Issue 7, 2019

Magnetically driven piezoelectric soft microswimmers for neuron-like cell delivery and neuronal differentiation

Abstract

Wireless micro- and nanorobots are biomedical devices with a potential use in high-precision minimally invasive therapies. Here, a highly integrated multifunctional soft microrobot is developed for targeted cell therapy applications, featuring targeted cell transportation and induced cell differentiation. The micromachines are made of composites consisting of a soft piezoelectric polymer matrix in which magnetic nanoparticles are dispersed. The magnetic nanoparticles serve as the component for the device's magnetic actuation, while the piezoelectric polymer acts as both a steerable scaffold and an acoustically responsive cell electrostimulation platform. With the application of a rotating magnetic field, the microrobots swim in a corkscrew motion in different liquid environments that mimic human body fluids. When the swimmers are subjected to acoustic waves, their piezoelectric body is electrically polarized which induces cell differentiation of neuron-like PC12 cells loaded on the swimmers surface. This combinatorial technique may open up new avenues for bioelectronic therapies.

Graphical abstract: Magnetically driven piezoelectric soft microswimmers for neuron-like cell delivery and neuronal differentiation

Supplementary files

Article information

Article type
Communication
Submitted
21 Febr. 2019
Accepted
17 Apr. 2019
First published
25 Apr. 2019
This article is Open Access
Creative Commons BY-NC license

Mater. Horiz., 2019,6, 1512-1516

Magnetically driven piezoelectric soft microswimmers for neuron-like cell delivery and neuronal differentiation

X. Chen, J. Liu, M. Dong, L. Müller, G. Chatzipirpiridis, C. Hu, A. Terzopoulou, H. Torlakcik, X. Wang, F. Mushtaq, J. Puigmartí-Luis, Q. Shen, B. J. Nelson and S. Pané, Mater. Horiz., 2019, 6, 1512 DOI: 10.1039/C9MH00279K

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