Chengzhi HU
Chengzhi HU
Southern University of Science and Technology (SUSTech)
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Cited by
Cited by
Recent developments in magnetically driven micro-and nanorobots
XZ Chen, M Hoop, F Mushtaq, E Siringil, C Hu, BJ Nelson, S Pané
Applied Materials Today 9, 37-48, 2017
3d printed enzymatically biodegradable soft helical microswimmers
X Wang, XH Qin, C Hu, A Terzopoulou, XZ Chen, TY Huang, ...
Advanced Functional Materials 28 (45), 1804107, 2018
Small‐Scale Machines Driven by External Power Sources
XZ Chen, B Jang, D Ahmed, C Hu, C De Marco, M Hoop, F Mushtaq, ...
Advanced Materials 30 (15), 1705061, 2018
Soft micro-and nanorobotics
C Hu, S Pané, B Nelson
Annual Review of Control, Robotics, and Autonomous Systems 1, 53-57, 2018
MOFBOTS: Metal–Organic‐Framework‐Based Biomedical Microrobots
X Wang, XZ Chen, CCJ Alcântara, S Sevim, M Hoop, A Terzopoulou, ...
Advanced Materials 31 (27), 1901592, 2019
Design and fabrication of a magnetic propulsion system for self-propelled capsule endoscope
M Gao, C Hu, Z Chen, H Zhang, S Liu
IEEE Transactions on Biomedical Engineering 57 (12), 2891-2902, 2010
Magnetically driven piezoelectric soft microswimmers for neuron-like cell delivery and neuronal differentiation
XZ Chen, JH Liu, M Dong, L Müller, G Chatzipirpiridis, C Hu, ...
Materials Horizons 6 (7), 1512-1516, 2019
Surface-chemistry-mediated control of individual magnetic helical microswimmers in a swarm
X Wang, C Hu, L Schurz, C De Marco, X Chen, S Pané, BJ Nelson
ACS nano 12 (6), 6210-6217, 2018
On-chip self-assembly of cell embedded microstructures to vascular-like microtubes
T Yue, M Nakajima, M Takeuchi, C Hu, Q Huang, T Fukuda
Lab on a Chip 14 (6), 1151-1161, 2014
Catalytic Locomotion of Core–Shell Nanowire Motors
B Jang, W Wang, S Wiget, AJ Petruska, X Chen, C Hu, A Hong, D Folio, ...
ACS nano 10 (11), 9983-9991, 2016
Modulation of electric dipoles inside electrospun BaTiO3@ TiO2 core-shell nanofibers for enhanced piezo-photocatalytic degradation of organic pollutants
B Fu, J Li, H Jiang, X He, Y Ma, J Wang, C Hu
Nano Energy 93, 106841, 2022
Three-dimensional hepatic lobule-like tissue constructs using cell-microcapsule technology
Z Liu, M Takeuchi, M Nakajima, C Hu, Y Hasegawa, Q Huang, T Fukuda
Acta biomaterialia 50, 178-187, 2017
Hybrid 3D printing and electrodeposition approach for controllable 3D alginate hydrogel formation
W Shang, Y Liu, W Wan, C Hu, Z Liu, CT Wong, T Fukuda, Y Shen
Biofabrication 9 (2), 025032, 2017
Magnetic alginate microfibers as scaffolding elements for the fabrication of microvascular-like structures
T Sun, Q Shi, Q Huang, H Wang, X Xiong, C Hu, T Fukuda
Acta biomaterialia 66, 272-281, 2018
Dynamic modeling of magnetic helical microrobots
X Wang, C Hu, S Pané, BJ Nelson
IEEE Robotics and Automation Letters 7 (2), 1682-1688, 2021
On-chip fabrication and magnetic force estimation of peapod-like hybrid microfibers using a microfluidic device
T Sun, C Hu, M Nakajima, M Takeuchi, M Seki, T Yue, Q Shi, T Fukuda, ...
Microfluidics and nanofluidics 18, 1177-1187, 2015
Massively Parallelized Pollen Tube Guidance and Mechanical Measurements on a Lab-on-a-Chip Platform
N Shamsudhin, N Laeubli, HB Atakan, H Vogler, C Hu, W Haeberle, ...
PloS one 11 (12), e0168138, 2016
Characterization of size-dependent mechanical properties of tip-growing cells using a lab-on-chip device
C Hu, G Munglani, H Vogler, TN Fabrice, N Shamsudhin, FK Wittel, ...
Lab on a Chip 17 (1), 82-90, 2017
Biodegradable porous sheet-like scaffolds for soft-tissue engineering using a combined particulate leaching of salt particles and magnetic sugar particles
C Hu, C Tercero, S Ikeda, M Nakajima, H Tajima, Y Shen, T Fukuda, ...
Journal of bioscience and bioengineering 116 (1), 126-131, 2013
Feeling the force: how pollen tubes deal with obstacles
JT Burri, H Vogler, NF Läubli, C Hu, U Grossniklaus, BJ Nelson
New Phytologist 220 (1), 187-195, 2018
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