Optimizing Glucose Sensor Calibration With Lightweight Neural Networks: A Comparative Study

IF 2.2 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC

IEEE Sensors Letters Pub Date : 2024-08-02 DOI:10.1109/LSENS.2024.3436630

Costanza Cenerini;Anna Sabatini;Luca Vollero;Danilo Pau

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Abstract

Diabetes presents a significant global health challenge, necessitating precise blood glucose monitoring for effective management. Continuous glucose monitoring (CGM) devices offer a minimally invasive approach, yet require accurate calibration models to improve reliability. This letter investigates various neural network architectures for predicting time errors in CGM sensor readings, aiming for high accuracy and minimal computational burden. Using simulated data, models were trained and evaluated, with Legendre memory unit and temporal convolutional network architectures emerging as promising candidates. With these architectures, it was possible to lower the sensor's reading error to, respectively, 24.22 and 25.34 mg/dL, decreasing the error by 40.6% and 37.9%. Furthermore, the letter explores the impact of sensor calibration frequency on prediction accuracy, revealing optimal performance with calibrations once every three or five days, obtaining an error in the reading of approximately 16 and 15 mg/dL. These findings underscore the potential for enhancing glucose monitoring systems and suggest avenues for future research in diabetes management.

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利用轻量级神经网络优化葡萄糖传感器校准：比较研究

糖尿病是全球健康面临的重大挑战，需要精确的血糖监测来进行有效管理。连续血糖监测（CGM）设备提供了一种微创方法，但需要精确的校准模型来提高可靠性。这封信研究了预测 CGM 传感器读数时间误差的各种神经网络架构，旨在实现高精确度和最小计算负担。利用模拟数据对模型进行了训练和评估，发现 Legendre 存储单元和时序卷积网络架构很有前途。利用这些架构，可以将传感器的读数误差分别降低到 24.22 毫克/分升和 25.34 毫克/分升，误差分别降低了 40.6% 和 37.9%。此外，信中还探讨了传感器校准频率对预测准确性的影响，结果表明每隔三或五天校准一次可获得最佳性能，读数误差分别约为 16 毫克/分升和 15 毫克/分升。这些发现强调了增强血糖监测系统的潜力，并为今后的糖尿病管理研究提出了建议。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

IEEE Sensors Letters Engineering-Electrical and Electronic Engineering

CiteScore

3.50

自引率

7.10%

发文量

194