Being the most common and rapidly growing disease, Diabetes affecting a huge number of people from all span of ages each year that reduces the lifespan. Having a high affecting rate, it increases the significance of initial diagnosis. Diabetes brings other complicated complications like cardiovascular disease, kidney failure, stroke, damaging the vital organs etc. Early diagnosis of diabetes reduces the likelihood of transiting it into a chronic and severe state. The identification and analysis of risk factors of different spinal attributes help to identify the prevalence of diabetes in medical diagnosis. The prevalence measure and identification of diabetes in the early stages reduce the chances of future complications. In this research, the collective NHANES dataset of 1999-2000 to 2015-2016 was used and the purposes of this research were to analyze and ascertain the potential risk factors correlated with diabetes by using Logistic Regression, ANOVA and also to identify the abnormalities by using multiple supervised machine learning algorithms. Class imbalance, outlier problems were handled and experimental results show that age, blood-related diabetes, cholesterol and BMI are the most significant risk factors that associated with diabetes. Along with this, the highest accuracy score .90 was achieved with the random forest classification method.

For this project, I used publicly available Electronic Health Records (EHRs) datasets. The MIT Media Lab for Computational Physiology has developed MIMIC-IIIv1.4 dataset based on 46,520 patients who stayed in critical care units of the Beth Israel Deaconess Medical Center of Boston between 2001 and 2012. MIMIC-IIIv1.4 dataset is freely available to researchers across the world. A formal request should be made directly to www.mimic.physionet.org, to gain access to the data. There is a required course on human research ‘Data or Specimens Only Research’ prior to data access request. I have secured one here -www.citiprogram.org/verify/?kb6607b78-5821-4de5-8cad-daf929f7fbbf-33486907. We built flexible and better performing model using the same 17 variables used in the SAPS II severity prediction model. The question ‘Can we improve the prediction performance of widely used severity scores using a more flexible model?’ is the central question of our project. I used the exact 17 variables used to develop the SAPS II severity prediction algorithm. These are 13 physiological variables, three underlying (chronic) disease variables and one admission variable. The physiological variables includes demographic (age), vital (Glasgow Comma Scale, systolic blood pressure, Oxygenation, Renal, White blood cells count, serum bicarbonate level, blood sodium level, blood potassium level, and blood bilirubin level). The three underlying disease variables includes Acquired Immunodeficiency Syndrome (AIDS), metastatic cancer, and hematologic malignancy. Finally, whether admission was scheduled surgical or unscheduled surgical was included in the model. The dataset has 26 relational tables including patient’s hospital admission, callout information when patient was ready for discharge, caregiver information, electronic charted events including vital signs and any additional information relevant to patient care, patient demographic data, list of services the patient was admitted or transferred under, ICU stay types, diagnoses types, laboratory measurments, microbiology tests and sensitivity, prescription data and billing information. Although I have full access to the MIMIC-IIIv1.4 datasets, I can not share any part of the data publicly. If you are interested to learn more about the data, there is a MIMIC III Demo dataset based on 100 patients https://mimic.physionet.org/gettingstarted/demo/. If you are interested to requesting access to the data - https://mimic.physionet.org/gettingstarted/access/. Linked repositories: Exploratory-Data-Analysis-Clinical-Deterioration, Data-Wrangling-MIMICIII-Database, Clinical-Deterioration-Prediction-Model--Inferential-Statistics, Clinical-Deterioration-Prediction-Model--Ensemble-Algorithms-, Clinical-Deterioration-Prediction-Model--Logistic-Regression, Clinical-Deterioration-Prediction-Model---KNN © 2020 GitHub, Inc.

Deep learning based respiratory sound analysis for detection of chronic obstructive pulmonary disease

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Data mining projects include predicting risk score of chronic diseases with NHANES data and analysis of patient and insurance claim data.

This project aims to explore clinical and laboratory features associated with chronic kidney disease (CKD) and to identify key predictors that distinguish CKD from non-CKD individuals.

The Chronic Kidney Disease Predictor is a machine learning project that offers early detection, accurate prediction, and risk assessment of chronic kidney disease. It utilizes patient data analysis, provides a user-friendly interface, and serves as a valuable decision support tool for healthcare professionals.

This dashboard provides a comprehensive analysis of chronic disease prevalence across the United States, focusing on diabetes, obesity, heart disease, and physical inactivity. It demonstrates the full pipeline from data preparation through interactive visualization—key skills for data analytics roles in healthcare and pharmaceutical industries.

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Chronic Disease Control Data Analysis and Visualization

Exploratory Data Analysis of Chronic Disease dataset using Python, Pandas, Seaborn, and Matplotlib to uncover health patterns and risk factors.

This report explores the development of a predictive model for chronic kidney disease (CKD) using advanced data analysis and machine learning techniques.

This repository contains the analysis code for the paper titled "The spatially resolved transcriptome signatures of glomeruli in chronic kidney disease" by Hasmik Soloyan et al. 2022.

Machine Learning project for predicting chronic kidney disease using the Random Forest, KNN, Decision Tree and Regression algorithms. Includes data preprocessing, model training, evaluation, and performance analysis based on a real-world dataset.

The data is the largest health survey conducted by CDC (Centers for Disease Control and Prevention) across 50 states in USA.The objective was to conduct an exploratory analysis to understand factors influencing health related risk behaviors. Analyzed factors like food habits and activity that influence health related risks using techniques like linear regression, cluster analysis such as k-means and Hierarchical clustering methods in R. Performed data cleansing in R and implemented classification technique like decision tree approach to classify different chronic diseases.

Machinery learning is a fast-expanding area that will change the method for the diagnosis and management of this chronic condition by applying itself to diabetes as a global pandemic. Machine learning principles have been used to build algorithms to help predictive models of the likelihood of diabetes development or related complications. Digital therapy has shown to be a well-established lifestyle care intervention for diabetes control. Patients are becoming more self-managed, and the assistance of therapeutic decision-making is available to both them and health care practitioners. Machine learning helps patient signs and bio-markers to persist, unburdened, remotely controlled. Social networking and online forums also increase patient commitment to the treatment of diabetes. Development in technologies helped to optimize the use of diabetes tools. These smart technological reforms together have led to an improved glycemic regulation, a decrease in fast glucose and glycosylated hemoglobin levels. Machine learning introduces a change in diabetes treatment model from traditional management techniques to data-driven care growth The trouble with medicines is that various drug formulations can cure the condition in several ways. As the diabetic population grows, new medications are increasingly emerging. In order to treat common diseases such as elevated cholesterol and high blood pressure, diabetics also continue to take other drugs. With the patient's age and other physical conditions, the potency of these medicines varies In this method, the effectiveness, risks of side effects and costs are measured side by side, and are readily grasped by doctors and patients. The most prevalent form of Type 2 diabetes effects more people as people grow up. This disease has also escalated dramatically due to the spread of western diets and lifestyles to developing countries. Diabetes is an incurable metabolic illness that happens when high blood sugar is present, and may have deadly effects. Today, medicine, nutritious diets and exercise will regulate diabetes. It is also unpredictable to choose and administer the most appropriate mixture of prescription, which is stable, cheap and well tolerated by patients as well By applying an adequate methodology for the design and development of systems experts can achieve objectives satisfactorily, as in the case of the Weiss and Kuligowski methodology. On the other hand, machine learning has several knowledge machine algorithms, which can be useful to be applied on various data sets through the different interfaces that offers, as the option of Explorer and Datasets, which were worked in this case of study, or to be included in other applications. Furthermore, both tools, contain what is necessary to conduct data transformations, grouping, regression, clustering, correlation and visualization tasks. Because they are designed as extensibility-oriented tools which allows to add new functionalities to a project, because it can be combined with other programming languages such as Prolog, for generation more robust expert systems Readmitted diabetes patients Machine learning techniques allow to automatically identify patterns and even make predictions based on a large amount of data that could be extracted from the computer systems used to ascertain information on readmission of diabetes patients. The analysis Clustering or grouping is a technique that allows exploring a setoff objects to determine if there are groups that can be significantly represented by certain characteristics, in this way, objects of the same group are very similar to each other and different from objects in other groups. The results obtained by comparing the relevance of different attributes as well as the use of two of the most popular algorithms in the world of machine learning are presented: neural networks and decision trees. Automatic classification of blood glucose measurements will allow specialists to prescribe a more accurate treatment based on the information obtained directly from the patients' glucometer (Hosseini et al, 2020). Thus, it contributes to the development of automatic decision support systems for gestational diabetes. This high level of glucose in the blood is transferred to the fetus causing various disorders: excessive growth of adipose tissues, which increases the need for caesarean section, neonatal hypoglycemia and increased risk of intrauterine fetal death (Dagliati et al, 2018). It also increases the risk of type 2 diabetes once the gestation period is over for both the mother and the fetus. The project proposes the development of intelligent and educational tools for the survey based on neurodiffuse techniques integrated into a telemedicine system. Telemedicine systems have been used with success on numerous occasions in diabetes and the integration of decision support tools in this type of system helps a better interpretation of the data (Abhari et al, 2019).

Transcriptomic cross-species analysis of chronic liver disease reveals consistent regulation between humans and mice

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medical image analysis for chronic diseases

This project focuses on analyzing the prevalence of chronic diseases among seniors aged 65+ across the nine U.S. Census districts.

M.Sc final year project analyzing chronic disease data using SAS, SPSS, statistical modeling, and logistic regression.

End-to-end machine learning project involving exploratory data analysis, preprocessing, and model development using the U.S. Chronic Disease Indicators dataset. Implements supervised and unsupervised learning techniques, compares model performance using appropriate evaluation metrics, and derives data-driven insights from healthcare data.

We have collected a dataset of the US Chronic Disease Indicators and cleaned, analysed and visualised the data using python

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Exploratory Data Analysis for Epidemiology Studies: Chronic Disease Monitoring

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Nephron AI is a project by Ayush Anand. This is a Machine Learning powered toll for diagnosis and analysis of causes for Chronic Kidney Disease with 99.9% accuracy.

Analysis of serum miRNA abundance on elk with chronic wasting disease

Learning-focused exploratory data analysis of chronic disease indicators using Python

Designed a Gaussian Bayesian Network (GBN) to evaluate Chronic Kidney Disease using patient health data, facilitating probabilistic predictions of disease risk based on overall health indicators