3D-printed electrochemical glucose device with integrated Fe(II)-MOF nanozyme

Estimation of glucose (GLU) levels in the human organism is very important in the diagnosis and monitoring of diabetes. Scientific advances in nanomaterials have led to the construction of new generations of enzymatic-free GLU sensors. In this work, an innovative 3D-printed device modified with a water-stable and non-toxic metal-organic framework of iron (Fe(II)-MOF), which serves as a nanozyme, has been developed for the voltammetric determination of GLU in artificial sweat. In contrast to existing MOF-based GLU sensors which exhibit electrocatalytic activity for the oxidation of GLU in alkaline media, the nanozyme Fe(II)-MOF/3D-printed device can operate in the acidic epidermal sweat environment. The enzymatic-free GLU sensor is composed of a 3-electrode 3D-printed device with the MOF nanozyme immobilized on the surface of the working electrode. GLU sensing is conducted by differential pulse voltammetry without interference from other co-existing metabolites in artificial sweat. The response is based on the oxidation of glucose to gluconolactone, induced by the redox activity of the Fe-centers of the MOF. GLU gives rise to an easily detectable and well-defined voltammetric peak at about - 1.2 V and the limit of detection is 17.6 mu mol L-1. The synergy of a nanozyme with 3D printing technology results in an advanced, sensitive, and low-cost sensor, paving the way for on-skin applications.

Automated summary

A nanozyme based on a metal-organic framework (MOF) modified 3D-printed device has been developed for the voltammetric determination of glucose in artificial sweat. This enzymatic-free glucose (GLU) sensor can operate in the acidic epidermal sweat environment and shows a well-defined voltammetric peak at about -1.2 V with a limit of detection of 17.6 mu mol L-1. The synergy of a nanozyme with 3D printing technology results in an advanced, sensitive, and low-cost sensor for on-skin applications.