KR102642023B1 - Portable medical diagnosis device and disease diagnosis method using same - Google Patents

Abstract

The present invention relates to a portable medical diagnostic device and a method of diagnosing diseases using the same. More specifically, the present invention relates to a portable medical diagnostic device and a method of diagnosing diseases using the same. By enabling accurate diagnosis of various diseases at home or outdoors, even ordinary people without medical expertise can continuously monitor their physical condition anytime, anywhere. This is to enable monitoring and accurate health management.
In particular, the present invention not only enables accurate diagnosis of the affected area by acquiring a shadowless image with the shadows removed, but also allows it to be held and used naturally through ergonomic design, and diagnoses by acquiring and fusing various biological signals and analyzing them. By doing so, accurate diagnosis and health management for various diseases are possible.
In addition, the present invention allows each component to operate in an IoT-based sensor network, so that the fusion and management of various biological signals and information, information processing (data processing), etc. can be smoothly performed.
Therefore, reliability and competitiveness in the medical field, diagnostic field, diagnostic device field, portable medical device field, home medical device field, IoT-based medical device field, remote medical treatment field, non-face-to-face medical treatment field, etc., as well as similar or related fields. can be improved.

Description

Portable medical diagnosis device and disease diagnosis method using the same {Portable medical diagnosis device and disease diagnosis method using same}

The present invention relates to a portable medical diagnostic device and a method of diagnosing diseases using the same. More specifically, the present invention relates to a portable medical diagnostic device and a method of diagnosing diseases using the same. By enabling accurate diagnosis of various diseases at home or outdoors, even ordinary people without medical expertise can continuously monitor their physical condition anytime, anywhere. This is to enable monitoring and accurate health management.

In particular, the present invention not only enables accurate diagnosis of the affected area by acquiring a shadowless image with the shadows removed, but also allows it to be held and used naturally through ergonomic design, and diagnoses by acquiring and fusing various biological signals and analyzing them. In doing so, it relates to a portable medical diagnostic device that enables accurate diagnosis and health management for various diseases and a disease diagnosis method using the same.

In general, when something goes wrong with your body due to an accident or illness, you visit a local hospital, receive a diagnosis from a medical expert, and receive treatment and prescriptions accordingly.

However, if you move to a region other than your residential area for the purpose of travel or business, there is a high possibility that you will be exposed to diseases in that region. In particular, young children can be easily exposed to diseases while traveling as a family, and in this case, they can be exposed to diseases quickly and easily. Difficulties may arise in diagnosis and treatment.

In particular, since diagnosis of diseases has mainly been made by doctors, it is difficult for non-medical people to determine whether their current physical condition is due to a disease or is temporary. Moreover, if they are in another area, they should visit a local hospital. Another problem is that it is not easy to find.

Recently, technology related to telemedicine has been developed, but in this case, it has the disadvantage of being difficult to apply when traveling or on a business trip because specific equipment must be provided in a remote location away from the hospital.

Meanwhile, the following prior art document, Republic of Korea Patent Publication No. 10-2004370, 'Portable Medical Diagnostic Device Box' (hereinafter referred to as 'prior art'), is configured to carry a medical device outdoors, and uses it to treat a patient's condition. After determining the severity, information on patients requiring emergency treatment is delivered to nearby medical facilities.

However, in the case of prior art, the configuration of the diagnostic device box is a simple arrangement of each medical device, and since the diagnosis of the patient must be performed by medical staff, there is a problem in that it is difficult for non-medical people to diagnose.

In other words, the prior art is a technology that has clear limitations in that it can only be used by medical experts, and its composition is simply a combination of medical devices placed inside a box.

Meanwhile, patients with chronic diseases such as diabetes or high blood pressure manage their health by using medical devices to manage their diseases, such as blood sugar measuring devices or blood pressure measuring devices, but these medical devices do not Since it provides only one type of biometric information, such as blood sugar or blood pressure, it has the disadvantage of having restrictions or limitations in use.

Republic of Korea Patent Publication No. 10-2004370 ‘Portable medical diagnostic device box’

In order to solve the above problems, the present invention allows for accurate diagnosis of various diseases at home or outdoors, enabling continuous monitoring of one's body condition and accurate health management anytime, anywhere, even for ordinary people without medical expertise. The purpose is to provide a portable medical diagnostic device and a disease diagnosis method using the same.

In particular, the present invention not only enables accurate diagnosis of the affected area by acquiring a shadowless image with the shadows removed, but also allows it to be held and used naturally through ergonomic design, and diagnoses by acquiring and fusing various biological signals and analyzing them. The purpose is to provide a portable medical diagnostic device and a disease diagnosis method using the same that can enable accurate diagnosis and health management for various diseases.

In addition, the present invention allows measurement modules capable of measuring necessary bio-signals to be selectively combined, configured, and carried based on the subject's (e.g., patient's) disease or hospital medical records, thereby enabling the subject to use a single device. The purpose is to provide a portable medical diagnostic device that can measure various biosignals necessary for people and a disease diagnosis method using the same.

In order to achieve the above object, a portable medical diagnostic device according to the present invention includes at least one biosignal measurement module that measures a specific biosignal of a subject; and a medical diagnostic module that diagnoses the health condition of the subject based on at least one biosignal measured by the biosignal measurement module.

Additionally, the biosignal measurement module may be configured to change and adjust the measurement method by controlling the medical diagnostic module.

In addition, the bio-signal measurement module includes a lesion imaging module for photographing the affected portion of the subject, and the affected portion imaging module includes at least one LED for removing shadows by illuminating the affected portion of the subject to capture a non-image image. The medical diagnostic module is configured to enable data communication with a remote server, including a hospital server, based on at least one of the user's operation, the subject's disease, hospital medical records, and a request from the remote server, The color of the LED can be adjusted.

Additionally, the medical diagnostic module can adjust the brightness of the LED to obtain an optimized image for the affected part of the subject.

In addition, the bio-signal measurement module includes a distance measurement sensor that measures the distance to the subject's skin; A piezoelectric sensor that checks whether there is adhesion to the subject's skin; A temperature sensor that measures the subject's body temperature; and a microphone that measures biological sounds of the subject, wherein the medical diagnostic module measures at least one of the distance to the skin of the subject and the degree of skin adhesion based on at least one of the distance measurement sensor and the piezoelectric sensor. Check, and according to the results, the sensitivity of at least one of the temperature sensor and the microphone can be adjusted.

In addition, the medical diagnostic module may analyze the pattern of biological sounds obtained from the subject and separately obtain at least one of basic biological sounds including breathing sounds and disease biological sounds including coughing sounds.

In addition, the medical diagnostic device may have an ergonomically designed grip portion formed on at least a portion of an outer surface, and the biosignal measurement module may include an oxygen saturation measurement sensor configured in at least a portion of the grip portion.

In addition, the medical diagnostic module matches the basic biological signals of the subject measured by the biosignal measurement module with the necessary biological signals for each disease required for diagnosis of the subject, and provides converged biometric data for diagnosis of the subject. can be created.

In addition, the bio-signal measurement module is configured in a module form to be attachable and detachable from the medical diagnostic module, and at least one of the types and numbers is selected based on at least one of the disease and hospital medical records of the subject and the medical diagnostic module is detachable from the medical diagnostic module. Can be combined with a diagnostic module.

In addition, the medical diagnostic module operates as a sink node in an IoT-based sensor network and is a sensor node that includes at least one of the biosignal measurement module and a separate personal diagnostic device. ) can be linked.

In addition, the method of diagnosing a disease using a portable medical diagnostic device according to the present invention includes a medical diagnostic module of the portable medical diagnostic device operating as a sink node, and at least one of a bio-signal measurement module and a separate personal diagnostic device. A disease diagnosis method based on a sensor network using IoT, one of which is configured to operate as a sensor node, comprising: a bio-signal measurement step in which the sensor node measures the subject's bio-signals; and a disease diagnosis step in which the medical diagnostic module diagnoses the subject's disease by analyzing bio-signals measured by the sensor node.

In addition, before the bio-signal measurement step, the medical diagnostic module checks the type of bio-signal measured at the sensor node, checks whether it matches the subject's disease and medical records, and then sets the matched sensor node. It may further include a device registration step of registering information as a linked device, and the bio-signal measurement step may measure the subject's bio-signal using at least one of the registered linked devices.

In addition, the device registration step includes: a first interlocking device registration process of registering the biosignal measurement module as an interconnection device when necessary biosignals for each disease are received from the biosignal measurement module; a second interlocking device registration process of registering the relevant diagnostic device as an interlocking device when necessary biosignals for a disease are not received from the biosignal measurement module and necessary biosignals for a corresponding disease are also received from the personal diagnostic device; And if the required biosignals for each disease are not received from the biosignal measurement module and the required biosignals for each disease are not received from the personal diagnostic device, the necessary biosignals for each disease are replaced among the linked personal diagnostic devices. It may include a replacement signal setting process of checking available biosignals and setting the biosignals measured by the relevant personal diagnostic device as replacement biosignals for necessary biosignals for each disease.

In addition, the disease diagnosis step includes a basic biological signal confirmation process of confirming the basic biological signal of the subject measured by the biological signal measurement module; Necessary biosignal confirmation process to check necessary biosignals for each disease required for diagnosis of the subject; and a convergence biometric data generation process of matching the basic biometric signals and necessary biometric signals to generate convergence biometric data for diagnosis of the subject.

In addition, the disease diagnosis step includes: a reference position guidance process that guides the reference position required for the disease to be diagnosed in the subject's body when the measurement of the biosignal measurement module begins; Location confirmation process to check the current location of the biosignal measurement module; And when the bio-signal measurement module moves to the reference position, the bio-signal measurement process checks the movement of the bio-signal measurement module based on the reference position, sequentially guides the location requiring measurement, and measures the bio-signal for each measurement location. May include ;.

In addition, the sensor node of the IoT-based sensor network further includes personal terminals for each member, and after the disease diagnosis step, each member's personal terminal is linked to provide disease history data for the members. It may further include a disease history management step for each member performing management.

In addition, the IoT-based sensor network is configured to enable data communication with a remote server including at least one of a hospital server and an insurance company server, and after the disease diagnosis step, disease history data for each member is converted into hospital data. And it may further include a disease history data providing step of classifying and generating at least one of the insurance use data and then transmitting it to the corresponding remote server when necessary.

Through the above solution, the present invention has the advantage of enabling accurate diagnosis of various diseases at home or outdoors, enabling continuous monitoring of one's body condition and accurate health management anytime, anywhere, even for ordinary people without medical expertise. There is.

In particular, the present invention not only enables an accurate diagnosis of the affected area by acquiring a shadowless image with the shadows removed, but also allows it to be held and used naturally through ergonomic design, thereby minimizing discomfort and fatigue during use. there is.

In addition, the present invention has the advantage of enabling accurate diagnosis and health management of various diseases by acquiring and fusing various biological signals and analyzing them for diagnosis.

In addition, the present invention allows measurement modules capable of measuring necessary bio-signals to be selectively combined, configured, and carried based on the subject's (e.g., patient's) disease or hospital medical records, thereby enabling the subject to use a single device. It has the advantage of being able to measure various bio-signals necessary for people.

In addition, the present invention has the advantage of allowing each module to operate in an IoT-based sensor network, allowing the convergence and management of various biological signals and information, information processing (data processing), etc. to be smoothly performed.

In addition, the present invention enables the acquisition of optimized data (biosignals, images, etc.) by controlling the operation of the biosignal measurement module based on disease or hospital medical records, so that a more accurate diagnosis can be made for the subject. There is an advantage.

In addition, the present invention connects separate personal diagnostic devices such as blood pressure measurement devices, diabetes measurement devices, electrocardiogram measurement devices, etc. in addition to the modularized biosignal measurement module based on IoT, enabling diagnosis even without a module that measures specific biosignals. There is an advantage in being able to acquire the relevant biosignal using devices or to obtain a biosignal that can replace the relevant biosignal.

Through this, the present invention has the advantage of enabling accurate diagnosis of a wider variety of diseases using limited resources (biosignal measurement module and personal diagnostic device).

In addition, the present invention uses a positioning sensor such as a gyro sensor to detect the location of a medical diagnostic module or biosignal measurement module, and to accurately obtain biosignals required by the disease or hospital medical records, etc. It has the advantage of allowing even non-medical people to obtain biosignals at accurate locations.

In addition, the present invention not only manages disease history data for the subject by linking the acquired bio-signals with the hospital server, but also allows non-face-to-face telemedicine from medical experts when necessary, or various biometric data at the request of medical experts. It has the advantage of being able to obtain signals and easily processing insurance for the disease by linking with the insurance company server.

In addition, the present invention can be used in patient associations, which are groups of people with specific diseases, to share information among patients, which has the effect of greatly helping patients manage their health.

Therefore, reliability and competitiveness in the medical field, diagnostic field, diagnostic device field, portable medical device field, home medical device field, IoT-based medical device field, remote medical treatment field, non-face-to-face medical treatment field, etc., as well as similar or related fields. can be improved.

1 is a perspective view showing an embodiment of a portable medical diagnostic device according to the present invention.
Figure 2 is a bottom perspective view of Figure 1.
Figure 3 is a perspective view showing another embodiment of Figure 1.
Figures 4 and 5 are diagrams explaining how to use Figure 3.
FIG. 6 is a configuration diagram showing an embodiment of a disease diagnosis system using the portable medical diagnosis device of FIG. 1.
Figure 7 is a flowchart showing an embodiment of a disease diagnosis method using a portable medical diagnosis device according to the present invention.
Figure 8 is a flowchart showing a specific embodiment of step 'S100' of Figure 7.
Figure 9 is a flowchart showing another specific embodiment of step 'S100' of Figure 7.
Figure 10 is a flowchart showing a specific embodiment of step 'S200' of Figure 7.
Figure 11 is a flowchart showing a specific embodiment of step 'S300' of Figure 7.
Figure 12 is a flowchart showing another specific embodiment of step 'S300' of Figure 7.
Figure 13 is a configuration diagram showing another embodiment of Figure 6.
FIG. 14 is a diagram illustrating an embodiment of the method of using FIG. 12.

Examples of the portable medical diagnostic device and the disease diagnosis method using the same according to the present invention can be applied in various ways, and the most preferred embodiment will be described below with reference to the attached drawings.

Figure 1 is a perspective view showing an embodiment of a portable medical diagnostic device according to the present invention, and Figure 2 is a bottom perspective view of Figure 1.

Referring to FIG. 1, a portable medical diagnostic device includes a biosignal measurement module 100 and a medical diagnostic module 200.

The biosignal measurement module 100 measures specific biosignals of a subject (patient) and can be integrated with the medical diagnostic module 200, and can also be configured in a modular form so that it can be attached and detached when necessary.

Specifically, the biosignal measurement module 100 is configured to enable respiration measurement, fever measurement, ultrasound measurement, blood pressure measurement, electrocardiogram measurement, blood sugar measurement, oxygen saturation measurement, imaging, fetal heart sound measurement, etc., and each biosignal Regarding the configuration and method for measuring , various methods may be applied depending on the needs of those skilled in the art, so it is of course not limited to a specific one.

For example, the biosignal measurement module 100 may include a respiration measurement module, a fever measurement module, an imaging module, an oxygen saturation measurement module, a fetal heart sound measurement module, etc., and subjects including mothers in normal times (e.g. , family members, etc.) may be configured to measure biosignals.

As another example, the biosignal measurement module 100 may include an ultrasound measurement module, blood pressure measurement module, electrocardiogram measurement module, blood sugar measurement module, etc., when the subject is a chronic patient or receives treatment at a hospital due to a specific disease or accident. , at least one of the types and numbers may be selected based on the relevant disease or medical record.

The measurement time can be set for each type of biosignal, and if a specific pattern is repeated, the pattern can be analyzed to extract one or two cycles, thereby preventing unnecessary increase in biosignal data. .

For example, when trying to obtain a subject's heart sound, biosignals can be acquired a set number of times (for example, 3 heartbeats).

The acquisition time of such bio-signals can be set according to the bio-signals being measured, or can be selected and adjusted by user manipulation.

Accordingly, the medical treatment module 200 may be combined and combined with at least some of the modules that measure basic biosignals of the subject in normal times and the modules that measure biosignals required for each subject's disease.

This bio-signal measurement module 100 not only allows the subject to directly check his or her bio-signals, but can also be configured to enable medical professionals to perform inspection or auscultation from a remote location.

The medical diagnosis module 200 diagnoses the health status of the subject based on at least one biosignal measured by the biosignal measurement module 100, and the diagnosis result is provided through visual information or audio using a display or speaker. Diagnosis results can be output as information.

At this time, the medical diagnostic module 200 can provide guidance on measuring methods for biological signals, etc., or guidance on precautions for measurement, etc., through visual information or audio information using a display or speaker.

In addition, the medical diagnostic module 200 can improve the security of an individual's biometric information by allowing only registered subjects to operate and check biometric information using a fingerprint sensor, etc.

In addition, the medical diagnosis module 200 notifies the need for re-measurement when the legitimacy of the bio-signals collected from each bio-signal measurement module 100 is not sufficiently secured, or displays the diagnosis results according to the analysis of the bio-signals. It can be output as information or sound information.

In addition, the medical diagnostic module 200 can store and manage biometric information for each family member. In particular, by managing infectious diseases or family history, if a specific member is exposed to an infectious disease, it guides other members to prevent infection. In addition to preventing the spread of diseases, it is also possible to prevent the development of specific diseases due to family history.

For example, information about family members is matched and stored as a dataset, various information measured using a diagnostic device is stored by matching the measurement time, and when one session ends, it is saved as a dataset. It is possible to manage family members.

Additionally, the biosignal measurement module 100 may be configured on one side of the medical diagnostic module 200.

For example, the medical diagnostic module 200 may be formed in a pillar shape, and the biosignal measurement module 100 may be coupled to one side (upper part in FIG. 1) in the longitudinal direction of the medical diagnostic module 200.

Additionally, the biosignal measurement module 100 may be configured to change and adjust the measurement method by controlling the medical diagnosis module 200.

For example, if the biosignal measurement module 100 is a lesion imaging module that photographs the affected part of the subject (e.g., oral cavity, tonsils, eyes, inside the ear, skin, etc.), A camera 110 may be configured in the center, and a plurality of LEDs 120 may be configured around the camera 110.

At this time, the LED 120 performs a function of removing shadows by illuminating the affected part of the subject, and through this, the camera 110 can capture a shadowless image of the affected part.

Meanwhile, color interference may occur depending on the subject's disease and affected area, and in this case, it is necessary to make the image of the affected area clearer and clearer through complementary color contrast.

To this end, the medical diagnostic module 200 is based on at least one of automatic control according to the user's operation or setting information, or a hospital medical record through linkage with a hospital server configured to enable data communication, and a request from a remote server, The emission color of the LED 120 can be adjusted.

In addition, the medical diagnostic module 200 can adjust the brightness of the LED 120 to obtain an optimized image for the affected part of the subject.

In addition, the portable medical diagnostic device shown in FIG. 1 is generally formed in the shape of a square pillar, but it is not limited thereto and of course can be changed into various shapes according to the needs of those skilled in the art.

Referring to FIG. 2 , the biosignal measurement module 100 may include a temperature sensor 130 that measures the body temperature of the subject and a microphone 140 that measures the subject's biological sounds.

Accordingly, the medical diagnostic module 200 measures the subject's body temperature through the temperature sensor 130, and uses the microphone 140 to make sounds such as breathing, coughing, heart movement, pulse, stomach, large intestine, small intestine, etc. As such, various sounds occurring within the subject's body can be acquired.

The sounds obtained in this way can be stored by matching tag information according to each item (cough, heart, pulse, stomach, large intestine, small intestine, etc.), and body temperature or oxygen saturation can also be matched and stored with tag information. .

Meanwhile, the subject's body temperature, breathing sound, coughing sound, etc. vary depending on the measurement location or whether the subject is in close contact with the skin.

Accordingly, the medical diagnostic module 200 checks at least one of the distance to the subject's skin and the degree of skin adhesion, and adjusts the sensitivity of at least one of the temperature sensor and the microphone according to the results to produce a clearer biosignal ( sound, etc.) can be obtained.

To this end, the present invention can further comprise a distance measuring sensor (not shown) that measures the distance to the subject's skin, and a piezoelectric sensor (not shown) that checks whether it is in close contact with the subject's skin, Through this, at least one of the distance to the subject's skin and the degree of skin adhesion can be confirmed.

For example, the distance measuring sensor may be configured at a location adjacent to the temperature sensor 130.

As another example, the piezoelectric sensor may be configured on one side of the sound insulation wing 150 in close contact with the skin. Here, the sound insulation wings 150 are used to prevent external noise from mixing in the process of acquiring biological sounds, and may be made of synthetic resin, etc.

Through this, the medical diagnostic module 200 analyzes the pattern of biological sounds obtained from the subject, separates and obtains at least one of the basic biological sounds including breathing sounds and disease biological sounds including coughing sounds, thereby providing accurate Diagnosis can be made possible.

Additionally, grip portions 210 may be formed on the outer surface of the medical diagnostic module 200, specifically, on both sides of the central portion, so that the subject can easily grasp the medical diagnostic module 200.

The grip portion 210 is ergonomically shaped to provide an excellent grip feeling, and at least part of the grip portion 210 is configured with an oxygen saturation sensor 220, so that when the subject holds the medical diagnostic module 200, Oxygen saturation can be measured naturally.

Here, the oxygen saturation sensor 220 measures oxygen saturation in the blood non-invasively by measuring light absorption for each wavelength, and sends light of two different wavelengths to specific body parts such as fingers located on the grip unit 210. irradiates, receives the light that has passed through the relevant body part, converts it into an electrical signal, and uses the converted electrical signal to calculate oxygen saturation.

In addition, the medical diagnostic module 200 matches the basic biological signals of the subject measured by the biosignal measurement module 100 with the necessary biological signals for each disease required for diagnosis of the subject, and is used for diagnosis of the subject. Fusion biometric data can be generated and, if necessary, provided to a remote hospital server.

Through this, the subject's doctor can more accurately diagnose the subject's current condition.

In addition, at least one button 240 may be configured on another side of the medical diagnostic module 200 for operation by the subject, and the number of buttons may be minimized and placed.

In addition, on another side of the medical diagnostic module 200, a display 230 may be configured to output the current status of each module (eg, connection status, setting information, operation information, etc.) or the subject's biometric information.

In addition, by further configuring an ultrasonic transmitter and an ultrasonic receiver in the biosignal measurement module 100 configured at the bottom of the medical diagnostic module 200, an ultrasonic image of the subject can be obtained.

Figure 3 is a perspective view showing another embodiment of Figure 1, and Figures 4 and 5 are diagrams explaining how to use Figure 3.

Referring to FIG. 3, the biosignal measurement module 100 may be configured in a module form so that it can be attached and detached from the medical diagnostic module 200.

In particular, the biosignal measurement module 100 is selected based on at least one of the subject's disease and hospital medical records, and at least one of the types and numbers can be selected and combined with the medical diagnostic module 200 or carried so as to be exchangeable. You can.

In addition, the medical diagnostic module 200 can be operated as a sink node in an IoT-based sensor network and includes at least one of the biosignal measurement module 100 and a separate personal diagnostic device. It can be linked to a sensor node.

This IoT-based sensor network will be described in more detail below.

In addition, the medical diagnostic module 200 can be used by combining various modules such as an ultrasound measurement module, a respiration measurement module, a fever measurement module, an imaging module, an oxygen saturation measurement module, and a fetal heart sound measurement module, in addition to the affected area imaging module described above. there is.

In Figure 5, the unexplained symbol 'S' is a smartphone, and the unexplained code 'C' is a charger for charging the medical diagnostic module 200 and the smartphone (S).

FIG. 6 is a configuration diagram showing an embodiment of a disease diagnosis system using the portable medical diagnosis device of FIG. 1.

Referring to FIG. 6, the medical diagnostic module 200 may be linked with the biosignal measurement module 100 through an IoT-based sensor network.

At this time, the medical diagnostic module 200 can be operated as a sink node in an IoT-based sensor network, and the biosignal measurement module 100 can be operated as a sensor node.

In addition, the medical diagnostic module 200 can be linked to the personal diagnostic device 300 used by the subject or other family members through an IoT-based sensor network, and the personal diagnostic device 300 also operates as a sensor node. Of course it can be done. Here, the personal diagnostic device 300 may include a blood pressure measurement device 310, an electrocardiogram measurement device 320, and a blood sugar measurement device 330.

Accordingly, the medical diagnostic module 200 operating as a sink node collects various biosignals from modules or devices operating as a sensor node, selectively fuses them for each subject, and generates fused biometric data for diagnosis to provide to a remote doctor. can be provided.

Below, we will look in more detail at embodiments of a disease diagnosis method using this system.

Figure 7 is a flowchart showing an embodiment of a disease diagnosis method using a portable medical diagnosis device according to the present invention.

Referring to FIG. 7, the disease diagnosis method using a portable medical diagnostic device includes a device registration step (S100), a biosignal measurement step (S200), and a disease diagnosis step (S300).

The device registration step (S100) is a step of registering the biosignal measurement module 100 to be linked to the medical diagnostic module 200, and the medical diagnostic module 200 measures biometric signals measured by sensor nodes configured in an IoT-based sensor network. After checking the type and whether it matches the subject's disease and medical records, the setting information of the matched sensor node is registered as a linked device.

In the bio-signal measurement step (S200), when the bio-signal measurement begins, the subject's bio-signal is measured using sensor nodes registered as linked devices.

At this time, sensor nodes that measure the subject's biosignals may be selected by manipulation by the user (subject), or may be selected based on the subject's disease or medical records.

In addition, the subject's biosignals can be measured in various ways depending on the type of linking device and the needs of those skilled in the art.

In the disease diagnosis step (S300), the medical diagnostic module 200 diagnoses the subject's disease by analyzing bio-signals measured at the sensor node.

At this time, the medical diagnostic module 200 can diagnose the subject's disease based on bio-signals measured using medical artificial intelligence, and if necessary, transmit them to a remote hospital server and request a diagnosis from the doctor in charge.

In addition, after the described disease diagnosis step (S300), a member-specific disease history management step of managing disease history data for each member by linking with each member's personal terminal (e.g., smartphone); More may be included.

In addition, after the described disease diagnosis step (S300), the disease history data providing step of classifying and generating disease history data for each member into at least one of hospital data and insurance data, and then transmitting it to the corresponding remote server when necessary; It can be included.

Each of these steps will be examined in more detail with reference to more specific examples below.

Figure 8 is a flowchart showing a specific embodiment of step 'S100' of Figure 7.

First, the medical diagnostic module 200 checks the type of biosignal measured by the sensor node including the biosignal measurement module 100 and the personal diagnostic device 300 (S111), and records the subject's disease and medical records. After confirmation (S112), you can check whether the subject's disease and medical records match the biosignals (S113).

At this time, the medical diagnostic module 200 can register and store the subject's disease and medical records, or request and receive them from a remote hospital server.

Accordingly, the medical diagnostic module 200 uses the setting information of a sensor node to measure biosignals that are matched with the subject's disease and medical records, that is, biosignals that need to be measured according to the subject's disease and medical records, to a linked device. It can be registered (S114).

When the necessary sensor nodes are registered as interlocking devices, the medical diagnostic module 200 guides the subject to the biosignal that needs to be measured and the module or device for measuring the biosignal when measuring the subject's biosignal, You can check whether all necessary biosignals have been collected, and the subject can be asked to measure biosignals that were not collected.

Additionally, the medical diagnostic module 200 can register unmatched sensor nodes as additional devices (S115), and the additional devices can be used to measure alternative biological signals, which will be explained below.

Figure 9 is a flowchart showing another specific embodiment of step 'S100' of Figure 7.

Referring to FIG. 9, the device registration step (S100) may include a first linked device registration process (S124), a second linked device registration process (S127), and a replacement signal setting process.

First, as discussed above, the medical diagnostic module 200 can be linked with at least one of the biosignal measurement module 100 and a separate personal diagnostic device 300 through an IoT-based sensor network.

Accordingly, the medical diagnostic module 200 can check the linked bio-signal measurement module 100 (S121) and check whether necessary bio-signals for each disease according to the subject's disease or medical records are received (S122).

At this time, when necessary biosignals for each disease are received from the biosignal measurement module 100, the medical diagnostic module 200 can register the biosignal measurement module 100 as a linked device (S124).

If the necessary biometric signals for each disease are not received from the biosignal measurement module 100 (S123), you can check the personal diagnostic device 300 (S125) and check whether the necessary biosignals for each disease are received (S125). S126).

At this time, when necessary biometric signals for each disease are received from the personal diagnostic device 300, the medical diagnostic module 200 can register the personal diagnostic device 300 as a linked device (S127).

If the necessary biological signals for each disease are not received from the personal diagnostic device 300, that is, the necessary biological signals for each disease are not received from the biological signal measurement module 100, the corresponding If the required biosignal for each disease is not received, the medical diagnostic module 200 selects a personal diagnostic device 300 that measures a biosignal that can replace the required biosignal for the disease among the linked personal diagnostic devices 300. After confirming, the biosignal measured by the personal diagnostic device can be set as a replacement biosignal for the necessary biosignal for each disease (S128).

Figure 10 is a flowchart showing a specific embodiment of step 'S200' of Figure 7.

First, the biosignal measurement module 100 may be configured to change and adjust the measurement method by controlling the medical diagnosis module 200.

For example, the biosignal measurement module 100 may include a lesion imaging module that photographs the affected part (e.g., oral cavity, tonsils, eyes, inside the ear, skin, etc.) of the subject, and the affected portion imaging module is shown in FIG. As shown, it may include at least one LED 120 that illuminates the affected area of the subject.

As discussed above, the LED 120 is used to prevent shadows from occurring during the process of photographing the affected part of a subject, and is used to photograph a shadowless image.

And, the lesion photographed by the lesion imaging module can be output to the display 230 as shown in FIG. 1.

At this time, the contrast or clarity of the image may vary depending on the affected area to be photographed.

Accordingly, the medical diagnostic module 200 can adjust the emission color of the LED 120 according to the affected area to be imaged.

Looking more specifically, the medical diagnostic module 200 can adjust the emission color of the LED 120 based on at least one of the subject's disease (S211), hospital medical records (S212), and a request from a remote server (S213). There is (S215).

To this end, the medical diagnostic module 200 may be configured to enable data communication with a remote server, including a hospital server.

In addition, the subject can check the image output on the display 230 and directly adjust the emission color of the LED 120 using the button 240 configured on the medical diagnostic module 200 (S214), as shown in FIG. 1. There is (S215).

In addition, the medical diagnostic module 200 can adjust the brightness of the LED 120 (S216) to obtain an optimized image for the affected part of the subject (S217).

In particular, adjustment of the color and brightness of the LED 120 can be requested from a remote hospital server, and the hospital server uses AI based on deep learning to optimize the image to accurately diagnose the disease or disease. The color and brightness of the LED 120 can be adjusted.

In addition, this affected area imaging module can be used to photograph the skin or specific parts of not only family members, but also dogs and cats, and can be used in conjunction with animal hospitals, etc.

Figure 11 is a flowchart showing a specific embodiment of step 'S300' of Figure 7.

Referring to FIG. 11, the disease diagnosis step (S300) may include a basic biosignal confirmation process (S311), a necessary biosignal confirmation process (S312), and a fusion biometric data generation process (S314).

Looking at this in more detail, the medical diagnostic module 200 confirms the basic biological signals of the subject measured by the biosignal measurement module 100 (S311), as well as the necessary biosignals for each disease required for diagnosis of the subject. (S312).

For example, if the subject is a patient with high blood pressure, the medical diagnostic module 200 checks the body temperature, which is a basic biological signal, as well as necessary biological signals such as blood pressure required for high blood pressure, and if matching is necessary according to the subject's disease or medical records. (S313), two biosignals (body temperature and blood pressure) can be fused to generate fused biometric data for diagnosis of the subject (S314).

When the medical diagnostic module 200 transmits this fused biometric data to a remote hospital server, the doctor can check the fused biometric data and diagnose the subject's condition from various perspectives.

If matching is not necessary (S313), the medical diagnosis module 200 may classify the measured biosignals into individual data (S315).

Figure 12 is a flowchart showing another specific embodiment of step 'S300' of Figure 7.

Referring to FIG. 12, the disease diagnosis step (S300) may include a reference position guidance process (S322), a location confirmation process (S325), and a biosignal measurement process (S327).

For example, when measuring a subject's body temperature and breathing sounds, a subject who is an ordinary person without professional medical knowledge may not know which part of the body to measure the breathing sounds.

Accordingly, when the medical diagnostic module 200 starts measuring bio-signals due to the subject's manipulation, etc. (S321), it may request that it or the bio-signal measurement module 100 move to the reference position of the body (S322).

For example, when the subject selects measurement of breathing sounds by manipulating the button 240 of the medical diagnostic module 200, the medical diagnostic module 200 can output an image as shown in FIG. 14 through the display 230. (S322), the subject can check the output image, move the biosignal measurement module (100, for example, microphone, etc.) that measures breathing to the body's reference position (P0), and operate the measurement start button ( S323).

When confirmation of the reference position (P0) is completed (S323), the medical diagnostic module 200 confirms the position (P1) for measuring the subject's breathing sound (S324) and outputs this on the display 230. , It can be confirmed that the biosignal measurement module 100 moves from the reference position (P0) to the first breathing sound measurement position (P1) due to the subject's movement (S325).

The positional movement of the biological signal measurement module 100 can be confirmed using a positioning sensor such as a gyro sensor or an acceleration sensor.

In addition, by further configuring a laser pointer in the bio-signal measurement module 100 and checking which part of the subject's body the laser output from the laser pointer points to, the subject (or user) is currently using the bio-signal measurement module 100. Alternatively, it is possible to visually confirm where the medical diagnostic module 200 is located.

The medical diagnostic module 200 can measure the corresponding biosignal (breathing sound) when the biosignal measurement module 100 is located at the correct position (P1) (S326), and not at the correct position (P1). In this case (S326), the movement of the bio-signal measurement module 100 can be continuously guided (S328).

In this way, the medical diagnostic module 200 can repeat steps 'S324' to 'S328' of FIG. 12 to sequentially guide the location where the subject's breathing sound should be measured, as shown in FIG. 14, and the positioning sensor Through this, the location of the bio-signal measurement module 100 can be continuously checked and guided (guided) to be located in the correct position.

Figure 13 is a configuration diagram showing another embodiment of Figure 6.

Referring to FIG. 13, the medical diagnostic module 200 includes at least one biosignal measurement module 100, a separate personal diagnostic device 300, a personal terminal for each member (e.g., a smartphone), and an IoT-based It can be linked to the sensor network and can be used to manage disease history data for relevant members.

For example, the medical diagnostic module 200 may be configured to enable data communication with a remote server including at least one of the hospital server 400 and the insurance company server 500, and may convert disease history data for each member into hospital data. It can be classified into at least one of the following: and insurance data, and then transmitted to the remote server when necessary.

Accordingly, the hospital server 400 can perform remote medical treatment for the subject through the medical diagnosis module 200, and the insurance company server 500 can perform insurance information confirmation and insurance payment according to remote medical treatment. .

Above, the portable medical diagnostic device according to the present invention and the disease diagnosis method using the same have been described. Those skilled in the art will understand that the technical configuration of the present invention can be implemented in other specific forms without changing the technical idea or essential features of the present invention.

Therefore, the embodiments described above should be understood as illustrative in all respects and not restrictive.

100: Biosignal measurement module
110: Camera 120: LED
130: temperature sensor 140: microphone
150: Sound insulation wings
200: Medical diagnostic module
210: Grip part 220: Oxygen saturation measurement sensor
230: display 240: button
300: Personal diagnostic device
310: Device for measuring blood pressure 320: Device for measuring electrocardiogram
330: Blood sugar measurement device
400: Hospital server 500: Insurance company server

Claims (17)

At least one biosignal measurement module that measures a specific biosignal of a subject; and
It includes a medical diagnostic module that diagnoses the health status of the subject based on at least one bio signal measured by the bio signal measurement module,
The biosignal measurement module is,
It is configured in a modular form so that it can be attached and detached from the medical diagnostic module,
Based on at least one of the subject's disease and hospital medical records, at least one of the types and numbers is selected and combined with the medical diagnosis module,
The medical diagnostic module is,
It operates as a sink node in an IoT-based sensor network and is linked with a sensor node that includes at least one of the bio-signal measurement module and a separate personal diagnostic device,
The medical diagnostic module is
Diagnose the subject's disease by analyzing the subject's biological signals measured by the sensor node,
The medical diagnostic module is
After checking the type of biosignal measured by the sensor node and whether it matches the subject's disease and medical records, the setting information of the matched sensor node is registered as a linked device,
The medical diagnostic module is
When necessary biosignals for each disease are received from the biosignal measurement module, the biosignal measurement module is registered as a linked device,
The medical diagnostic module is
When the necessary biological signals for each disease are not received from the bio-signal measurement module, the bio-signal measurement module is registered as an interlocking device, and when the bio-signals required for the disease are received from the personal diagnostic device, the relevant diagnostic device is connected to the interlocking device. Register with
The medical diagnostic module is
If the necessary biological signals for each disease are not received from the biosignal measurement module and the necessary biosignals for the disease are not received from the personal diagnostic device, a device that can replace the necessary biosignals for the relevant disease among the linked personal diagnostic devices A portable medical diagnostic device that checks biosignals and sets the biosignals measured by the personal diagnostic device as alternative biosignals for the necessary biosignals for each disease.
According to clause 1,
The biosignal measurement module is,
A portable medical diagnostic device configured to change and adjust the measurement method by controlling the medical diagnostic module.
According to clause 2,
The biosignal measurement module is,
Includes a lesion imaging module for photographing the affected portion of the subject,
The affected area imaging module,
It includes at least one LED that illuminates the affected area of the subject and removes shadows to capture a shadowless image,
The medical diagnostic module is,
It is configured to enable data communication with remote servers, including hospital servers, and
A portable medical diagnostic device, characterized in that the color of the LED is adjusted based on at least one of the user's operation, the subject's disease, hospital medical records, and a request from a remote server.
According to clause 3,
The medical diagnostic module is,
A portable medical diagnostic device characterized in that the brightness of the LED is adjusted to obtain an optimized image for the affected part of the subject.
According to clause 2,
The biosignal measurement module is,
A distance measuring sensor that measures the distance to the subject's skin;
A piezoelectric sensor that checks whether there is adhesion to the subject's skin;
A temperature sensor that measures the subject's body temperature; and
Includes a microphone that measures the subject's biological sounds,
The medical diagnostic module is,
Based on at least one of the distance measuring sensor and the piezoelectric sensor, confirming at least one of the distance to the subject's skin and the degree of skin contact, and adjusting the sensitivity of at least one of the temperature sensor and the microphone according to the results. Characterized by a portable medical diagnostic device.
According to clause 5,
The medical diagnostic module is,
A portable medical diagnostic device that analyzes the pattern of biological sounds obtained from the subject and separately obtains at least one of basic biological sounds including breathing sounds and disease biological sounds including coughing sounds.
According to clause 1,
The medical diagnostic module is,
Forming an ergonomically designed grip portion on at least a portion of the outer surface,
The biosignal measurement module is,
A portable medical diagnostic device comprising an oxygen saturation sensor configured in at least a portion of the grip portion.
According to clause 1,
The medical diagnostic module is,
A portable device characterized in that it generates convergence biometric data for diagnosis of the subject by matching the basic biosignals of the subject measured by the biosignal measurement module, as well as the necessary biosignals for each disease required for diagnosis of the subject. Medical diagnostic device.
delete delete A sensor network using IoT configured such that the medical diagnostic module of the portable medical diagnostic device of claim 1 operates as a sink node, and at least one of the biosignal measurement module and a separate personal diagnostic device operates as a sensor node. In the (Sensor network)-based disease diagnosis method,
A bio-signal measurement step in which the sensor node measures the subject's bio-signals; and
A disease diagnosis step in which the medical diagnostic module diagnoses the subject's disease by analyzing bio-signals measured by the sensor node,
Before the biosignal measurement step,
A device registration step in which the medical diagnostic module checks the type of biosignal measured by the sensor node, checks whether it matches the subject's disease and medical records, and then registers the setting information of the matched sensor node as a linked device. further includes ;,
The biosignal measurement step is,
Measure the subject's biosignals using at least one of the registered linked devices,
The device registration step is,
A first interlocking device registration process of registering the biosignal measurement module as a interconnection device when necessary biosignals for each disease are received from the biosignal measurement module;
a second interlocking device registration process of registering the relevant diagnostic device as an interlocking device when necessary biosignals for a disease are not received from the biosignal measurement module and necessary biosignals for a corresponding disease are also received from the personal diagnostic device; and
If the necessary biological signals for each disease are not received from the biosignal measurement module and the necessary biosignals for the disease are not received from the personal diagnostic device, a device that can replace the necessary biosignals for the relevant disease among the linked personal diagnostic devices Disease using a portable medical diagnostic device, comprising: a replacement signal setting process of checking biosignals that can be detected and setting the biosignals measured by the personal diagnostic device as replacement biosignals for the necessary biosignals for each disease; Diagnosis method.
delete delete According to clause 11,
The disease diagnosis step is,
A basic biological signal confirmation process of confirming the basic biological signals of the subject measured by the biological signal measurement module;
Necessary biosignal confirmation process to check necessary biosignals for each disease required for diagnosis of the subject; and
A disease diagnosis method using a portable medical diagnostic device, comprising: a fusion biometric data generation process of matching the basic biometric signals and necessary biometric signals to generate diagnostic fusion biometric data for the subject.
According to clause 11,
The disease diagnosis step is,
When the measurement of the biosignal measurement module begins, a reference position guidance process that guides the reference position required for the disease to be diagnosed in the subject's body;
Location confirmation process to check the current location of the biosignal measurement module; and
When the biosignal measurement module moves to a reference position, a biosignal measurement process of checking the movement of the biosignal measurement module based on the reference position, sequentially guiding the locations requiring measurement, and measuring biosignals for each measurement location; A method of diagnosing a disease using a portable medical diagnostic device, comprising:
According to clause 11,
The sensor nodes of the IoT-based sensor network further include personal terminals for each member.
After the disease diagnosis step,
A disease diagnosis method using a portable medical diagnostic device, further comprising a member-specific disease history management step of managing disease history data for each member in conjunction with each member's personal terminal.
According to clause 16,
The IoT-based sensor network is configured to enable data communication with remote servers, including at least one of a hospital server and an insurance company server.
After the disease diagnosis step,
A disease history data providing step of classifying and generating disease history data for each member into at least one of hospital data and insurance data, and then transmitting the disease history data to the corresponding remote server when necessary, using a portable medical diagnostic device. How to diagnose a disease.