Abstract

BackgroundScreen-printed sensors can be easily fabricated and have advantages of cost-effectiveness, low instrument demand, and decentralized fabrication. However, they often suffered from low reproducibility and conductivity, restraining them from practical applications. MethodThis study demonstrated a high-performance sensor with large surface area, high conductivity, wide detection range, and consistent catalytic kinetics using screen printing and electrodeposition. The large surface area was achieved by blending sacrificer into carbon paste to fabricate porous electrodes. Two steps of electrodeposition decorated the porous electrode surface with graphene and nickel nanoparticles to enhance conductivity and enable catalytic reactions of lactate. Significant findingsElectrodeposition achieved consistent size and spatial distributions of graphene and Ni nanoparticles, enabling high conductivity and reactivity. The deposited nickel nanoparticles were a mixture of Ni2+ and Ni3+ derivatives, resulting in a high variation in response currents. By oxidizing the Ni-derivatives NPs to a uniform state of nickel hydroxide, the sensor attained a highly linear detection with an 83% lower standard error. Additionally, the improved sensor had an impressive linear detection range from 0.5 to 60 mM. The fabrication was easy to follow and had a minimum demand for the instrument, making it particularly valuable for practical applications in regions with limited resources.

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