Clement Appiah scite author profile

Living beings have an unsurpassed range of ways to manipulate objects and interact with them. They can make autonomous decisions and can heal themselves. So far, a conventional robot cannot mimic this complexity even remotely. Classical robots are often used to help with lifting and gripping and thus to alleviate the effects of menial tasks. Sensors can render robots responsive, and artificial intelligence aims at enabling autonomous responses. Inanimate soft robots are a step in this direction, but it will only be in combination with living systems that full complexity will be achievable. The field of biohybrid soft robotics provides entirely new concepts to address current challenges, for example the ability to self‐heal, enable a soft touch, or to show situational versatility. Therefore, “living materials” are at the heart of this review. Similarly to biological taxonomy, there is a recent effort for taxonomy of biohybrid soft robotics. Here, an expansion is proposed to take into account not only function and origin of biohybrid soft robotic components, but also the materials. This materials taxonomy key demonstrates visually that materials science will drive the development of the field of soft biohybrid robotics.

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Crystallization behavior of precision polymers containing azobenzene defects

Appiah

Woltersdorf

Pérez-Camargo

et al. 2017

European Polymer Journal

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Designing melt flow of poly(isobutylene)-based ionic liquids

et al. 2013

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Synthesis and characterization of new photoswitchable azobenzene-containing poly(ε-caprolactones)

et al. 2016

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A novel and efficient strategy in obtaining series of mono-and bi-armed azobenzene-containing poly(3-caprolactone)s is described, starting from a commercially available azobenzene dye via azide/alkyne-"click"-reactions. The attachment of alkyne-telechelic poly(3-caprolactone)s (1 kDa and 3 kDa), followed by chromatographic separation, allowed the attachment of either one or two PCl-chains to either side of the azobenzene-dye. The resulting mono-and bi-armed photo-switchable polymers are fully characterized by 2D-NMR techniques and show a high thermal stability. Additionally liquid chromatography at critical conditions (LCCC) coupled to ESI-TOF allowed us to prove the presence of either one or two polymer chains affixed onto the central azobenzene dye.

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Clement Appiah

Living Materials Herald a New Era in Soft Robotics

Crystallization behavior of precision polymers containing azobenzene defects

Designing melt flow of poly(isobutylene)-based ionic liquids

Synthesis and characterization of new photoswitchable azobenzene-containing poly(ε-caprolactones)

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