WO2024199198A1 - Virtual health system and use method therefor - Google Patents

Abstract

The present invention relates to the technical field of intelligent medicine, and disclosed are a virtual health system and a use method therefor. A database module is used to store different types of health models, and a processing module uses acquired patient information to match a virtual human body health model suitable for a patient, so that the virtual human body health model is used to dynamically analyze and predict multidimensional health-related indicators of the patient according to information related to the patient, so as to reflect a health condition of a human body, thereby accurately predicting a health condition of the patient, as well as further analyzing and adjusting a health intervention plan of the patient, ensuring that the predicted results of the health condition and health intervention plan are more in line with the patient's actual condition. The present invention solves the problem with conventional medical health analysis by means of examination by a doctor of not being able to comprehensively analyze a condition of a patient, as well as a relatively unified display results.

Description

A virtual health system and its use method

This application claims the priority of the Chinese patent application filed with the China Patent Office on March 25, 2023, with application number "2023103032766" and invention name "A virtual health system and its use method", all contents of which are incorporated by reference in this application.

Technical Field

The present invention relates to the field of intelligent medical technology, and in particular to a virtual health system and a method of using the same.

Background Art

The Metaverse is an important direction for the development of virtual technology. It can simulate different scenes, perceptions, skills, etc., and through the combination with computer graphics technology, human-computer interface technology, virtual reality technology, blockchain technology, etc., it can realize the virtualization and digitization of the real world, and make a lot of changes to the user experience and the content of the physical world. The development of the Metaverse is gradual, and it provides an immersive experience based on extended reality technology with the support of shared infrastructure, standards and protocols.

Traditional medical health analysis usually involves doctors obtaining various indicators/statuses of users through various methods such as examination/testing/monitoring/testing/inquiry/observation, which are used to discover diseases or analyze and evaluate health status. Since the focus is on aspects related to patient symptoms, and the doctor's own knowledge level, experience, and information are limited, it is difficult to analyze the patient's condition from an all-round perspective, and the display effect is relatively simple. However, applying metaverse technology to the health analysis process can be free from the restrictions of time, space, and form, and can be displayed in multiple angles, multiple paths, multiple sequences, and multiple levels that users need/are interested in. The immersive analysis and display methods are also easier to accept, understand, and apply. The relationships between various aspects of health analysis can be more directly presented to users, and the connections between content can also be presented to users through different time, transformation, and other factor relationships, allowing users to more easily obtain and analyze health content through the virtual health system, and better master and apply related content.

Summary of the invention

The purpose of the present invention is to provide a virtual health system and a method for using the same, which can provide a more accurate health status analysis without relying solely on doctors for health analysis, and can also provide a health intervention plan suitable for the patient and further adjust the health intervention plan. This ensures that the health intervention plan is more in line with the actual situation of the patient, and realizes the personalization of the health intervention plan. In addition, the virtual health system of the present invention has a high degree of intelligence, more comprehensive analysis, and high analysis accuracy.

To achieve the above object, the present invention provides the following solutions:

A virtual health system, comprising: a database module, an information acquisition module and a processing module;

The database module is used to store a human health database, which includes a virtual human health model. The virtual human health model is based on genetics, physiology, pathology, pharmacy, nutrition, kinematics, environmental science, and psychological health-related rules, and is established after fitting patient experimental/test data and real-world data. The model reflects the relationship between various physiological/psychological indicators and parameters of the patient, as well as the mutual influence of diet, drugs, operation, exercise, environmental factors and related indicators/parameters;

The information acquisition module is used to acquire patient information, input factors affecting human health, output factors affecting human health, and health goals, wherein the input factors affecting human health include at least one of nutrition, medicine, environment, and psychological factors, and the output factors affecting human health include at least one of exercise output, learning output, work output, entertainment output, blood donation output, and output donor;

The processing module is used to match a virtual human health model suitable for the patient from a human health database based on the patient information. The processing module is also used to calculate the patient's current relevant status, indicators, and parameters based on the virtual human health model suitable for the patient and the patient information, and then analyze the patient's health intervention plan based on the input factors affecting human health, the output factors affecting human health, and the health goals; the processing module is also used to analyze the patient's possible health risks and damages based on the patient information and the patient's status, indicators, and parameters, and adjust the patient's health intervention plan based on the patient's possible health risks and damages.

A method for using a virtual health system, the method comprising:

Establish a human health database, which includes a virtual human health model. The virtual human health model is based on genetics, physiology, pathology, pharmacy, nutrition, kinematics, environmental science, and psychological health-related rules. It is established after fitting the patient's experimental/test data and real-world data, and reflects the relationship between the patient's various physiological/psychological indicators and parameters, as well as diet, drugs, operation, exercise, and environmental factors. Models of interaction with relevant indicators/parameters;

Acquiring patient information, input factors affecting human health, output factors affecting human health, and health goals, wherein the input factors affecting human health include at least one of nutrition, medicine, environment, and psychological factors, and the output factors affecting human health include at least one of exercise output, learning output, work output, entertainment output, blood donation output, and output donor;

According to the patient information, a virtual human health model suitable for the patient is matched from the human health database. The patient's current relevant status, indicators, and parameters are calculated based on the virtual human health model suitable for the patient and the patient information. Then, based on the input factors affecting human health, output factors affecting human health, and health goals, a health intervention plan for the patient is analyzed.

A virtual health system, comprising: a database module, an information acquisition module and a processing module;

The database module is used to store a human health database; the human health database includes a virtual human health model; the virtual human health model is based on genetics, physiology, pathology, pharmacy, nutrition, kinematics, environmental science, and psychological health-related rules, and is established after fitting patient experimental/test data and real-world data, reflecting the relationship between various physiological/psychological indicators and parameters of the patient, as well as the mutual influence of diet, medicine, operation, exercise, environmental factors and related indicators/parameters;

The virtual human health model is used to dynamically analyze, predict, deduce, convert, and calculate the patient's multidimensional health-related indicators and/or states and/or functions to reflect the health status of the human body based on different conditions such as physiological information, psychological information, past historical information, environmental information, human input information, human output information, human reserve information, human damage information, and human risk information;

The information acquisition module is used to acquire patient information, input factors affecting human health, output factors affecting human health, and health goals, wherein the input factors affecting human health include at least one of nutrition, medicine, environment, and psychological factors, and the output factors affecting human health include at least one of exercise output, learning output, work output, entertainment output, blood donation output, and output donor;

The processing module is used to match a virtual human health model suitable for the patient from a human health database according to the patient information, and The information calculates the patient's current status, indicators, and parameters, and then analyzes the patient's health intervention plan based on the input factors that affect human health, the output factors that affect human health, and health goals.

According to the specific embodiments provided by the present invention, the present invention discloses the following technical effects:

The present invention provides a virtual health system and a method for using the same. The virtual health system includes a database module, an information acquisition module, and a processing module. The database module is used to store health models suitable for different groups or based on different individuals. The processing module uses the acquired patient information to match a virtual human health model suitable for the patient, so that the virtual human health model is used to dynamically analyze, predict, deduce, convert, and calculate the patient's multidimensional health-related indicators and/or states and/or functions under different conditions such as the patient's physiological information, psychological information, past historical information, environmental information, human input information, human output information, human reserve information, human damage information, and human risk information to reflect the health status of the human body, so as to accurately predict the patient's health status, and further analyze the patient's health intervention plan, solving the problem that the traditional medical health analysis method through doctor's examination cannot analyze the patient's condition from an all-round and overall perspective, and the display effect is relatively single. In addition, the present invention can further analyze the patient's possible health risks and damages according to the patient's information and the patient's state, indicators, and parameters, and adjust the patient's health intervention plan based on the patient's possible health risks and damages. Through the subsequent health intervention plan, the health intervention plan is ensured to be more in line with the patient's actual situation, and the personalization of the health intervention plan is achieved. The solution of the present invention does not need to rely solely on doctors for health analysis, but can also obtain more accurate health status analysis and further provide health intervention plans suitable for patients. The virtual health system of the present invention has a high degree of intelligence, more comprehensive analysis and high analysis accuracy.

BRIEF DESCRIPTION OF THE DRAWINGS

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings required for use in the embodiments will be briefly introduced below. Obviously, the drawings described below are only some embodiments of the present invention. For ordinary technicians in this field, other drawings can be obtained based on these drawings without paying creative work.

FIG. 1 is a schematic diagram of a virtual health system according to Embodiment 1 and Embodiment 2 of the present invention.

FIG. 2 is a partial schematic diagram of a virtual human health model according to Embodiment 2 of the present invention.

FIG. 3 is a flow chart of a method for using a virtual health system according to Embodiment 3 of the present invention.

DETAILED DESCRIPTION

The following will be combined with the drawings in the embodiments of the present invention to clearly and completely describe the technical solutions in the embodiments of the present invention. Obviously, the described embodiments are only part of the embodiments of the present invention, not all of the embodiments. Based on the embodiments of the present invention, all other embodiments obtained by ordinary technicians in this field without creative work are within the scope of protection of the present invention.

The purpose of the present invention is to provide a virtual health system and a method of using the same, which can obtain a more accurate health status analysis without relying solely on doctors for health analysis, and can further provide a health intervention plan suitable for the patient. It has a high degree of intelligence, a more comprehensive analysis, and a strong analysis accuracy.

In order to make the above-mentioned objects, features and advantages of the present invention more obvious and easy to understand, the present invention is further described in detail below with reference to the accompanying drawings and specific embodiments.

Example 1

As shown in FIG. 1 , a virtual health system in this embodiment includes: a database module 11 , an information acquisition module 14 and a processing module 13 .

The database module 11 is used to store a human health database, which includes a virtual human health model. The virtual human health model is based on health-related rules in genetics, physiology, pathology, pharmacy, nutrition, kinematics, environmental science, and psychology, and is established after fitting patient experimental/test data and real-world data. It reflects the relationship between various physiological/psychological indicators and parameters of patients, as well as the mutual influence of diet, drugs, operations, exercise, environmental factors and related indicators/parameters.

The information acquisition module 14 is used to obtain patient information, input factors affecting human health, output factors affecting human health and health goals. The input factors affecting human health include: at least one of nutrition, medicine, environment, and psychological factors; the output factors affecting human health include: at least one of sports output, learning output, work output, entertainment output, blood donation output, and output donor.

The processing module 13 is used to match a virtual human health model suitable for the patient from the human health database according to the patient information. The processing module 13 is also used to match a virtual human health model suitable for the patient according to the patient information. The virtual human health model and patient information are used to calculate the patient's current status, indicators, and parameters, and then the patient's health intervention plan is analyzed based on the input factors affecting human health, output factors affecting human health, and health goals.

Example 2

As shown in FIG. 1 , this embodiment provides a virtual health system, which includes: a database module 11 , an information acquisition module 14 and a processing module 13 .

The database module 11 is used to store a human health database; the human health database includes a virtual human health model; the virtual human health model is based on genetics, physiology, pathology, pharmacy, nutrition, kinematics, environmental science, and psychological health-related rules, and is established after fitting patient experimental/test data and real-world data. It reflects the relationship between various physiological/psychological indicators and parameters of the patient, as well as the mutual influence of diet, drugs, operations, exercise, environmental factors and related indicators/parameters.

The virtual human health model includes health models suitable for different groups or based on different individuals; among them, the health model is based on the patient's age, gender, race, ethnicity, height, weight, genetic information, living habits, region, marital history, family history, medical history, and allergy history. The health information of similar patients is classified and analyzed to obtain a virtual human health model for each type of patient.

The virtual human health model is used to dynamically analyze, predict, deduce, convert, and calculate the patient's multidimensional health-related indicators and/or states and/or functions under different conditions such as physiological information, psychological information, past historical information, environmental information, human input information, human output information, human reserve information, human damage information, and human risk information to reflect the health status of the human body.

The information acquisition module 14 is used to obtain patient information, input factors affecting human health, output factors affecting human health and health goals. The input factors affecting human health include: at least one of nutrition, medicine, environment, and psychological factors; the output factors affecting human health include: at least one of sports output, learning output, work output, entertainment output, blood donation output, and output donor.

The processing module 13 is used to match a virtual human health model suitable for the patient from the human health database according to the patient information, calculate the patient's current relevant state, indicators, and parameters according to the virtual human health model suitable for the patient and the patient information, and then The processing module is also used to analyze the patient's possible health risks and damages based on the patient's information and the patient's status, indicators, and parameters, and adjust the patient's health intervention plan based on the patient's possible health risks and damages.

In the present invention, patients refer to the objects of health intervention and health analysis of the virtual health system of the present invention, and may include: patients, objects of health management, objects of health services, objects requiring health-related analysis, including healthy people, etc. Users refer to the users of the virtual health system of the present invention.

The virtual human health model is based on health-related rules in genetics, physiology, pathology, pharmacology, nutrition, kinesiology, environmental science and psychology. It is established by fitting patient experimental/test data and real-world data. It reflects the relationship between various physiological/psychological indicators and parameters of patients, as well as the mutual influence of diet, drugs, operations, exercise, environmental factors and related indicators/parameters. The patient's indicators, parameters, and status may include: body temperature, vision, hearing, blood sugar, red blood cells, white blood cells, platelets, uric acid, cholesterol, transaminase, calcium, iron, potassium, triglycerides, heart rate, body fat, vital capacity, imaging, acoustics, intelligence, psychology, athletic ability, etc., and may also include ratios of various indicators, such as: height/weight, height/waist circumference, etc.; height, weight, circumference of various parts of the body, fat thickness, strength, speed, physical fitness, hearing, vision, taste, smell, touch, nutritional status, breathing, motor coordination, digestion, absorption, excretion, sexual function, intelligence, attention, memory, perception, communication ability, expression ability, etc.; physiological state, psychological state, fatigue state, complexion, tongue coating, fundus, body fat, skin, skin color, hair quality, etc. There are also interrelationships and mutual influences between different indicators, parameters, and statuses, such as: back strength is positively correlated with weight; body mass index is also positively correlated with blood insulin. The patient's status, indicators, and parameters change dynamically over time. Similarly, the input factors that affect human health, the output factors that affect human health, and the patient's health intervention plan can also change dynamically over time.

The virtual human health model is a model used to simulate and analyze the health of patients. It reflects the dynamic, relevant, comprehensive and accurate health status of the human body under different basic information, genetic information, disease information, medication information, nutritional information, psychological information and other conditions. It can be based on different conditions such as physiological information, psychological information, past historical information, environmental information, human input information, human output information, human reserve information, human damage information, human risk information, etc. Dynamically analyze, predict, deduce, convert, and calculate multi-dimensional health-related indicators and/or states and/or functions of patients under certain conditions.

The virtual human health model can be newly established for the individual currently in use, or it can be a historical model established for different groups or other individuals. The virtual human health model can include health models suitable for different groups or based on different individuals. It can be based on the patient's age, gender, race, ethnicity, height, weight, genetic information, living habits, region, marital history, family history, medical history, allergy history, etc., and classify and analyze the health information of similar patients to obtain virtual human health models for various types of patients. During the use of the virtual health system of the present invention, the virtual health system can also compare the data obtained from the health analysis with the patient's feelings, performance, symptoms, and output information obtained from the actual examination/testing/observation, and the results can be used to establish, optimize, verify and adjust the virtual human health model. It is also possible to continuously improve the virtual human health model based on the information obtained during use, and further refine the health models of each category until an individualized virtual human health model for the patient is achieved, which fully fits the patient's actual situation and obtains the most accurate health analysis results.

Genetics, physiology, pathology, pharmacy, nutrition and psychology health-related rules are the basis for health analysis, and may include: relevant rules on the relationship between basic information and human health status, relevant rules on the relationship between genetic information and human health status, relevant rules on the relationship between disease information and human health status, relevant rules on the relationship between medication information and human health status, relevant rules on the relationship between nutritional information and human health status, relevant rules on the relationship between time factors and human health status, relevant rules on the relationship between physiological parameters and human health status, and at least one of the relevant rules on the relationship between psychological parameters and human health status; other rules related to human health may also be included.

The health-related rules of genetics, physiology, pathology, pharmacy, nutrition and psychology contain a large amount of content, which can be subdivided into different categories/sections, such as by different diseases, by different departments, by different operation items, by different goals, etc. The health-related rules of genetics, physiology, pathology, pharmacy, nutrition and psychology also include various elements, which may include: at least one of basic information, genetic information, disease information, medication information, nutritional information, time factors, physiological parameters, psychological parameters, and health information, and may also include other related elements. Specifically including:

The various elements of basic information related to human health status may include: age, gender, race/ethnicity, nationality, place of origin, living background, dietary background, educational background, etc. The attributes and values of each element of basic information are quantitative/qualitative descriptions of each element of basic information, such as the attribute of the race element: race name, value: Asian American, Caucasian, etc.

The various elements of genetic information related to human health conditions may include: genetic genes, genetic gene variations/changes, genetic defects, genetic disease history, family medical history, etc. The attributes and values of each element of genetic information are quantitative/qualitative descriptions of each element of genetic information, such as the attributes of genetic gene elements: gene loci, gene structure, gene type, etc.

The various elements of disease information related to human health status may include: medical history, disease classification, disease incidence, disease manifestation, disease severity, drug absorption, distribution, metabolism, excretion, intellectual development, psychological state, etc. The attributes and values of each element of disease information are quantitative/qualitative descriptions of each element of disease information, such as the attributes of fever elements: body temperature, duration, whether dizziness, etc.

Various elements of medication information related to human health status may include: binding of drugs to targets, drug efficacy, drug onset time, drug tolerance, drug contraindications, drug interactions, drug allergies, nutrient requirements, absorption, distribution, metabolism, excretion, tolerance, storage, etc.

The various elements of nutrition information related to human health status may include: energy/matter/water/calorie/sugar/fat/protein/amino acid/carbohydrate/salt/vitamin/trace element/mineral/cellulose/probiotics, etc. The attributes and values of each element of nutrition information are quantitative/qualitative descriptions of each element of nutrition information, such as 30 grams of water, sugar-free, low sodium, etc.

Time elements related to human health conditions may include: time elements related to natural rhythms, time elements related to personal work and rest routines, time elements related to specific illnesses/symptoms/indicators/psychological states/physiological states/feelings, time elements related to treatment methods, time elements related to age/developmental stages, time elements related to physiological cycles, time elements related to fertility/sexual life, time elements related to work/activity/exercise/learning, etc. The attributes and values of time elements are quantitative/qualitative descriptions of time elements, such as the attributes of time elements related to natural rhythms: year, month, day, daytime, nighttime, morning, morning, noon, afternoon, evening, season, solar terms, etc.; such as the attributes of time elements related to personal work and rest routines: getting up, breakfast, lunch, dinner, sleeping, etc.

The various elements of health-related rules in genetics, physiology, pathology, pharmacy, nutrition and psychology can also include various elements of physiological parameters and various elements of psychological parameters. Physiological parameters refer to various physiological states, indicators and other parameters of the human body. The various elements of physiological parameters can include: elemental layer elements such as calcium, iron, zinc, selenium, etc.; molecular layer elements such as proteins, nucleic acids, lipids, polysaccharides, etc.; cell layer elements such as neutrophils, eosinophils, basophils, etc.; tissue layer elements such as epithelial tissue, connective tissue, muscle tissue, nervous tissue, etc.; organ layer elements such as heart, liver, spleen, lungs, stomach, kidneys, etc.; system layer elements such as locomotor system, digestive system, respiratory system, urinary system, reproductive system, endocrine system, immune system, nervous system, circulatory system, etc.; internal environment layer elements such as plasma, tissue fluid, lymph, etc. The attributes and values of each element of the physiological state are quantitative/qualitative descriptions of each element of the physiological state. The attributes of the elements related to the physiological state include but are not limited to quantity, concentration, saturation, length, thickness, inner diameter, distribution, activity, reserve, consumption, etc. For example, the properties of calcium ion at the element level: content; the properties of heart at the organ level: inner diameter, thickness, length, etc.

Psychological parameters refer to various psychological states, indicators and other parameters of the human body. Various elements of psychological state can include: cognitive layer elements such as feeling, perception, memory, thinking, imagination, etc.; emotional layer elements such as emotions, personality, moral sense, aesthetics, values, etc.; volitional layer elements such as consciousness, decisiveness, self-control, persistence, etc.; motivational layer elements such as ideals, wishes, interests, hobbies, etc. The attributes and values of each element of psychological state are quantitative/qualitative descriptions of each element of psychological state, such as cognitive layer element memory attributes: agility, persistence, correctness, reserve, etc.

In the process of establishing a virtual human health model, in addition to the health-related rules of genetics, physiology, pathology, pharmacy, nutrition and psychology, it is also possible to combine medical and health knowledge such as kinesiology, environmental science, medical economics, medical devices, surgery, operations, physical therapy, rehabilitation, traditional Chinese medicine, etc. to dynamically analyze, predict, deduce, convert and calculate the patient's multidimensional health-related indicators and/or states and/or functions.

In the present invention, various elements of genetics, physiology, pathology, pharmacy, nutrition and psychology health-related rules may also include: basic information of patients, population information, genetic-related information, disease information, medical history information, medication history information, medical device use history information, operation items, symptoms, indicators, feelings, physical condition, operation objects, operation methods, operation goals, physiological development information, marriage and childbearing information, physiological condition, psychological/intellectual condition, life/work/study/sports/entertainment information, environmental information, drugs/medical devices/health care Information on the use of products/cosmetics, information on medical insurance, ability/willingness to pay medical expenses, information on medical institutions, information on medical personnel, medical devices/consumables/equipment/instruments/drugs/implants required for diagnostic plans, costs of diagnostic plans, care, risk assessment, staging, stages, anesthesia, breathing, hemostasis, infection prevention, pain, first aid measures, indicator control, preparation and requirements, training, indications/indications, contraindications, related protection and first aid, nutritional support, doctor level and authority, auxiliary software, imaging and other elements. Population information may include specific population information such as specific age, gender, development status, marital status, fertility status, work status, learning status, exercise status, living status, physiological status, psychological status, genetic status, etc. Genetic related information includes: genetic information, genetic information variation/change information, genetic defect information, genetic disease history, family medical history and other information. Disease information includes: disease, diagnosis, symptoms, syndrome type, symptoms, indicators, pulse condition, tongue diagnosis and other information. Medical history information includes medical history, surgical history, radiotherapy history, chemotherapy history, psychotherapy history, physical therapy history, immunotherapy history, gene therapy history, etc. Medication history information includes: medication history, drug efficacy, adverse drug reactions, drug allergy history, drug tolerance, etc. Medical device use history information includes: medical device use history, medical device efficacy, adverse reactions, medical device tolerance, etc. Operation items include surgery, inspection, inspection, testing, detection, operation, health care, rehabilitation, psychotherapy, radiotherapy, chemotherapy, physical therapy, heat therapy, phototherapy, magnetic therapy, electrotherapy, cold therapy, electromagnetic therapy, sound therapy, immunotherapy, gene therapy, weight loss, fitness, plastic surgery, beauty, etc. Physiological development information includes: growth and development, physiological stage, fertility, etc. Marital and childbearing information includes marital history, fertility history, sexual life, etc. Physiological conditions include: physical fitness, nutritional status, hearing, vision, taste, smell, touch, breathing, motor coordination, digestion, absorption, excretion, sexual function, etc. and the level of related abilities. Psychological/intellectual status includes: mental illness, emotions, feelings, intelligence, attention, memory, perception, communication skills, expression skills, etc. Life/work/study/sports/entertainment information includes: diet, work and rest, sleep, work, study, entertainment, sports and other related information. Environmental information includes: temperature, humidity, air pressure, season, altitude, air quality, terrain, landform, oxygen content, light, ultraviolet rays, radiation, electromagnetic waves, noise, epidemics, plants and other information. Medical insurance related information includes medical benefits, medical insurance, commercial insurance, etc. Medical institution information includes medical institution level, specialty, attribute, region, department and other information. Medical personnel information includes: age, gender, position, title, specialty Professional qualifications, professional training, protective measures and other information. Medical devices include: active surgical instruments, passive surgical instruments, neurological and cardiovascular surgical instruments, orthopedic surgical instruments, radiotherapy instruments, medical imaging instruments, medical diagnosis and monitoring instruments, respiratory/anesthesia and emergency equipment, physical therapy instruments, transfusion/dialysis and extracorporeal circulation instruments, medical device disinfection and sterilization instruments, active implantable instruments, passive implantable instruments, injection/nursing and protective instruments, patient carrying instruments, ophthalmic instruments, oral instruments, obstetrics and gynecology/assisted reproduction and contraceptive instruments, medical rehabilitation instruments, traditional Chinese medicine instruments, medical software, clinical testing instruments, surgical robots, nursing robots and other products that belong to the category of medical devices or are similar to medical devices, as well as other products with similar functions, including components or accessories, consumables, etc. Implants include: transplants, cultures, gene carriers, implantable chips, implantable equipment/devices, etc. Nutritional support includes: water, calories, protein, trace elements, sugar, salt, fat, carbohydrates, minerals, amino acids, vitamins, detection, content standards, supplementary dosage, etc.

At the same time, the contents and/or elements of the health-related rules of genetics, physiology, pathology, pharmacy, nutrition and psychology also include mutual relationships, which can be the mutual relationship between elements, between contents or between contents and elements. The mutual relationship includes: at least one of composition relationship, cause-effect relationship, conversion relationship, mutual influence and interaction, and can also include other types of mutual relationships, such as time relationship, space relationship, logical relationship, comparison relationship, structural relationship, component relationship, etc. For example, the composition relationship can include: the composition of organs/parts/positions/tissues/cells/ingredients/active ingredients/hormones/fetuses/neuromediators/electrolytes/trace elements/proteins/sugars/fat, blood composition, tissue fluid composition, etc. The cause-effect relationship refers to the relationship between one or more causes and results, such as: thyroid hormone deficiency leads to thyroid enlargement, etc. The time relationship refers to the characteristics and relationships of things in terms of sequence, early and late, duration, etc. The time relationship can include the absolute time when things occur, the duration of time, the sequence of occurrence of different things, etc. For example: time can include year, month, day, hour, minute, second, morning/morning/noon/afternoon/evening/night, season, solar term, lunar year/month/day, various reign titles, etc., as well as order of before/during/after meals, before bedtime, 2 weeks after birth, 30 minutes before boarding a ship, etc. Transformation relationship refers to the relationship generated by the transformation of related substances, such as anaerobic glycolysis of glucose, aerobic oxidation, pentose phosphate pathway, uronic acid pathway, polyol pathway, glycogen synthesis and glycogenolysis, gluconeogenesis and other hexose metabolism. Logical relationship refers to the thinking rules and Objective laws may include: and, or, non-, identical, belonging, containing, reflexive, symmetrical, transitive, connected, etc. Comparative relations are the correlation and operational relations between the contents or elements themselves or their values, which may include: greater than, less than, equal to, mean, variance, integral, differential, etc. Component relations refer to the relations between the various substances or factors that constitute things, which may include: chemical composition, biological composition, material composition, microscopic structure, etc.

The virtual human health model regards the element information contained in the patient's basic information, genetic information, disease information, medication information, nutritional information, psychological information and health status as structural units according to the relationship between elements. The affected element is the latter element in this structural unit, and all the elements that directly affect it are the former elements. The affected element and other elements directly affect another element together, and form a structural unit. For example: factors affecting blood pressure - factors affecting blood pressure. The internal and external structural units are connected to each other through the relationship between elements, and the collection of structural units constitutes the patient's virtual human health model. Figure 2 is a partial schematic diagram of the patient's virtual human health model composed of a limited number of structural units, in which the circle represents the element, and the direction of the arrow represents the influence and influence relationship between the elements. Assuming that element y1 is only affected by elements x1 and x2, then x1, x2, and y1 form a structural unit.

As mentioned above, a rule of relationship between elements may only cover one structural unit, such as:

A rule may also cover multiple structural units, such as:

Among them, _Rk is the kth rule, (1≤k≤H), _xn is the previous element, _pi is the element attribute, is the value of the corresponding attribute of the previous element, y _m is the value of the subsequent element, and v _km is the value of the corresponding attribute of the subsequent element. The value of an element can be a specific value, a value range, or just a qualitative description. In a rule, the attribute of an element may be one or more, so the value of the corresponding element may also be one or more. An attribute and value of an element constitute an element information.

Genetics, physiology, pathology, pharmacy, nutrition and psychology health-related rules include the information of the previous elements or the combination of the previous elements in each structural unit to the information of the subsequent elements. Influence function, threshold value of subsequent element information change, etc. When one or more element information changes and exceeds the threshold value of subsequent element information change directly associated with it, the value of the subsequent element information changes accordingly through the influence function of the previous element information or the combination of previous element information in the rule, and the changed element information continues to affect its subsequent element information through the influence function.

In the present invention, the health-related rules of genetics, physiology, pathology, pharmacy, nutrition and psychology in the human health database are connected through their respective contents, elements or mutual relationships, and then can be expanded through these connections to form a multi-dimensional and multi-level system. This health knowledge system can be conveniently presented to users using the virtual health system of the present invention, making it easier for users to accept, understand and apply, and easier to grasp the correlation between different contents. It can also apply a wider range of content, improve efficiency, and increase the dimensions of learning, analysis, and application and the scope of discovery and search.

In the present invention, the virtual human health model may also include historical information, possible impacts, and corresponding health-related outcomes of the relevant health services or health analysis results used/accepted/experienced by the patient. The above-mentioned history of using or accepting or experiencing drugs, medical devices, inspections and tests, surgeries, physical therapy, operations, traditional Chinese medicine treatments, psychological interventions, etc., and the corresponding health-related outcomes can be used as the output result of the previous health analysis using the virtual human health model, or as the previous input information for the next health analysis using the virtual human health model.

The human health database of the present invention is established by obtaining the content of genetics, physiology, pathology, pharmacy, nutrition and psychology health-related rules from at least one source of medical textbooks, manuals, guidelines, clinical treatment pathways, prescription collections, pharmacopoeias, expert consensus, meeting minutes and consensus within medical alliances/hospitals/departments, industry specifications, textbooks, papers, works, inventions, scientific inferences, experimental reports, test reports, data analysis reports, test reports, inspection reports, approval documents, policies and regulations, guidelines, medical systems, literature, evaluations/reports of doctors/nurses/pharmacists/caregivers/patients/salesmen, research results, health big data, and personal health data, analyzing the elements and relationships from the content, and then establishing connections between the contents corresponding to the same elements or relationships. The human health database is established manually and/or through artificial intelligence analysis.

The information acquisition module 14 acquires patient information, input factors affecting human health, Output factors and health goals that affect human health.

Patient information may include basic patient information and patient health-related information. Basic patient information may include: patient age, gender, race, ethnicity, height, weight, genetic information, living habits, region, marital history, family history, medical history, allergy history and other information, and a virtual human health model suitable for the patient may be matched from a human health database based on the patient's basic information. Patient health-related information may include: at least one of: drugs, medical devices, inspections, surgeries, physical therapy, operations, Chinese medicine treatments, psychological interventions, environments, sports, work, study, event impacts, work and rest, diet, stress, leisure, entertainment, sex life, and fertility, and may specifically include: indicators, parameters, states or conditions of various physiological/psychological/learning/work/physical/sleep/exercise/emotion/metabolism/vision/hearing/intelligence/attention/appetite/immunity/growth and development/memory/fertility/genetic related information of the patient; pathological/physiological indicator information, physical parameter information and physical condition information. Pathological/physiological index information includes: body temperature, vision, hearing, blood sugar, red blood cells, white blood cells, platelets, uric acid, cholesterol, transaminase, calcium, iron, potassium, triglycerides, heart rate, body fat, vital capacity, imaging, acoustics, intelligence, psychology, athletic ability, etc., and can also include ratios of various indicators such as height/weight, height/waist circumference, etc. Physical parameter information includes: height, weight, circumference of various parts of the body, fat thickness, strength, speed, physical fitness, hearing, vision, taste, smell, touch, nutritional status, breathing, motor coordination, digestion, absorption, excretion, sexual function, intelligence, attention, memory, perception, communication ability, expression ability, etc. Physical condition information includes: skin color, tongue coating, fundus, body fat, skin, skin color, hair quality, whether there is sufficient energy, etc.; information obtained through inquiry, inspection, detection, test, experiment, surgery, assessment, evaluation, and observation of diseases/symptoms/indicators; information related to the patient's growth and development/fertility/contraception/assisted reproduction/psychological needs/learning needs/work needs/exercise needs/entertainment needs/nutrition needs/calorie needs, etc.; information on the patient's surgery/operation/inspection/detection/monitoring/assessment/evaluation/analysis/prediction/physical therapy/thermal therapy/phototherapy/magnetic therapy/electrotherapy/rehabilitation/health care/immunotherapy/gene therapy, etc.; information related to the patient's medicines/medical devices/health products/cosmetics, etc., the patient's occupation, family situation, genetic information, life, work, study, exercise, entertainment, diet, work and rest, hobbies, personality, environment, travel, preferences and dependence on treatment-related methods, medical devices, materials, taste, smell, feel, temperature, hardness, irritation, strength, concentration, amount of exercise, time, timing, duration, frequency, cycle, course of treatment, work and rest, etc. The above information can be static or time-varying. For example, the blood sugar concentration of a patient after taking a hypoglycemic drug is a curve that changes over time.

The input factors that affect human health include: at least one of nutrition, medicine, environment, and psychological factors. The output factors that affect human health include: at least one of sports output, learning output, work output, entertainment output, blood donation output, and output donor. Health goals may include: nutritional support, heat relief, cooling, decompression, sleep aid, staying awake, excitement, calmness, sleep aid, beauty, delaying menopause, enhancing immunity, improving mental state, restoring fatigue, adjusting body functions, regulating the body's internal environment, promoting development, promoting disease recovery, assisting reproduction, raising blood, quenching thirst, enhancing satiety, diuresis, aiding digestion, improving defecation, improving metabolism, etc. In the present invention, the health goal can be decomposed into the patient's state, indicators, and parameter requirements through a virtual human health model suitable for the patient. For example, if the patient's body temperature is 39 degrees, the health goal is cooling down. The health goal can be decomposed into the specific requirements of the patient's indicators, such as the body temperature dropping below 37 degrees.

The sources of the above information may be: patient personal information database, health records, family or family member health records, doctor's orders, medical records, medication records, prescriptions, electronic medical records, medical institution information systems, drugstore/medical device store information systems, medical records, treatment records, assessment reports, consultation records, investigation records, work and rest records/plans, diet records/plans, shopping records/plans, medication records/plans, treatment records/plans, exercise records/plans, work records/plans, study records/plans, rehabilitation records/plans, health care records/plans, inspection/checklists, surgical plans/records, health management plans, bills, clinical treatment pathways, inspection/test results, surgical settings/records, genetic test results, and may also be obtained from doctors/ It can be obtained from the usage/prescription/recommendation records of nurses/caregivers, or from various wearable devices, sensors, electronic devices, electronic positioning systems, weather forecast systems, electronic temperature and humidity/air pressure detection equipment, smart speakers, smart home systems, smart surveillance/monitoring systems, smart glasses, smart toilets, smart floors, smart scales, smart detection/analysis equipment, electronic infusion systems, surgical robots, face recognition analysis, fingerprint recognition, voice recognition, gait recognition, positioning systems, social platforms and other devices or systems. It can also be obtained through big data analysis of the patient's life, study, work, sports, travel, social interaction, shopping, diet, work and rest, entertainment and other information, or from the patient's race/family/region/age/marital/fertility and other related information Analysis. Missing information can also be provided by the patient or relevant information can be completed, or highly relevant information can be actively prompted by the doctor to observe, monitor, check, inquire, analyze, confirm, and record whether relevant situations occur or obtain relevant indicators/performance/feelings/symptoms/physiological changes. The evaluation report includes physiological, psychological, economic, credit, athletic ability, etc. Intelligent detection/analysis equipment includes: smell, image, sound, pulse, X-ray, CT, MRI, ultrasound, brain wave, mass spectrometer, tongue diagnosis and analysis, fundus examination, gastroscopy, colonoscopy, catheter, minimally invasive mirror, heart rate, blood oxygen level, blood pressure, blood sugar, blood lipids, body temperature, blood test, urine test, stool test, pulse measurement/analysis equipment, weight/body fat scale, etc.

The processing module 13 matches a virtual human health model suitable for the patient from the human health database according to the patient information, calculates the patient's current relevant status, indicators, and parameters according to the virtual human health model suitable for the patient and the patient information, and then analyzes the patient's health intervention plan based on the input factors affecting human health, the output factors affecting human health, and the health goals.

The virtual human health model suitable for the patient is matched from the human health database based on the patient's information such as age, gender, race, ethnicity, height, weight, genetic information, living habits, region, marital history, family history, medical history, allergy history, medication history, surgical history, etc. If the health model is not matched, it will affect the results of the health intervention plan analysis and may lead to incorrect analysis results.

After matching the virtual human health model suitable for the patient, the patient's current relevant status, indicators, and parameters are calculated based on the virtual human health model suitable for the patient and the patient's information. This includes the conversion, calculation, prediction, and deduction of the patient's various indicators, parameters, and status based on genetics, physiology, pathology, pharmacy, nutrition, kinematics, environmental science, and psychological health-related rules. For example, the patient's fatigue status can be calculated based on the patient's heart rate variability, skin temperature, and sleep status.

After that, the input factors that affect human health, the output factors that affect human health, and the health goals are comprehensively considered to analyze the patient's health intervention plan. For example: blood pressure control during surgery for hypertensive patients, the patient's current blood pressure is 180/110mmHg. The health goal is converted into an indicator that the diastolic blood pressure drops below 110mmHg within 30 minutes, and the blood pressure drops to no more than 160/100mmHg after 2-6 hours. The input factors and output factors that affect human health are that the patient bleeds during surgery and receives a blood transfusion. The patient's health intervention plan obtained from the analysis is intravenous Esmolol was injected intravenously, and the dosage was calculated to be 40 mg based on the patient's weight of 80 kg.

The virtual health system of the present invention can also analyze and predict various indicators, states, and functions of patients after one or more interventions are performed on the patients. The interventions may include: medical interventions such as drugs, medical devices, inspections and tests, surgery, physical therapy, manipulation, traditional Chinese medicine treatment, psychological intervention, etc., or non-medical interventions such as diet, exercise, work and rest, work, study, and changes in living habits.

The virtual health system of the present invention can analyze the changes in various indicators, states, and functions of patients caused by the above-mentioned intervention variables, thereby obtaining changes in the patient's health status, including: changes in indicators, performance, symptoms, feelings, work status, learning status, exercise status, body composition, etc.

The virtual health system of the present invention can also analyze the possibility of the patient's physical output after the intervention, which may include: sports output, learning output, work output, blood donation output, donors, experiments, tests, etc.

The virtual health system of the present invention can also analyze the needs of patients in various health conditions, and provide corresponding nutrition, treatment (drugs, medical devices, examinations and tests, surgery, physical therapy, rehabilitation, psychology), exercise, rest and other needs based on the health analysis results.

The virtual health system of the present invention can also analyze the patient's risks. Based on the results of the patient's health analysis, it can analyze the patient's risks without intervention under the current circumstances, or the risks of various interventions under the current circumstances, such as: risks of drugs, medical devices, examinations and tests, surgery, exercise, etc.

The virtual health system of the present invention can also analyze the patient's comprehensive treatment plan. Based on the results of the patient's health analysis, it analyzes the patient's treatment needs such as indicators/parameters/values, symptoms, manifestations, feelings, functions, abilities, status, etc. in the current health state, as well as the various medical interventions required to meet the relevant treatment needs, and gives the possible risks of the above medical interventions to the patient. Finally, based on the patient's treatment needs, the medical interventions that need to be adopted, and the related risks, a comprehensive analysis is performed to obtain a comprehensive treatment plan suitable for the patient.

The virtual health system of the present invention may further include a user interaction module 12, which is used to obtain signals sent by the user and present feedback information to the user. In the present invention, the signals sent by the user may be instructions for health analysis. The user interaction module 12 may include an information acquisition device and an information presentation device. The information acquisition device is used to obtain The signal sent by the user to the virtual health system; the information presentation device is used by the virtual health system to present information to the user.

In the present invention, the user can send information to the virtual health system through voice, gesture, action, expression, sight, smell, body temperature, body index/parameter/reaction, brain wave, neural substance, etc., or send a signal to the virtual health system by operating a tablet computer, mobile phone, mouse, keyboard, smart handle, remote control, smart wearable device, etc., or send a signal to the virtual health system in other suitable ways. Therefore, the information acquisition device may include at least one of a voice acquisition device, a gesture acquisition device, a limb movement acquisition device, an expression acquisition device, a body signal acquisition device, a smart wearable device, a tablet computer, a mobile phone, a mouse, a keyboard, a smart handle, and a remote control, and may also include other devices suitable for obtaining signals sent by the user. The information presentation device may be at least one of a display screen, smart glasses, headphones, a speaker, a hearing aid, and a brain-computer interface, or may be other suitable devices. In the present invention, the user interaction module 12 is preferably AR/VR glasses, a human-machine interface, a keyboard, a mouse, a tablet computer, a mobile phone, a smart handle, a remote control, a naked eye 3D device, a 3D projection device, a display screen, a headset, and a wearable device. The human-machine interface may be a brain-machine interface or other types of human-machine interfaces. The user interaction module 12 may also include a device for scanning/receiving/intervening in brain waves or neural information/bioelectric signals.

In the virtual health system of the present invention, the user interaction module 12 can be based on at least one of visual signals, auditory signals, tactile signals, olfactory signals, taste signals, mouthfeel signals, temperature signals, humidity signals, and human-machine interface signals, and can display feedback information to the user in at least one form of points, lines, graphics, images, planes, curved surfaces, three-dimensional graphics, three-dimensional images, marks, symbols, codes, codes, text, colors, sounds, touch, smell, temperature, and formulas through different combinations. A coordinate system can be established in the established virtual space/system, and multi-dimensional information coordinates can be formed by spatial position, visual signals, auditory signals, tactile signals, olfactory signals, taste signals, mouthfeel signals, temperature signals, humidity signals, human-machine interface signals, etc. to display relevant information to the user.

The user interaction module 12 can also display feedback information to the user through auditory perception signals and tactile perception signals. Auditory perception signals refer to information expressed through at least one of the characteristics of sound frequency, rhythm, melody, interval, direction, distance, size, height, length and timbre, so that the user can perceive the information through the signal. For example, the user can perceive the information through sound. Deliver spatial orientation information to the user. Since the transmission characteristics of a sound source transmitting sound waves to a specific orientation can be expressed as a function data set, this function data set characterizing the sound wave transmission characteristics can be used to process audio signals so that the audio signals reflect the transmission characteristics of the sound source transmitting sound waves to the orientation. When this processed audio signal is converted into sound via a playback device, the sound exhibits the transmission characteristics of the sound source transmitting sound waves to the orientation, allowing the user to feel the virtual spatial orientation of the sound source. The specific orientation may include the direction, position, height, and so on of the sound.

A tactile perception signal refers to information represented by at least one of the contact position, shape, contact area, action, temperature and pressure of the contact, so that the user can perceive the information through the signal. Different information can be represented by contacting different positions of the user's body, for example: different positions of the user's head, hands, fingers, palms, back of hands, forearms, upper arms, chest, back, legs, feet, etc. represent different orientation information or other various information. In addition to representing information by the position of the contact of the user's body, the tactile perception signal can also represent information by at least one of the contact type, shape, contact area, action, temperature and pressure of the contact. The action of contacting the user's body may include: tapping, sliding, turning, clicking, pressing, etc.

In the virtual health system of the present invention, users can input information such as drugs, medical devices, inspections, surgeries, physical therapy, operations, Chinese medicine treatments, psychological interventions, environments, sports, work, study, event impacts, work and rest, diet, stress, leisure, entertainment, sex life, and childbirth. The information can be static or time-varying. The processing module 13 matches a virtual human health model suitable for the patient from the human health database based on the patient's basic information, and then obtains the patient's health analysis results based on the patient's information and the virtual human health model suitable for the patient. The output information of the health analysis results can be various indicators, functions, reserves of physical strength/energy, physiological/psychological/spiritual/work/study/exercise states, feelings, pathological analysis results, pharmacological analysis results (such as drug blood concentration, drug metabolism, drug distribution, drug excretion, drug interactions, adverse drug reactions, etc.), immune response results, and the like.

The user interaction module of the virtual health system of the present invention can be used to input the health/disease information of the patient. Afterwards, the relevant information can be integrated and output as the multi-dimensional electronic medical record of the patient. The virtual health system performs health monitoring based on the multi-dimensional electronic medical record and patient information. After the analysis, the relevant multi-dimensional dynamic comprehensive evaluation, including analysis and prediction of indicators, status, functions, treatment needs analysis, treatment intervention recommendations, risk assessment prompts, etc., can be displayed through the user interaction module, enabling doctors to complete multi-dimensional quantitative analysis of patients' treatment plans through the virtual health system.

In the present invention, the health analysis also needs to consider the influence of time factors on the analysis results. The influence of time factors can include: the influence of different rhythms on the health analysis results; the influence of different relative times of elements on the health analysis results; the influence of mutually influencing time factors on the health analysis results, etc. For example: the water replenishment demand in the dry winter is less than the water replenishment demand in the humid summer; the demand for food 2 hours after eating is less than 6 hours after eating.

The virtual health system of the present invention can also perform dynamic health analysis on patients according to real-time changes in patient information and provide dynamic patient health analysis results.

For example, a user studies the treatment of acute simple cystitis caused by ESBL-positive Escherichia coli in patients through the virtual health system of the present invention, including:

Patient information: 25 years old, second trimester of pregnancy.

Symptoms: frequent urination, urgency, pain when urinating, and mild tenderness in the suprapubic bladder area.

Etiological diagnosis: Escherichia coli.

Then, in addition to the above content, the information displayed to the user by the user interaction module 12 also includes related content associated with the elements and element relationships of the above content, which may include:

Optional drugs: amoxicillin/clavulanic acid, sulfamethoxazole + trimethoprim, nitrofurantoin, fosfomycin tromethamine, etc.

Drug applicability: Sulfamethoxazole + trimethoprim is not suitable for pregnant women.

Drug sensitivity: Amoxicillin/clavulanic acid resistance is high; the local Escherichia coli resistance rate to sulfamethoxazole + trimethoprim is 30%; the resistance to nitrofurantoin and fosfomycin tromethamine is low.

Contraindications: No contraindications.

Economical; Amoxicillin/clavulanic acid: 30 yuan; Sulfadiazine + trimethoprim: 10 yuan; Nitrofurantoin: 3 yuan; Fosfomycin tromethamine: 70 yuan.

A virtual space containing patient information, symptoms, diagnosis, drugs and their applicability/sensitivity/contraindications/economics can be established to display relevant content, elements, and interrelationships. It can be associated with other related content such as rehabilitation and post-healing, so that users can easily understand and master relevant information and knowledge. For example: patient information, symptoms, diagnosis, and drugs can be represented by different points, and lines are used to represent the relationship/connection between them. Marks/text/symbols can also be included to represent other information. After clicking to select, the information such as drug usage and dosage can be specifically displayed. Different colors can also be used to represent different information, such as severe symptoms represented by red/mild symptoms represented by blue, etc. Users can choose the information to be displayed according to their own needs, such as only showing drug applicability/sensitivity/contraindications without showing drug economics. Users can also perform various operations, such as modification, addition, etc. Modification can be to modify content such as text/pictures, etc., or to modify relationships such as removing the connection between a certain drug and a certain symptom and replacing it with other symptoms; it can also operate on a collection of related content/elements/relationships, such as directly deleting/transferring a certain drug, and the applicability/sensitivity/contraindications/economics under the drug are also deleted/transferred together.

The virtual health system of the present invention provides the patient's virtual human health model or health analysis results in one or more display dimensions, levels, and sequences according to the user's operation or setting, and displays them to the user according to the dimension, level, and sequence after the user selects them. For example: in the above-mentioned virtual space containing patient information, symptoms, diagnosis, drugs and their applicability/sensitivity/contraindications/economic efficiency, the user can choose to display the feedback information in the logical order of symptoms-diagnosis-drug economic efficiency priority, or can choose to display the feedback information in the order of symptoms-diagnosis-drug sensitivity priority.

Of course, the related content associated with the elements and mutual relationships of the above-mentioned content can be directly displayed in detail, or only the title or label can be displayed. When the user sends a signal of wanting to see through the user interaction module 12, it will be displayed in detail to reduce the complexity of the displayed content. The signal sent by the user through the user interaction module 12 can be that the user stares at the title of the related content for a certain period of time, which means that the user wants to see the content of the title. The user interaction module 12 obtains the signal sent by the user based on eye tracking, and the processing module 13 gives feedback information, that is, the content under the title. At the same time, the related content associated with the elements and mutual relationships in the content under the title can also be displayed. When displaying, different signals can be used to reflect different elements or mutual relationships. For example, different elements can be displayed through different sounds, images, colors, and brain waves.

The virtual health system of the present invention can analyze genetics from different sources and with different confidence levels. Physiology, pathology, pharmacy, nutrition and psychology health-related rules are marked differently to select appropriate rules under different requirements/business scenarios.

The virtual health system of the present invention may also include a docking module for docking/converting/comparing/translating virtual human health models and health analysis results of different knowledge and information systems and their elements and interrelationships. The docking module may include one or more parsers and/or translators, which can dock/convert/comparison/translate the contents of health records, health reports, medical orders, medical records, drug records, prescriptions, electronic medical records, electronic drug cases, data bases, and databases from different sources, different data structures, different languages, different descriptions, different data standards, different knowledge/information systems, and different perspectives. When different information is docked, a unified standard may be adopted in advance, and different information may be translated and converted according to the unified standard for use by users; or a translation/conversion tool may be applied when transitioning between different information, so that users can switch at any time. If there are differences in standards between different information, the virtual health system of the present invention may prompt the relevant differences when users switch different information.

The virtual health system of the present invention may also include a rights management module for managing the use rights of different users to prevent privacy leakage or disclosure. Different use rights levels can be set for different users and/or different patient information. The use rights may include reading, copying, viewing, converting, analyzing, calculating, processing, comparing, editing, storing, etc. of information. The corresponding rights may also be set for different models, contents, elements, relationships, or sets thereof. The use rights level may be set manually or by artificial intelligence analysis.

The virtual health system of the present invention can be applied to the acquisition/learning/application/processing/analysis/evaluation/management of various health records, health reports, medical orders, medical records, medication records, prescriptions, electronic medical records, electronic medication examples, databases, and the like.

Example 3

As shown in FIG3 , this embodiment provides a method for using a virtual health system, and the method specifically includes:

S1: Establish a human health database, which includes a virtual human health model. The virtual human health model is based on genetics, physiology, pathology, pharmacy, nutrition, kinesiology, environmental science, and psychological health-related rules, and is established after fitting patient experimental/test data and real-world data to reflect the patient's various physiological and Models of the relationship between physical/psychological indicators and parameters and the mutual influence of diet, drugs, operations, exercise, environmental factors and related indicators/parameters.

S2: Obtain patient information, input factors affecting human health, output factors affecting human health and health goals, wherein the input factors affecting human health include at least one of nutrition, medicine, environment, and psychological factors, and the output factors affecting human health include at least one of sports output, learning output, work output, entertainment output, blood donation output, and output donor.

S3: Match a virtual human health model suitable for the patient from the human health database based on the patient information, calculate the patient's current relevant status, indicators, and parameters based on the virtual human health model suitable for the patient and the patient information, and then analyze and derive a health intervention plan for the patient based on the input factors affecting human health, the output factors affecting human health, and health goals.

The method of using a virtual health system of the present invention corresponds one to one with the technical features of a virtual health system of the present invention, and reference may be made to the description of the aforementioned virtual health system, which will not be repeated here.

In summary, a virtual health system and a method for using the same of the present invention, the virtual health system comprises: a database module 11, an information acquisition module 14 and a processing module 13. The method for using the virtual health system comprises: establishing a human health database, the human health database comprising a virtual human health model; obtaining patient information, input factors affecting human health, output factors affecting human health and health goals; matching a virtual human health model suitable for the patient from the human health database according to the patient information, calculating the patient's current relevant state, index and parameter according to the virtual human health model suitable for the patient and the patient information, and then analyzing and obtaining the patient's health intervention plan according to the input factors affecting human health, the output factors affecting human health and the health goals. A virtual health system and a method for using the same of the present invention apply digital technology to the health analysis process, so that users are not restricted by time, space and form, and analyze and display the health of patients from multiple angles, multiple paths, multiple sequences and multiple levels required/interested by users. Users can more easily accept, understand and apply health analysis through immersive analysis and display methods, and the relationship between the content of human health rules can be more directly displayed, so that users can more easily obtain health analysis through the virtual health system, and better master and apply health analysis and virtual human health models.

This article uses specific examples to illustrate the principles and implementation methods of the present invention. The above embodiments are only used to help understand the method and core idea of the present invention; at the same time, for those skilled in the art, according to the idea of the present invention, there will be changes in the specific implementation and application scope. In summary, the content of this specification should not be understood as limiting the present invention.

Claims (10)

A virtual health system, characterized in that the virtual health system comprises: a database module, an information acquisition module and a processing module; The database module is used to store a human health database, which includes a virtual human health model. The virtual human health model is based on genetics, physiology, pathology, pharmacy, nutrition, kinematics, environmental science, and psychological health-related rules, and is established after fitting patient experimental/test data and real-world data. It reflects the relationship between various physiological/psychological indicators and parameters of patients, as well as the mutual influence of diet, drugs, operation, exercise, environmental factors and related indicators/parameters. The information acquisition module is used to acquire patient information, input factors affecting human health, output factors affecting human health, and health goals, wherein the input factors affecting human health include at least one of nutrition, medicine, environment, and psychological factors, and the output factors affecting human health include at least one of exercise output, learning output, work output, entertainment output, blood donation output, and output donor; The processing module is used to match a virtual human health model suitable for the patient from a human health database based on the patient information. The processing module is also used to calculate the patient's current relevant status, indicators, and parameters based on the virtual human health model suitable for the patient and the patient information, and then analyze and obtain a health intervention plan for the patient based on the input factors affecting human health, the output factors affecting human health, and the health goals. A method for using the virtual health system according to claim 1, characterized in that the method comprises: Establishing a human health database, wherein the human health database includes a virtual human health model, wherein the virtual human health model is based on genetics, physiology, pathology, pharmacy, nutrition, kinematics, environmental science, and psychological health-related rules, and is established after fitting patient experimental/test data and real-world data, and reflects the relationship between various physiological/psychological indicators and parameters of the patient, as well as the mutual influence of diet, drugs, operation, exercise, environmental factors and related indicators/parameters; Obtain patient information, input factors affecting human health, output factors affecting human health and health goals, wherein the input factors affecting human health include at least one of nutrition, medicine, environment and psychological factors, and the output factors affecting human health include sports output, learning output, work output, entertainment output, blood donation output, output donor output, At least one of According to the patient information, a virtual human health model suitable for the patient is matched from the human health database. The patient's current relevant status, indicators, and parameters are calculated based on the virtual human health model suitable for the patient and the patient information. Then, based on the input factors affecting human health, output factors affecting human health, and health goals, a health intervention plan for the patient is analyzed. A virtual health system, characterized in that the virtual health system comprises: a database module, an information acquisition module and a processing module; The database module is used to store a human health database; the human health database includes a virtual human health model; the virtual human health model is based on genetics, physiology, pathology, pharmacy, nutrition, kinematics, environmental science, and psychological health-related rules, and is established after fitting patient experimental/test data and real-world data, reflecting the relationship between various physiological/psychological indicators and parameters of the patient, as well as the mutual influence of diet, medicine, operation, exercise, environmental factors and related indicators/parameters; The virtual human health model is used to dynamically analyze, predict, deduce, convert, and calculate the patient's multidimensional health-related indicators and/or states and/or functions to reflect the health status of the human body based on different conditions such as physiological information, psychological information, past historical information, environmental information, human input information, human output information, human reserve information, human damage information, and human risk information; The information acquisition module is used to acquire patient information, input factors affecting human health, output factors affecting human health, and health goals, wherein the input factors affecting human health include at least one of nutrition, medicine, environment, and psychological factors, and the output factors affecting human health include at least one of exercise output, learning output, work output, entertainment output, blood donation output, and output donor; The processing module is used to match a virtual human health model suitable for the patient from a human health database based on the patient information, calculate the patient's current relevant status, indicators, and parameters based on the virtual human health model suitable for the patient and the patient information, and then analyze the patient's health intervention plan based on the input factors affecting human health, the output factors affecting human health, and the health goals; the processing module is also used to analyze the patient's possible health risks and damages based on the patient information and the patient's status, indicators, and parameters, and adjust the patient's health intervention plan based on the patient's possible health risks and damages. A virtual health system according to claim 3 is characterized in that the virtual human health model includes health models suitable for different groups or based on different individuals, and the health model is based on the patient's age, gender, race, ethnicity, height, weight, genetic information, living habits, region, marital history, family history, medical history, and allergy history. The health information of similar patients is classified and analyzed to obtain virtual human health models for each type of patient. A virtual health system according to claim 3 is characterized in that the virtual health system is also used to compare the data obtained from the health analysis with the patient's feelings, performance, symptoms, and output information obtained from actual examination/testing/observation, and use the comparison results to establish, optimize, verify and adjust the virtual human health model until an individualized virtual human health model is achieved for the patient, which fully fits the patient's actual situation and obtains the most accurate health analysis results. A virtual health system according to claim 3 is characterized in that, in the process of establishing the virtual human health model, medical health knowledge is also combined to dynamically analyze, predict, deduce, convert, and calculate the patient's multidimensional health-related indicators and/or states and/or functions; medical health knowledge at least includes kinematics, environmental science, medical economics, medical devices, surgery, operation, physical therapy, rehabilitation, and traditional Chinese medicine. A virtual health system according to claim 3, characterized in that the genetics, physiology, pathology, pharmacy, nutrition and psychology health-related rules in the human health database are connected through their respective contents, elements or relationships, and the generated connections are expanded to form a multi-dimensional and multi-level health knowledge system. A virtual health system according to claim 3 is characterized in that the virtual health system is also used to analyze and predict various indicators, states, and functions of patients after one or more interventions are performed on the patients; the interventions include medical interventions and non-medical interventions: the medical interventions include at least drugs, medical devices, examinations and tests, surgery, physical therapy, operations, traditional Chinese medicine treatments, and psychological interventions; the non-medical interventions include at least changes in diet, exercise, work and rest, work, study, and living habits. A virtual health system according to claim 8, characterized in that the virtual health system is also used to analyze the changes in various indicators, states, and functions of patients caused by intervention variables, obtain changes in the patient's health status to analyze the possibility of the patient's physical output after the intervention; the patient's physical output includes at least: exercise output, learning output, work output and blood donation output. A virtual health system according to claim 9, characterized in that the virtual health system is also used to analyze the treatment needs of the patient in the current health state and the various medical interventions required to meet the relevant treatment needs based on the results of the patient's health analysis, and provide the risks that the medical intervention may cause to the patient. Combined with the patient's treatment needs, the medical intervention to be adopted, and the related risks, a comprehensive analysis is performed to obtain a comprehensive treatment plan suitable for the patient.