CN114203295A - Cerebral apoplexy risk prediction intervention method and system - Google Patents

Abstract

The application relates to a method and a system for predicting and intervening cerebral apoplexy risks. The system comprises: the information collection module is used for collecting blood biochemical data, carotid artery color Doppler ultrasound data and daily continuous monitoring data of high-risk people suffering from cerebral apoplexy; the signal preprocessing and analyzing module is used for preprocessing the data collected by the information collecting module and extracting and analyzing the characteristics; the characteristic fusion module is used for carrying out characteristic fusion on the characteristics obtained through processing and analysis; the stroke risk prediction module is used for predicting the stroke risk according to the characteristics obtained by the characteristic fusion module; the intervention module is used for recommending an intervention scheme according to the risk level obtained by the stroke risk prediction module; and the human-computer interaction module is used for performing human-computer interaction according to the intervention scheme generated by the intervention module, wherein the feature fusion module performs feature fusion on the features obtained by the signal preprocessing analysis module by using a multi-source feature deep neural network fusion algorithm, and finally obtains fusion features DCNN-LSTM.

Description

Cerebral apoplexy risk prediction intervention method and system

Technical Field

The invention relates to the field of health management, in particular to a stroke risk prediction intervention method and system based on multi-source heterogeneous information fusion.

Background

The stroke is a serious chronic non-infectious disease seriously harming the health of China, is the first cause of death and disability of adults in China, and has the five characteristics of high morbidity, high disability rate, high mortality, high recurrence rate and high economic burden. With the development of social economy, the national life style is remarkably changed, particularly, the aging of population and the urbanization progress are accelerated, the epidemic trend of risk factors of cerebrovascular diseases is obvious, and the number of people suffering from cerebrovascular diseases is continuously increased.

The stroke has a long onset incubation period, early symptoms are slight, and the symptoms are difficult to discover, so that the medical field generally considers that the most effective measure for the diagnosis and treatment of the stroke is to intervene in high-risk groups of the stroke through effective risk assessment before the stroke occurs so as to achieve the purpose of preventing the stroke from occurring. At present, the wide cerebral apoplexy risk prediction clinically applied is mainly a risk assessment scale such as the Fuminghan stroke and the like for predicting the stroke incidence risk in the future 10 years, but the scale has obvious effect difference on the evaluation of different nationalities and regions, and the scale evaluation focuses on the prediction of the whole incidence and has limited cerebral apoplexy prevention and screening capability. With the rapid development of artificial intelligence technology and big data in recent years, scholars at home and abroad begin to apply artificial intelligence technology such as machine learning to the early risk prediction of stroke, and carry out big data mining and analysis on information such as clinical biochemical data indexes and imaging to carry out early risk prediction of stroke, which can be roughly divided into two categories. The first type is that deep learning algorithm such as convolutional neural network is used for modeling and predicting data in biochemistry or image, and single data hardly represents the high-risk factors of stroke completely; the second type is that modeling prediction is carried out on multi-source data in the aspects of biochemistry, images and the like by using a certain algorithm in deep learning, and a single neural network cannot simultaneously learn the characteristics of the multi-source heterogeneous data, so that the prediction result is not ideal.

Therefore, in order to fully play the relevance and complementarity of multi-source heterogeneous data, the method and the system for predicting and intervening the stroke risk of multi-source heterogeneous information fusion are researched and designed, and have important significance for predicting and preventing the stroke risk.

Disclosure of Invention

The invention aims to provide a stroke risk prediction intervention system based on multi-source heterogeneous information fusion, which comprises an information collection module, an information preprocessing analysis module, a feature fusion module, a stroke risk prediction module, an intervention module and a man-machine interaction module, wherein:

the information collection module is used for collecting blood biochemical data, carotid artery color hyper-data and daily continuous monitoring data of high-risk people suffering from the cerebral apoplexy;

the signal preprocessing and analyzing module is used for preprocessing blood biochemical data, carotid artery color Doppler ultrasound data and daily continuous monitoring data of the information collecting module and extracting and analyzing features;

the characteristic fusion module is used for carrying out characteristic fusion on the characteristics obtained by the preprocessing and analysis of the signal preprocessing and analysis module;

the stroke risk prediction module is used for predicting the stroke risk according to the characteristics obtained by the characteristic fusion module;

the intervention module is used for recommending an intervention scheme according to the risk level obtained by the stroke risk prediction module;

and the human-computer interaction module is used for performing human-computer interaction according to the intervention scheme generated by the intervention module. The feature fusion module performs feature fusion on the features obtained by the signal preprocessing analysis module by using a deep neural network model through a multi-source feature deep neural network fusion algorithm to finally obtain fusion features D_CNN-LSTM。

In the stroke risk prediction intervention system, the high-risk group in the stroke in the information collection module is screened according to the basic information of clinical cases, and has more than 3 high-risk factors in the stroke.

Preferably, the high risk factors in stroke include: age is high, hypertension, hyperglycemia, hyperlipemia, heart disease, family history of apoplexy, smoking, obesity, high salt and high oil eating habit, and less exercise 10 items; the blood biochemical data include: high density lipoproteins, low density lipoproteins, cholesterol, triglycerides, homocysteine, D dimers, glycated serum proteins, and the like; the daily continuous monitoring data comprises: heart rate, blood pressure, electrocardiogram, exercise, blood sugar, body fat ratio.

In the system for predicting and intervening the cerebral apoplexy risk, the signal preprocessing analysis performed by the signal preprocessing analysis module comprises the preprocessing analysis of biochemical data, carotid artery color Doppler ultrasound data and daily continuous monitoring data, wherein,

the biochemical data preprocessing analysis comprises the following steps: normalization processing is carried out by utilizing dispersion normalization, and the data is compressed to [0,1] through linear transformation of the original data, wherein the formula is as follows:

wherein X' is the compressed value, X is the original value of a biochemical index, X_maxIs the maximum value of index X, X_miIs the minimum value of index X.

The preprocessing of carotid color Doppler ultrasound data comprises the following steps: vectorizing the carotid color hyper-data report result words by using word2vec word vector technology.

The preprocessing analysis of daily continuous monitoring data comprises the following steps: the heart rate variability index is calculated by utilizing the electrocardiogram data, the blood pressure variability index is calculated by utilizing the continuously monitored blood pressure data, and the average value of the heart rate, the blood pressure, the blood sugar, the exercise and the body fat ratio every 7 days is calculated.

In a system for predicting and intervening stroke risk, an information preprocessing and analyzing module analyzes and processes information obtained by the information preprocessing module, and the method comprises the following steps:performing feature extraction on the preprocessed biochemical data information through a convolutional neural network model to obtain a feature vector X_CNN。

X_CNN＝G_CNN(Net_1CNN，Tr_1CNN，X)

[Net_1CNN，Tr_1CNN]＝Feedforward(W_1CNN,B_1CNN；M_1CL,M_1pool；Z)

Wherein, X_CNNIs a feature vector, G, extracted from a convolutional neural network_CNNIs the output function of the convolutional neural network, Net_1CNNIs a trained convolutional neural network, Tr_1CNNIs a parameter of the trained convolutional neural network, W_1CNNIs a convolution kernel matrix parameter, B_1CNNIs a bias parameter, M_1CLIs the convolution kernel size and number of layers, M_1poolIs the maximum pooled nuclear size and number of layers, and X is the input biochemical data.

Extracting the characteristics of the preprocessed daily physiological monitoring signals through a long-time and short-time memory network, and outputting a characteristic vector Y_LSTM。

Y_LSTM＝G_LSTM(Net_LSTM，Tr_LSTM，Y)

[Net_LSTM,Tr_LSTM]＝Feedforward(W_LSTM1,W_LSTM2,B_LSTM1,B_LSTM2；Y)

Wherein, Y_LSTMIs a characteristic vector, Net, extracted by a long-time and short-time memory network_LSTMIs a long and short term memory network after training, Tr_LSTMIs the network parameter memorized after training, and the feed forward is the Feedforward neural network function, W_LSTM1、W_LSTM2For long and short term memory of the weight parameters of the network input gate and the forgetting gate, B_LST1、B_LSTM2The method is characterized in that bias parameters of a network input gate and a forgetting gate are memorized at long time, and Y is an input daily physiological monitoring signal.

Performing feature extraction on the preprocessed carotid artery color Doppler ultrasound data through a convolutional neural network model to obtain a feature vector Z_CNN。

Z_CNN＝G_CNN(Net_2CNN，Tr_2CNN，Z)

[Net_2CNN，Tr_2CNN]＝Feedforward(W_2CNN,B_2CNN；M_2CL,M_2pool；Z)

Wherein Z is_CNNIs a feature vector, Net, extracted by a convolutional neural network_2CNNIs a trained convolutional neural network, Tr_2CNNIs a trained convolutional neural network parameter, W_2CNNIs a convolution kernel matrix parameter, B_2CNNIs a bias parameter, M_2CLIs the convolution kernel size and number of layers, M_2poolThe maximum pool nucleus size and the number of layers are adopted, and Z is input carotid artery color Doppler ultrasound data.

In the stroke risk prediction intervention system, a feature fusion module performs feature fusion on the features obtained by a signal analysis module by using a multi-source feature deep neural network fusion algorithm to finally obtain a fusion feature D_CNN-LSTMThe method comprises the following steps:

s1: constructing a deep neural network structure, which consists of an input layer, a hidden layer and an output layer;

s2 initializing deep neural network parameters

Wherein, Tr_CNN-LSTM0Is a deep neural network initialization parameter, R is the number of input layer neurons, W_CNN-LSTM1Is the weight of the input layer to the hidden layer, b_CNN-LSTM1Is a bias of the hidden layer 1, W_CNN-LSTM2Is the weight of hidden layer 1 to hidden layer 2, b_CNN-LSTM2Is a bias of the hidden layer 2, W_CNN-LSTM3Is the weight of hidden layer 2 to hidden layer 3, b_CNN-LSTM3Is the bias of the hidden layer 3, h_{CNN_LSTM1}、h_{CNN_LSTM2}、 h_{CNN_LSTM3}The number of neurons in the hidden layer 1, the hidden layer 2, and the hidden layer 3; rand is a random number function between random generations (0, 1) and zeros is a zero function.

S3: mixing X_CNNIs inputted intoIn the initialized deep neural network, continuously updating the network parameters and obtaining the trained network parameters Tr_CNN-LSTM1And new feature X_CNN,1

X_CNN，1＝G_CNN-LSTM1(Net_CNN-LSTM1,Tr_CNN-LSTM1,X_CNN)

G_CNN-LSTM1Is a deep neural network Net_CNN-LSTM1Is used to generate the output function of (1).

S4: will depth neural network Tr_CNN-LSTM1Value of as network layer Net_CNN-LSTM2Initial value of (2), feature Y_LSTMInput to network layer Net_CNN-LSTM2In the method, updating network parameters is carried out to complete the characteristic X_CNNAnd Y_LSTMIs optimized alternately, then Z is_CNNInput to network layer Net_CNN-LSTM3In the method, network parameter updating is carried out, thereby completing the characteristic X_CNN、Y_LSTMAnd Z_CNNFirst alternate optimization of (a).

Network layer Net_CNN-LSTM1For feature X_CNNIs measured for the reconstruction error L_θ1Comprises the following steps:

Uc_CNN1＝σ(W′_CNN-LSTM1*σ(W′_CNN-LSTM2*σ(W′_CNN-LSTM3*X_CNN，1+b′_CNN-LSTM3))+b′_CNN-LSTM2))+b′_CNN-LSTM1)

where n is the total number of neurons, Uc_CNN1Is network layer Net_CNN-LSTM1To X_CNNThe reconstructed value of (1), W'_CNN-LSTM1Is a hidden layer 1 to the inputWeight, W ', of out-layer transfer'_CNN-LSTM2Is the weight, W ', that the hidden layer 2 transfers to the output layer'_CNN-LSTM3Is the weight, b ', that the hidden layer 3 transfers to the output layer'_CNN-LSTM1Is the offset of the output layer corresponding to the hidden layer 1, b'_CNN-LSTM2Is the offset of the output layer corresponding to the hidden layer 2, b'_CNN-LSTM3Is the offset of the output layer corresponding to the hidden layer 2, b_CNN-LSTM1Is the bias of the hidden layer 1, σ is the activation function, and α is the learning rate.

In the same way for feature Y_LSTMAnd feature Z_CNNIs measured for the reconstruction error L_θ2And L_θ3Thereby obtaining X_CNN、Y_LSTMAnd Z_CNNError L of the first alternating optimization₁:

L₁＝L_θ1+L_θ2+L_θ3

S5: repeating step X according to steps S3 and S4_CNN、Y_LSTMAnd Z_CNNInputting the data into a deep neural network for alternate optimization until the error L is smaller than a set threshold value. At the moment, the final deep neural network parameters and the fusion characteristics D are obtained_CNN-LSTM。

D_CNN-LSTM=G_CNN-LSTM(Net_{CNN-LSTM,TrCNN-LSTM}；X_CNN,Y_LSTM,Z_CNN)

Wherein G is_CNN-LSTMIs a deep neural network output function, Net_CNN-LSTMIs a deep neural network, Tr, after training_CNN-LSTMAre the trained deep neural network parameters.

The risk prediction module carries out risk prediction according to the fusion characteristics obtained by the characteristic fusion module and comprises the following steps:

the obtained final fusion characteristics D_CNN-LSTMInputting the risk prediction into a softmax classifier for risk prediction, and classifying the risk prediction into the following levels: the high risk first grade, high risk second grade, high risk third grade, the risk prediction mode is as follows:

P(result|D_CNN-LSTM)=softmax(Wp*D_CNN-LSTM+bp)

W_p、b_pis a classifierParameter of softmax, P (result | D)_CNN-LSTM) Is the predicted probability of a certain risk level, and the predicted risk level is obtained by decoding according to the predicted probability value.

The intervention module comprises a health information management library, an intelligent learning module and an intervention scheme, wherein the health management information library stores personal basic health information of a user and an intervention recommendation scheme library matched with the personal health information; the intelligent learning module is a pre-designed intelligent learning module, and recommends an individualized intervention scheme from an intervention recommendation scheme library according to the stroke risk prediction grade and the personal health basic condition of the user, and finally, a doctor adjusts and confirms the intervention scheme; the intervention program is an intervention program that is ultimately confirmed by a physician and recommended to the user.

Preferably, an intervention scheme is provided for a user for the first time and stored in the health information management base, and the intervention scheme is updated and adjusted periodically according to the stroke risk prediction result and the health management information updating condition.

And the human-computer interaction module is used for informing the doctor of the final intervention scheme to the user and carrying out communication interaction with the user in voice, text and other modes.

Compared with the prior art, the invention has the beneficial effects that:

(1) and performing feature fusion on the biochemical data information, the carotid artery color ultrasound information and the basic physiological monitoring information by adopting a multi-source feature deep neural network fusion algorithm, and fully exerting relevance and complementarity of multi-source heterogeneous data.

(2) According to the screening of the clinical case basic information, people with more than 3 high-risk factors in stroke are screened, and then the stroke risk prediction is carried out on the people, so that the prediction result has pertinence and practical application value.

(3) By using the method and the system, the risk level of the high-risk group of the cerebral apoplexy can be obtained by collecting the biochemical data information, the carotid artery color Doppler ultrasound information and the basic physiological monitoring information of the high-risk group of the cerebral apoplexy, different intervention schemes are recommended according to the risk level of the high-risk group of the cerebral apoplexy, the personalized self-adaptive intervention scheme is recommended through intelligent learning, and man-machine interaction is carried out with the old people, so that personalized intervention is realized, and the attack risk of the cerebral apoplexy is reduced.

Drawings

In the drawings, like reference numerals refer to the same or similar parts or elements throughout the several views unless otherwise specified. The figures are not necessarily to scale. It is appreciated that these drawings depict only some embodiments in accordance with the disclosure and are therefore not to be considered limiting of its scope.

Fig. 1 is a schematic diagram of a stroke risk prediction intervention system based on multi-source heterogeneous information fusion according to the present invention;

fig. 2 is a flowchart of a stroke risk prediction intervention method based on multi-source heterogeneous information fusion according to the present invention;

FIG. 3 is a flow chart of feature fusion according to FIG. 2;

FIG. 4 is a flow chart of adaptive human-machine interaction according to the present invention.

Detailed Description

In the following, only certain exemplary embodiments are briefly described. As those skilled in the art will appreciate, the described embodiments may be modified in various different ways, without departing from the spirit or scope of the present invention. Accordingly, the drawings and description are to be regarded as illustrative in nature, and not as restrictive.

The following detailed description of the present invention will be made with reference to the accompanying drawings 1-4.

As shown in fig. 1, the invention provides a stroke risk prediction intervention system based on multi-source heterogeneous information fusion, which includes an information collection module, an information preprocessing analysis module, a feature fusion module, a stroke risk prediction module, an intervention module and a human-computer interaction module.

The information collection module is used for collecting blood biochemical data, carotid artery color Doppler ultrasound data and daily continuous monitoring data of high-risk groups suffering from cerebral apoplexy.

The signal preprocessing and analyzing module is used for preprocessing blood biochemical data, carotid artery color hyper-data and daily continuous monitoring data of the information collecting module and extracting and analyzing features.

And the feature fusion module performs feature fusion on the features obtained by the signal preprocessing analysis module by using the deep neural network model.

And the stroke risk prediction module is used for inputting the features obtained according to the feature fusion module into the softmax module to predict the stroke risk.

The intervention module is used for recommending an intervention scheme according to the risk level obtained by the stroke risk prediction module.

And the human-computer interaction module is used for performing human-computer interaction according to the intervention scheme generated by the intervention module.

The method for predicting the stroke risk by using the stroke risk prediction module based on multi-source heterogeneous information fusion according to the invention is described below with reference to fig. 2 to 4.

The information collection module collects biochemical data, carotid artery color Doppler ultrasound data and daily continuous monitoring data of high-risk groups in the stroke, the groups are screened according to the basic information of clinical cases, and the groups have more than 3 high-risk factors in the stroke.

Specifically, high risk factors in stroke include: age is high, hypertension, hyperglycemia, hyperlipemia, heart disease, family history of apoplexy, smoking, obesity, high salt and high oil eating habit, and less exercise 10 items; the blood biochemical data comprise: high density lipoproteins, low density lipoproteins, cholesterol, triglycerides, homocysteine, D dimers, glycated serum proteins, and the like; the daily continuous monitoring data comprises: heart rate, blood pressure, electrocardiogram, exercise, blood sugar, body fat ratio.

The signal preprocessing analysis performed by the signal preprocessing analysis module comprises preprocessing analysis on biochemical data, carotid artery color Doppler ultrasound data and daily continuous monitoring data, wherein:

the biochemical data preprocessing comprises the following steps: normalization processing is carried out by utilizing dispersion normalization, the data is compressed to [0,1] through linear transformation of the original data, and the formula is as follows:

wherein X' is the compressed value, X is the original value of a biochemical index, X_maxIs the maximum value of index X, X_miIs the minimum value of index X.

The preprocessing of carotid color Doppler ultrasound data comprises the following steps: vectorizing the carotid color hyper-data report result words by using word2vec word vector technology.

The preprocessing analysis of daily continuous monitoring data comprises the following steps: the heart rate variability index is calculated by utilizing the electrocardiogram data, the blood pressure variability index is calculated by utilizing the continuously monitored blood pressure data, and the average value of the heart rate, the blood pressure, the blood sugar, the exercise and the body fat ratio every 7 days is calculated.

The signal preprocessing and analyzing module is used for analyzing and processing the preprocessed information and comprises the following steps: performing feature extraction on the preprocessed biochemical data information through a convolutional neural network model to obtain a feature vector X_CNN。

X_CNN=G_CNN(Net_1CNN,Tr_1CNN,X)

[Net_1CNN,Tr_1CNN]=Feedforward(W_1CNN,B_1CNN；M_1CL,M_1pool；X)

Wherein, X_CNNIs a feature vector, Net, extracted by a convolutional neural network_1CNNIs a trained convolutional neural network, Tr_1CNNIs the parameter of the convolutional neural network after training, and feed forward is the function of the Feedforward neural network, W_1CNNIs a convolution kernel matrix parameter, B_1CNNIs a bias parameter, M_1CLIs the size and number of convolution kernel layers set to 3 x 2 convolution kernel, the number of convolution layers is 2, M_1poolThe maximum pooled nucleus size and number of layers were set to 2X 2 pooled nuclei, the number of pooled layers was 2, and X was the input biochemical data.

Extracting the characteristics of the preprocessed daily physiological monitoring signals through a long-time and short-time memory network, and outputting a characteristic vector Y_LSTM。

Y_LSTM＝G_LSTM(Net_LSTM，Tr_LSTM，Y)

[Net_LSTM,Tr_LSTM]=Feedforward(W_LSTM1,W_LSTM2,B_LSTM1,B_LSTM2；Y)

Wherein, Y_LSTMIs a characteristic vector, Net, extracted by a long-time and short-time memory network_LSTMIs a long and short term memory network after training, Tr_LSTMIs the network parameter memorized after training, and the feed forward is the Feedforward neural network function, W_LSTM1、W_LSTM2For long and short term memory of the weight parameters of the network input gate and the forgetting gate, B_LST1、B_LSTM2The method is characterized in that bias parameters of a network input gate and a forgetting gate are memorized at long time, and Y is an input daily physiological monitoring signal.

Performing feature extraction on the preprocessed carotid artery color Doppler ultrasound data through a convolutional neural network model to obtain a feature vector Z_CNN。

Z_CNN=G_CNN(Net_2CNN，Tr_2CNN，Z)

[Net_2CNN，Tr_2CNN]=Feedforward(W_2CNN,B_2CNN；M_2CL,M_2pool；Z)

Wherein Z is_CNNIs a feature vector, Net, extracted by a convolutional neural network_2CNNIs a trained convolutional neural network, Tr_2CNNIs the parameter of the convolutional neural network after training, and feed forward is the function of the Feedforward neural network, W_2CNNIs a convolution kernel matrix parameter, B_2CNNIs a bias parameter, M_2CLIs the size and number of convolution kernels, the convolution kernel is 3 x 3, the number of convolution layers is 3, M_2poolThe maximum pool nucleus size and the number of layers are shown, the pool nucleus is 2 x 2, the pool layer is 2, and Z is input carotid artery color ultrasound data.

The feature fusion module performs feature fusion on the features obtained by the signal preprocessing analysis module by using a multi-source feature deep neural network fusion algorithm to finally obtain a fusion feature D_CNN-LSTMAs shown in fig. 3:

s1: constructing a deep neural network structure, wherein the deep neural network is composed of an input layer, a hidden layer and an output layer;

s2 initializing deep neural network parameters

Wherein, Tr_CNN-LSTM0Is a deep neural network initialization parameter, R is the number of input layer neurons, W_CNN-LSTM1Is the weight of the input layer to the hidden layer, b_CNN-LSTM1Is a bias of the hidden layer 1, W_CNN-LSTM2Is the weight of hidden layer 1 to hidden layer 2, b_CNN-LSTM2Is a bias of the hidden layer 2, W_CNN-LSTM3Is the weight of hidden layer 2 to hidden layer 3, b_CNN-LSTM3Is the bias of the hidden layer 3, h_{CNN_LSTM1}、h_{CNN_LSTM2}、 h_{CNN_LSTM3}The number of neurons in the hidden layer 1, the hidden layer 2, and the hidden layer 3; rand is a random number function between random generations (0, 1) and zeros is a zero function.

S3: mixing X_CNNInputting the data into an initialized deep neural network, continuously updating network parameters and obtaining trained network parameters Tr_CNN-LSTM1And new feature X_CNN,1,

X_CNN，1＝G_CNN-LSTM1(Net_CNN-LSTM1,Tr_CNN-LSTM1,X_CNN)

G_CNN-LSTM1Is a deep neural network Net_CNN-LSTM1Is used to generate the output function of (1).

S4: will depth neural network Tr_CNN-LSTM1Value of as network layer Net_CNN-LSTM2Initial value of (2), feature Y_LSTMInput to network layer Net_CNN-LSTM2In the method, updating network parameters is carried out to complete the characteristic X_CNNAnd Y_LSTMThen the deep neural network Tr is optimized_CNN-LSTM2Value of as network layer Net_CNN-LSTM3Initial value of (1), feature Z_CNNInput to network layer Net_CNN-LSTM3In the method, updating network parameters is carried out, thereby completing the characteristic X_CNN、Y_LSTMAnd Z_CNNThe first alternate optimization of.

Network layer Net_CNN-LSTM1For feature X_CNNIs measured for the reconstruction error L_θ1Comprises the following steps:

Uc_CNN1＝σ(W′_CNN-LSTM1*σ(W′_CNN-LSTM2*σ(W′_CNN-LSTM3*X_CNN，1+b′_CNN-LSTM3))+b′_CNN-LSTM2))+b′_CNN-LSTM1)

where n is the total number of neurons, Uc_CNN1Is network layer Net_CNN-LSTM1To X_CNNThe reconstructed value of (1), W'_CNN-LSTM1Is the weight, W ', that hidden layer 1 transfers to the output layer'_CNN-LSTM2Is the weight, W ', that the hidden layer 2 transfers to the output layer'_CNN-LSTM3Is the weight, b ', that the hidden layer 3 transfers to the output layer'_CNN-LSTM1Is the offset of the output layer corresponding to the hidden layer 1, b'_CNN-LSTM2Is the offset of the output layer corresponding to the hidden layer 2, b'_CNN-LSTM3Is the offset of the output layer corresponding to the hidden layer 2, b_CNN-LSTM1Is the bias of the hidden layer 1, σ is the activation function, and α is the learning rate.

In the same way for feature Y_LSTMAnd feature Z_CNNIs measured for the reconstruction error L_θ2And L_θ3Thereby obtaining X_CNN、Y_LSTMAnd Z_CNNError L of the first alternating optimization₁:

L₁＝L_θ1+L_θ2+L_θ3

S5: will be deepNeural network parameter Tr_CNN-LSTM3As the next initial value, step S3 and S4 are repeated for X_CNN、Y_LSTMAnd Z_CNNInputting the data into a deep neural network for repeated alternate optimization until the error L is less than a set threshold value. At the moment, the final deep neural network parameters and fusion characteristics D are obtained_CNN-LSTM。

D_CNN-LSTM＝G_CNN-LSTM(Net_CNN-LSTM,Tr_CNN-LSTM；X_CNN,Y_LSTM,Z_CNN)，

Wherein G is_CNN-LSTMIs a deep neural network output function, Net_CNN-LSTMIs a deep neural network, Tr, after training_CNN-LSTMAre the trained deep neural network parameters.

The risk prediction module carries out risk prediction according to the fusion characteristics obtained by the characteristic fusion module, and the risk prediction comprises the following steps:

the obtained final fusion characteristics D_CNN-LSTMInputting the risk prediction into a softmax classifier for risk prediction, and classifying the risk prediction into the following levels: the high risk first grade, high risk second grade, high risk third grade, the risk prediction mode is as follows:

P(result|D_CNN-LSTM)＝softmax(Wp*D_CNN-LSTM+b_p)

W_p、b_pis a parameter of the classifier softmax, P (result | D)_CNN-LSTM) Is the predicted probability of a certain risk level, and the predicted risk level is obtained by decoding according to the predicted probability value.

The intervention module comprises a health information management library, an intelligent learning module and an intervention scheme, wherein the health management information library stores personal basic health information of a user and an intervention recommendation scheme library matched with the personal health information; the intelligent learning module is a pre-designed intelligent learning module, and recommends an individualized intervention scheme from an intervention recommendation scheme library according to the stroke risk prediction grade and the personal health basic condition of the user, and finally, a doctor adjusts and confirms the intervention scheme; the intervention program is an intervention program that is ultimately confirmed by a physician and recommended to the user.

Preferably, an intervention scheme is provided for a user for the first time and stored in the health information management base, and the intervention scheme is updated and adjusted periodically according to the stroke risk prediction result and the health management information updating condition.

And the human-computer interaction module is used for informing the doctor of the final intervention scheme to the user and carrying out communication interaction with the user in voice, text, video and other modes.

Preferably, the human-computer interaction module timely informs the user of the change of the stroke risk prediction result and the intervention scheme recommended by the intervention module according to the change after the adjustment and confirmation of the intervention scheme by the doctor, and simultaneously increases the adjusted intervention scheme to the intervention scheme library. For example, when the stroke risk prediction module predicts that the risk level of the user is changed from the high risk level to the high risk level from the high risk level of the last prediction result, the intervention module recommends a new intervention scheme of the user through intelligent learning of the risk level of the user and basic health information of the user and sends the new intervention scheme to a doctor, the doctor adjusts and confirms the intervention scheme by comprehensively analyzing health management information of the old, informs the user of the intervention scheme in a voice, text or video mode and the like, and simultaneously reminds the user of timely medical examination and personal basic health condition needing to be stated to the doctor, so that the user can check and intervene as soon as possible, and the probability of stroke occurrence is reduced.

The foregoing summary is provided for the purpose of illustration only and is not intended to be in any way limiting. In addition to the illustrative aspects, embodiments, and features described above, further aspects, embodiments, and features of the present invention will be readily apparent by reference to the drawings and following detailed description.

Claims (10)

1. A stroke risk prediction intervention system, comprising:

the information collection module is used for collecting blood biochemical data, carotid artery color Doppler ultrasound data and daily continuous monitoring data of high-risk people suffering from cerebral apoplexy;

the signal preprocessing and analyzing module is used for preprocessing blood biochemical data, carotid artery color Doppler ultrasound data and daily continuous monitoring data collected by the information collecting module and extracting and analyzing characteristics;

the characteristic fusion module is used for carrying out characteristic fusion on the characteristics obtained by the preprocessing and analysis of the signal preprocessing and analysis module;

the stroke risk prediction module is used for predicting the stroke risk according to the characteristics obtained by the characteristic fusion module;

the intervention module is used for recommending an intervention scheme according to the risk level obtained by the stroke risk prediction module; and

a human-computer interaction module for performing human-computer interaction according to the intervention scheme generated by the intervention module,

the feature fusion module performs feature fusion on the features obtained by the signal preprocessing analysis module by using a deep neural network model through a multi-source feature deep neural network fusion algorithm to finally obtain fusion features D_CNN-LSTM。

2. The system of claim 1, wherein the signal preprocessing and analyzing module performs feature extraction on the preprocessed biochemical data information through a convolutional neural network model to obtain a feature vector X_CNNPerforming feature extraction on the preprocessed daily physiological monitoring signals through a long-time and short-time memory network to obtain a feature vector Y_LSTMPerforming feature extraction on the preprocessed carotid artery color Doppler ultrasound data through a convolutional neural network model to obtain a feature vector Z_CNN。

3. The system of claim 2, wherein in the feature fusion module, X is_CNNIs input into the initialized deep neural network, network parameters are updated, and trained network parameters Tr are obtained_CNN-LSTM1And new feature X_CNN,1(ii) a Will depth neural network Tr_CNN-LSTM1Value of as network layer Net_CNN-LSTM2Initial value of, feature Y_LSTMIs input to the network layer Net_CNN-LSTM2In, go intoUpdating network parameters to complete feature X_CNNAnd Y_LSTMAlternate optimization of (2); then the deep neural network Tr_CNN-LSTM2Value of as network layer Net_CNN-LSTM3Initial value of (1), Z_CNNIs input to the network layer Net_CNN-LSTM3In (3), updating network parameters is performed to complete feature X_CNN、Y_LSTMAnd Z_CNNFirst alternate optimization of (a).

4. The system of claim 3, wherein the computing network layer Net in the feature fusion module_CNN-LSTM1For feature X_CNNIs measured for the reconstruction error L_θ1Network layer Net_CNN-LSTM2For feature Y_LSTMIs measured for the reconstruction error L_θ2And network layer Net_CNN-LSTM3For feature Z_CNNIs measured for the reconstruction error L_θ3Thereby obtaining X_CNN、Y_LSTMAnd Z_CNNError L of the first alternating optimization₁：L₁＝L_θ1+L_θ2+L_θ3。

5. The system of claim 4, wherein the deep neural network parameters Tr are combined in the feature fusion module_CNN-LSTM3As the initial value of the next time, X is repeatedly set_CNN、Y_LSTMAnd Z_CNNInputting the data into a deep neural network for alternate optimization until the error L is smaller than a set threshold value, and obtaining final parameters of the deep neural network and fusion characteristics D at the moment_CNN-LSTM,

D_CNN-LSTM＝G_CNN-LSTM(Net_CNN-LSTM,Tr_CNN-LSTM；X_CNN,Y_LSTM,Z_CNN)，

Wherein G is_CNN-LSTMIs a deep neural network output function, Net_CNN-LSTMIs a deep neural network, Tr, after training_CNN-LSTMIs the parameter of the deep neural network after training, and the final fusion characteristic D is obtained_CNN-LSTMInputting the risk prediction data into a stroke risk prediction module for risk predictionAnd (6) measuring.

6. A method of using the stroke risk prediction intervention system according to any of claims 1 to 5, comprising:

collecting blood biochemical data, carotid artery color Doppler ultrasound data and daily continuous monitoring data of high-risk people with stroke by using an information collection module;

preprocessing and characteristic extraction analysis are carried out on the collected blood biochemical data, carotid artery color Doppler ultrasound data and daily continuous monitoring data by utilizing a signal preprocessing and analyzing module;

performing feature fusion on the extracted and analyzed features by using a feature fusion module; and

the stroke risk prediction module is used for predicting the stroke risk according to the characteristics obtained by the characteristic fusion,

performing feature fusion on the obtained features by using a deep neural network model through a multi-source feature deep neural network fusion algorithm to finally obtain fusion features D_CNN-LSTM。

7. The method of stroke risk predictive intervention according to claim 6,

performing feature extraction on the preprocessed biochemical data information through a convolutional neural network model to obtain a feature vector X_CNN，

X_CNN＝G_CNN(Net_1CNN，Tr_1CNN，X)

[Net_1CNN，Tr_1CNN]＝Feedforward(W_1CNN,B_1CNN；M_1CL,M_1pool；Z)

Wherein, X_CNNIs a feature vector, Net, extracted by a convolutional neural network_1CNNIs a trained convolutional neural network, Tr_1CNNIs the parameter of the convolutional neural network after training, and feed forward is the function of the Feedforward neural network, W_1CNNIs a convolution kernel matrix parameter, B_1CNNIs a bias parameter, M_1CLIs the convolution kernel size and number of layers, M_1poolIs the maximum pool nucleus size and the layer number, X is the input biochemical data,

extracting the characteristics of the preprocessed daily physiological monitoring signals through a long-time and short-time memory network, and outputting a characteristic vector Y_LSTM，

Y_LSTM＝G_LSTM(Net_LSTM，Tr_LSTM，Y)

[Net_LSTM,Tr_LSTM]＝Feedforward(W_LSTM1,W_LSTM2,B_LSTM1,B_LSTM2；Y)

Wherein, Y_LSTMIs a characteristic vector, Net, extracted by a long-time and short-time memory network_LSTMIs a long and short term memory network after training, Tr_LSTMIs the network parameter memorized after training, and the feed forward is the Feedforward neural network function, W_LSTM1、W_LSTM2For long and short term memory of the weight parameters of the network input gate and the forgetting gate, B_LST1、B_LSTM2For memorizing the bias parameters of the input gate and the forgetting gate of the network at long time, Y is an input daily physiological monitoring signal,

performing feature extraction on the preprocessed carotid artery color Doppler ultrasound data through a convolutional neural network model to obtain a feature vector Z_CNN。

Z_CNN＝G_CNN(Net_2CNN，Tr_2CNN，Z)

[Net_2CNN，Tr_2CNN]＝Feedforward(W_2CNN,B_2CNN；M_2CL,M_2pool；Z)

Wherein Z is_CNNIs a feature vector, Net, extracted by a convolutional neural network_2CNNIs a trained convolutional neural network, Tr_2CNNIs the parameter of the convolutional neural network after training, and feed forward is the function of the Feedforward neural network, W_2CNNIs a convolution kernel matrix parameter, B_2CNNIs a bias parameter, M_2CLIs the convolution kernel size and number of layers, M_2poolThe maximum pool nucleus size and the number of layers are adopted, and Z is input carotid artery color Doppler ultrasound data.

8. The stroke wind of claim 7A risk prediction intervention method, characterized in that X is_CNNInputting the data into the initialized deep neural network, updating the network parameters and obtaining the trained network parameters Tr_CNN-LSTM1And new feature X_CNN,1

X_CNN，1＝G_CNN-LSTM1(Net_CNN-LSTM1,Tr_CNN-LSTM1,X_CNN)

G_CNN-LSTM1Is a deep neural network Net_CNN-LSTM1The output function of (a) is selected,

will depth neural network Tr_CNN-LSTM1Value of as network layer Net_CNN-LSTM2Initial value of (2), feature Y_LSTMInput to network layer Net_CNN-LSTM2In the method, updating network parameters is carried out to complete the characteristic X_CNNAnd Y_LSTMThe alternating optimization of (a) and (b),

deep neural network Tr_CNN-LSTM2Value of as network layer Net_CNN-LSTM3Initial value of (1), will Z_CNNInput to network layer Net_CNN-LSTM3In (3), updating network parameters is performed to complete feature X_CNN、Y_LSTMAnd Z_CNNFirst alternate optimization of (a).

9. The method of intervention of stroke risk prediction as claimed in claim 8, wherein calculating network layer Net_CNN-LSTM1For feature X_CNNIs measured for the reconstruction error L_θ1Calculating network layer Net_CNN-LSTM2For feature Y_LSTMIs measured for the reconstruction error L_θ2And network layer Net_CNN-LSTM3For feature Z_CNNIs measured for the reconstruction error L_θ3Thereby obtaining X_CNN、Y_LSTMAnd Z_CNNError L of the first alternating optimization₁:

L₁＝L_θ1+L_θ2+L_θ3，

Fitting the deep neural network parameters Tr_CNN-LSTM3As the initial value of the next time, X is repeatedly set_CNN、Y_LSTMAnd Z_CNNInputting the depth data into a deep neural network for alternate optimization until the error L is less than a set threshold value, and obtaining the final depth at the momentNeural network parameters and fusion characteristics D_CNN-LSTM。

D_CNN-LSTM＝G_CNN-LSTM(Net_CNN-LSTM,Tr_CNN-LSTM；X_CNN,Y_LSTM,Z_CNN)

Wherein G is_CNN-LSTMIs a deep neural network output function, Net_CNN-LSTMIs a deep neural network, Tr, after training_CNN-LSTMAre the trained deep neural network parameters.

10. The method of claim 8, wherein the final fusion feature D is obtained_CNN-LSTMInputting the risk prediction data into a stroke risk prediction module for risk prediction, wherein the risk prediction mode is as follows:

P(result|D_CNN-LSTM)＝softmax(Wp*D_CNN-LSTM+b_p)

W_p、b_pis a parameter of the classifier, P (result | D)_CNN-LSTM) Is the predicted probability of a certain risk level, and the predicted risk level is obtained by decoding according to the predicted probability value.

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