Diabetic Risk Prediction Using Machine Learning

Year : 2024 | Volume :02 | Issue : 01 | Page : 11-17
By
vector

Danavale Vaishnavi Vaishnavi,

vector

Malusare Shamal,

vector

Dharpale Nikita,

vector

Gavhane Sanika,

vector

Amol C. Jadhav,

  1. Student, Shri Chhatrapati Shivaji Maharaj College of Engineering, Pune, Maharashtra, India
  2. Student, Shri Chhatrapati Shivaji Maharaj College of Engineering, Pune, Maharashtra, India
  3. Student, Shri Chhatrapati Shivaji Maharaj College of Engineering, Pune, Maharashtra, India
  4. Student, Shri Chhatrapati Shivaji Maharaj College of Engineering, Pune, Maharashtra, India
  5. Student, Shri Chhatrapati Shivaji Maharaj College of Engineering, Pune, Maharashtra, India

Abstract

The global prevalence of Type 2 diabetes has risen dramatically in recent years, posing a serious public health risk. Long-term risk prediction is an important technique for evaluating who is most likely to develop type 2 diabetes. Early detection and response can lead to better management and prevention of diabetes complications. Developing a user-friendly Windows program for long-term Type 2 diabetes risk prediction could revolutionize preventive healthcare due to technological improvements and ubiquitous smartphone use. The Machine Learning Application for long- term Type 2 And Type 1 diabetes risk predic-tion presented in this study addresses the escalating global health crisis by leveraging technology to empower individuals in managing their health. This innovative application employs advanced predic- tive algorithms to offer personalized risk assessments based on user- input data such as age, gender, family history, and lifestyle choices. The user-friendly interface ensures seamless navigation, enabling users to access educational content, set health reminders, and track their progress over time. By fostering a sense of community through peer support features, the application promotes informed decision- making andencourages positive lifestyle changes.

Keywords: Type 2 diabetes, long-term risk prediction, personalized assessments, preventive healthcare, educational content, health track-ing, community support, technology, public health

[This article belongs to International Journal of Satellite Remote Sensing(ijsrs)]

How to cite this article: Danavale Vaishnavi Vaishnavi, Malusare Shamal, Dharpale Nikita, Gavhane Sanika, Amol C. Jadhav. Diabetic Risk Prediction Using Machine Learning. International Journal of Satellite Remote Sensing. 2024; 02(01):11-17.
How to cite this URL: Danavale Vaishnavi Vaishnavi, Malusare Shamal, Dharpale Nikita, Gavhane Sanika, Amol C. Jadhav. Diabetic Risk Prediction Using Machine Learning. International Journal of Satellite Remote Sensing. 2024; 02(01):11-17. Available from: https://journals.stmjournals.com/ijsrs/article=2024/view=0

References

  1. American Diabetes Association. Economic costs of diabetes in the u.s. in 2020. Diabetes Care, 41(5):917– 928, 2021.
  2. American Diabetes Association and others. Report of the expert com- mittee on the diagnosis and classification of diabetes mellitus. Diabetes care, 26(suppl 1):s5–s20, 2022.
  3. Liu, Y. Li, S. Ghosh, Z. Sun, K. Ng, and J. Hu. Complication risk profiling in diabetes care: A bayesian multi-task and feature relationship learning approach.IEEE Transactions on Knowledge and Data Engi- neering, 32(7):1276–1289, 2020.
  4. Kalaiselvi and M. Thangamani, “An efficient pearson correlation based improved random forest classification for protein structure prediction techniques,” Measurement, vol. 162, Oct. 2020, Art. no. 107885.
  5. Muthukrishnan and R. Rohini, “LASSO: A feature selection technique in predictive modeling for machine learning,” in Proc. IEEE Int. Conf. Adv. Comput. Appl. (ICACA), Oct. 2020, pp. 18–20.
  6. Engchuan, A. C. Dimopoulos, S. Tyrovolas,F. Caballero, A. Sanchez- Niubo, H. Arndt, J. L. Ayuso-Mateos, J. M. Haro, S. Chatterji, and D. B. Panagiotakos, “Sociodemographic indicators of health status using a ma- chine learning approach and data from the English longitudinal study of aging (ELSA),” Med. Sci. Monitor Int. Med. J. Exp. Clin. Res., vol. 25, p. 1994, Mar. 2021.
  7. Syed L, Jabeen S, Manimala S, Alsaeedi A. Smart healthcare framework for ambient assisted living using IoMT and big data analytics techniques. Future Generation Computer Systems. 2019 Dec 1;101:136-51.
  8. Sappelli M. An adaptive recipe recommendation system for people with Diabetes type 2.
  9. Boersma HE, van der Klauw MM, Smit AJ, Wolffenbuttel BH. A non-invasive risk score including skin autofluorescence predicts diabetes risk in the general population. Scientific reports. 2022 Dec 16;12(1):21794.
  10. Chen L, Magliano DJ, Balkau B, Colagiuri S, Zimmet PZ, Tonkin AM, Mitchell P, Phillips PJ, Shaw JE. AUSDRISK: an Australian Type 2 Diabetes Risk Assessment Tool based on demographic, lifestyle and simple anthropometric measures. Medical Journal of Australia. 2010 Feb;192(4):197-202.
  11. Hegde H, Shimpi N, Panny A, Glurich I, Christie P, Acharya A. Development of non-invasive diabetes risk prediction models as decision support tools designed for application in the dental clinical environment. Informatics in medicine unlocked. 2019 Jan 1;17: 100254.
  12. Liu Y, Ye S, Xiao X, Sun C, Wang G, Wang G, Zhang B. Machine learning for tuning, selection, and ensemble of multiple risk scores for predicting type 2 diabetes. Risk Management and Healthcare Policy. 2019 Nov 5:189-98.
  13. Fazakis N, Kocsis O, Dritsas E, Alexiou S, Fakotakis N, Moustakas K. Machine learning tools for long-term type 2 diabetes risk prediction. ieee Access. 2021 Jul 20;9: 103737-57.
  14. Tama BA, Rhee KH. Performance evaluation of intrusion detection system using classifier ensembles. International Journal of Internet Protocol Technology. 2017;10(1):22-9.
  15. Panda M, Mishra D, Mishra S. Ensemble methods for improving classifier performance. InInternational Proceedings on Advances in Soft Computing, Intelligent Systems and Applications: ASISA 2016 2018 (pp. 363-374). Springer Singapore.
Regular Issue Subscription Original Research
Volume 02
Issue 01
Received May 23, 2024
Accepted July 10, 2024
Published September 7, 2024
202

function myFunction2() {
var x = document.getElementById(“browsefigure”);
if (x.style.display === “block”) {
x.style.display = “none”;
}
else { x.style.display = “Block”; }
}
document.querySelector(“.prevBtn”).addEventListener(“click”, () => {
changeSlides(-1);
});
document.querySelector(“.nextBtn”).addEventListener(“click”, () => {
changeSlides(1);
});
var slideIndex = 1;
showSlides(slideIndex);
function changeSlides(n) {
showSlides((slideIndex += n));
}
function currentSlide(n) {
showSlides((slideIndex = n));
}
function showSlides(n) {
var i;
var slides = document.getElementsByClassName(“Slide”);
var dots = document.getElementsByClassName(“Navdot”);
if (n > slides.length) { slideIndex = 1; }
if (n (item.style.display = “none”));
Array.from(dots).forEach(
item => (item.className = item.className.replace(” selected”, “”))
);
slides[slideIndex – 1].style.display = “block”;
dots[slideIndex – 1].className += ” selected”;
}