Roman Grisch scite author profile

Shape change is a prevalent function apparent in a diverse set of natural structures, including seed dispersal units, climbing plants and carnivorous plants. Many of these natural materials change shape by using cellulose microfibrils at specific orientations to anisotropically restrict the swelling/shrinkage of their organic matrices upon external stimuli. This is in contrast to the material-specific mechanisms found in synthetic shape-memory systems. Here we propose a robust and universal method to replicate this unusual shape-changing mechanism of natural systems in artificial bioinspired composites. The technique is based upon the remote control of the orientation of reinforcing inorganic particles within the composite using a weak external magnetic field. Combining this reinforcement orientational control with swellable/ shrinkable polymer matrices enables the creation of composites whose shape change can be programmed into the material's microstructure rather than externally imposed. Such bioinspired approach can generate composites with unusual reversibility, twisting effects and site-specific programmable shape changes.

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Hybrid Helical Magnetic Microrobots Obtained by 3D Template‐Assisted Electrodeposition

Zeeshan

Grisch

Pellicer

et al. 2013

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135

111

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The biocompatibility and anti-biofouling properties of magnetic core–multishell Fe@C NWs–AAO nanocomposites

Lindo

Pellicer

Zeeshan

et al. 2015

Phys. Chem. Chem. Phys.

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Soft-magnetic core-multishell Fe@C NWs-AAO nanocomposites were synthesized using anodization, electrodeposition and low-pressure chemical vapour deposition (CVD) at 900 °C. High chemical and mechanical stability is achieved by the conversion from amorphous to θ- and δ-Al2O3 phases above 600 °C. Moreover, the surface properties of the material evolve from bioactive, for porous AAO, to bioinert, for Fe@C NW filled AAO nanocomposite. Although the latter is not cytotoxic, cells do not adhere onto the surface of the magnetic nanocomposite, thus proving its anti-biofouling character.

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Lithography: Hybrid Helical Magnetic Microrobots Obtained by 3D Template‐Assisted Electrodeposition (Small 7/2014)

Zeeshan

Grisch

Pellicer

et al. 2014

Small

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Hybrid artificial flagella (h‐ABF) consisting of a ferromagnetic alloy head and a helical polymer tail can be fabricated by sequential electrodeposition of a cobalt‐nickel alloy and polypyrrole inside a photoresist template patterned by 3D laser lithography. As M. A. Zeeshan, S. Pané, and co‐workers report on page 1284, the h‐ABFs are physically stable in an aqueous environment with a rigid connection between the metallic and the polymer segments. Controlled actuation of the microrobots by a rotating magnetic field is demonstrated in a fluidic environment with a focus on swarm control.

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Roman Grisch

Self-shaping composites with programmable bioinspired microstructures

Hybrid Helical Magnetic Microrobots Obtained by 3D Template‐Assisted Electrodeposition

The biocompatibility and anti-biofouling properties of magnetic core–multishell Fe@C NWs–AAO nanocomposites

Lithography: Hybrid Helical Magnetic Microrobots Obtained by 3D Template‐Assisted Electrodeposition (Small 7/2014)

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