电流型葡萄糖传感器：误差来源及冗余的潜在益处。

Amperometric glucose sensors: sources of error and potential benefit of redundancy.

作者信息

Castle Jessica R, Ward W Kenneth

机构信息

Oregon Health Services University, Portland, Oregon, USA.

出版信息

J Diabetes Sci Technol. 2010 Jan 1;4(1):221-5. doi: 10.1177/193229681000400127.

DOI:10.1177/193229681000400127

PMID:20167187

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2825644/

Abstract

Amperometric glucose sensors have advanced the care of patients with diabetes and are being studied to control insulin delivery in the research setting. However, at times, currently available sensors demonstrate suboptimal accuracy, which can result from calibration error, sensor drift, or lag. Inaccuracy can be particularly problematic in a closed-loop glycemic control system. In such a system, the use of two sensors allows selection of the more accurate sensor as the input to the controller. In our studies in subjects with type 1 diabetes, the accuracy of the better of two sensors significantly exceeded the accuracy of a single, randomly selected sensor. If an array with three or more sensors were available, it would likely allow even better accuracy with the use of voting.

摘要

安培型葡萄糖传感器推动了糖尿病患者的护理工作，并且正在研究中用于在研究环境中控制胰岛素输送。然而，目前可用的传感器有时显示出欠佳的准确性，这可能是由校准误差、传感器漂移或滞后导致的。在闭环血糖控制系统中，不准确可能会特别成问题。在这样的系统中，使用两个传感器可以选择更准确的传感器作为控制器的输入。在我们对1型糖尿病患者的研究中，两个传感器中较好的那个的准确性显著超过了随机选择的单个传感器的准确性。如果有一个包含三个或更多传感器的阵列，使用投票可能会带来更高的准确性。

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电流型葡萄糖传感器：误差来源及冗余的潜在益处。

Amperometric glucose sensors: sources of error and potential benefit of redundancy.

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