The escalating prevalence of Type 2 Diabetes (T2D) represents a substantial burden on global healthcare systems, especially in regions such as Mexico. Existing diagnostic techniques, although effective, often require invasive procedures and labor-intensive efforts. The promise of artificial intelligence and data science for streamlining and enhancing T2D diagnosis is well-recognized; however, these advancements are frequently constrained by the limited availability of comprehensive patient datasets. To mitigate this challenge, the present study investigated the efficacy of Generative Adversarial Networks (GANs) for augmenting existing T2D patient data, with a focus on a Mexican cohort. The researchers utilized a dataset of 1019 Mexican nationals, divided into 499 non-diabetic controls and 520 diabetic cases. GANs were applied to create synthetic patient profiles, which were subsequently used to train a Random Forest (RF) classification model. The study’s findings revealed a notable improvement in the model’s diagnostic accuracy, validating the utility of GAN-based data augmentation in a clinical context. The results bear significant implications for enhancing the robustness and reliability of Machine Learning tools in T2D diagnosis and management, offering a pathway toward more timely and effective patient care.
CITATION STYLE
García-Domínguez, A., Galván-Tejada, C. E., Magallanes-Quintanar, R., Cruz, M., Gonzalez-Curiel, I., Delgado-Contreras, J. R., … Galván-Tejada, J. I. (2023). Optimizing Clinical Diabetes Diagnosis through Generative Adversarial Networks: Evaluation and Validation. Diseases, 11(4). https://doi.org/10.3390/diseases11040134
Mendeley helps you to discover research relevant for your work.