Innovation in potentiometry: 3D-printed polylactic acid-based ion-selective bulk electrode membranes

Although ion-selective membrane-based potentiometric sensors have already proved their analytical performance in several fields of life, their applicability is still limited in practice. Biodegradable, ionic additive-free, polylactic acid-based bulk electrode membrane matrix containing various environmentally friendly polyethylene glycol derivatives as plasticizer was developed for the first time to replace the conventional PVC-based ones. Moreover, the first introduction of 3D printing in potentiometric chemosensing was also reported. It was demonstrated that a thoroughly optimized and generalizable procedure for filament extrusion combined with 3D printing technology provides a unique tool for series production of the redesigned ion-selective bulk electrochemical membranes. Finally, the potentiometric detection of Hg2+ in water was carried out as a proof-of-concept study on sensing. Results showed an unexpected improvement in electrochemical characteristics of the novel membranes compared to their conventional analogues. The present work expanded the practical applicability of conventional potentiometric cation-selective electrode membranes enabling their green, decentralized, and automated state-of-the-art manufacturing using a novel matrix composition. [GRAPHICS] .

Automated summary

In this study, a biodegradable, ionic additive-free bulk electrode membrane matrix was developed to replace conventional PVC-based ones, and 3D printing technology was introduced to enhance the performance of ion-selective electrochemical membranes. The detection of Hg2+ demonstrated the superior characteristics of the novel membranes.