Inkjet-printed 3D micro-ring-electrode arrays for amperometric nanoparticle detection

Hu Peng; Leroy Grob; Lennart Jakob Konstantin Weiß; Lukas Hiendlmeier; Emir Music; Inola Kopic; Tetsuhiko F. Teshima; Philipp Rinklin; Bernhard Wolfrum

doi:10.1039/d2nr05640b

Inkjet-printed 3D micro-ring-electrode arrays for amperometric nanoparticle detection

Hu Peng, Leroy Grob, Lennart Jakob Konstantin Weiß, Lukas Hiendlmeier, Emir Music, Inola Kopic, Tetsuhiko F. Teshima, Philipp Rinklin, Bernhard Wolfrum

Associate Professorship of Neuroelectronics

Research output: Contribution to journal › Article › peer-review

9 Scopus citations

Abstract

Chip-based impact electrochemistry can provide means to measure nanoparticles in solution by sensing their stochastic collisions on appropriately-polarized microelectrodes. However, a planar microelectrode array design still restricts the particle detection to the chip surface and does not allow detection in 3D environments. In this work, we report a fast fabrication process for 3D microelectrode arrays by combining ink-jet printing with laser-patterning. To this end, we printed 3D pillars from polyacrylate ink as a scaffold. Then, the metal structures are manufactured via sputtering and laser-ablation. Finally, the chip is passivated with a parylene-C layer and the electrode tips are created via laser-ablation in a vertical alignment. As a proof of principle, we employ our 3D micro-ring-electrode arrays for single impact recordings from silver nanoparticles.

Original language	English
Pages (from-to)	4006-4013
Number of pages	8
Journal	Nanoscale
Volume	15
Issue number	8
DOIs	https://doi.org/10.1039/d2nr05640b
State	Published - 31 Jan 2023

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abstract = "Chip-based impact electrochemistry can provide means to measure nanoparticles in solution by sensing their stochastic collisions on appropriately-polarized microelectrodes. However, a planar microelectrode array design still restricts the particle detection to the chip surface and does not allow detection in 3D environments. In this work, we report a fast fabrication process for 3D microelectrode arrays by combining ink-jet printing with laser-patterning. To this end, we printed 3D pillars from polyacrylate ink as a scaffold. Then, the metal structures are manufactured via sputtering and laser-ablation. Finally, the chip is passivated with a parylene-C layer and the electrode tips are created via laser-ablation in a vertical alignment. As a proof of principle, we employ our 3D micro-ring-electrode arrays for single impact recordings from silver nanoparticles.",

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AU - Peng, Hu

AU - Grob, Leroy

AU - Weiß, Lennart Jakob Konstantin

AU - Hiendlmeier, Lukas

AU - Music, Emir

AU - Kopic, Inola

AU - F. Teshima, Tetsuhiko

AU - Rinklin, Philipp

AU - Wolfrum, Bernhard

PY - 2023/1/31

Y1 - 2023/1/31

N2 - Chip-based impact electrochemistry can provide means to measure nanoparticles in solution by sensing their stochastic collisions on appropriately-polarized microelectrodes. However, a planar microelectrode array design still restricts the particle detection to the chip surface and does not allow detection in 3D environments. In this work, we report a fast fabrication process for 3D microelectrode arrays by combining ink-jet printing with laser-patterning. To this end, we printed 3D pillars from polyacrylate ink as a scaffold. Then, the metal structures are manufactured via sputtering and laser-ablation. Finally, the chip is passivated with a parylene-C layer and the electrode tips are created via laser-ablation in a vertical alignment. As a proof of principle, we employ our 3D micro-ring-electrode arrays for single impact recordings from silver nanoparticles.

AB - Chip-based impact electrochemistry can provide means to measure nanoparticles in solution by sensing their stochastic collisions on appropriately-polarized microelectrodes. However, a planar microelectrode array design still restricts the particle detection to the chip surface and does not allow detection in 3D environments. In this work, we report a fast fabrication process for 3D microelectrode arrays by combining ink-jet printing with laser-patterning. To this end, we printed 3D pillars from polyacrylate ink as a scaffold. Then, the metal structures are manufactured via sputtering and laser-ablation. Finally, the chip is passivated with a parylene-C layer and the electrode tips are created via laser-ablation in a vertical alignment. As a proof of principle, we employ our 3D micro-ring-electrode arrays for single impact recordings from silver nanoparticles.

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Inkjet-printed 3D micro-ring-electrode arrays for amperometric nanoparticle detection

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