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Immobilizing nanozymes on 3D-printed metal substrates for enhanced peroxidase-like activity and trace-level glucose detection

Paramita Koley, Ranjithkumar Jakku, Tayebeh Hosseinnejad, Selvakannan Periasamy, Suresh K. Bhargava

2024Nanoscale10 citationsDOI

Abstract

, a 3D-printed metal substrate-based enzyme. Our inventive methodology involved the synthesis of a thermally degraded Fe-based metal-organic framework, DEG 500, followed by its deposition on a 3D-printed metal substrate composed of Ti-Al-V alloy. This novel composite exhibited remarkable peroxidase-like activity in a range of different temperatures and pH, coupled with the ability to detect glucose in real-world samples such as blood and fruit juices. The exceptional enzymatic behaviour was attributed to the diverse iron (Fe) oxidation states and the presence of oxygen vacancies, as evidenced through advanced characterization techniques. Fundamentally, we rigorously explored the mechanistic pathway through controlled studies and theoretical calculations, culminating in a transformative stride toward more sustainable and effective biomedical sensing practices.

Topics & Concepts

Substrate (aquarium)Materials science3d printedNanotechnologyDeposition (geology)PeroxidaseMetal-organic frameworkChemical engineeringChemistryEnzymeOrganic chemistryBiomedical engineeringOceanographyAdsorptionPaleontologyGeologyBiologySedimentEngineeringMedicineAdvanced Nanomaterials in CatalysisElectrochemical sensors and biosensorsAdvanced biosensing and bioanalysis techniques
Immobilizing nanozymes on 3D-printed metal substrates for enhanced peroxidase-like activity and trace-level glucose detection | Litcius