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Volume 18, Issue 2
  • ISSN: 2352-0965
  • E-ISSN: 2352-0973

Abstract

Introduction

This study intends to support medical professionals in the early and precise detection and diagnosis of type1 and type2 Diabetes. Many complexities occur if Diabetes is unidentified and remains untreated. 9.3% of individuals worldwide have Diabetes as of 2019, according to data from the World Health Organization. The anticipated increase would be close to 11% of the global population by 2045.

Diabetes mellitus is a chronic, one of the deadliest diseases that causes Body blood glucose levels to be above average level knowing a blood sugar. Diabetes can be type1 (T1D) and type2(T2D). An autoimmune condition called Type 1 diabetes is frequently found in young children. Adults are frequently diagnosed with type 2 diabetes, which is not autoimmune. A branch of artificial intelligence called machine learning has the potential to be successful in the field of predictions.

Methods

This research aims to design a machine learning model to predict Diabetes in a patient. The collective performance of the four algorithms is evaluated on various measures like accuracy, precision, sensitivity, and specificity. Therefore, four machine learning classification algorithms, namely Bayes-Net, Naïve-Bayes, J48, and Random Forest, were used to predict Diabetes in the early stage using 10–fold cross validation.

Results

For experiments, a standard PIMA Indian diabetes dataset is used. According to the results, Bayes-Net performs better than other algorithms, with an accuracy rate of 87.72%.

Conclusion

Diabetes Mellitus may harm kidneys, nerves, eyes, and other organs if it is not diagnosed in time. Therefore, early diagnosis and treatment could save countless lives. The process is tedious because patients visit a diagnostic facility and see a doctor, but various machine learning and deep learning approaches solve this clinical problem earlier.

© 2025 Bentham Science Publishers
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2024-01-24
2025-05-23

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/content/journals/raeeng/10.2174/0123520965268488231129104039
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On the Improvements of the Performance of Bayes-Net Classification for Diagnosis of Diabetes: A Cross-validation Approach
Recent Advances in Electrical & Electronic Engineering 18, 234 (2025); https://doi.org/10.2174/0123520965268488231129104039
/content/journals/raeeng/10.2174/0123520965268488231129104039
/content/journals/raeeng/10.2174/0123520965268488231129104039
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  • Article Type:     Research Article
Keyword(s): Accuracy; autoimmune condition; classification; diabetes; logistic regression; machine learning

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