume of the mixed gas of air and oxygen supplied to the patient may be varied based on .

Further, the present invention may check whether an anesthesia and sleep monitoring end request is received (S90), and if the anesthesia and sleep monitoring end request is received, the anesthesia and sleep monitoring execution process may be ended.

6 is a flowchart illustrating an anesthesia and sleep monitoring method according to a second embodiment of the present invention.

As shown in FIG. 6, the present invention may obtain current location information (S110).

Here, in the present invention, current location information may be obtained at the start point of measuring the patient's EEG signal.

Then, the present invention, based on the current location information obtained, it can determine whether the current location is an operating room or an intensive care unit (S120).

Subsequently, in the present invention, when the current location is confirmed as an operating room (S130), the patient's depth of anesthesia information may be generated based on the patient's EEG signal (S140).

Here, the present invention may analyze the frequency signal corresponding to the brain wave of the patient to calculate the depth of anesthesia of the patient to generate depth of anesthesia information.

In addition, according to the present invention, when the patient's depth of anesthesia information is generated, the generated depth of anesthesia information of the patient may be displayed on the display screen.

Next, the present invention may adjust the patient's artificial respiration environment based on the depth of anesthesia information (S150).

Here, according to the present invention, the artificial respiration environment of the patient may be adjusted by maintaining or changing the parameters of the mixed gas of air and oxygen supplied to the patient based on the generated depth of anesthesia information of the patient.

In some cases, the present invention may control the patient's artificial respiration environment by controlling at least one parameter among the flow rate, pressure, and volume of the mixed gas of air and oxygen supplied to the patient based on the patient's depth of anesthesia information.

As another case, the present invention, when the patient's depth of anesthesia information is generated, extracts the parameter value of the mixed gas of air and oxygen for the depth of anesthesia of the patient from the data table stored in the memory and extracts the parameter value of the mixed gas of air and oxygen. At least one of the flow rate, pressure, and volume of the mixed gas of air and oxygen supplied to the patient may be varied based on the above.

In addition, the present invention, when the current location is confirmed as an intensive care unit (S160), it is possible to generate the patient's sleep stage information based on the patient's EEG signal (S170).

Here, the present invention can pre-process the EEG signal of the patient to remove noise, extract features of the EEG signal, determine a sleep stage corresponding to the extracted feature, and generate sleep stage information corresponding to the determined sleep stage. there is.

Also, according to the present invention, when the patient's sleep stage information is generated, the generated patient's sleep stage information may be displayed on the display screen.

Subsequently, the present invention may adjust the patient's artificial respiration environment based on the sleep stage information (S180).

Here, according to the present invention, the patient's artificial respiration environment can be adjusted by controlling at least one parameter of the flow rate, pressure, and volume of the mixed gas of air and oxygen supplied to the patient based on the patient's sleep stage information.

In some cases, the present invention, when the patient's sleep stage information is generated, extracts the parameter value of the mixed gas of air and oxygen for the patient's sleep stage from the data table stored in the memory. At least one of the flow rate, pressure, and volume of the mixed gas of air and oxygen supplied to the patient may be varied based on the above.

In addition, according to the present invention, when the patient's sleep stage information is generated, it may be checked whether the generated patient's sleep stage information is a wakeup stage, and if it is a wakeup stage, alarm information may be generated.

For example, according to the present invention, at least one of first alarm information for visually displaying information informing of the patient's waking state on a display screen and second alarm information for audibly transmitting information informing of the patient's waking state to a speaker of alarm information can be created.

Further, the present invention may check whether an anesthesia and sleep monitoring end request is received (S190), and if the anesthesia and sleep monitoring end request is received, the anesthesia and sleep monitoring execution process may be ended.

As such, the present invention measures the patient's depth of anesthesia and sleep stage together based on the patient's brain wave signal and adjusts the patient's artificial respiration environment corresponding to the patient's depth of anesthesia and sleep stage, thereby providing optimal ventilation for the patient. environment can be provided.

In addition, the present invention selectively measures the depth of anesthesia and the sleep stage of the patient based on the patient's brain wave signal through the user input unit or the acquired location information according to the location, so that it is convenient without replacing the equipment for measuring the depth of anesthesia and the sleep stage. Measurement time can be shortened and user convenience can be provided.

The features, structures, effects, etc. described in the present inventions above are included in at least one embodiment of the present invention, and are not necessarily limited to only one embodiment. Furthermore, the features, structures, and effects illustrated in each embodiment can be combined or modified with respect to other embodiments by those skilled in the art in the field to which the embodiments belong. Therefore, contents related to these combinations and variations should be construed as being included in the scope of the present invention.

In addition, although the above has been described with a focus on the embodiments, these are only examples and do not limit the present invention, and those skilled in the art to which the present invention belongs can exemplify the above to the extent that does not deviate from the essential characteristics of the present embodiment. It will be seen that various variations and applications that have not been made are possible. For example, each component specifically shown in the embodiment can be modified and implemented. And the differences related to these modifications and applications should be construed as being included in the scope of the present invention as defined in the appended claims.

100: anesthesia and sleep monitoring device
110: EEG measuring unit
120: anesthesia and sleep information generation unit
130: user input unit
140: control unit
150: display unit
160: memory unit
170: communication department

Claims (7)

EEG measuring unit for measuring the brain wave signal of the patient;
an anesthesia and sleep information generating unit generating depth of anesthesia information and sleep stage information of the patient based on the measured EEG signal;
a user input unit that receives generation of the anesthesia depth information or the sleep stage information from a user;
A control unit for controlling the anesthesia and sleep information generating unit;
A location information module for obtaining current location information; further comprising,
The control unit,
When generation of the anesthesia depth information is received from the user input unit, the anesthesia and sleep information generation unit is controlled to generate depth of anesthesia information of the patient, and when generation of the sleep stage information is received from the user input unit, the sleep stage information is generated. The anesthesia and sleep information generation unit controls the anesthesia and sleep information generation unit to generate, and then, for any one of the anesthesia depth information and sleep stage information generated from the anesthesia and sleep information generation unit, a parameter value of the mixed gas of the patient corresponding thereto is stored in the memory unit. While extracting from the data table stored in and adjusting the artificial respiration environment of the patient based on the extracted parameter value of the mixed gas of the patient,
When adjusting the artificial respiration environment of the patient, at least one parameter of the flow rate, pressure, and volume of the mixed gas of air and oxygen supplied to the patient is controlled based on any one of the depth of anesthesia and sleep stage information of the patient Control the artificial respiration environment of the patient,
The control unit,
Corresponding to the current location information obtained from the location information module, the anesthesia and sleep information generating unit may be controlled to selectively and automatically generate information on depth of anesthesia and information on sleep stages of the patient,
Controlling the anesthesia and sleep information generation unit to generate anesthesia depth information of the patient when the current location is an operating room;
If the current location is in an intensive care unit, since a wakeup state during anesthesia may occur, the anesthesia and sleep information generation unit is controlled to generate the sleep stage information, so that the anesthesia depth and sleep stage measurement can be performed without changing equipment. Anesthesia and sleep monitoring device, characterized in that it can be selectively measured according to. According to claim 1,
The user input unit,
a first user input button to receive generation of the depth of anesthesia information; and,
Anesthesia and sleep monitoring device comprising a second user input button for receiving the generation of the sleep stage information. delete According to claim 1,
The control unit,
Anesthesia and sleep monitoring device, characterized in that for generating alarm information when the patient's sleep stage information generated from the anesthesia and sleep information generation unit is a wake-up (WAKEUP) stage. delete delete In the anesthesia and sleep monitoring method of the anesthesia and sleep monitoring device including a control unit for controlling the anesthesia and sleep information generating unit,
checking, by the control unit, whether the information input through the user input unit is an anesthesia depth information generation request or a sleep stage information generation request;
controlling, by the controller, the anesthesia and sleep information generation unit to generate depth of anesthesia information of the patient based on the brain wave signal of the patient when the information input through the user input unit is a request for generating depth of anesthesia information;
controlling, by the controller, the anesthesia and sleep information generation unit to generate sleep stage information of the patient based on the brain wave signal of the patient, if the information input through the user input unit is the request for generating the sleep stage information;
The controller extracts, from a data table stored in the memory unit, a parameter value of the gas mixture of the patient corresponding to any one of the anesthesia depth information and the sleep stage information generated by the anesthesia and sleep information generation unit, , adjusting the patient's artificial respiration environment based on the extracted parameter values of the mixed gas of the patient;
The step of adjusting the artificial respiration environment of the patient,
The control unit controls at least one parameter of the flow rate, pressure, and volume of the mixed gas of air and oxygen supplied to the patient based on any one of the depth of anesthesia and sleep stage information of the patient, thereby providing an artificial respiration environment for the patient. while controlling
The control unit obtains current location information from the location information module of the anesthesia and sleep monitoring device, and generates the anesthesia and sleep information to selectively generate anesthesia depth information and sleep stage information of the patient corresponding to the acquired current location information. Controlling the unit; further comprising,
Controlling, by the controller, the anesthesia and sleep information generation unit to generate depth of anesthesia information of the patient when the current location is an operating room;
controlling, by the control unit, the anesthesia and sleep information generation unit to generate the sleep stage information, since a wakeup (awakening) state may occur during anesthesia if the current location is an intensive care unit;
Further including, anesthesia and sleep monitoring method characterized in that it can be selectively measured according to the location without replacing the equipment for measuring the depth of anesthesia and the sleep stage.

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