JP2024091324A - Treatment audit system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a treatment audit system for auditing whether or not beauty treatment is properly performed.

SOLUTION: A medical audit system for recording treatment in a beauty clinic and auditing whether or not the treatment is performed according to specific procedures, includes the functions of: generating a model relating to the respective procedures from an image obtained by photographing the treatment; analyzing a newly acquired moving image; and auditing whether or not the treatment in the moving image is performed according to the procedures. The medical audit system thus makes it possible to automatically audit whether or not the respective procedures of the treatment are appropriately performed, thereby efficiently performing quality control of the treatment, securing appropriateness of the surgery, and reducing the risk of medical errors.

SELECTED DRAWING: None

COPYRIGHT: (C)2024,JPO&INPIT

Description

The present invention relates to a treatment audit system.

In recent years, the need for aesthetic medical treatment has increased, with many hospitals and clinics offering a wide variety of aesthetic medical treatments. In response to this growing need, there is also growing importance of providing aesthetic medical treatment more efficiently, accurately, and safely.

Japan Society of Aesthetic Plastic Surgery, "Japan Society of Aesthetic Plastic Surgery Newsletter Aesthetic Medical Practice Guidelines (Revised Edition for 2021)," published on October 10, 2022

The present invention provides a method for evaluating whether cosmetic medical treatment is being performed appropriately, in order to meet the need for more efficient, more accurate, and safer cosmetic medical treatment.

The present invention provides an evaluation method, evaluation device, evaluation system, evaluation program, analysis method, analysis device, analysis system, analysis program, medical accident prevention method, medical accident prevention device, medical accident prevention system, medical accident prevention program, medical safety assurance method, medical safety assurance device, medical safety assurance system, and medical safety assurance program for determining whether cosmetic medical care is being performed more efficiently, more accurately, and more safely.

The present invention can improve the safety and efficiency of treatment. It can also use a terminal to provide support for treatment and ensure safety.

Embodiments of the present invention can be used as an evaluation method, evaluation device, evaluation system, evaluation program, analysis method, analysis device, analysis system, analysis program, medical accident prevention method, medical accident prevention device, medical accident prevention system, medical accident prevention program, medical safety assurance method, medical safety assurance device, medical safety assurance system, and medical safety assurance program for determining whether cosmetic medical care is being performed more efficiently, more accurately, and more safely.

[Technology 1]
The present invention is a system for monitoring compliance with manuals for procedures in beauty clinics. Specifically, the system captures information on the actions of medical staff during procedures and the tools they use in real time, and uses AI to determine whether the procedures are being performed according to the manual. If proper procedures are not performed, the system immediately issues an alert. This improves patient safety and reduces the possibility of medical errors.

Specifically, the present invention is a system for monitoring compliance with a manual for treatment procedures in a beauty clinic. The problem that the present invention aims to solve is the deterioration of patient safety due to human error during surgery or examination or deviation from the manual. Specifically, in treatment at a beauty clinic where compliance with procedures is required, human error and non-compliance with routines are serious problems. The specific content of the present invention is a system that captures information on the movements of medical personnel and the tools they use in real time and uses artificial intelligence (AI) to determine whether those actions conform to the manual. If appropriate actions are not taken, an alert is issued immediately, allowing appropriate responses. As an effect of the present invention, first of all, patient safety is significantly improved. By detecting deviations from the manual in real time, it is possible to prevent medical errors. In addition, the reaction of medical personnel to the generated alert and their subsequent actions are also recorded, making it possible to collect information that will contribute to subsequent improvement activities. Furthermore, the present invention promotes training and skill improvement of medical personnel. Based on the generated alert, it is possible to clarify specific points for improvement, such as in what situations medical personnel tend to deviate from the manual or what procedures are difficult.

The system of the present invention includes the following elements. First, sensor devices, such as high-resolution cameras and motion sensors, are used to capture the movements of medical staff. This allows detailed records of the doctor's movements during surgery and the operation of surgical tools. Second, RFID (Radio Frequency Identification) tags and barcode scanners are installed to identify the tools and medicines used.

Motion sensors and high-resolution cameras capture medical staff's movements in real time, and the data is sent to the AI engine. For example, the moment a doctor picks up a surgical instrument, his or her hand movements are captured and information is generated. Specific movement patterns during surgery (e.g., the direction and depth of the incision) are also captured as data.

RFID tags and barcode scanners are used to identify the instruments and medicines used. For example, RFID tags or barcodes attached to syringes, scalpels, and even medicines can be scanned to record which instruments or medicines were used and when. This ensures that the right instruments and medicines are used at the right time.

This data is sent to the AI engine in real time. The AI engine uses a deep learning algorithm to determine whether the data sent is in accordance with the manual. This determination covers a wide range of aspects, including the timing of use of various instruments, surgical procedures, and the amount and timing of drug use.

If any behavior that does not comply with the manual is detected, the AI engine generates an alert and warns medical personnel. The alert can be conveyed in the form of a message displayed on the screen, a voice notification, or a vibration on a specific device (e.g., a smartwatch). At the same time, detailed information about the alert and appropriate responses are also provided. In this way, by combining specific sensor devices and AI technology, the present invention monitors compliance with medical procedure manuals at beauty clinics in real time, improving patient safety.

The audit system according to this embodiment will now be described in detail.
Incomplete or inadequate records of procedures in beauty clinics make proper audits difficult. Specifically, it is difficult with current technology to verify whether procedures have been performed correctly and whether safety assessments have been properly carried out. Also, standard safety procedures are fragmented and difficult to ensure compliance.

This invention makes it possible to automatically record and audit treatments at beauty clinics. By inputting a video of the treatment, generating a learning model based on appropriate procedures, and analyzing the newly acquired video, it becomes possible to automatically audit whether the treatment is being performed according to the procedures.

As one embodiment of the present invention, the following procedure is considered.
1. Photographing and acquiring images of treatment procedures at a beauty clinic. Specifically, photographing the procedure of a treatment (HIFU) in which ultrasound is irradiated onto the skin to heat it and coagulate necrotic tissue.
2. A learning model is generated based on the captured images. At this time, a machine learning algorithm is used to learn the correct treatment procedure. Specifically, it learns the procedure to pinpoint irradiation to the required depth and to exclude certain areas (under the eyes, temples, etc.).
3. Analyze the newly acquired video and audit whether the actions in it are being performed according to procedure.

The present invention provides a medical audit system for recording and auditing treatments at beauty clinics, comprising:
A first learning model created by machine learning using information indicating whether or not a first situation in which a lift-up treatment using metabolism is being performed in an image of the treatment and the image as training data;
A second learning model created by machine learning using information indicating whether or not a second situation is occurring in which pinpoint irradiation is being performed to a depth required for “lifting up” with ultrasound and the image as training data; and
A third learning model created by machine learning using information indicating whether or not the third situation is one in which HIFU therapy is being performed and the image as training data;
A fourth learning model created by machine learning using information indicating whether or not a fourth situation is occurring in which a treatment using high intensity focused ultrasound (HIFU) is being performed and the image as training data; and
A fifth learning model created by machine learning using information indicating whether or not a fifth situation in which a non-surgical lift-up treatment is being performed and the image as training data;
A sixth learning model created by machine learning using information indicating whether or not a sixth situation is being treated by combining high intensity focused ultrasound and an ultrasound image diagnostic function and the image as training data; and
A seventh learning model created by machine learning using information indicating whether or not a seventh situation is occurring in which irradiation is being performed inside the pupil midline or at an inappropriate location, and the image as training data; and
An eighth learning model created by machine learning using information indicating whether or not an eighth situation in which the transducer and the skin are in proper contact and the image as training data; and
A ninth learning model created by machine learning using information indicating whether or not a ninth situation in which an appropriate irradiation range is confirmed and the image as training data; and
A learning model storage unit that stores the
An acquisition unit for acquiring a video of the treatment;
An auditing unit that audits whether the treatment is being performed correctly by providing the video to the first to ninth learning models and determining whether the video is in the first to ninth situations;
A medical audit system that includes:

The system may acquire video footage in real time, and the auditing unit may audit the video footage in real time. The system may further include an alarm unit that issues an alarm when it is detected that the treatment is not being performed correctly.

Below, we explain the audit model used by the Audit Department. The audit model mainly uses deep learning techniques. This model judges the face band application process for each frame of video and evaluates whether the correct application process has been followed. Specifically, it uses a Convolutional Neural Network (CNN) to extract image features for each frame, and Long Short-Term Memory (LSTM) to determine temporal continuity.

Specifically, the model is generated by the following steps: Data collection:
Collect video data of correct and incorrect use of the faceband, preferably with labels for each step.
Data preprocessing:
Split the video into frames and organize each frame into a dataset along with its label.
Model training:
CNN is used to extract image features for each frame, and LSTM is used to learn temporal continuity.
Model evaluation:
The performance of the model is evaluated using a test dataset. Specific evaluation indicators include accuracy, precision, recall, and F1 score.
Applying the model:
The model will be applied to videos from actual medical settings to audit whether treatments are being performed properly.

[Technology 2]
The invention is an AR (Augmented Reality) device that allows medical personnel to smoothly refer to manuals when performing procedures. This device is a headset or glasses type, and displays manual instructions directly within the field of view of the medical personnel performing surgery. This makes it possible to check the manual more efficiently and quickly than conventional paper-based or electronic manual references.

The problem that this invention aims to solve is the difficulty of referring to the manuals required when performing medical procedures, which prevents smooth examinations and surgery. In particular, some procedures are complex, and if the appropriate manual cannot be instantly checked, the quality and efficiency of the procedures may decline.

The specific content of this invention is a system that utilizes AI and AR (Augmented Reality) technology to provide appropriate manuals for each procedure. When a medical professional starts a procedure, the AI selects the manual corresponding to that procedure from a database and displays it in real time through an AR device (e.g., AR glasses or a head-mounted display). At that time, a voice recognition system is also used, allowing the medical professional to request the next procedure by voice.

The effect of the present invention is that it becomes much easier to refer to the manual, thereby improving the quality and efficiency of medical procedures. Specifically, by using AR technology to visually present the manual in real time, examinations and surgeries can be carried out smoothly. In addition, by using a voice recognition system, it becomes possible to refer to the manual and give instructions on how to proceed even when one's hands are full.

Additionally, the invention can be used in education and training. When educating and training new medical personnel, using the system of the invention could potentially increase the speed at which they learn new procedures.

As described above, the present invention plays an important role in improving the quality and efficiency of medical procedures in beauty clinics.

[Technology 3]
This invention is an AI audit system that integrates the recording of medical examinations and surgeries with the evaluation of compliance with the manual. This system records video of each stage of medical treatment, and then the AI evaluates the degree of compliance with the manual. The AI evaluation results are used as feedback for medical staff, contributing to the provision of higher quality medical services.

The problem that this invention aims to solve is the difficulty of properly evaluating whether medical procedures are being performed in accordance with a manual and recording and analyzing the results over the long term. If this problem cannot be solved, it may be impossible to gain insight into improving the quality of medical procedures, preventing medical errors, and improving the education of medical professionals.

The specific content of this invention is a medical procedure recording and evaluation system that utilizes AI and video recording technology. The AI engine analyzes high-resolution video feeds in real time and evaluates whether each step of a procedure or examination is performed according to the manual. This evaluation is performed automatically and a detailed report is generated. The report is stored in an electronic medical history system and can be referenced and analyzed later.

The invention also records high-resolution video of surgical or medical procedures, which are then automatically tagged and evaluated by AI. This allows for the recording of small details and abnormalities that may be overlooked during the medical procedure to be recorded and analysed later.

The benefits of this invention include quality assurance and continuous improvement of medical procedures. Automatic evaluation by AI and high-resolution video recording make it possible to check whether examinations and surgeries are being performed according to manuals and provide appropriate feedback. In addition, the records and evaluation results are stored in an electronic medical history system, making it possible to use them for long-term trend analysis and as training material.

As described above, the present invention plays an important role in improving the efficiency and quality of recording and evaluation of medical procedures in beauty clinics.

[Technology 4]
This invention is a system that uses robotics technology to complement or replace medical procedures in beauty clinics. This system inputs manual information into AI, and the robot performs the medical procedure based on that information. For example, robots are used for procedures that require precision and consistency, such as injections, delicate surgery, and even the application of cosmetics. This makes it possible to standardize the quality of medical care and reduce the workload of medical professionals.

The problem that this invention aims to solve is that there are limitations to the examinations and surgeries performed by human medical professionals, and it is difficult to ensure quality and consistency, especially when high precision and delicate operations are required.

The specific content of this invention is a robotic arm that inputs information from a manual and performs medical procedures as instructed, and an AI engine that controls its operation. First, information from the manual (e.g. surgical procedures, selection and use of surgical instruments, etc.) is input into the system. The AI engine then analyzes the information and generates specific operation instructions for the robotic arm. The robotic arm performs medical procedures as instructed in the manual according to the instructions received from the AI engine.

The effects of the present invention include improved quality and consistency of medical procedures. In particular, in surgeries that require delicate manipulation, the precise movements of the robotic arm can achieve greater accuracy and consistency than human medical personnel. In addition, because the movements of the robotic arm, which are based on a manual, are controlled by an AI engine, it is easy to accommodate updates or changes to the manual.

Furthermore, the present invention contributes to reducing the workload of medical staff. In particular, it can reduce fatigue and stress caused by long surgeries and continuous examinations, thereby reducing the risk of medical errors.

As described above, the present invention plays an important role in improving the quality and consistency of medical procedures in beauty clinics and reducing the workload of medical staff.

The above-mentioned functions (units) can be configured, for example, by hardware provided in a server device, a DSP (Digital Signal Processor), or software. For example, when configured by software, the above-mentioned function blocks 11 to 16 are actually configured with a computer's CPU, RAM, ROM, etc., and are realized by the operation of a program stored in a recording medium such as the RAM, ROM, hard disk, or semiconductor memory.

The present invention can include the following four configuration groups:

[Technology 1]
<Item 1>
A system that monitors whether medical procedures are being performed appropriately according to a pre-set manual and issues an alarm if inappropriate procedures are detected,
A step of storing a standard manual for various medical procedures in beauty clinics in a database;
A step of analyzing real-time data acquired during medical procedures and evaluating whether the procedures are being performed in accordance with a database manual;
The system has a step of issuing an alarm if a deviation from the manual is detected.
<Item 2>
In the system according to claim 2, the alarm is a combination of visual and audio signals.
In the system described in item 1 or 2, the acquisition of real-time data includes video data from a head-mounted display, bioinformation from a biosensor, and operation information of a surgical instrument.
<Item 4>
In the system according to any one of items 1 to 3, the analysis of the real-time data is performed by an AI engine.
<Item 5>
In the system according to any one of items 1 to 4, the manual describes detailed procedures for various cosmetic treatments and surgical procedures.
<Item 6>
In the system according to any one of items 1 to 5, the alarm is issued immediately when an action that does not conform to the manual is detected.
<Item 7>
In the system according to any one of items 1 to 6, after the alarm is issued, the contents of the alarm are stored as a log for review.
<Item 8>
In the system according to any one of items 1 to 7, if an action that does not conform to the manual continues, a continuous warning is issued.
<Item 9>
In the system according to any one of items 1 to 8, the alarm issues different levels of warning depending on the type of violation and its importance.
<Item 10>
In the system according to any one of items 1 to 9, the manual is updated periodically, and the system performs evaluation based on the latest manual.

[Technology 2]
<Item 1>
A system that presents manuals as needed to medical professionals so that they can smoothly perform medical procedures,
analyzing the healthcare professional's voice input and identifying an appropriate section of the manual;
The system includes the step of immediately presenting the identified section of the manual.
<Item 2>
In the system according to item 1, the voice input analysis is performed using natural language processing techniques.
<Item 3>
In the system according to item 1 or 2, the voice input is analyzed not only for the spoken words of the medical professional but also for specific voice commands.
<Item 4>
In the system described in any one of items 1 to 3, the sections of the manual are displayed on a device such as a head mounted display, a tablet, or a smartphone.
<Item 5>
In the system according to any one of items 1 to 4, when a specified section of a manual is displayed, necessary illustrations and related information are also displayed.
<Item 6>
In the system of any one of items 1 to 5, sections of the manual are scrolled in accordance with voice commands from a medical professional.
<Item 7>
In the system according to any one of items 1 to 6, past patient data and treatment results related to the section of the manual displayed can be referenced.
<Item 8>
In the system according to any one of items 1 to 7, when a section of the manual is displayed, a specific case study of a patient suitable for that section is also presented.
<Item 9>
In the system according to any one of items 1 to 8, the manual is periodically updated, and the system operates based on the latest manual.
<Item 10>
In the system according to any one of items 1 to 9, when a section of the manual is displayed, the document is summarized and the main points are highlighted to make it easier for medical personnel to understand.

[Technology 3]
<Item 1>
A system for automating the recording and evaluation of medical examinations and surgical procedures in a beauty clinic, comprising:
obtaining and storing a high resolution video recording of the medical procedure;
analyzing the video footage with an AI engine to evaluate whether the actions were performed according to the manual;
The system includes storing the results of the assessment in an electronic medical history system.
<Item 2>
In the system described in item 1, the real-time video and audio are recorded using a head-mounted display, a body camera, or the like.
<Item 3>
In the system described in item 1 or 2, the video and audio recording covers all medical procedures.
<Item 4>
In the system described in any one of items 1 to 3, the analysis of the real-time video and audio data is performed using an AI engine.
<Item 5>
In the system according to any one of items 1 to 4, the analysis result indicates whether an action consistent with a specific manual has been taken.
<Item 6>
In the system according to any one of items 1 to 5, after the medical procedure is completed, the recorded data is stored as a log for evaluation and review.
<Item 7>
In the system according to any one of items 1 to 6, the evaluation and review may be done by the medical practitioner himself, a colleague or a superior.
<Item 8>
In the system according to any one of items 1 to 7, the results of the evaluation and review are used as feedback for improvement or as training material.
<Item 9>
In the system according to any one of items 1 to 8, the manual is periodically updated, and the system performs evaluation based on the latest manual.
<Item 10>
In the system described in any one of items 1 to 9, the AI engine analyzes video and audio data using machine learning algorithms including deep learning.

[Technology 4]
A system for performing medical procedures according to a manual using a robot arm,
inputting medical procedure manual information into the system;
The AI engine analyzes the manual information and generates an operation command for the robot arm;
A system comprising a step in which a robotic arm performs a medical procedure according to the generated motion commands.
<Item 2>
In the system described in item 1, the robot arm is capable of movement with six or more degrees of freedom.
<Item 3>
In the system according to item 1 or 2, the robot arm has a high-precision position adjustment function for accurately reproducing a specific treatment procedure.
<Item 4>
In the system according to any one of items 1 to 3, the robot arm detects the movement of the patient's body and adjusts its position accordingly.
<Item 5>
In the system described in any one of items 1 to 4, the robot arm utilizes real-time sensor feedback to respond to various situations that arise during treatment.
<Item 6>
In the system described in any one of items 1 to 5, the robot arm has advanced control algorithms for performing delicate medical procedures.
<Item 7>
In the system described in any one of items 1 to 6, the AI engine uses machine learning algorithms including deep learning to control the robot arm.
<Item 8>
In the system described in any one of items 1 to 7, the robot arm can be remotely operated and can be monitored and operated in real time by a specialized medical professional.
<Item 9>
In the system according to any one of items 1 to 8, the manual is periodically updated, and the system controls the robot arm based on the latest manual.
<Item 10>
In the system described in any one of items 1 to 9, the operation results of the robot arm are recorded and stored for later review and feedback.

The above-described embodiment is merely an example to facilitate understanding of the present invention, and is not intended to limit the present invention. The present invention can be modified and improved without departing from the spirit of the invention, and it goes without saying that the present invention includes equivalents.

Claims (3)

A medical audit system for recording and auditing treatments at beauty clinics, comprising:
A first learning model created by machine learning using information indicating whether or not a first situation in which a lift-up treatment using metabolism is being performed in an image of the treatment and the image as training data;
A second learning model created by machine learning using information indicating whether or not a second situation is occurring in which pinpoint irradiation is being performed to a depth required for “lifting up” with ultrasound and the image as training data; and
A third learning model created by machine learning using information indicating whether or not the third situation is one in which HIFU therapy is being performed and the image as training data;
A fourth learning model created by machine learning using information indicating whether or not a fourth situation is occurring in which a treatment using high intensity focused ultrasound (HIFU) is being performed and the image as training data; and
A fifth learning model created by machine learning using information indicating whether or not a fifth situation in which a non-surgical lift-up treatment is being performed and the image as training data;
A sixth learning model created by machine learning using information indicating whether or not a sixth situation is being treated by combining high intensity focused ultrasound and an ultrasound image diagnostic function and the image as training data; and
A seventh learning model created by machine learning using information indicating whether or not a seventh situation is occurring in which irradiation is being performed inside the pupil midline or at an inappropriate location, and the image as training data; and
An eighth learning model created by machine learning using information indicating whether or not an eighth situation in which the transducer and the skin are in proper contact and the image as training data; and
A ninth learning model created by machine learning using information indicating whether or not a ninth situation in which an appropriate irradiation range is confirmed and the image as training data; and
A learning model storage unit that stores the
An acquisition unit for acquiring a video of the treatment;
An auditing unit that audits whether the treatment is being performed correctly by providing the video to the first to ninth learning models and determining whether the video is in the first to ninth situations;
A medical audit system that includes: 2. The medical audit system of claim 1,
The learning model storage unit includes a first learning model created by machine learning using information and an image indicating whether or not the first situation in which epidural anesthesia is being performed as training data;
The learning model storage unit includes a second learning model created by machine learning using information and an image indicating whether or not a second situation in which epidural anesthesia is being performed as training data;
I remember,
an auditing unit that audits whether the treatment is being performed correctly by providing the captured image to the first to third learning models and determining whether the captured image is in the first to third situations;
A medical audit system that includes: 2. The audit system according to claim 1,
The acquisition unit acquires the video moving image in real time,
The auditing unit audits the video footage in real time;
The medical audit system further comprises an alarm unit that issues an alarm if it is detected that the treatment method is not being performed correctly.