CN112289435A - Gestational diabetes screening system based on machine learning and physical examination data - Google Patents

Abstract

The invention belongs to the technical field of information processing, and discloses a gestational diabetes screening system and a method based on machine learning and physical examination data, wherein a parameter setting module is used for setting a pre-pregnancy weight index, glycosylated hemoglobin and a reference value of blood sugar; the historical data input module is used for inputting the height, the weight, the social and demographic data, the family history, the medical history, the allergy history and the living habits of the physical examiner; the data acquisition module is used for historical data, pre-pregnancy weight index, glycosylated hemoglobin and blood glucose data; the data processing module is used for comparing and analyzing the data; the display module is used for displaying the progestational precursor weight index, the glycosylated hemoglobin and the blood glucose data. The physical conditions of physical examination persons are preliminarily known through life styles, diseases and the like, and the gestational diabetes is judged through the measurement results of the progestational precursor weight index, the glycosylated hemoglobin and the blood sugar; the system has simple composition and convenient operation, and has important significance for screening the diabetes of the pregnant women.

Description

Gestational diabetes screening system based on machine learning and physical examination data

Technical Field

The invention belongs to the technical field of information processing, and particularly relates to a gestational diabetes screening system based on machine learning and physical examination data.

Background

Gestational diabetes is the disease with the highest incidence in gestational period, is a group of metabolic diseases characterized by hyperglycemia in the middle gestational period (24-28 weeks), and not only causes huge fetus, hypoglycemia, dystocia and postpartum hemorrhage of newborn, but also increases cardiovascular diseases and metabolic disorders of two generations of mothers and children in the future. However, at present, a screening method for gestational diabetes mellitus is not available in the early gestational period, and a diagnosis standard is also unavailable, so that missed diagnosis and delayed treatment are easy to occur. At present, the national and international guidelines diagnose gestational diabetes with 24-28 weeks glucose tolerance (OGTT) blood sugar rise, and the adverse effect of hyperglycemia on the mother and the son generations is generated. Therefore, a screening system for gestational diabetes in the early stage of gestation must be found, an early warning guide is established, medical nutrition management is carried out in time, the purpose of blocking the forward shift of a checkpoint for gestational diabetes is achieved, and the occurrence of gestational diabetes is reduced.

In summary, the problems of the prior art are as follows: at present, a method for screening the gestational diabetes mellitus in the early gestational period is not available, and medical nutrition intervention indication is not established in the early gestational period.

The difficulty of solving the technical problems is as follows: the gestational period is a special physiological period of the female life, and hormones secreted by the placenta have insulin resistance effect in order to adapt to the growth and development of the fetus. Easily causes disorder of energy metabolism and leads to increase of blood sugar. However, the screening and diagnosis standard of gestational diabetes is lacked before 24 weeks of gestation, and particularly under the condition that the blood sugar in early gestation is normal, the incidence rate of gestational diabetes in the middle gestation period (24 weeks to 28 weeks) cannot be predicted

The significance of solving the technical problems is as follows: the gestational diabetes screening early warning system is established in the early pregnancy, so that the purpose of accurately intervening gestational diabetes is achieved, the birth population quality is improved, and the poor perinatal fate of the mother and the child is reduced.

Disclosure of Invention

Aiming at the problems in the prior art, the embodiment of the invention provides a gestational diabetes screening system based on machine learning and physical examination data.

The invention is realized in such a way that a gestational diabetes screening method based on machine learning and physical examination data comprises the following steps:

inputting a progestational precursor weight index, historical height, historical weight, historical waist circumference, historical blood pressure, historical glycosylated hemoglobin, historical blood glucose reference value, socio-demographic data, family history, medical history, allergy history and living habits of a physical examiner through a historical data input module;

acquiring standard body weight index, waist circumference, blood pressure, glycosylated hemoglobin and blood sugar reference data of the current height and age of the pregnant person through a parameter setting module;

thirdly, constructing a standard vector based on the historical data acquired in the first step and the related standard data acquired in the second step, and constructing a parameter setting model based on the related historical data and the constructed vector;

after setting the standard body mass index, waist circumference, blood pressure, glycosylated hemoglobin and blood sugar reference values of the height and age of the pregnant person, measuring the pre-pregnant body mass index, the glycosylated hemoglobin, the blood sugar, the waist circumference and the blood pressure of the physical examiner, which comprises the following steps:

the progestational precursor weight index determination module is used for determining the progestational precursor weight index of the physical examinee; the glycosylated hemoglobin measurement module measures glycosylated hemoglobin of a physical examiner through a mercury glycosylated hemoglobin meter; the blood sugar measuring module measures the blood sugar of the physical examiner through the blood collecting device and the blood detecting device; the waist circumference measuring module measures the waist circumference of the pregnant person; the blood pressure measuring module measures the blood pressure of the pregnant person through a sphygmomanometer;

step four, the data acquisition module integrates a data acquisition tool set in the historical data input module, the body mass index measuring module, the glycosylated hemoglobin measuring module, the blood sugar measuring module, the waist circumference measuring module and the blood pressure measuring module;

implanting the data acquisition tool set into life cycle functions of a historical data input module, a body mass index measuring module, a glycosylated hemoglobin measuring module, a blood glucose measuring module, a waist circumference measuring module and a blood pressure measuring module by the data acquisition module;

sixthly, the central control module controls the data acquisition module to acquire channel data through context data in the historical data input module, the body mass index measurement module, the glycosylated hemoglobin measurement module, the blood sugar measurement module, the waist measurement module and the blood pressure measurement module;

step seven, the central control module controls the data acquisition module to acquire user access data through a life cycle function of a frame in the rewriting historical data input module, the body mass index measuring module, the glycosylated hemoglobin measuring module, the blood glucose measuring module, the waist circumference measuring module and the blood pressure measuring module;

step eight, the central control module controls the data acquisition module to acquire bottom layer environment data of the intelligent terminal equipment through system interfaces of frames in the historical data input module, the weight measurement module, the glycosylated hemoglobin measurement module, the blood glucose measurement module, the waist measurement module and the blood pressure measurement module;

step nine, the data acquisition module obtains the pre-pregnancy weight index, the historical height, the historical weight, the historical waist circumference, the historical blood pressure, the historical glycosylated hemoglobin, the historical blood glucose reference value, the social demographic data, the family history, the medical history, the allergy history, the living habits, the current glycosylated hemoglobin, the blood glucose, the waist circumference and the blood pressure data of the physical examinee based on the steps six to eight, and corresponding data summarization is carried out;

step ten, the data processing module compares and analyzes the information acquired by the data acquisition module; obtaining the conclusion whether the gestational diabetes is high risk group or not; the display module displays the weight index of the progestational precursor, the height, the waist circumference, the blood pressure, the glycosylated hemoglobin and the blood sugar data through a display;

the data processing module compares and analyzes the information acquired by the data acquisition module and comprises the following steps:

acquiring a first matrix data set;

performing first dimension processing on the first matrix data set to obtain a second matrix data set;

performing second dimension processing on the second matrix data set to obtain a third matrix data set;

obtaining a fourth matrix data set from the first matrix data set and the third matrix data set;

quantizing the feature data of the fourth matrix data set to a specific area to obtain a feature data set;

comparing the data in the feature data set with corresponding target feature data;

and outputting a comparison result.

Further, the constructing a parameter setting model based on the relevant historical data and the constructed vector specifically includes: setting standard body weight index, waist circumference, blood pressure, glycosylated hemoglobin and blood sugar reference value of the height and age of the pregnant person.

Further, the ninth step is performed before: the central control module controls the data collection module to report collected data including at least a portion of the channel data, the user access data, and the underlying environmental data to the server.

Further, the method for determining the progestational precursor weight index of the physical examinee by the progestational precursor weight index determination module comprises the following steps:

the pre-pregnancy weight index determination module measures the weight and height data of the pregnant person by using a weight scale and a height measuring instrument, and calculates the weight index based on the following formula;

pregnancies weight index-weight per height squared, weight unit: kg; the height unit is: and m is selected.

Further, the glycated hemoglobin measurement module measures glycated hemoglobin of a subject with a mercurial glycated hemoglobin meter twice.

Further, when the blood glucose measurement module collects blood glucose through the blood collection device, it is determined that the blood sample is obtained in an empty stomach.

Further, the method of waist circumference measurement module measuring waist circumference of a pregnant person comprises:

and measuring the circumference of the midpoint of the connecting line of the upper edge of the axillary midline ilium and the lower edge of the twelfth rib by using a measuring tape, and obtaining the waist circumference of the pregnant person.

Another object of the present invention is to provide a method for implementing the machine learning and physical examination data-based gestational diabetes screening, which includes:

the progestational precursor weight index measuring module is connected with the central control module and is used for measuring the progestational precursor weight index of the physical examiner;

the glycosylated hemoglobin measurement module is connected with the central control module and is used for measuring the glycosylated hemoglobin of the physical examination person through the mercury glycosylated hemoglobin meter;

the blood sugar measuring module is connected with the central control module and is used for measuring the blood sugar of the physical examinee through the blood collecting device and the blood detecting device;

the parameter setting module is connected with the central control module and is used for setting reference values of weight index of progestational precursor, height, waist circumference, blood pressure, glycosylated hemoglobin and blood sugar;

the historical data input module is connected with the central control module and is used for inputting the progestational precursor weight index, the historical height, the historical weight, the historical waist circumference, the historical blood pressure, the historical glycosylated hemoglobin, the historical blood glucose reference value, the social demographic data, the family history, the medical history, the allergic history and the living habits of the physical examiner;

the data acquisition module is connected with the central control module and is used for acquiring historical data acquired by the historical data input module and summarizing the progestational body weight index, the glycated hemoglobin and the glycated hemoglobin measured by the progestational body weight index measuring module, the blood glucose measuring module, the waist circumference measuring module and the blood pressure measuring module;

the data processing module is connected with the central control module and is used for comparing and analyzing the information acquired by the data acquisition module;

the display module is connected with the central control module and is used for displaying the progestational precursor weight index, the height, the waist circumference, the blood pressure, the glycosylated hemoglobin and the blood sugar data through the display;

the central control module is connected with the progestational precursor weight index measuring module, the glycosylated hemoglobin measuring module, the blood sugar measuring module, the parameter setting module, the historical data input module, the data acquisition module, the data processing module and the display module and is used for controlling the modules to normally work through the main control computer.

Further, the gestational diabetes screening system based on machine learning and physical examination data comprises:

the waist measuring module is connected with the central control module and is used for measuring the waist of the pregnant person;

and the blood pressure measuring module is connected with the central control module and is used for measuring the blood pressure of the pregnant person through a sphygmomanometer.

Another object of the present invention is to provide an information data processing terminal for implementing the method for screening gestational diabetes based on machine learning and physical examination data.

It is another object of the present invention to provide a computer-readable storage medium comprising instructions which, when executed on a computer, cause the computer to perform the method for gestational diabetes screening based on machine learning and physical examination data.

In summary, the advantages and positive effects of the invention are: setting a progestational precursor weight index, glycosylated hemoglobin and a blood sugar reference value through a parameter setting module; the height, the weight, social and demographic data, family history, medical history, allergy history and living habits of the physical examiner are input through the historical data input module; the weight index of the progestational precursor, the glycated hemoglobin and the blood sugar of the physical examinee are respectively measured by a progestational precursor weight index measuring module, a glycated hemoglobin measuring module and a blood sugar measuring module; the physical condition of a physical examiner is preliminarily known through life style, diseases and the like, and the gestational diabetes is judged through the measurement results of the progestational precursor weight index, the glycosylated hemoglobin and the blood sugar; the screening system has simple composition and convenient operation, and has important significance for screening the diabetes of the pregnant women.

Drawings

Fig. 1 is a flowchart of a method for screening gestational diabetes based on machine learning and physical examination data according to an embodiment of the present invention.

FIG. 2 is a schematic structural diagram of a gestational diabetes screening system based on machine learning and physical examination data according to an embodiment of the present invention;

in the figure: 1. a progestational precursor weight index determination module; 2. a glycated hemoglobin measurement module; 3. a blood glucose measurement module; 4. a parameter setting module; 5. a historical data input module; 6. a data acquisition module; 7. a data processing module; 8. a display module; 9. a central control module; 10. a waist circumference measuring module; 11. a blood pressure measuring module.

Fig. 3 is a flowchart of a data acquisition method according to an embodiment of the present invention.

Fig. 4 is a flowchart of a parameter setting method according to an embodiment of the present invention.

Fig. 5 is a flowchart of a data processing method according to an embodiment of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is further described in detail with reference to the following embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

In order to solve the problems in the prior art, embodiments of the present invention provide a gestational diabetes screening system based on machine learning and physical examination data, which is described in detail below with reference to the accompanying drawings.

S101, inputting a progestational precursor weight index, historical height, historical weight, historical waist circumference, historical blood pressure, historical glycosylated hemoglobin, historical blood glucose reference value, social demographic data, family history, medical history, allergy history and life habits of a physical examinee through a historical data input module;

s102, setting standard body weight indexes of the height and the age of the pregnant person, waist circumference, blood pressure, glycosylated hemoglobin and blood sugar reference values through a parameter setting module;

s103, the progestational precursor weight index determination module determines the progestational precursor weight index of the physical examinee; the glycosylated hemoglobin measurement module measures glycosylated hemoglobin of a physical examiner through a mercury glycosylated hemoglobin meter;

s104, the blood sugar measuring module measures the blood sugar of the physical examiner through the blood collecting device and the blood detecting device; the waist circumference measuring module measures the waist circumference of the pregnant person; the blood pressure measuring module measures the blood pressure of the pregnant person through a sphygmomanometer;

s105, acquiring a pregnancies body mass index, historical height, historical weight, historical waist circumference, historical blood pressure, historical glycosylated hemoglobin, a historical blood glucose reference value, social and demographic data, family history, medical history, allergy history, living habits, current glycosylated hemoglobin, blood glucose, waist circumference and blood pressure data of the physical examinee by a data acquisition module, and summarizing corresponding data;

s106, the data processing module compares and analyzes the information acquired by the data acquisition module to obtain the conclusion whether the gestational diabetes high risk group is present or not; the display module displays the weight index of the progestational precursor, the height, the waist circumference, the blood pressure, the glycosylated hemoglobin and the blood sugar data through the display.

As shown in fig. 2, the gestational diabetes screening system based on machine learning and physical examination data provided by the embodiment of the present invention includes:

the pre-pregnancy weight index measuring module 1, the glycosylated hemoglobin measuring module 2, the blood sugar measuring module 3, the parameter setting module 4, the historical data input module 5, the data acquisition module 6, the data processing module 7, the display module 8, the central control module 9, the waist circumference measuring module 10 and the blood pressure measuring module 11.

The progestational precursor weight index measuring module 1 is connected with the central control module and is used for measuring the progestational precursor weight index of the physical examinee;

a glycosylated hemoglobin measurement module 2 connected to the central control module for measuring glycosylated hemoglobin of the subject by a mercury glycosylated hemoglobin meter;

the blood sugar measuring module 3 is connected with the central control module and is used for measuring the blood sugar of the physical examiner through the blood collecting device and the blood detecting device;

the parameter setting module 4 is connected with the central control module and is used for setting reference values of weight index of progestational precursor, height, waist circumference, blood pressure, glycosylated hemoglobin and blood sugar;

the historical data input module 5 is connected with the central control module and is used for inputting the progestational precursor weight index, the historical height, the historical weight, the historical waist circumference, the historical blood pressure, the historical glycosylated hemoglobin, the historical blood glucose reference value, the social demographic data, the family history, the medical history, the allergic history and the living habits of the physical examiner;

the data acquisition module 6 is connected with the central control module and is used for acquiring historical data acquired by the historical data input module and summarizing the progestational body weight index, the glycated hemoglobin, the blood glucose, the waist circumference and the blood pressure data measured by the progestational body weight index measuring module, the glycated hemoglobin measuring module, the blood glucose measuring module, the waist circumference measuring module and the blood pressure measuring module;

the data processing module 7 is connected with the central control module and is used for comparing and analyzing the information acquired by the data acquisition module;

the display module 8 is connected with the central control module and is used for displaying the progestational precursor weight index, the height, the waist circumference, the blood pressure, the glycosylated hemoglobin and the blood sugar data through a display;

the central control module 9 is connected with the progestational precursor weight index measuring module, the glycosylated hemoglobin measuring module, the blood sugar measuring module, the parameter setting module, the historical data input module, the data acquisition module, the data processing module and the display module and is used for controlling the modules to normally work through the main control computer;

a waist measuring module 10 connected with the central control module 9 for measuring the waist of the pregnant person;

and a blood pressure measurement module 11 connected to the central control module 9 for measuring the blood pressure of the pregnant person by a blood pressure meter.

As shown in fig. 3, a method for data acquisition by the data acquisition module 6 provided by the embodiment of the present invention includes:

s201, integrating a data acquisition tool set in a historical data input module 5, a progestational precursor weight index measuring module 1, a glycosylated hemoglobin measuring module 2, a blood glucose measuring module 3, a waist circumference measuring module 10 and a blood pressure measuring module 11;

s202, implanting the initialization method of the data acquisition tool set into the life cycle functions of the historical data input module 5, the progestational mass index measuring module 1, the glycated hemoglobin measuring module 2, the blood glucose measuring module 3, the waist circumference measuring module 10, and the blood pressure measuring module 11;

s203, acquiring channel data through context data in the historical data input module 5, the progestational precursor weight index measuring module 1, the glycosylated hemoglobin measuring module 2, the blood sugar measuring module 3, the waist circumference measuring module 10 and the blood pressure measuring module 11;

s204, acquiring user access data by rewriting the life cycle functions of the frames in the historical data input module 5, the progestational precursor vital index measuring module 1, the glycated hemoglobin measuring module 2, the blood glucose measuring module 3, the waist circumference measuring module 10 and the blood pressure measuring module 11;

s205, acquiring bottom layer environment data of the intelligent terminal equipment through system interfaces of frames in the historical data input module 5, the progestational mass index measuring module 1, the glycated hemoglobin measuring module 2, the blood glucose measuring module 3, the waist circumference measuring module 10 and the blood pressure measuring module 11;

s206, reporting the collected data including at least one part of the channel data, the user access data and the bottom layer environment data to a server.

As shown in fig. 4, the method for setting a parameter setting module according to the embodiment of the present invention includes:

s301, acquiring a pregnancies weight index, historical height, historical weight, historical waist circumference, historical blood pressure, historical glycosylated hemoglobin, historical blood glucose reference value, social and demographic data, family history, medical history, allergy history and living habits of the physical examinee;

s302, acquiring standard body weight index, waist circumference, blood pressure, glycosylated hemoglobin and blood sugar reference data of the current height and age of the pregnant person;

and S303, constructing a standard vector based on the historical data acquired in the step S301 and the related standard data acquired in the step S302, constructing a parameter setting model based on the related historical data and the constructed vector, and setting standard body mass indexes of the height and the age of the pregnant person, waist circumference, blood pressure, glycosylated hemoglobin and blood glucose reference values.

As shown in fig. 5, a method for data processing by the data processing module 7 according to the embodiment of the present invention includes:

s401, acquiring a first matrix data set;

s402, performing first dimension processing on the first matrix data set to obtain a second matrix data set;

s403, performing second dimension processing on the second matrix data set to obtain a third matrix data set;

s404, obtaining a fourth matrix data set according to the first matrix data set and the third matrix data set;

s405, quantizing the feature data of the fourth matrix data set to a specific area to obtain a feature data set;

s406, comparing the data in the feature data set with corresponding target feature data;

and S407, outputting the comparison result.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.

Claims (10)

1. A method for screening gestational diabetes based on machine learning and physical examination data is characterized by comprising the following steps:

inputting a progestational precursor weight index, historical height, historical weight, historical waist circumference, historical blood pressure, historical glycosylated hemoglobin, historical blood glucose reference value, socio-demographic data, family history, medical history, allergy history and living habits of a physical examiner through a historical data input module;

acquiring standard body weight index, waist circumference, blood pressure, glycosylated hemoglobin and blood sugar reference data of the current height and age of the pregnant person through a parameter setting module;

thirdly, constructing a standard vector based on the historical data acquired in the first step and the related standard data acquired in the second step, and constructing a parameter setting model based on the related historical data and the constructed vector;

after setting the standard body mass index, waist circumference, blood pressure, glycosylated hemoglobin and blood sugar reference values of the height and age of the pregnant person, measuring the pre-pregnant body mass index, the glycosylated hemoglobin, the blood sugar, the waist circumference and the blood pressure of the physical examiner, which comprises the following steps:

the progestational precursor weight index determination module is used for determining the progestational precursor weight index of the physical examinee; the glycosylated hemoglobin measurement module measures glycosylated hemoglobin of a physical examiner through a mercury glycosylated hemoglobin meter; the blood sugar measuring module measures the blood sugar of the physical examiner through the blood collecting device and the blood detecting device; the waist circumference measuring module measures the waist circumference of the pregnant person; the blood pressure measuring module measures the blood pressure of the pregnant person through a sphygmomanometer;

step four, the data acquisition module integrates a data acquisition tool set in the historical data input module, the body mass index measuring module, the glycosylated hemoglobin measuring module, the blood sugar measuring module, the waist circumference measuring module and the blood pressure measuring module;

implanting the data acquisition tool set into life cycle functions of a historical data input module, a body mass index measuring module, a glycosylated hemoglobin measuring module, a blood glucose measuring module, a waist circumference measuring module and a blood pressure measuring module by the data acquisition module;

sixthly, the central control module controls the data acquisition module to acquire channel data through context data in the historical data input module, the body mass index measurement module, the glycosylated hemoglobin measurement module, the blood sugar measurement module, the waist measurement module and the blood pressure measurement module;

step seven, the central control module controls the data acquisition module to acquire user access data through a life cycle function of a frame in the rewriting historical data input module, the body mass index measuring module, the glycosylated hemoglobin measuring module, the blood glucose measuring module, the waist circumference measuring module and the blood pressure measuring module;

step eight, the central control module controls the data acquisition module to acquire bottom layer environment data of the intelligent terminal equipment through system interfaces of frames in the historical data input module, the weight measurement module, the glycosylated hemoglobin measurement module, the blood glucose measurement module, the waist measurement module and the blood pressure measurement module;

step nine, the data acquisition module obtains the pre-pregnancy weight index, the historical height, the historical weight, the historical waist circumference, the historical blood pressure, the historical glycosylated hemoglobin, the historical blood glucose reference value, the social demographic data, the family history, the medical history, the allergy history, the living habits, the current glycosylated hemoglobin, the blood glucose, the waist circumference and the blood pressure data of the physical examinee based on the steps six to eight, and corresponding data summarization is carried out;

step ten, the data processing module compares and analyzes the information acquired by the data acquisition module; obtaining the conclusion whether the gestational diabetes is high risk group or not; the display module displays the weight index of the progestational precursor, the height, the waist circumference, the blood pressure, the glycosylated hemoglobin and the blood sugar data through a display;

the data processing module compares and analyzes the information acquired by the data acquisition module and comprises the following steps:

acquiring a first matrix data set;

performing first dimension processing on the first matrix data set to obtain a second matrix data set;

performing second dimension processing on the second matrix data set to obtain a third matrix data set;

obtaining a fourth matrix data set from the first matrix data set and the third matrix data set;

quantizing the feature data of the fourth matrix data set to a specific area to obtain a feature data set;

comparing the data in the feature data set with corresponding target feature data;

and outputting a comparison result.

2. The method for screening gestational diabetes based on machine learning and physical examination data as claimed in claim 1, wherein the parameter setting model is constructed based on the relevant historical data and the constructed vector, specifically: setting standard body weight index, waist circumference, blood pressure, glycosylated hemoglobin and blood sugar reference value of the height and age of the pregnant person.

3. The method for screening gestational diabetes mellitus based on machine learning and physical examination data as claimed in claim 2, wherein the pre-pregnancy weight index determination module determines the pre-pregnancy weight index of the physical examinee by:

the pre-pregnancy weight index determination module measures the weight and height data of the pregnant person by using a weight scale and a height measuring instrument, and calculates the weight index based on the following formula;

pregnancies weight index-weight per height squared, weight unit: kg; the height unit is: and m is selected.

4. The method for screening gestational diabetes mellitus based on machine learning and physical examination data of claim 2, wherein the glycated hemoglobin measurement module measures glycated hemoglobin of the examinee with a mercurial glycated hemoglobin meter twice.

5. The method for screening gestational diabetes mellitus based on machine learning and physical examination data as claimed in claim 2, wherein the blood glucose determination module determines that the blood sample is taken on an empty stomach when collecting blood glucose through the blood collection device.

6. The method for gestational diabetes screening based on machine learning and physical examination data of claim 2, wherein the method for waist circumference measurement module to measure waist circumference of the pregnant person comprises:

and measuring the circumference of the midpoint of the connecting line of the upper edge of the axillary midline ilium and the lower edge of the twelfth rib by using a measuring tape, and obtaining the waist circumference of the pregnant person.

7. The method for screening gestational diabetes mellitus based on machine learning and physical examination data as claimed in claim 1, wherein the step nine is preceded by: the central control module controls the data collection module to report collected data including at least a portion of the channel data, the user access data, and the underlying environmental data to the server.

8. A method of conducting the machine learning and physical examination data-based gestational diabetes screening of claims 1-7, wherein the machine learning and physical examination data-based gestational diabetes screening system comprises:

the progestational precursor weight index measuring module is connected with the central control module and is used for measuring the progestational precursor weight index of the physical examiner;

the glycosylated hemoglobin measurement module is connected with the central control module and is used for measuring the glycosylated hemoglobin of the physical examination person through the mercury glycosylated hemoglobin meter;

the blood sugar measuring module is connected with the central control module and is used for measuring the blood sugar of the physical examinee through the blood collecting device and the blood detecting device;

the parameter setting module is connected with the central control module and is used for setting reference values of weight index of progestational precursor, height, waist circumference, blood pressure, glycosylated hemoglobin and blood sugar;

the historical data input module is connected with the central control module and is used for inputting the progestational precursor weight index, the historical height, the historical weight, the historical waist circumference, the historical blood pressure, the historical glycosylated hemoglobin, the historical blood glucose reference value, the social demographic data, the family history, the medical history, the allergic history and the living habits of the physical examiner;

the data acquisition module is connected with the central control module and is used for acquiring historical data acquired by the historical data input module and summarizing the progestational body weight index, the glycated hemoglobin and the glycated hemoglobin measured by the progestational body weight index measuring module, the blood glucose measuring module, the waist circumference measuring module and the blood pressure measuring module;

the data processing module is connected with the central control module and is used for comparing and analyzing the information acquired by the data acquisition module;

the display module is connected with the central control module and is used for displaying the progestational precursor weight index, the height, the waist circumference, the blood pressure, the glycosylated hemoglobin and the blood sugar data through the display;

the central control module is connected with the progestational precursor weight index measuring module, the glycosylated hemoglobin measuring module, the blood sugar measuring module, the parameter setting module, the historical data input module, the data acquisition module, the data processing module and the display module and is used for controlling the modules to normally work through the main control computer;

further, the gestational diabetes screening system based on machine learning and physical examination data comprises:

the waist measuring module is connected with the central control module and is used for measuring the waist of the pregnant person;

and the blood pressure measuring module is connected with the central control module and is used for measuring the blood pressure of the pregnant person through a sphygmomanometer.

9. An information data processing terminal for implementing the method for screening gestational diabetes based on machine learning and physical examination data according to any one of claims 1 to 7.

10. A computer readable storage medium comprising instructions which, when executed on a computer, cause the computer to perform the method of gestational diabetes screening based on machine learning and physical examination data of any one of claims 1 to 7.

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