血糖性
胰岛素释放
医学
计算机科学
生物标志物
连续血糖监测
糖尿病
钥匙(锁)
风险分析(工程)
重症监护医学
疾病
糖尿病管理
计算机辅助设计
胰岛素
灵敏度(控制系统)
预测值
胰岛素敏感性
流线、条纹线和路径线
人工智能
精密医学
血糖自我监测
胰岛素泵
远程病人监护
作者
Marco Fratus,Muhammad A. Alam
标识
DOI:10.1073/pnas.2523517122
摘要
Continuous biomarker monitoring and on-demand therapy are essential for chronic disease management, with diabetes being a key example. Although continuous glucose monitoring (CGM) and insulin pumps are moving toward a closed-loop system, it remains difficult to predict how device design influences system performance. Traditional optimization methods are inefficient and empirical: Data-driven algorithms lack interpretability, trial-and-error design is time-consuming, and first-principle models are difficult to integrate at the system level. To address these challenges, we introduce a physics-based framework which integrates microneedle (MN) designs for sensing and therapy with a physiological model of glycemic control. The framework builds compact relationships showing how material, chemical, and geometrical features affect key metrics such as response time, extraction flux, and insulin delivery rate. Specifically, we develop a theory for three sensing MN types (hollow, porous/swellable, and nanostructured MNs) and one therapeutic patch (electro-termo-mechanical device) to create a predictive model for glycemic regulation. By linking device design to system behavior across time and spatial scales, we examine the framework in three cases: How disease progression, MN design, and MN sensitivity affect plasma glucose levels and time-in-range metrics. This work establishes the foundation for a physics-based digital twin for diabetes management, complementing ML, experiments, and numerical models. More broadly, it streamlines patch design, minimizing glycemic events and trial-and-error in next-generation CGM technology.
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