An Enzyme‐Encapsulated Metal‐Organic Frameworks Nanomesh Biosensor for Salivary Glucose Detection

Diabetes mellitus has become a serious public health problem worldwide. Current home‐based glucose testing, including fingerstick blood testing and continuous glucose monitoring, suffers from low compliance and potential infection. Non‐invasive glucose detection, with the advantages of pain‐free, easy‐to‐operate, and low‐cost, is expected to significantly improve the experience of glucose testing at home for diabetic patients. Here, an enzymatic biosensing platform with high sensitivity and high stability is developed based on a conductive nanomesh composed of interconnected metal‐organic frameworks (MOF). The as‐prepared enzyme‐encapsulated MOF nanomesh exhibits uniform morphology, regular structure, superior catalytic performance, and outstanding electrical conductivity. The glucose sensor modified by enzyme‐encapsulated MOF nanomesh demonstrates a considerably high sensitivity of 86.86 µA mm−1 cm−2 with a limit of detection of 16.57 µm, and remains stable for 16 days of usage. Detection of real saliva samples matches well with the commercial salivary glucose assay kit with an accuracy >93%, and a high correlation with blood glucose with Pearson's r > 0.7. Therefore, the presented enzyme‐encapsulated MOF nanomesh biosensor holds great potential in salivary glucose testing and provides a novel strategy for noan‐invasive glucose detection. Here, a CNT/GOx@ZIF‐8‐based nanomesh enzymic electrochemical biosensor is presented for glucose testing. The as‐designed sensing interface integrates the “armor” effect of zeolitic imidazolate frameworks‐8 (ZIF‐8) and the “conductor” effect of carbon nanotubes (CNTs) based on the self‐assembly procedure of ZIF‐8 that loads glucose oxidase (GOx) along with CNTs. The developed nanomesh biosensor exhibits outstanding performance in glucose detection.