Philipp Rinklin
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Nanoscale electrochemical sensor arrays: redox cycling amplification in dual-electrode systems
B Wolfrum, E Kätelhön, A Yakushenko, KJ Krause, N Adly, M Hüske, ...
Accounts of chemical research 49 (9), 2031-2040, 2016
The influence of supporting ions on the electrochemical detection of individual silver nanoparticles: understanding the shape and frequency of current transients in nano-impacts
KJ Krause, F Brings, J Schnitker, E Kätelhön, P Rinklin, D Mayer, ...
Chemistry 23 (19), 2017
All-inkjet-printed gold microelectrode arrays for extracellular recording of action potentials
B Bachmann, NY Adly, J Schnitker, A Yakushenko, P Rinklin, ...
Flexible and Printed Electronics 2 (3), 035003, 2017
Nanostructured cavity devices for extracellular stimulation of HL-1 cells
A Czeschik, P Rinklin, U Derra, S Ullmann, P Holik, S Steltenkamp, ...
Nanoscale 7 (20), 9275-9281, 2015
Fully printed μ-needle electrode array from conductive polymer ink for bioelectronic applications
S Zips, L Grob, P Rinklin, K Terkan, NY Adly, LJK Weiß, D Mayer, ...
ACS applied materials & interfaces 11 (36), 32778-32786, 2019
On-chip stochastic detection of silver nanoparticles without a reference electrode
PG Figueiredo, L Grob, P Rinklin, KJ Krause, B Wolfrum
ACS sensors 3 (1), 93-98, 2018
Ion transport through polyelectrolyte multilayers
S Carregal‐Romero, P Rinklin, S Schulze, M Schäfer, A Ott, D Hühn, X Yu, ...
Macromolecular rapid communications 34 (23-24), 1820-1826, 2013
Direct stereolithographic 3D printing of microfluidic structures on polymer substrates for printed electronics
S Zips, OJ Wenzel, P Rinklin, L Grob, K Terkan, NY Adly, L Weiß, ...
Advanced Materials Technologies 4 (3), 1800455, 2019
On-chip electromagnetic tweezers–3-dimensional particle actuation using microwire crossbar arrays
P Rinklin, HJ Krause, B Wolfrum
Lab on a Chip 16 (24), 4749-4758, 2016
Printed 3D electrode arrays with micrometer‐scale lateral resolution for extracellular recording of action potentials
L Grob, H Yamamoto, S Zips, P Rinklin, A Hirano‐Iwata, B Wolfrum
Advanced Materials Technologies 5 (3), 1900517, 2020
Inducing microscopic thermal lesions for the dissection of functional cell networks on a chip
P Rinklin, D Afanasenkau, S Wiegand, A Offenhäusser, B Wolfrum
Lab on a chip 15 (1), 237-243, 2015
On‐chip control of magnetic particles
P Rinklin, HJ Krause, B Wolfrum
physica status solidi (a) 209 (5), 871-874, 2012
Actuation and tracking of a single magnetic particle on a chip
P Rinklin, HJ Krause, B Wolfrum
Applied physics letters 100 (1), 014107, 2012
Soft peripheral nerve interface made from carbon nanotubes embedded in silicone
K Terkan, F Zurita, T Jamal Khalaf, P Rinklin, T Teshima, T Kohl, ...
APL Materials 8 (10), 101111, 2020
Chip‐Based Heat Stimulation for Modulating Signal Propagation in HL‐1 Cell Networks
KM Dang, P Rinklin, D Afanasenkau, G Westmeyer, T Schürholz, ...
Advanced biosystems 2 (12), 1800138, 2018
Fabrication of precisely aligned microwire and microchannel structures: Toward heat stimulation of guided neurites in neuronal cultures
KM Dang, P Rinklin, J Schnitker, B Haberkorn, K Zobel, S Gribaudo, ...
physica status solidi (a) 214 (9), 1600729, 2017
Electrochemical nanocavity devices
P Rinklin, D Mayer, B Wolfrum
Label-Free Biosensing, 199-214, 2017
Opportunities and challenges of translating direct single impact electrochemistry to high-throughput sensing applications
LJK Weiß, P Rinklin, B Wolfrum
Current Opinion in Electrochemistry, 2020
Electronic design automation for increased robustness in inkjet-printed electronics
P Rinklin, TM Tseng, C Liu, M Li, K Terkan, L Grob, N Adly, S Zips, L Weiß, ...
Flexible and Printed Electronics 4 (4), 045002, 2019
Microwire crossbar arrays for chemical, mechanical, and thermal stimulation of cells
P Rinklin, J Fitter, B Wolfrum
Fachgruppe Physik, 2015
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