Continuous monitoring of diabetes with an integrated microneedle biosensing device through 3D printing

Continuous monitoring of diabetes with an integrated microneedle biosensing device through 3D printing

Abstract Diabetes is a prevalent chronic metabolic disease with multiple clinical manifestations and complications, and it is among the leading causes of death. Painless and continuous monitoring of interstitial glucose is highly desirable for diabetes management. Here we unprecedentedly show contin...

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Main Authors: Yiqun Liu, Qi Yu, Xiaojin Luo, Li Yang, Yue Cui
Format: Article
Language:English
Published: Nature Publishing Group 2021-09-01
Series:Microsystems & Nanoengineering
Online Access:https://doi.org/10.1038/s41378-021-00302-w
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spelling doaj-b0bcc9e00e71423aa430989d5e5d4df52021-10-03T11:11:44ZengNature Publishing GroupMicrosystems & Nanoengineering2055-74342021-09-017111210.1038/s41378-021-00302-wContinuous monitoring of diabetes with an integrated microneedle biosensing device through 3D printingYiqun Liu0Qi Yu1Xiaojin Luo2Li Yang3Yue Cui4School of Materials Science and Engineering, Peking UniversityRenal Division, Peking University Institute of Nephrology, Peking University First HospitalSchool of Materials Science and Engineering, Peking UniversityRenal Division, Peking University Institute of Nephrology, Peking University First HospitalSchool of Materials Science and Engineering, Peking UniversityAbstract Diabetes is a prevalent chronic metabolic disease with multiple clinical manifestations and complications, and it is among the leading causes of death. Painless and continuous monitoring of interstitial glucose is highly desirable for diabetes management. Here we unprecedentedly show continuous monitoring of diabetes with an integrated microneedle biosensing device. The device was manufactured with a 3D printing process, a microfabrication process, an electroplating process, and an enzyme immobilization step. The device was inserted into the dermis layer of mouse skin and showed accurate sensing performance for monitoring subcutaneous glucose levels in normal or diabetic mice. The detection results were highly correlated with those obtained from a commercial blood glucose meter. We anticipate that the study could open exciting avenues for monitoring and managing diabetes, alongside fundamental studies of subcutaneous electronic devices.https://doi.org/10.1038/s41378-021-00302-w
collection DOAJ
language English
format Article
sources DOAJ
author Yiqun Liu
Qi Yu
Xiaojin Luo
Li Yang
Yue Cui
spellingShingle Yiqun Liu
Qi Yu
Xiaojin Luo
Li Yang
Yue Cui
Continuous monitoring of diabetes with an integrated microneedle biosensing device through 3D printing
Microsystems & Nanoengineering
author_facet Yiqun Liu
Qi Yu
Xiaojin Luo
Li Yang
Yue Cui
author_sort Yiqun Liu
title Continuous monitoring of diabetes with an integrated microneedle biosensing device through 3D printing
title_short Continuous monitoring of diabetes with an integrated microneedle biosensing device through 3D printing
title_full Continuous monitoring of diabetes with an integrated microneedle biosensing device through 3D printing
title_fullStr Continuous monitoring of diabetes with an integrated microneedle biosensing device through 3D printing
title_full_unstemmed Continuous monitoring of diabetes with an integrated microneedle biosensing device through 3D printing
title_sort continuous monitoring of diabetes with an integrated microneedle biosensing device through 3d printing
publisher Nature Publishing Group
series Microsystems & Nanoengineering
issn 2055-7434
publishDate 2021-09-01
description Abstract Diabetes is a prevalent chronic metabolic disease with multiple clinical manifestations and complications, and it is among the leading causes of death. Painless and continuous monitoring of interstitial glucose is highly desirable for diabetes management. Here we unprecedentedly show continuous monitoring of diabetes with an integrated microneedle biosensing device. The device was manufactured with a 3D printing process, a microfabrication process, an electroplating process, and an enzyme immobilization step. The device was inserted into the dermis layer of mouse skin and showed accurate sensing performance for monitoring subcutaneous glucose levels in normal or diabetic mice. The detection results were highly correlated with those obtained from a commercial blood glucose meter. We anticipate that the study could open exciting avenues for monitoring and managing diabetes, alongside fundamental studies of subcutaneous electronic devices.
url https://doi.org/10.1038/s41378-021-00302-w
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AT qiyu continuousmonitoringofdiabeteswithanintegratedmicroneedlebiosensingdevicethrough3dprinting
AT xiaojinluo continuousmonitoringofdiabeteswithanintegratedmicroneedlebiosensingdevicethrough3dprinting
AT liyang continuousmonitoringofdiabeteswithanintegratedmicroneedlebiosensingdevicethrough3dprinting
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