A colorimetric glucose sensor based on natural enzyme coupled with highly efficient nanozyme prepared by in situ reduction.

BACKGROUND

Colorimetric sensors based on natural enzyme-nanozyme cascade reactions are commonly employed in glucose detection owing to their high selectivity and stability. However, nanozyme synthesis often conducted under harsh conditions, leading to the disruption of the natural enzyme structure, thereby reducing the catalytic performance of natural enzyme-nanozyme hybrid catalysts.

RESULTS

A simple synthesis strategy was devised to obtain natural enzyme-metal nanocluster (NC) hybrid catalysts under mild conditions, thus eliminating the need for a potent reducing agent. Highly dispersible ruthenium nanoclusters (RuNCs) were fabricated via in situ reduction based on the potential difference between glucose oxidase (GOx) and Ru, which enhanced the peroxidase (POD)-like activity of the hybrid catalysts. The POD-like activity of multi-walled carbon nanotube-GOx-RuNCs (MWCNT-GOx-RuNCs) was approximately four-fold higher than that of MWCNT-GOx@RuNCs prepared by reduction with sodium borohydride (NaBH). The developed glucose colorimetric sensor demonstrated an outstanding detection range of 5-750 μM, with a satisfactory detection limit (2.85 μM). In addition, the sensor had excellent selectivity, stability, and sensitivity, enabling the accurate detection of glucose real samples even in the presence of similar interferents.

SIGNIFICANCE

A simple method is introduced to synthesise natural enzyme-metal NCs hybrid catalysts under mild conditions, avoiding the harsh reaction conditions that result in natural enzyme inactivation and nanocluster aggregation. Furthermore, a colorimetric sensor based on the natural enzyme-nanozyme cascade reaction shows significantly improved sensitivity and stability, which is crucial for glucose detection in real samples.