Volume 9, Issue 2 (Apr- June 2020)
JCHR 2020, 9(2): 69-80 |
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jabarpour E, Abedini A, keshtkar A. Osteoporosis Risk Prediction Using Data Mining Algorithms. JCHR 2020; 9 (2) :69-80
URL: http://jhr.ssu.ac.ir/article-1-504-en.html
URL: http://jhr.ssu.ac.ir/article-1-504-en.html
1- 1. Department of Industrial Engineering, School of Engineering, Payame Noor University, Tehran Shomal Branch, Tehran,Iran
2- 2. Department of Computer Engineering, School of Electrical and Computer, Engineering Islamic Azad University, Qazvin Branch, Iran , aminabedini.ai@gmail.com
3- 3. Department of Health Sciences Education Development, School of Public Health, Tehran University of Medical Sciences, Tehran, Iran
2- 2. Department of Computer Engineering, School of Electrical and Computer, Engineering Islamic Azad University, Qazvin Branch, Iran , aminabedini.ai@gmail.com
3- 3. Department of Health Sciences Education Development, School of Public Health, Tehran University of Medical Sciences, Tehran, Iran
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.PNG)
Figure 1. Support Vector Machine (SVM)
SVM node was selected in the Clementine software. Primarily, 45 studied features were entered in the elementary configuration of this model. These 45 features have been selected using dimensional reduction methods (KMeans algorithm and the opinion of specialists). Osteoporosis in two groups of healthy people and patients was considered as a target feature and other features were considered as entrance features. The results of this step are calculated for SVM.
Subsequently, regarding the effects of the dimensional reduction in data mining, the model was repeated with 35 features. Feature selection was performed based on their importance degree in the previous model so that features that were more important in the last step are selected in this step and the model was run based on them. An SVM model was run using these 35 features and its results were obtained.
Bayesian Network
Bayesian network makes it possible to develop a probable model via a combination of observed and recorded evidence from the real world to calculate the probability of events from a set of apparently unrelated features. Bayes networks are used for the prediction of different status. A Bayes network is known as a graphical model revealing the variables of a dataset (that are often called a node) along with their probable and conditional relationships. Casual relationships between nodes can be shown using the Bayes network (43).
However, connections of a network (arcs) do not necessarily show direct cause and effect aspects. For instance, a Bayes network can be used to calculate the probability of the presence of a disease in a specific person. In this case, the presence or absence of a specific symptom could be considered as a causal connection between the symptom and the disease in the Bayesian network. These networks are very powerful and make the best predictions about different types of data (43).
For designation of Bayes model (TAN), educational data are defined as elementary data in Bayes Net node and parameters of the model are adjusted as below:
Use Partitioned Data Structure Type: TAN
Parameter learning method: Maximum likelihood (Figure 2).
.PNG)
.PNG)
.PNG)
.PNG)
.PNG)
.PNG)
The Bayes network-produced model (with 45 features) detected immune-suppressor drugs, hyperlipidemia, osteoporosis drugs, history of osteoporosis in the family, calcium intake, lactation duration, and hyperlipidemia drugs as factors affecting osteoporosis the most.
The results of the Bayes network model with 35 features are as follows: (Figure 7)
.PNG)
In the second step, the Bayes network-produced model detected immune-suppressor drugs, anti-inflammatory drugs, vitamin D, and exercising during the week, lactation duration, and autoimmune diseases as factors affecting osteoporosis the most.
.PNG)
Conflict of Interests
The authors declare no conflict of interest.
Full-Text: (803 Views)
Abstract
Introduction: Osteoporosis is a disease that reduces bone density and loses the quality of bone microstructure leading to an increased risk of fractures. It is one of the major causes of inability and death in elderly people. The current study aims at determining the factors influencing the incidence of osteoporosis and providing a predictive model for the disease diagnosis to increase the diagnostic speed and reduce diagnostic costs.
Methods: An Individual's data including personal information, lifestyle, and disease information were reviewed. A new model has been presented based on the Cross-Industry Standard Process CRISP methodology. Besides, Support Vector Machine (SVM) and Bayes methods (Tree Augmented Naïve Bayes (TAN) and Clementine12 have been used as data mining tools.
Results: Some features have been detected to affect this disease. The rules have been extracted that can be used as a pattern for the prediction of the patients' status. Classification precision was calculated to be 88.39% for SVM, and 91.29% for (TAN) when the precision of TAN is higher comparing to other methods.
Conclusion: In this study, lactation duration, history of osteoporosis, calcium intake, immune-suppressor drugs, hyperlipidemia drugs, autoimmune diseases, number of pregnancies, hyperlipidemia, vitamin D, hyperparathyroidism, exercising during the week, anti-inflammatory drugs, thalassemia, waist disc, anti-coagulants drugs, hypothyroidism, hypertension drugs, history of surgery, diabetes and diabetes-related drugs were identified as important factors in relation to osteoporosis. These factors can be used for a new sample with defined characteristics to predict the possibility of osteoporosis in a person.
Keywords: Osteoporosis, Data mining, Support vector machine, Bayesian network
Introduction
Introduction: Osteoporosis is a disease that reduces bone density and loses the quality of bone microstructure leading to an increased risk of fractures. It is one of the major causes of inability and death in elderly people. The current study aims at determining the factors influencing the incidence of osteoporosis and providing a predictive model for the disease diagnosis to increase the diagnostic speed and reduce diagnostic costs.
Methods: An Individual's data including personal information, lifestyle, and disease information were reviewed. A new model has been presented based on the Cross-Industry Standard Process CRISP methodology. Besides, Support Vector Machine (SVM) and Bayes methods (Tree Augmented Naïve Bayes (TAN) and Clementine12 have been used as data mining tools.
Results: Some features have been detected to affect this disease. The rules have been extracted that can be used as a pattern for the prediction of the patients' status. Classification precision was calculated to be 88.39% for SVM, and 91.29% for (TAN) when the precision of TAN is higher comparing to other methods.
Conclusion: In this study, lactation duration, history of osteoporosis, calcium intake, immune-suppressor drugs, hyperlipidemia drugs, autoimmune diseases, number of pregnancies, hyperlipidemia, vitamin D, hyperparathyroidism, exercising during the week, anti-inflammatory drugs, thalassemia, waist disc, anti-coagulants drugs, hypothyroidism, hypertension drugs, history of surgery, diabetes and diabetes-related drugs were identified as important factors in relation to osteoporosis. These factors can be used for a new sample with defined characteristics to predict the possibility of osteoporosis in a person.
Keywords: Osteoporosis, Data mining, Support vector machine, Bayesian network
Introduction
Osteoporosis is a disease that is known to reduce bone density and lose the quality of bone microstructure increasing the risk of bone fractures (1,2,3(. The disease has few symptoms and only appears when bones are easily broken. The
World Health Organization (WHO) has defined osteoporosis as a reduction in bone density that lies 2.5 standard deviations below the average value for young healthy people (4,5). According to WHO, annually more than 9.8 million breakages occur due to osteoporosis. It is estimated that osteoporosis will affect 200 million women worldwide (almost 1 out of 10 women aged over 60 years, 1 out of 5 women aged over 70 years, 2 out of 5 women aged over 80 years, and 2 out of 3 women aged over 90 years) (6,7,8). A recent study carried out by the Ministry of Health and Medical Education (MOHME) in Iran showed that osteoporosis affected 1 out of 4 Iranian women aged over 50 years old (9).
Genetic (10,11) and racial factors are among the most significant factors affecting bone density (12,13,14). Correspondingly, physiological, and environmental factors and lifestyles such as a diet with low contents of vitamin D and calcium, alcohol consumption and smoking, excess protein intake, caffeine, salt, and physical inactivity affect osteoporosis (15,16,17) which can significantly contribute to achieving maximum bone density and maintaining it throughout life (18,19). Some of these factors include the effect of sex hormones in adolescence (20), suitable nutrition, and total
body weight (21,22) as well as physical activity (23,24). Determining the risk factors concerning osteoporosis in different societies and countries and at various socioeconomic levels can help planning the osteoporosis prevention programs. Osteoporosis is one of the major causes of disability and mortality in older people (25). The mortality rate of hip fracture (femoral head) in the first year after the fracture occurred is about 20% in older people and half of these people will have some degree of disability for the rest of their lives. It is anticipated that more than 75% of osteoporosis fractures may occur in developing countries over the next 50 years (26). The country of Iran as well as other developing countries will have a significant population of the elderly in the next 50 years. So, it seems that the planning for prevention programs regarding osteoporosis must be one of the health priorities in Iran. Recently, some data mining methods can be helpful in the detection of the disease.
In the present study, the risk prediction of osteoporosis is investigated in clinical records using data mining algorithms. Using these methods, the risk of developing osteoporosis in a person can be prevented without using any diagnosis methods. Besides, the factors that are effective in this disease can be detected. Therefore, a model for the prevention of osteoporosis can be developed using Support Vector Machine (SVM) and (TAN).
Some studies predicting osteoporosis include the accuracy of the predictive osteoporosis model introduced by Wang et al. which is 70.5% in one of the finest hybrid models of the decision tree and artificial neural network with 33 features (27). Gao et al. have investigated a feature extracted from the fractal of the micro CT scan to predict osteoporosis in individuals. They used the decision tree C 4.5 for the predictive model and the accuracy is 92.9% (28). Moudani et al. have predicted the risk of osteoporosis using the random forest method in the decision tree. The model predicted four classes without risk, low risk, moderate risk, high risk, and a severe risk of osteoporosis. The study analyzed 15 features and obtained an accuracy of 99.92% (29). In another study, Alizadeh et al. showed that the artificial neural network model with multiple methods has the most accuracy for the prediction of osteoporosis in patients. The study was conducted on 670 patients with 60 features and had an accuracy of 95.70 (30).
Methods
For effective data mining, not only related information is needed, but also an appropriate
data mining method should be used. A method including all data mining steps such as data collection, data preparation, modeling, and evaluation is required.
Data collection and description
The clinical history used in this study was related to 4083 women referred to the osteoporosis research center placed in the endocrinology and metabolism Institute of Tehran University of Medical Sciences between 2006 and 2010. The history included personal information, lifestyle, and disease information. There are 425 attributes in this data set that includes personal information, lifestyle, and illness information. Having eliminated ineffective attributes such as name, father's name, phone number, etc, 400 attributes were extracted. All referrals were labeled as having osteoporosis. In this study, 4083 women with 365 cases had osteoporosis.
Data preparation
This step aimed at increasing the quality of user data, so that appropriate data could be provided for the next phase and data modeling.
Data cleaning: This step included noise softening, detection and removing fling data (isolated), resolving incompatibilities, filling gaps, and missed data.
Homogenizing formats: Because of its significance and its hidden aspects, this issue is of utmost importance while aggregating the data, so data miners address it lonely. For instance, sometimes in the data, the weight is calculated using the gram scale or kilogram scale which should be edited in the way that all data has the same format.
Data normalization: Data such as age, weight, height, BMI, lactation duration, and the number of pregnancies could have special values because they can be more effective in the analysis. The whole data, which are in the same way, should be normalized in this step.
Combination of some data: To facilitate modeling and extraction of results, that could be referable in medical uses, data were converted from continuous values to an interspersed value that has medical definitions.
To reduce the size of the initial 400 features in the data, according to the opinion of an expert in the Institute of Endocrinology and Metabolism, and with the help of scientific papers (31, 32, 33, 34, 35, 36, 37, 38, 39) in the field of osteoporosis, 45 attributes were selected.
Features include osteoporosis, staying around the day, arrhythmia, autoimmune disease, pregnancy rate, high blood lipids, anti-inflammatory drugs, gastrointestinal drugs, diabetes-related drugs, osteoporosis drug, blood lipids drug, cancer drugs, immunosuppressive drugs, hypertension, chloroquine drug, diabetes, arthritis, familial osteoporosis, age, menopausal age, body mass index, surgery, duration of breastfeeding, contraceptive pills, calcium intake, multivitamin intake, home type, menstruation age, cancer, anemia, weekly exercise, antiepileptic and seizure drug, gastrointestinal surgery, coffee, and tea consumption, hyperadrenalism, lumbar disc, falling, hyperparathyroidism, hyperthyroidism, hypothyroidism, smoking, vitamin D, thalassemia, history of fracture, and anticoagulation drug.
Data modeling
Support Vector Machine (SVM) is a classification method specifically used for large data sets. A large data set is a set that has a lot of predictors such as samples used in bioinformatics. The method is usually used when a lot of data is available such as medical datasets. (40 , 41).
The SVM simple model was used in this study. Firstly, data were divided into two educational (for education) and test (for evaluation) groups. This classification was performed in a completely random manner using Partition node in Clementine software training data in which educational data had 70% of the data and test data had the remaining 30% of the data (42) ( Figure 1).
World Health Organization (WHO) has defined osteoporosis as a reduction in bone density that lies 2.5 standard deviations below the average value for young healthy people (4,5). According to WHO, annually more than 9.8 million breakages occur due to osteoporosis. It is estimated that osteoporosis will affect 200 million women worldwide (almost 1 out of 10 women aged over 60 years, 1 out of 5 women aged over 70 years, 2 out of 5 women aged over 80 years, and 2 out of 3 women aged over 90 years) (6,7,8). A recent study carried out by the Ministry of Health and Medical Education (MOHME) in Iran showed that osteoporosis affected 1 out of 4 Iranian women aged over 50 years old (9).
Genetic (10,11) and racial factors are among the most significant factors affecting bone density (12,13,14). Correspondingly, physiological, and environmental factors and lifestyles such as a diet with low contents of vitamin D and calcium, alcohol consumption and smoking, excess protein intake, caffeine, salt, and physical inactivity affect osteoporosis (15,16,17) which can significantly contribute to achieving maximum bone density and maintaining it throughout life (18,19). Some of these factors include the effect of sex hormones in adolescence (20), suitable nutrition, and total
body weight (21,22) as well as physical activity (23,24). Determining the risk factors concerning osteoporosis in different societies and countries and at various socioeconomic levels can help planning the osteoporosis prevention programs. Osteoporosis is one of the major causes of disability and mortality in older people (25). The mortality rate of hip fracture (femoral head) in the first year after the fracture occurred is about 20% in older people and half of these people will have some degree of disability for the rest of their lives. It is anticipated that more than 75% of osteoporosis fractures may occur in developing countries over the next 50 years (26). The country of Iran as well as other developing countries will have a significant population of the elderly in the next 50 years. So, it seems that the planning for prevention programs regarding osteoporosis must be one of the health priorities in Iran. Recently, some data mining methods can be helpful in the detection of the disease.
In the present study, the risk prediction of osteoporosis is investigated in clinical records using data mining algorithms. Using these methods, the risk of developing osteoporosis in a person can be prevented without using any diagnosis methods. Besides, the factors that are effective in this disease can be detected. Therefore, a model for the prevention of osteoporosis can be developed using Support Vector Machine (SVM) and (TAN).
Some studies predicting osteoporosis include the accuracy of the predictive osteoporosis model introduced by Wang et al. which is 70.5% in one of the finest hybrid models of the decision tree and artificial neural network with 33 features (27). Gao et al. have investigated a feature extracted from the fractal of the micro CT scan to predict osteoporosis in individuals. They used the decision tree C 4.5 for the predictive model and the accuracy is 92.9% (28). Moudani et al. have predicted the risk of osteoporosis using the random forest method in the decision tree. The model predicted four classes without risk, low risk, moderate risk, high risk, and a severe risk of osteoporosis. The study analyzed 15 features and obtained an accuracy of 99.92% (29). In another study, Alizadeh et al. showed that the artificial neural network model with multiple methods has the most accuracy for the prediction of osteoporosis in patients. The study was conducted on 670 patients with 60 features and had an accuracy of 95.70 (30).
Methods
For effective data mining, not only related information is needed, but also an appropriate
data mining method should be used. A method including all data mining steps such as data collection, data preparation, modeling, and evaluation is required.
Data collection and description
The clinical history used in this study was related to 4083 women referred to the osteoporosis research center placed in the endocrinology and metabolism Institute of Tehran University of Medical Sciences between 2006 and 2010. The history included personal information, lifestyle, and disease information. There are 425 attributes in this data set that includes personal information, lifestyle, and illness information. Having eliminated ineffective attributes such as name, father's name, phone number, etc, 400 attributes were extracted. All referrals were labeled as having osteoporosis. In this study, 4083 women with 365 cases had osteoporosis.
Data preparation
This step aimed at increasing the quality of user data, so that appropriate data could be provided for the next phase and data modeling.
Data cleaning: This step included noise softening, detection and removing fling data (isolated), resolving incompatibilities, filling gaps, and missed data.
Homogenizing formats: Because of its significance and its hidden aspects, this issue is of utmost importance while aggregating the data, so data miners address it lonely. For instance, sometimes in the data, the weight is calculated using the gram scale or kilogram scale which should be edited in the way that all data has the same format.
Data normalization: Data such as age, weight, height, BMI, lactation duration, and the number of pregnancies could have special values because they can be more effective in the analysis. The whole data, which are in the same way, should be normalized in this step.
Combination of some data: To facilitate modeling and extraction of results, that could be referable in medical uses, data were converted from continuous values to an interspersed value that has medical definitions.
To reduce the size of the initial 400 features in the data, according to the opinion of an expert in the Institute of Endocrinology and Metabolism, and with the help of scientific papers (31, 32, 33, 34, 35, 36, 37, 38, 39) in the field of osteoporosis, 45 attributes were selected.
Features include osteoporosis, staying around the day, arrhythmia, autoimmune disease, pregnancy rate, high blood lipids, anti-inflammatory drugs, gastrointestinal drugs, diabetes-related drugs, osteoporosis drug, blood lipids drug, cancer drugs, immunosuppressive drugs, hypertension, chloroquine drug, diabetes, arthritis, familial osteoporosis, age, menopausal age, body mass index, surgery, duration of breastfeeding, contraceptive pills, calcium intake, multivitamin intake, home type, menstruation age, cancer, anemia, weekly exercise, antiepileptic and seizure drug, gastrointestinal surgery, coffee, and tea consumption, hyperadrenalism, lumbar disc, falling, hyperparathyroidism, hyperthyroidism, hypothyroidism, smoking, vitamin D, thalassemia, history of fracture, and anticoagulation drug.
Data modeling
Support Vector Machine (SVM) is a classification method specifically used for large data sets. A large data set is a set that has a lot of predictors such as samples used in bioinformatics. The method is usually used when a lot of data is available such as medical datasets. (40 , 41).
The SVM simple model was used in this study. Firstly, data were divided into two educational (for education) and test (for evaluation) groups. This classification was performed in a completely random manner using Partition node in Clementine software training data in which educational data had 70% of the data and test data had the remaining 30% of the data (42) ( Figure 1).
Figure 1. Support Vector Machine (SVM)
SVM node was selected in the Clementine software. Primarily, 45 studied features were entered in the elementary configuration of this model. These 45 features have been selected using dimensional reduction methods (KMeans algorithm and the opinion of specialists). Osteoporosis in two groups of healthy people and patients was considered as a target feature and other features were considered as entrance features. The results of this step are calculated for SVM.
Subsequently, regarding the effects of the dimensional reduction in data mining, the model was repeated with 35 features. Feature selection was performed based on their importance degree in the previous model so that features that were more important in the last step are selected in this step and the model was run based on them. An SVM model was run using these 35 features and its results were obtained.
Bayesian Network
Bayesian network makes it possible to develop a probable model via a combination of observed and recorded evidence from the real world to calculate the probability of events from a set of apparently unrelated features. Bayes networks are used for the prediction of different status. A Bayes network is known as a graphical model revealing the variables of a dataset (that are often called a node) along with their probable and conditional relationships. Casual relationships between nodes can be shown using the Bayes network (43).
However, connections of a network (arcs) do not necessarily show direct cause and effect aspects. For instance, a Bayes network can be used to calculate the probability of the presence of a disease in a specific person. In this case, the presence or absence of a specific symptom could be considered as a causal connection between the symptom and the disease in the Bayesian network. These networks are very powerful and make the best predictions about different types of data (43).
For designation of Bayes model (TAN), educational data are defined as elementary data in Bayes Net node and parameters of the model are adjusted as below:
Use Partitioned Data Structure Type: TAN
Parameter learning method: Maximum likelihood (Figure 2).
Figure 2. Bayesian networks model
Bayes Network node was selected in Clementine software. Firstly, 45 features were entered into the elementary configuration. Features of osteoporosis are defined as target features and other features were selected as entrance features. Results were obtained from the Bayes network.
In the second step, 35 features were selected from 45 features of the previous step. The selection of 35 features was based on their importance degree in the previous step. Afterward, the Bayes network model was run using 35 features and the results were obtained.
Features include calcium intake, weekly exercise, anemia, antiepileptic and seizure drugs, gastrointestinal surgery, coffee, and tea consumption, hyperadrenalism, lumbar disc, falling, hyperparathyroidism, hypothyroidism, hyperthyroidism, smoking, vitamin D intake, thalassemia, fracture history, an anticoagulant drug, osteoporosis, autoimmune disease, pregnancy rate, high blood lipids, anti-inflammatory drugs, diabetes-related drugs, osteoporosis drug, blood lipids drug, cancer drugs, an immunosuppressive drug, hypertension, diabetes, arthritis, familial osteoporosis, age, menopausal age, body mass index, duration of breastfeeding.
Evaluation of the model prepared using SVM
The precision of the classification evaluated for test and educational data separately via entering them in an Analysis nod. The precision of the developed model was also evaluated and factors having the highest importance were detected.
Results
The clinical history used in this study was 4083 women with 365 patients suffering from osteoporosis. The following table provides a brief description of the data.
The results of the evaluation were obtained by entering 45 features in the configuration section of the SVM node in the Clemantine software.
Figure 3 shows ten features that matter the most to the software output ( Figure 3).
In the second step, 35 features were selected from 45 features of the previous step. The selection of 35 features was based on their importance degree in the previous step. Afterward, the Bayes network model was run using 35 features and the results were obtained.
Features include calcium intake, weekly exercise, anemia, antiepileptic and seizure drugs, gastrointestinal surgery, coffee, and tea consumption, hyperadrenalism, lumbar disc, falling, hyperparathyroidism, hypothyroidism, hyperthyroidism, smoking, vitamin D intake, thalassemia, fracture history, an anticoagulant drug, osteoporosis, autoimmune disease, pregnancy rate, high blood lipids, anti-inflammatory drugs, diabetes-related drugs, osteoporosis drug, blood lipids drug, cancer drugs, an immunosuppressive drug, hypertension, diabetes, arthritis, familial osteoporosis, age, menopausal age, body mass index, duration of breastfeeding.
Evaluation of the model prepared using SVM
The precision of the classification evaluated for test and educational data separately via entering them in an Analysis nod. The precision of the developed model was also evaluated and factors having the highest importance were detected.
Results
The clinical history used in this study was 4083 women with 365 patients suffering from osteoporosis. The following table provides a brief description of the data.
The results of the evaluation were obtained by entering 45 features in the configuration section of the SVM node in the Clemantine software.
Figure 3 shows ten features that matter the most to the software output ( Figure 3).
Figure 3. Important features of SVM in the first stage with 45 features
The SVM-produced model (with 45 features in the first step) detected calcium usage, hypothyroidism, diabetes, anti-coagulants, immune-suppressor drugs, diabetes-related drugs, hyperparathyroidism, history of surgery, hypertension drugs, and waist disc as factors affecting osteoporosis the most.
The results of the SVM model with 35 features are as follows: (Figure 4).
Figure 4. Important features of SVM in the first stage with 35 features
In the second step, the SVM-produced model detected hyperlipidemia drugs, exercising during the week, history of osteoporosis, immune-suppressor drugs, autoimmune diseases, lactation duration, thalassemia, number of pregnancies, hyperlipidemia, and osteoporosis drugs as factors affecting osteoporosis the most.
Evaluation of the model prepared using Bayes network
The precision of the classification evaluated for test and educational data separately by entering them in an Analysis nod. The precision of the developed model was also evaluated and factors affecting osteoporosis the most are detected.
The results of the evaluation are obtained by entering 45 features in the configuration section of the Bayes network node in the Clementine software. Results are described as followings: (Figure 5) (Figure 6)
Evaluation of the model prepared using Bayes network
The precision of the classification evaluated for test and educational data separately by entering them in an Analysis nod. The precision of the developed model was also evaluated and factors affecting osteoporosis the most are detected.
The results of the evaluation are obtained by entering 45 features in the configuration section of the Bayes network node in the Clementine software. Results are described as followings: (Figure 5) (Figure 6)
Figure 5. The network designed in Bayesian network model
Figure 6. Important features of the Bayesian network in the first step with 45 features
The Bayes network-produced model (with 45 features) detected immune-suppressor drugs, hyperlipidemia, osteoporosis drugs, history of osteoporosis in the family, calcium intake, lactation duration, and hyperlipidemia drugs as factors affecting osteoporosis the most.
The results of the Bayes network model with 35 features are as follows: (Figure 7)
Figure 7. Important features of the Bayes network in the second step with 35 features
In the second step, the Bayes network-produced model detected immune-suppressor drugs, anti-inflammatory drugs, vitamin D, and exercising during the week, lactation duration, and autoimmune diseases as factors affecting osteoporosis the most.
Discussion
SVM model: The classification precision of this model is lower than in other studied models. The highest classification precision of this model was 86.18 that obtained using 35 features. Moreover, calcium intake, hypoparathyroidism, diabetes, anti-coagulation drugs, immune-suppressor drugs, diabetes-related drugs, hyperparathyroidism, surgery, blood pressure drugs, and waist discs were detected to be the most effective factors on osteoporosis.
Bayes network model: This model had the highest classification precision using 35 features (91.29) which seems to be an appropriate precision. The model detected immune-suppressor drugs, hyperlipidemia, osteoporosis drugs, history of osteoporosis in family, calcium intake, lactation duration, and hyperlipidemia drugs to be the most effective factors on osteoporosis.
As it is shown, the Bayes method has a higher precision in comparison with the SVM method. Furthermore, evaluation of factors detected using each method indicated that age, vitamin D intake, calcium intake, hypothyroidism, immune-suppressor drugs, blood pressure drugs, weekly exercising, hypoparathyroidism and hyperparathyroidism, probability and tendency of people to fall, anemia, lactation duration, and hyperlipidemia are the most important factors known to be effective on osteoporosis.
Moreover, some features including osteoporosis history in family, diabetes, number of pregnancies, anti-seizures and epilepsy drugs, anti-cancer drugs, waist discs, and anti-coagulation drugs are factors that are also effective on osteoporosis. The notable point is that medical and clinical studies showed that osteoporosis risk factors include age (over 65 years), early menopause (before 45 years), calcium intake (or calcium loss), tea and coffee consumption, lack of exercise and activity, low weight (body mass index), thyroid and parathyroid disorders, etc (44).
The accuracy of the osteoporosis predictor model introduced by Wang et al. in the hybrid decision tree model and artificial neural network is 70.5% with 33 features in 2934 women (21). The results of the present study reveal that the Bayes network model has a 91.29% accuracy for 4083 women.
Dreiher et al. performed a study on the correlation of two osteoporosis and psoriasis diseases using multivariable logistic regression. The studied data included age, gender, race, socioeconomic status, and chronic diagnosis including osteoporosis and suspected or known disease as risk factors for osteoporosis (for example, smoking, thyroid disorders, inflammatory bowel disease, chronic hepatitis, rheumatoid arthritis, and chronic obstructive pulmonary disease), status related to decreased physical activity (blindness and depression) and obesity (a protective factor against osteoporosis) (45). In this regard, the current study is much more complete in terms of sample size and number of features studied.
Gao et al. investigating a feature extracted from a fractal spectrum of a microcosm T image which predicted osteoporosis in human beings. They performed one study on 14 healthy individuals and 14 people with osteoporosis using the C4.5 decision tree for the predictive model and the accuracy is 92.9% (28). In this study, similar accuracy to Gao's study was found with sample size and a higher number of features.
Moudani et al. (2011) predicted osteoporosis using the decision tree random forest method. The study was conducted on 2845 individuals with 15 characteristics. The model predicts four classes of risk-free, low-risk, moderate-risk, high-risk, and severe-risk for osteoporosis. In this study, 15 features were analyzed, and 99.92% accuracy was achieved (29).
Zhou et al. (2012) developed a model for risk factors for osteoporosis based on traditional Chinese medicine and modern western medicine using data mining. To achieve this purpose, two methods of support vector machine and random forest were used. The results of their studies showed that the symptoms and factors mentioned in traditional medicine play a more important role in assessing the risk of osteoporosis. Among the variables mentioned, postmenopausal years were among the significant risk factors for osteoporosis (46).
In another study, Alizadeh et al. (2014) Showed that the multiple-method neural network model is the most accurate model for predicting osteoporosis. This study was performed on 60 characteristics of the questionnaire information of 670 people and had an accuracy of 95.70 (30).
Conclusion
Studying the conditions and results of previous researches in the field of data mining and osteoporosis, it can be concluded that the present study has the highest number in terms of sample size and number of features studied. Also, the use of decision tree methods and neural network feature selection are other strengths points of this study. In this study, multiple models were examined on several different features and the results were compared to find the best predictive model in terms of accuracy. Given the above, the results of data mining on the clinical records studied show the predictive features of the data mining algorithms in this study which is both in line with the clinical results obtained from medical studies and the findings of the previous researches.
Finally, it is important to note that health care organizations always collect large amounts of information while this information and data are not used properly. This study indicates that these data can be properly utilized to improve the quality of diagnostic and therapeutic services by uncovering patterns and relationships hidden in these data.
Acknowledgments
This research was a part of MSc project number 21441007942006 of Islamic Azad University of Qazvin. The authors would like to express their gratitude to Endocrinology and Metabolism Research Institute of Tehran University of Medical Sciences for providing the data used in this study.
Authors' contribution
A.A., E.J, and A.K. contributed to the design and implementation of the research, to the analysis of the results and to the writing of the manuscript.
SVM model: The classification precision of this model is lower than in other studied models. The highest classification precision of this model was 86.18 that obtained using 35 features. Moreover, calcium intake, hypoparathyroidism, diabetes, anti-coagulation drugs, immune-suppressor drugs, diabetes-related drugs, hyperparathyroidism, surgery, blood pressure drugs, and waist discs were detected to be the most effective factors on osteoporosis.
Bayes network model: This model had the highest classification precision using 35 features (91.29) which seems to be an appropriate precision. The model detected immune-suppressor drugs, hyperlipidemia, osteoporosis drugs, history of osteoporosis in family, calcium intake, lactation duration, and hyperlipidemia drugs to be the most effective factors on osteoporosis.
As it is shown, the Bayes method has a higher precision in comparison with the SVM method. Furthermore, evaluation of factors detected using each method indicated that age, vitamin D intake, calcium intake, hypothyroidism, immune-suppressor drugs, blood pressure drugs, weekly exercising, hypoparathyroidism and hyperparathyroidism, probability and tendency of people to fall, anemia, lactation duration, and hyperlipidemia are the most important factors known to be effective on osteoporosis.
Moreover, some features including osteoporosis history in family, diabetes, number of pregnancies, anti-seizures and epilepsy drugs, anti-cancer drugs, waist discs, and anti-coagulation drugs are factors that are also effective on osteoporosis. The notable point is that medical and clinical studies showed that osteoporosis risk factors include age (over 65 years), early menopause (before 45 years), calcium intake (or calcium loss), tea and coffee consumption, lack of exercise and activity, low weight (body mass index), thyroid and parathyroid disorders, etc (44).
The accuracy of the osteoporosis predictor model introduced by Wang et al. in the hybrid decision tree model and artificial neural network is 70.5% with 33 features in 2934 women (21). The results of the present study reveal that the Bayes network model has a 91.29% accuracy for 4083 women.
Dreiher et al. performed a study on the correlation of two osteoporosis and psoriasis diseases using multivariable logistic regression. The studied data included age, gender, race, socioeconomic status, and chronic diagnosis including osteoporosis and suspected or known disease as risk factors for osteoporosis (for example, smoking, thyroid disorders, inflammatory bowel disease, chronic hepatitis, rheumatoid arthritis, and chronic obstructive pulmonary disease), status related to decreased physical activity (blindness and depression) and obesity (a protective factor against osteoporosis) (45). In this regard, the current study is much more complete in terms of sample size and number of features studied.
Gao et al. investigating a feature extracted from a fractal spectrum of a microcosm T image which predicted osteoporosis in human beings. They performed one study on 14 healthy individuals and 14 people with osteoporosis using the C4.5 decision tree for the predictive model and the accuracy is 92.9% (28). In this study, similar accuracy to Gao's study was found with sample size and a higher number of features.
Moudani et al. (2011) predicted osteoporosis using the decision tree random forest method. The study was conducted on 2845 individuals with 15 characteristics. The model predicts four classes of risk-free, low-risk, moderate-risk, high-risk, and severe-risk for osteoporosis. In this study, 15 features were analyzed, and 99.92% accuracy was achieved (29).
Zhou et al. (2012) developed a model for risk factors for osteoporosis based on traditional Chinese medicine and modern western medicine using data mining. To achieve this purpose, two methods of support vector machine and random forest were used. The results of their studies showed that the symptoms and factors mentioned in traditional medicine play a more important role in assessing the risk of osteoporosis. Among the variables mentioned, postmenopausal years were among the significant risk factors for osteoporosis (46).
In another study, Alizadeh et al. (2014) Showed that the multiple-method neural network model is the most accurate model for predicting osteoporosis. This study was performed on 60 characteristics of the questionnaire information of 670 people and had an accuracy of 95.70 (30).
Conclusion
Studying the conditions and results of previous researches in the field of data mining and osteoporosis, it can be concluded that the present study has the highest number in terms of sample size and number of features studied. Also, the use of decision tree methods and neural network feature selection are other strengths points of this study. In this study, multiple models were examined on several different features and the results were compared to find the best predictive model in terms of accuracy. Given the above, the results of data mining on the clinical records studied show the predictive features of the data mining algorithms in this study which is both in line with the clinical results obtained from medical studies and the findings of the previous researches.
Finally, it is important to note that health care organizations always collect large amounts of information while this information and data are not used properly. This study indicates that these data can be properly utilized to improve the quality of diagnostic and therapeutic services by uncovering patterns and relationships hidden in these data.
Acknowledgments
This research was a part of MSc project number 21441007942006 of Islamic Azad University of Qazvin. The authors would like to express their gratitude to Endocrinology and Metabolism Research Institute of Tehran University of Medical Sciences for providing the data used in this study.
Authors' contribution
A.A., E.J, and A.K. contributed to the design and implementation of the research, to the analysis of the results and to the writing of the manuscript.
Conflict of Interests
The authors declare no conflict of interest.
Review: Research |
Subject:
Health information management
Received: 2019/02/16 | Accepted: 2020/06/29 | Published: 2020/06/29
Received: 2019/02/16 | Accepted: 2020/06/29 | Published: 2020/06/29
References
1. Camacho PM, Petak SM, Binkley N, et al. American Association of Clinical Endocrinologists and American College of Endocrinology Clinical Practice guidelines for the diagnosis and treatment of postmenopausal osteoporosis-2016. Endocrine Practice. 2016; 22(4): 1-42. [DOI:10.4158/EP161435.GL]
2. Eastell, R., Treatment of postmenopausal osteoporosis. New England Journal of Medicine. 1998; 338(11): 736-746. [DOI:10.1056/NEJM199803123381107]
3. Ominsky MS, Boyce RW, Li X, et al. Effects of sclerostin antibodies in animal models of osteoporosis. Bone. 2017; 96: 63-75. [DOI:10.1016/j.bone.2016.10.019]
4. Wright VJ, Tejpar F. The New Science of Musculoskeletal Aging in Bone, Muscle, and Tendon/Ligament. InMasterful Care of the Aging Athlete. 2018: 9-15. [DOI:10.1007/978-3-319-16223-2_2]
5. Bouxsein ML, Eastell R, Lui LY, et al. Change in bone density and reduction in fracture risk: a meta-regression of published trials.Journal of Bone and Mineral Research. 2019; 34(4): 632-642. [DOI:10.1002/jbmr.3641]
6. Sugimoto T, Sato M, Dehle FC, et al. Lifestyle-related metabolic disorders, osteoporosis, and fracture risk in Asia: A systematic review. Value in Health Regional Issues. 2016; 9: 49-56. [DOI:10.1016/j.vhri.2015.09.005]
7. Johnell O, Kanis JA .An estimate of the worldwide prevalence and disability associated with osteoporotic fractures. Osteoporosis international. 2006; 17(12): 1726-1733. [DOI:10.1007/s00198-006-0172-4]
8. Kanis JA. Assessment of osteoporosis at the primary health care level. WHO Collaborating Centre for Metabolic Bone Diseases. 2007; Available at:URL: https://ci.nii.ac.jp/naid/20001202369/en/.
9. Rohollahi F. Take a look at prevalence of osteoporosis in the world and Iran. Hamshahri newspaper. Health part. 2007; 4150. Available online at: http:// www. isaarsci. ir/ general.
10. Morris JA, Kemp JP, Youlten SE, et al. An atlas of genetic influences on osteoporosis in humans and mice. Nature genetics. 2019; 51(2): 258-66. [DOI:10.1038/s41588-018-0302-x]
11. Hsu YH, Xu X, Jeong S. Genetic Determinants and Pharmacogenetics of Osteoporosis and Osteoporotic Fracture. InOsteoporosis. 2020: 485-506. [DOI:10.1007/978-3-319-69287-6_25]
12. Pisani P, Renna MD, Conversano F, et al. Major osteoporotic fragility fractures: Risk factor updates and societal impact. World Journal of Orthopedics. 2016; 7(3): 171. [DOI:10.5312/wjo.v7.i3.171]
13. Unnikrishnan G, Xu C, Popp KL, et al. Regional variation of bone density, microarchitectural parameters, and elastic moduli in the ultradistal tibia of young black and white men and women. Bone. 2018; 112: 194-201. [DOI:10.1016/j.bone.2018.05.004]
14. Bitar AN, Sulaiman SA, Ali IA, et al. Osteoporosis among patients with chronic obstructive pulmonary disease: Systematic review and meta-analysis of prevalence, severity, and therapeutic outcomes. Journal of Pharmacy & Bioallied Sciences. 2019; 11(4): 310-320. [DOI:10.4103/jpbs.JPBS_126_19]
15. Vidal M, Thibodaux RJ, Neira LF, et al. Osteoporosis: a clinical and pharmacological update. Clinical Rheumatology. 2019; 38(2): 385-395. [DOI:10.1007/s10067-018-4370-1]
16. Sugimoto T, Fujiwara S, Hagino H, et al. Clinical practice guide on fracture risk in lifestyle-related diseases. 2011.
17. Lindsay R, Cosman F. Harrison's Principles of Internal Medicine: Osteoporosis. 2012: 3131-3136.
18. Wilson DJ. Osteoporosis and sport. European journal of radiology. 2019; 110:169-74. [DOI:10.1016/j.ejrad.2018.11.010]
19. Saadi HF, Reed RL, Carter AO, et al. Bone density estimates and risk factors for osteoporosis in young women. Eastern Mediterranean Health Journal. 2001; 7 (4-5): 730-737.
20. Mäkitie R, Costantini A, Kämpe A,et al. New insights into monogenic causes of osteoporosis. Frontiers in Endocrinology.2019; 10: 70. [DOI:10.3389/fendo.2019.00070]
21. Rizzoli R, Bonjour JP, Ferrari SL. Osteoporosis, genetics and hormones. Journal of Molecular Endocrinology. 2001; 26(2): 79-94. [DOI:10.1677/jme.0.0260079]
22. Kaewboonchoo O, Sung FC, Lin CL, et al. Risk of osteoporosis and fracture in victims with burn injury. Osteoporosis International. 2019; 30(4): 837-843. [DOI:10.1007/s00198-018-04818-2]
23. Bass S, Pearce G, Bradney M, et al. Exercise before puberty may confer residual benefits in bone density in adulthood: studies in active prepubertal and retired female gymnasts. Journal of Bone and Mineral Research. 1998; 13(3): 500-507. [DOI:10.1359/jbmr.1998.13.3.500]
24. Lee M, Jung R, Jung Y, et al. Association of Work-Time, Leisure-Time Physical Activity and Osteoporosis Prevalence: Korea National Health and Nutrition Examination Survey in 2015-2016. Korean Journal of Family Practice. 2019; 9(5): 403-407. [DOI:10.21215/kjfp.2019.9.5.403]
25. Fredman L, Ranker LR, Strunin L, et al. Caregiving Intensity and Mortality in Older Women, Accounting for Time-Varying and Lagged Caregiver Status: The Caregiver-Study of Osteoporotic Fractures Study. The Gerontologist. 2019; 59(5): 461-469. [DOI:10.1093/geront/gny135]
26. Sambrook P, Dequiker J, Rasp H. metabolic bone disease, Report of a WHO study group, Assessment of fracture risk and its application to screening for postmenopausal Osteoporosis. World Health Organization Technical Report Series. Geneva. 1994; 5.
27. Wang W, Richards G, Rea S. Hybrid Data Mining Ensemble for Predicting Osteoporosis Risk. 2005 IEEE Engineering in Medicine and Biology 27th Annual Conference, Shanghai. 2005: 886-889.
28. Gao Z, Hong W, Xu Y, et al. Osteoporosis Diagnosis Based on the Multifractal Spectrum Features of Micro-CT Images and C4. 5 Decision Tree. In 2010 First International Conference on Pervasive Computing, Signal Processing and Applications. 2010: 1043-1047. [DOI:10.1109/PCSPA.2010.257]
29. Moudani W, Shahin A, Chakik F, et al. Intelligent predictive osteoporosis system. International Journal of Computer Applications. 2011; 32(5):28-37.
30. Mona S, Somayeh A, Abbasi M, et al. Providing a model for predicting the risk of osteoporosis using decision tree algorithms. Journal of Mazandaran University of Medical Sciences. 2014; 24(116): 110-118.
31. Fitzpatrick, L. A. (2002, May). Secondary causes of osteoporosis. In Mayo Clinic Proceedings. 2002 ;77(5): 453-468 Elsevier. [DOI:10.4065/77.5.453]
32. Bogoch ER, Elliot-Gibson V, Wang RY, et al. Secondary causes of osteoporosis in fracture patients. Journal of Orthopaedic Trauma. 2012; 26(9): 145-152. [DOI:10.1097/BOT.0b013e3182323f2c]
33. Raisz LG. Screening for osteoporosis. New England Journal of Medicine. 2005; 353(2): 164-171. [DOI:10.1056/NEJMcp042092]
34. Zanker J, Duque G. Osteoporosis in older persons: old and new players. Journal of the American Geriatrics Society. 2019; 67(4): 831-840. [DOI:10.1111/jgs.15716]
35. Dubey R, Samantaray SR, Panigrahi BK, et al. Data-mining model based adaptive protection scheme to enhance distance relay performance during power swing. International Journal of Electrical Power & Energy Systems. 2016; 81: 361-370. [DOI:10.1016/j.ijepes.2016.02.014]
36. Xu N, Wang Y, Xu Y, et al. Effect of subclinical hyperthyroidism on osteoporosis: A meta-analysis of cohort studies. Endocrine. 2020. [DOI:10.1007/s12020-020-02259-8]
37. Elkady AA, Kazem HH, Elgendy EA. Protective effect of vitamin D against rats' mandibular osteoporosis induced by corticosteroids and gamma rays. International Journal of Radiation Research. 2020; 18(1): 125-131.
38. Mullin BH, Tickner J, Zhu K, et al. Characterisation of genetic regulatory effects for osteoporosis risk variants in human osteoclasts. Genome biology. 2020; 21(1): 1-3. [DOI:10.1186/s13059-020-01997-2]
39. Ireland N, Nabi S, Chand K, et al. Menopause and osteoporosis. Pulse. 2019; 50.
40. Fatahi M. Suport Vector Machines: A survey [dissertation]. [razi]: razi university: 2015: 48.
41. Huang S, Cai N, Pacheco PP, et al. Applications of support vector machine (SVM) learning in cancer genomics. Cancer Genomics-Proteomics. 2018; 15(1): 41-51. [DOI:10.21873/cgp.20063]
42. Koski T, Noble J. Bayesian networks: an introduction. 2011; 924. John Wiley & Sons.
43. Larijani B. An overview of osteoporosis in Iran. international osteoporosis seminar in Iran. 2004;1
44. Dreiher J, Weitzman D, Cohen AD. Psoriasis and osteoporosis: a sex-specific association?. Journal of Investigative Dermatology. 2009; 129(7): 1643-9. [DOI:10.1038/jid.2008.432]
45. Englebardt SP, Nelson R. Health care informatics: An interdisciplinary approach. Mosby Incorporated. 2002.
46. Zhou XH, Li SL, Tian F, et al. Building a disease risk model of osteoporosis based on traditional Chinese medicine symptoms and western medicine risk factors. Statistics in medicine. 2012; 31(7): 643-52. [DOI:10.1002/sim.4382]
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