KR102722421B1 - Remote medical treatment system based on artificial intelligence - Google Patents

Abstract

The present invention relates to a remote medical treatment system based on artificial intelligence, comprising: a display unit for displaying a remote medical treatment program screen for performing remote medical treatment of a patient in the event of an emergency; and a remote medical device including a user input unit; wherein the remote medical device is provided indoors or outdoors and is characterized by being provided within a medical treatment space for treatment.

Description

{Remote medical treatment system based on artificial intelligence}

The present invention relates to a remote medical treatment system based on artificial intelligence, and more specifically, to an artificial intelligence-based remote medical treatment system that enables remote medical treatment to be performed through a server that manages patient bio-information acquired periodically.

The existing medical service and emergency service systems had many structural and functional limitations. In particular, there was a problem that the provision of medical services was greatly affected by time and space constraints, which led to a major disadvantage in that it was difficult to respond quickly in emergency situations. In areas with low medical accessibility, this problem was more serious, and patients frequently did not receive appropriate medical services when they needed them.

In addition, the absence of advanced medical equipment that monitors patients' biometric information in real time and enables precise diagnosis significantly reduces the accuracy of treatment, making precise diagnosis of various diseases difficult, and this has acted as a significant obstacle in establishing and implementing appropriate treatment plans. If the patient's condition is not accurately identified at this time, it can lead to treatment failure, which not only causes the patient to lose the opportunity for recovery, but can also result in serious consequences that can threaten life.

In addition, since there was not enough deployment of appropriate medical personnel, provision of rapid medical services, and establishment of infrastructure to respond to emergency situations in case of an emergency, the 'golden time' to save patients' lives was missed, which had a negative impact on treatment outcomes.

In this way, the existing medical service and emergency service systems have failed to respond appropriately to emergency situations and have revealed serious limitations in providing patients with appropriate diagnosis and treatment at the time of need. The above-mentioned problems have significantly reduced the efficiency and effectiveness of the medical system, posing a significant risk factor in protecting patients' health and lives.

Therefore, there was an urgent need for the introduction of cutting-edge technologies that could overcome temporal and spatial constraints, enable real-time monitoring and precise diagnosis, and develop a system that could respond quickly to emergency situations.

The present invention is intended to solve the above-mentioned problems, and can be installed both indoors and outdoors to provide medical services anytime and anywhere by overcoming time and space constraints, and provides a treatment space that is accessible from any location where a patient needs medical services, thereby increasing the equality of medical services by allowing patients in areas with low medical accessibility to receive treatment quickly.

Real-time monitoring of the patient's bio-information and advanced diagnosis through various precision diagnostic equipment can be performed, which greatly improves the accuracy of diagnosis and, as a result, can quickly provide more suitable treatment methods to the patient. In particular, precise identification of health status through various precision diagnostic equipment contributes to maximizing the treatment effect and shortening the recovery time.

Rapid decision-making support through artificial intelligence models can significantly enhance the ability to respond to emergency situations, allowing real-time analysis of the patient's health status, automatic recognition of high-urgency situations, notification to appropriate medical staff, or calling rescue means when necessary. This function plays a critical role in securing the 'golden time' in emergency situations, and makes a decisive contribution to saving the patient's life.

By learning from multiple patient data, AI models can provide more sophisticated treatment, continuously improving the system's ability to diagnose and provide treatment over time, and enabling customized treatment for various patients.

That is, it provides an artificial intelligence-based remote medical treatment system that overcomes the limitations of the conventional medical service system, enables innovative developments in protecting the health and lives of patients, improves the quality of medical services, and greatly improves the efficiency and effectiveness of medical service provision, thereby becoming the foundation for great progress in the medical field.

According to one embodiment of the present invention, a remote medical treatment system based on artificial intelligence comprises: a display unit configured to display a remote medical treatment program screen for performing remote medical treatment of a patient in the event of an emergency; and a remote medical device including a user input unit; wherein the remote medical device is characterized in that it is installed indoors or outdoors and is installed within a medical treatment space for treatment.

A server connected to the above remote medical device via a network; and a data measurement device connected to the server via a network and worn on a patient's body to periodically measure biometric information; wherein the remote medical device includes a precision diagnosis device provided in the treatment space to measure precise biometric information of the patient, and the precision diagnosis device includes at least one of a cardiopulmonary flow meter, an asthma tester, an eye tester, an intraocular pressure tester, a remote endoscope, a robotic arm stethoscope, a medical magnifying glass, a patient monitoring device, a urine analyzer, a blood pressure monitor, a blood glucose meter, an electrocardiograph, a compact ultrasound diagnostic device, and a compact radiography device; and when the remote medical device detects that a patient has entered the treatment space via the user input unit or the precision diagnosis device, it displays an information collection screen for remote treatment of the patient via the display unit, and when the remote medical device receives brief situation information about the current status of the patient from the user input unit, it requests the server to transmit the patient's biometric information received from the data measurement device, and based on the situation information, At least one of the precision diagnosis devices is activated to enable diagnosis, and the remote medical device includes an artificial intelligence model that performs remote medical treatment based on biometric and clinical data of a plurality of patients, wherein the artificial intelligence model identifies the health status of the patient based on the precision biometric information and the biometric information measured from the precision diagnosis device, and the remote medical device transmits, in response to the health status of the patient identified through the artificial intelligence model, to a first user terminal of a medical staff corresponding to the diagnosis result among a plurality of medical staff lists stored in the remote medical device, and when the remote medical device receives a request for remote medical treatment from the first user terminal, the remote medical device performs remote medical treatment through a video and text call unit provided in the remote medical device, and when the artificial intelligence model identifies the health status and exceeds a preset level of urgency, the remote medical device calls an emergency means for patient transport provided in response to the remote medical device, and when the artificial intelligence model identifies the health status and does not exceed a preset level of urgency, the remote medical device automatically reserves and creates a treatment schedule with a medical staff corresponding to the diagnosis result. It is characterized by.

The above remote medical device displays a pop-up window for inputting the patient's language, disability information, and physical information on the display unit, and when receiving a user input from the patient for inputting information about the language, disability information, and physical information, performs remote treatment with the first user terminal through an interface that enables remote treatment in response to the language, disability information, and physical information, and the remote medical device further includes a robot assistance device for emergency treatment, and the remote medical device controls emergency treatment for a wounded area through the robot assistance device if the artificial intelligence model identifies a health condition and does not exceed a preset level of urgency, and the remote medical device includes a patient detection sensor that detects the patient's body temperature and motion, and is characterized in that it activates at least one function among oxygen supply, sterilization, medical waste sealing request, and air purification in response to the treatment result and the patient condition measured through the patient detection sensor.

It can be installed both indoors and outdoors to provide medical services anytime and anywhere, overcoming time and space constraints. It also provides a treatment space that is accessible to patients from any location where they need medical services, thereby increasing the equality of medical services by allowing patients in areas with low medical accessibility to receive treatment quickly.

Real-time monitoring of the patient's bio-information and advanced diagnosis through various precision diagnostic equipment can be performed, which greatly improves the accuracy of diagnosis and, as a result, can quickly provide more suitable treatment methods to the patient. In particular, precise identification of health status through various precision diagnostic equipment contributes to maximizing the treatment effect and shortening the recovery time.

Rapid decision-making support through artificial intelligence models can significantly enhance the ability to respond to emergency situations, allowing real-time analysis of the patient's health status, automatic recognition of high-urgency situations, notification to appropriate medical staff, or calling rescue means when necessary. This function plays a critical role in securing the 'golden time' in emergency situations, and makes a decisive contribution to saving the patient's life.

By learning from multiple patient data, AI models can provide more sophisticated treatment, continuously improving the system's ability to diagnose and provide treatment over time, and enabling customized treatment for various patients.

In other words, it is possible to provide an artificial intelligence-based remote medical treatment system that overcomes the limitations of conventional medical service systems, enables innovative developments in protecting patients' health and lives, improves the quality of medical services, and greatly improves the efficiency and effectiveness of medical service provision, thereby becoming the foundation for great progress in the medical field.

FIG. 1 is a diagram schematically illustrating the configuration of a remote diagnosis system based on artificial intelligence according to one embodiment of the present invention.
FIG. 2 is a drawing illustrating a specific configuration of a remote diagnosis system based on artificial intelligence according to one embodiment of the present invention.
FIG. 3 is a diagram briefly illustrating an algorithm by which an artificial intelligence-based remote medical treatment system according to one embodiment of the present invention operates.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numbers or symbols refer to components that perform substantially the same functions, and the size of each component in the drawings may be exaggerated for clarity and convenience of explanation. However, the technical idea of the present invention and its core configuration and operation are not limited to the configuration or operation described in the following embodiments. In describing the present invention, if it is determined that a specific description of a known technology or configuration related to the present invention may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted.

In the embodiments of the present invention, terms including ordinal numbers such as first, second, etc. are used only for the purpose of distinguishing one component from another component, and singular expressions include plural expressions unless the context clearly indicates otherwise. In addition, in the embodiments of the present invention, terms such as 'configured', 'include', 'have', etc. should be understood as not excluding in advance the possibility of the existence or addition of one or more other features, numbers, steps, operations, components, parts, or combinations thereof. In addition, in the embodiments of the present invention, a 'module' or 'part' performs at least one function or operation, may be implemented as hardware or software, or may be implemented as a combination of hardware and software, and may be integrated into at least one module and implemented as at least one processor. In addition, in the embodiments of the present invention, at least one of a plurality of elements refers not only to all of the plurality of elements, but also to each one excluding the rest of the plurality of elements or all combinations thereof. Also, "configured to" can be used interchangeably with, for example, "suitable for," "having the capacity to," "designed to," "adapted to," "made to," or "capable of." "Configured to" does not necessarily mean only that something is "specifically designed to" in terms of hardware. Instead, in some contexts, the phrase "a device configured to" can mean that the device is "capable of" doing something in conjunction with other devices or components. For example, the phrase "a processor configured to perform A, B, and C" can mean a dedicated processor (e.g., an embedded processor) for performing the operations, or a generic-purpose processor (e.g., a CPU or application processor) that can perform the operations by executing one or more software programs stored in a memory device.

Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the drawings. This is intended to describe in detail enough to enable a person having ordinary knowledge in the technical field to which the present invention belongs to to easily carry out the invention, and it is to be understood that the technical idea and scope of the present invention are not limited thereby.

FIG. 1 is a diagram schematically illustrating a configuration of an artificial intelligence-based remote diagnosis system according to one embodiment of the present invention, FIG. 2 is a diagram specifically illustrating a configuration of an artificial intelligence-based remote diagnosis system according to one embodiment of the present invention, and FIG. 3 is a diagram briefly illustrating an algorithm by which an artificial intelligence-based remote diagnosis system according to one embodiment of the present invention operates.

Referring to FIGS. 1 to 3, a remote medical treatment system based on artificial intelligence according to one embodiment of the present invention includes a remote medical device (100) including a display unit (120) and a user input unit (110) that display a remote medical treatment program screen for performing remote medical treatment of a patient in the event of an emergency.

A remote medical device (100) according to one embodiment of the present invention includes, for example, a personal computer, a handheld or laptop device, a mobile device (mobile phone, PDA, media player, etc.), a multiprocessor system, a consumer electronic device, a minicomputer, a mainframe computer, a distributed computing environment including any of the aforementioned systems or devices, an edge computing environment in which data is processed at the edge where the data is generated rather than at a central server, and the like, but the configuration is not limited to what is described.

The remote medical device (100) may include at least one processor and memory. Here, the processor may include, for example, a central processing unit (CPU), a graphics processing unit (GPU), a microprocessor, an application specific integrated circuit (ASIC), a field programmable gate array (FPGA), etc., and may have multiple cores.

The memory may be volatile memory (e.g., RAM, etc.), nonvolatile memory (e.g., ROM, flash memory, etc.), or a combination thereof. In addition, the telemedicine device (100) may include additional storage. The storage may include, but is not limited to, magnetic storage, optical storage, etc. The storage may store computer-readable instructions for implementing one or more embodiments disclosed herein, and may also store other computer-readable instructions for implementing an operating system, application programs, etc. The computer-readable instructions stored in the storage may be loaded into the memory for execution by the processor.

In addition, the remote medical device (100) may include a user input unit (110) and an output device. The user input unit (110) may include, for example, a keyboard, a mouse, a pen, a voice input device, a touch input device, an infrared camera, a video input device, or any other input device. In addition, the output device may include, for example, one or more displays, speakers, a printer, or any other output device. In addition, the computing device may use an input device or an output device provided in another computing device as a user input unit or an output device. In addition, the computing device may include a communication module that enables the computing device to communicate with another device. Here, the communication module may include a modem, a network interface card (NIC), an integrated network interface, a radio frequency transmitter/receiver, an infrared port, a USB connection, or other interface for connecting the computing device to another computing device. The communication module may include a wired connection or a wireless connection.

Each component of the remote medical device (100) may be connected by various interconnections such as buses (e.g., peripheral component interconnect (PCI), USB, firmware (IEEE 1394), optical bus structure, etc.) or may be connected by a network. Terms such as “component,” “system,” etc., used in this specification generally refer to a computer-related entity that is hardware, a combination of hardware and software, software, or software in execution.

A remote medical device (100) according to one embodiment of the present invention may include a display unit (120), and the display unit (120) may be implemented in various display methods, such as a liquid crystal, a plasma, a light-emitting diode, an organic light-emitting diode, a surface-conduction electron emitter, a carbon nanotube, a nano-crystral, etc. In the case of a liquid crystal method, the display unit (120) includes a liquid crystal display panel, a backlight unit that supplies light to the liquid crystal display panel, and a panel driver that drives the liquid crystal display panel. Meanwhile, the display unit (120) may be implemented with an OLED panel, which is a self-luminous element, without a backlight unit.

In an artificial intelligence-based remote medical treatment system according to one embodiment of the present invention, an emergency situation means a state that poses a serious threat to the health of a patient, and usually includes health problems that may threaten life or cause serious damage, such as sudden heart problems, difficulty breathing, serious trauma, serious infection, and loss of consciousness.

The present invention is designed to accurately identify an emergency situation and take immediate action necessary for the patient. When the above-described emergency situation occurs, the system quickly analyzes changes in the patient's vital signs to determine the emergency situation and provides necessary medical measures in a timely manner, thereby playing an important role in protecting life and supporting healthy recovery.

In an artificial intelligence-based remote medical treatment system according to one embodiment of the present invention, remote medical treatment means a process of providing medical services while the medical service provider and the patient are physically separated, and in this process, medical staff perform diagnosis, consultation, treatment plan establishment, monitoring, and other medical services by utilizing the Internet, video, audio, and other communication technologies.

Telemedicine according to one embodiment of the present invention is particularly useful for patients living in areas with limited accessibility, and suggests the possibility of providing high-quality medical services even in areas with insufficient medical resources. In addition, telemedicine reduces time and space constraints between patients and medical staff, and enables fast and efficient medical responses, and can be implemented to improve patient health management and enhance the quality of medical services by integrating various functions such as patient condition monitoring, consultation, provision of treatment guidelines, and medical record management.

In the remote medical treatment system based on artificial intelligence according to one embodiment of the present invention, a remote medical treatment program refers to a software application that enables remote communication between a medical service provider and a patient, and the program according to the present invention supports transmission, storage, and retrieval of medical information, monitors the health status of a patient, and provides important data to medical staff. The remote medical treatment program can usually be designed to include various functions including diagnosis support, establishment of treatment plans, patient monitoring, and medical consultation. In addition, it provides a user-friendly interface so that patients and medical staff can easily use it, and can adopt advanced technologies for data security and personal information protection, and in addition, the program according to the present invention can be operated on various platforms such as a cloud-based system, a mobile application, and a web-based platform to provide efficient medical services. In other words, the remote medical treatment program of the present invention plays an important role in increasing the accessibility of medical services, helping to efficiently distribute medical resources, and improving patient satisfaction and the quality of medical services.

A remote medical device (100) according to one embodiment of the present invention is a general term for equipment that can monitor a patient's vital signs and transmit information to medical staff in real time, and can be implemented to continuously monitor the patient's health status by having built-in sensors that measure various vital information such as skin temperature, heart rate, blood pressure, and blood oxygen saturation. Through this, medical staff can grasp the patient's condition in real time even from a remote location and provide necessary diagnosis or treatment guidelines.

In addition, a remote medical device (100) according to one embodiment of the present invention can improve overall health care efficiency by providing rapid medical services to patients in emergency situations, as well as enabling regular health care and preventive medical approaches, and can be implemented to improve the quality of treatment by providing a user-friendly interface so that patients can easily operate it, thereby facilitating communication between patients and medical staff.

An artificial intelligence-based remote medical treatment system according to one embodiment of the present invention includes a server (200) connected to a remote medical device (100) via a network.

The server (200) according to one embodiment of the present invention performs the function of monitoring the health status of the patient, managing medical data, analyzing bio-signal data received from the patient to determine the health status of the patient, and providing a notification to the medical staff when necessary. In addition, the server (200) according to the present invention also stores and manages the medical data of the patient, and provides this data so that it can be referenced during the diagnosis and treatment process, and the database of the server (200) includes the patient's health record, medical record, drug prescription information, etc., through which the server (200) can provide various applications and interfaces that support the medical staff to remotely diagnose the patient's condition and establish a treatment plan.

An artificial intelligence-based remote medical treatment system according to one embodiment of the present invention is network-connected to a server (200) and includes a data measurement device (400) worn on a patient's body to periodically measure biometric information.

A data measurement device (400) according to one embodiment of the present invention serves to periodically measure a patient's bio-information, and includes a plurality of sensors inside. These multiple sensors measure various bio-signals such as the patient's heart rate, blood pressure, and body temperature, and the measured data is transmitted to a server (200) using wireless communication technology. The server (200) can monitor the patient's health status based on this bio-information, and, if necessary, send a notification to a medical professional.

According to a specific embodiment, the data measurement device (400) according to the present invention is designed to be easily portable and implemented so that the patient can conveniently wear it in daily life, and furthermore, it may include a sensor that can measure not only the patient's bio-information but also environmental data, through which information on the patient's living environment can also be collected.

In addition, the data measurement device (400) according to the present invention is implemented to take into account the convenience of the user, for example, so that the user can easily put on and remove the device, and so that the user can replace the battery by himself/herself when necessary, and can be implemented to minimize skin irritation even when worn for a long time by being made of a hypoallergenic material.

That is, the server (200) according to the present invention analyzes information received from the data measurement device (400) to monitor the patient's health status in real time, and the analyzed data is stored together with the patient's medical records so that a medical professional can refer to it when evaluating the patient's health status. In addition, when an abnormality is detected, a notification is immediately sent to a medical professional so that a quick response can be made.

A remote medical device (100) according to one embodiment of the present invention includes a precision diagnosis device (130) installed in a medical treatment space to measure precise biometric information of a patient.

A precision diagnosis device (130) according to one embodiment of the present invention is intended to precisely measure various bio-information of a patient, and includes sensors capable of measuring various bio-signals such as blood pressure, electrocardiogram, and body temperature. This device plays an important role in monitoring the patient's health status in real time and enabling early diagnosis and treatment of diseases. The precision diagnosis device (130) according to the present invention was designed considering the convenience of the user, and was designed so that even patients who have difficulty moving can easily use it. In addition, this device provides accurate and reliable data to medical staff, so that more effective medical services can be provided.

The precision diagnosis device (130) according to the embodiment is manufactured in a form that can be attached to the skin, so that the patient can wear it without any discomfort during daily life, and collects and analyzes biometric information in real time. This data is transmitted to a remote medical device (100) through wireless communication technology, and the information enables medical staff to monitor the patient's health status and take appropriate medical measures. The use of this precision diagnosis device (130) greatly improves patient convenience, increases accessibility to medical services, and contributes to improving the overall quality of medical care.

A precision diagnostic device (130) according to one embodiment of the present invention may include at least one of a cardiopulmonary flow meter, an asthma tester, an eye tester, an intraocular pressure tester, a remote endoscope, a robotic arm stethoscope, a medical magnifying glass, a patient monitoring device, a urine analyzer, a blood pressure meter, a blood glucose meter, an electrocardiograph, a compact ultrasound diagnostic device, and a compact radiography device.

More specifically, each device in the precision diagnosis device (130) according to one embodiment of the present invention is designed for a specific medical diagnosis and can be used interactively to precisely evaluate the health status of the user. For example, the cardiopulmonary flow meter evaluates the respiratory function of the user, the asthma tester evaluates the presence and severity of asthma, the vision tester evaluates the vision of the user, the tonometry tester measures the pressure within the eye to evaluate the risk of glaucoma, the teleendoscopy examines the condition of internal organs, the robotic arm stethoscope listens to the heart and lung sounds to evaluate abnormalities, the medical magnifying glass examines the condition of skin or tissue in detail, the patient monitoring device continuously monitors the vital signs of the patient, the urinalysis analyzer analyzes urine samples to evaluate indicators of various diseases, the blood pressure monitor and the blood sugar monitor measure blood pressure and blood sugar levels, respectively, the electrocardiograph records the electrical activity of the heart to diagnose heart disease, and the compact ultrasound diagnostic device and the compact radiography device each provide images of internal organs to aid in diagnosis.

Meanwhile, the precision diagnosis device (130) according to the present invention may include all types of diagnostic devices that can be used independently or in combination to accurately and quickly evaluate the user's health status.

According to one embodiment of the present invention, when a remote medical device (100) detects that a patient has entered a treatment space through a user input unit or a precision diagnosis device (130), it can display an information collection screen for remote treatment of the patient through a display unit.

More specifically, the remote medical device (100) according to the present invention receives basic medical treatment information such as physical information and symptoms from the patient through an information collection screen, and the received information is transmitted to a server (200) and stored in a database, which is used by medical professionals to conduct remote medical treatment.

That is, the server (200) analyzes the patient's information to determine a medical professional who needs treatment, transmits the patient's information to the medical professional, and the medical professional starts remote treatment based on the received information, and may request the patient to enter additional information if necessary.

In addition, the remote medical device (100) according to the present invention provides voice and video communication functions to support real-time communication between a medical professional and a patient, and during the treatment process, the medical professional can give treatment instructions to the patient through the remote medical device (100), and the patient can receive treatment or perform necessary tests in accordance with the instructions, and the remote medical device (100) can store all information obtained during the treatment process in a database and utilize it for follow-up treatment or record management.

According to one embodiment of the present invention, when a remote medical device (100) receives brief situational information about a patient's current condition from a user input unit, it requests the server (200) to transmit the patient's bio-information received from the data measurement device (400), and activates at least one of the precision diagnosis devices (130) to enable diagnosis based on the situational information.

More specifically, the remote medical device (100) according to one embodiment of the present invention receives brief situation information about the patient's current condition from the user input unit, and then requests the server (200) to transmit the patient's bio-information from the data measurement device (400). At this time, if the patient reports that he or she is experiencing severe respiratory distress, the remote medical device (100) activates the pulmonary function analysis device capable of analyzing the respiratory condition based on the situation information. At the same time, the function of measuring the patient's heart rate and blood pressure is also activated, so that data is received from the heart rate measurement device and the blood pressure measurement device. The patient's data is transmitted to the server (200) in real time, and the remote medical system analyzes this data to evaluate the patient's condition. If the data indicates a serious condition, the system can immediately identify an emergency situation and send a notification to the emergency rescue team. During this process, the remote medical device (100) continuously monitors the patient's bio-information and, if necessary, can activate other diagnostic devices to provide additional medical support.

A remote medical device (100) according to one embodiment of the present invention includes an artificial intelligence model that enables remote medical treatment to be performed based on biometric and clinical data for a plurality of patients, and the artificial intelligence model can identify the health status of a patient based on precise biometric information and biometric information measured from a precision diagnosis device (130).

The artificial intelligence model applied to the remote medical device (100) according to the present invention performs remote medical treatment based on biometric and clinical data collected from multiple patients, and the artificial intelligence model analyzes precise biometric information and other biometric information measured from the precision diagnosis device (130) to identify the patient's health status.

Specifically, the AI model interprets bio-signals such as electrocardiograms, blood pressure, and body temperature to detect signs of specific health problems, and for example, the AI model can analyze electrocardiogram data to identify the presence of heart disease. In this process, the model learns patterns corresponding to various heart diseases and finds these patterns in the measured data. If the electrocardiogram pattern matches a specific disease, the model transmits the information to a doctor, and the doctor makes a diagnosis based on the data and suggests an appropriate treatment method. In this way, the remote medical device (100) supports rapid assessment of the patient's condition and taking necessary medical measures.

Meanwhile, the artificial intelligence model according to one embodiment of the present invention is based on a convolutional neural network (CNN) and a recurrent neural network (RNN), is optimized for processing image and sequence data, and can be implemented to be utilized particularly in the fields of image recognition, speech recognition, and natural language processing. Meanwhile, a convolutional neural network is useful for recognizing the spatial hierarchical structure of an image, and a recurrent neural network is suitable for learning the temporal continuity of sequence data, and the artificial intelligence model according to the present invention can process various types of data by combining the two models, thereby providing more accurate and detailed analysis of the user's input data.

As a specific example, an artificial intelligence model according to an embodiment of the present invention collects symptom information such as dyspnea, chest pain, cough, and fever from a user through a user input unit when a patient experiences severe dyspnea, and at the same time, obtains precise biometric information in which biometric information such as the patient's electrocardiogram, blood pressure, oxygen saturation, and respiratory rate are automatically measured by a data measurement device (400) and transmitted to a server (200), and analyzes the collected biometric information and symptom data to evaluate the patient's health status. In this process, the model uses a machine learning algorithm to classify the cause of dyspnea into heart disease, asthma, pneumonia, etc., and based on the analysis result, if the artificial intelligence model determines that the patient is likely to be suffering from a serious heart disease (e.g., myocardial infarction), it immediately notifies the medical staff, and at this time, the output value may include a warning message indicating the need for immediate medical treatment (e.g., emergency transport, oxygen therapy, emergency medication prescription) together with the diagnosis result.

A remote medical device (100) according to one embodiment of the present invention transmits to a first user terminal of a medical staff corresponding to a diagnosis result among a plurality of medical staff lists stored in the remote medical device (100) in response to the health status of a patient identified through an artificial intelligence model, and when a request for remote diagnosis is received from the first user terminal, remote diagnosis can be performed through a video and text call section provided in the remote medical device (100).

Meanwhile, the user terminal according to the present invention, like the above-described remote medical device (100), includes, for example, a personal computer, a handheld or laptop device, a mobile device (mobile phone, PDA, media player, etc.), a multiprocessor system, a consumer electronic device, a minicomputer, a mainframe computer, distributed computing including any of the above-described systems or devices, an edge computing environment that processes data at the edge where the data is generated rather than at a central server, and the like, and the configuration is not limited to what is described.

More specifically, the remote medical device (100) according to one embodiment of the present invention identifies the health status of a patient through an artificial intelligence model, selects medical staff appropriate for the status, and transmits a treatment request to the first user terminal. At this time, the list of medical staff is stored in advance in the remote medical device (100) and may include information such as each medical staff's specialty and experience. The user of the first user terminal, i.e., the medical staff, receives the request for remote treatment and connects to the remote medical device (100) in response thereto. Once the connection is established, remote treatment is performed between the patient and the medical staff through the video and text call section provided in the remote medical device (100). During this process, the medical staff can check information about the patient's health status in real time and provide necessary medical advice or treatment instructions. During the remote treatment, the patient's vital signs or health status can be monitored in real time and transmitted to the medical staff. Through this, the medical staff can more accurately evaluate the patient's condition and provide appropriate medical services.

According to one embodiment of the present invention, a remote medical device (100) can call an emergency means for patient transport prepared in response to the remote medical device (100) when the artificial intelligence model identifies a health condition and exceeds a preset level of urgency.

More specifically, the remote medical device (100) according to the present invention collects the patient's health data and analyzes the patient's health status using an artificial intelligence model, and at this time, the artificial intelligence model evaluates the patient's health status based on the patient's bio-signals such as heart rate, blood pressure, and body temperature. If the artificial intelligence model determines that the patient's health status exceeds the pre-set emergency level standard as a result of the analysis, the remote medical device (100) automatically activates the emergency system prepared in advance. In this process, the remote medical device (100) is connected to a system that calls an ambulance or other emergency medical services, and transmits the patient's location information and health status to an emergency service provider, and at the same time, the remote medical device (100) sends an alarm to the patient or the patient's guardian to notify the patient of the emergency situation. Through this process, the patient can quickly receive the necessary medical services, and the remote medical device (100) ensures the patient's safety and prevents medical accidents by enabling an appropriate response in the event of an emergency.

A remote medical device (100) according to one embodiment of the present invention can automatically reserve and create a treatment schedule with medical staff corresponding to the treatment result if the artificial intelligence model identifies the health condition and does not exceed a preset level of urgency.

More specifically, the remote medical device (100) according to one embodiment of the present invention analyzes the patient's health status through an artificial intelligence model, and if the patient's health status does not exceed the pre-set urgency standard based on the analysis, that is, if the patient's condition is determined to be not urgent, automatically reserves and creates a treatment schedule with a medical staff who requires treatment. In this process, the remote medical device (100) selects the most suitable medical staff by considering the user's schedule, preference, and location information, and finds a time compatible with the user among the medical staff's schedules and proceeds with the treatment reservation. When the reservation is completed, the remote medical device (100) provides the user with detailed information on the reserved treatment schedule and, if necessary, also provides an option to change or cancel the reservation. All of these processes are performed automatically, and the user can conveniently manage the treatment schedule without separate manual operation.

A remote medical device (100) according to one embodiment of the present invention displays a pop-up window on a display unit for inputting a patient's language, disability information, and body information, and when receiving a user input for inputting information about the patient's language, disability information, and body information, remote medical treatment can be performed with a first user terminal through an interface that enables remote medical treatment to be performed in response to the language, disability information, and body information.

More specifically, the remote medical device (100) according to the present invention configures a remote medical treatment interface based on the input of the patient's language, disability information, and physical information, and at this time, the language, disability information, and physical information entered by the patient are provided to medical staff in accordance with the treatment process, and through this, the medical staff can provide customized treatment considering the individual patient's situation. The patient's information is stored in a database so that the medical staff can access it, and includes information such as the patient's medical history, physical measurements, language, and disability information. This information is used for the doctor's diagnosis and treatment plan establishment during remote treatment, and the remote medical device (100) also provides various communication means for communication between the patient and the medical staff, so that two-way communication can be smoothly achieved. Through this, the patient can directly inquire the medical staff about his or her health condition, and the medical staff can monitor the patient's condition in real time and provide appropriate medical services.

For example, when a foreign patient seeks treatment, the remote medical device (100) can be implemented to provide an interface that supports various languages, through which the patient can input language, disability information, and physical information in his/her own language, and the medical staff can provide appropriate treatment to the patient based on this information.

In addition, for visually impaired patients, the remote medical device (100) provides an environment in which language, disability information, and physical information can be input through a voice recognition function and a screen reading program, and the patient inputs information through a voice command, and the device reconfirms the information through a voice, thereby enabling visually impaired patients to smoothly use remote medical treatment services.

In addition, for hearing-impaired patients, the remote medical device (100) can provide an interface that supports sign language or subtitles, and the patient can input language, disability information, and physical information in sign language or writing, and the medical staff can accurately understand the patient's condition and take appropriate measures through this. In addition, all voice information generated during the treatment process is converted into text and provided so that the hearing-impaired patient can understand it.

That is, the remote medical device (100) according to one embodiment of the present invention can be implemented so that patients with various physical conditions or language and disability conditions can effectively use remote medical treatment services.

A remote medical device (100) according to one embodiment of the present invention further includes a robot assistance device for emergency treatment, and the remote medical device (100) can control emergency treatment to be provided to a wounded area through the robot assistance device if the artificial intelligence model identifies the health condition and does not exceed a preset level of urgency.

More specifically, the robotic assistive device according to the present invention can be implemented to approach a wounded area of a patient and perform emergency treatment such as disinfecting the wound, applying medicine if necessary, and wrapping a bandage, and in this process, the artificial intelligence model evaluates the severity of the wound and adjusts the operation of the robotic assistive device in real time to provide appropriate emergency treatment to the patient, and further, the remote medical device (100) transmits the patient's condition to a medical professional and, if necessary, can execute additional medical measures through the robotic assistive device according to the instructions of the medical professional.

A remote medical device (100) according to one embodiment of the present invention includes a patient detection sensor that detects a patient's body temperature and movement, and can activate at least one function among oxygen supply, sterilization, medical waste sealing request, and air purification in response to the diagnosis result and the patient's condition measured through the patient detection sensor.

More specifically, the remote medical device (100) according to one embodiment of the present invention detects whether a patient is present in the examination booth by including a heat detection sensor and a motion detection sensor, and for example, when a patient enters the booth, these sensors are activated to monitor the patient's body temperature and motion. When a patient is present in the examination booth, the remote medical device (100) continuously maintains an appropriate oxygen supply and purifies the air, thereby ensuring the patient's comfort and safety and optimizing the examination environment.

Meanwhile, when the patient leaves the examination booth, i.e., upon leaving, the remote medical device (100) automatically starts the sterilization, disinfection and cleaning process, which maintains hygiene within the examination booth and automatically prepares for the next patient, and also, medical waste is isolated and sealed to minimize the risk of cross-contamination and maintain environmental hygiene.

These processes are controlled by the artificial intelligence model of the remote medical device (100) and are automatically performed after use of the treatment booth, providing a safe and sanitary environment for both medical staff and patients.

A control unit according to one embodiment of the present invention can identify that a patient has entered a treatment space if a patient detection level derived based on [Mathematical Formula 1] that takes into account a plurality of measurement values measured through a patient detection sensor exceeds a preset detection level.

[Mathematical Formula 1]

In the above [Mathematical Formula 1], A represents the temperature change (°C, Celsius degrees) in the environment that can change due to the patient's body heat, B represents the intensity of vibration or movement by the patient (m/s²), C represents the size of ambient noise (dB, decibel), D represents the degree of change in lighting in the space (lx, lux), and E represents the change in chemical concentration in the space (ppm).

More specifically, [Mathematical Formula 1] according to the present invention reflects that as the value of A increases, the patient detection rate increases through a logarithmic function, but the increase rate gradually slows down, which means that although temperature change is an important indicator of the presence of a patient, the change is not significantly detected above a certain level, and that as the value of B increases, the patient detection rate increases in proportion to the square, which means that the greater the patient's movement, the higher the possibility of the patient's presence, and that when a patient is in a treatment space, a certain amount of noise increase is expected, so that as the value of C increases, the patient detection rate increases through a square root function, but the increase rate is gradual compared to B, and that as D increases, the patient detection rate increases linearly, and that as E increases, the influence of D on the patient detection rate decreases, that is, E plays a role in regulating the influence of D, and through this, the presence or absence of a patient can be determined.

That is, the values of each variable used in [Mathematical Formula 1] according to the present invention change as a patient enters the treatment space, and the control unit calculates a patient detection map based on [Mathematical Formula 1] to identify the presence of the patient, thereby enabling detection of the patient's entry with a higher probability.

100: Telemedicine Device
110: User Input
120: Display section
130: Precision diagnostic device
200: Server
300: First user terminal
400: Data measurement device

Claims (3)

In a remote medical treatment system based on artificial intelligence,
A display unit configured to display a remote medical treatment program screen for performing remote medical treatment of a patient in the event of an emergency; and
A remote medical device including a user input unit;
The above remote medical device is installed indoors or outdoors and is placed in a treatment space for treatment.
A server network-connected to the above remote medical device;
A data measurement device that is connected to the above server and is networked and is worn on the patient's body to periodically measure biometric information;
The above remote medical device includes a precision diagnostic device installed in the above treatment space to measure the patient's precise biometric information.
The above precision diagnostic device includes at least one of a cardiopulmonary flow meter, an asthma tester, an eye tester, a tonometry device, a remote endoscope, a robotic arm stethoscope, a medical magnifying glass, a patient monitoring device, a urine analyzer, a blood pressure monitor, a blood glucose meter, an electrocardiograph, a compact ultrasound diagnostic device, and a compact radiography device.
When the above remote medical device detects that a patient has entered the treatment space through the user input unit or the precision diagnosis device, it displays an information collection screen for remote treatment of the patient through the display unit.
When the above remote medical device receives brief situation information about the patient's current condition from the user input unit, it requests the server to transmit the patient's bio-information received from the data measurement device, and activates at least one of the precision diagnosis devices to enable diagnosis based on the situation information.
The above remote medical device includes an artificial intelligence model that performs remote medical treatment based on biometric and clinical data for multiple patients, and the artificial intelligence model identifies the health status of the patient based on the precise biometric information and the biometric information measured from the precision diagnosis device.
The above remote medical device transmits to the first user terminal of a medical staff member corresponding to the health condition of the patient identified through the above artificial intelligence model among a list of multiple medical staff members stored in the above remote medical device.
When the above remote medical device receives a request for remote treatment from the first user terminal, it performs remote treatment through the video and text call section provided in the above remote medical device.
The above remote medical device identifies the health condition of the artificial intelligence model and, if it exceeds the preset level of urgency, calls the prepared emergency means for patient transport in response to the above remote medical device.
The above remote medical device automatically reserves and creates a medical appointment schedule with medical staff corresponding to the health condition if the artificial intelligence model identifies the health condition and does not exceed the preset level of urgency.
The above remote medical device displays a pop-up window for inputting the patient's language, disability information and physical information on the display unit, and when receiving user input for inputting information on the language, disability information and physical information from the patient, remote treatment is performed with the first user terminal through an interface that enables remote treatment to be performed in response to the language, disability information and physical information.
The above telemedicine device further includes a robotic assistive device for emergency treatment,
The above remote medical device controls the robot assistant device to provide emergency treatment to the injured area if the artificial intelligence model identifies the health condition and does not exceed the preset level of urgency.
The above remote medical device includes a patient detection sensor that detects the patient's body temperature and movement, and activates at least one function among oxygen supply, sterilization, medical waste sealing request, and air purification in response to the health condition and the patient condition measured through the patient detection sensor.
The control unit of the above remote medical device identifies that a patient has entered the treatment space if the patient detection level derived based on [Mathematical Formula 1] considering multiple measurement values measured through the patient detection sensor exceeds the preset detection level.

[Mathematical Formula 1]
A remote medical treatment system based on artificial intelligence, characterized in that in the above [Mathematical Formula 1], A represents the temperature change (°C, Celsius degree) in the environment that can change due to the patient's body heat, B represents the intensity of vibration or movement (m/s²) caused by the patient, C represents the size of ambient noise (dB, decibel), D represents the degree of change in lighting in the space (lx, lux), and E represents the change in chemical concentration in the space (ppm). delete delete