A Real-Time Digital Twin for Type 1 Diabetes using Simulation-Based Inference
This work addresses the problem of slow and computationally expensive parameter estimation for digital twins in Type 1 Diabetes, providing a faster, amortized inference method that could improve real-time management of the condition.
The study tackled the challenge of estimating parameters for physiological models in Type 1 Diabetes by proposing a Simulation-Based Inference approach based on Neural Posterior Estimation, which outperformed traditional methods in parameter estimation and generalized better to unseen conditions, offering real-time posterior inference with reliable uncertainty quantification.
Accurately estimating parameters of physiological models is essential to achieving reliable digital twins. For Type 1 Diabetes, this is particularly challenging due to the complexity of glucose-insulin interactions. Traditional methods based on Markov Chain Monte Carlo struggle with high-dimensional parameter spaces and fit parameters from scratch at inference time, making them slow and computationally expensive. In this study, we propose a Simulation-Based Inference approach based on Neural Posterior Estimation to efficiently capture the complex relationships between meal intake, insulin, and glucose level, providing faster, amortized inference. Our experiments demonstrate that SBI not only outperforms traditional methods in parameter estimation but also generalizes better to unseen conditions, offering real-time posterior inference with reliable uncertainty quantification.