An artificial molecular machine that builds an asymmetric catalyst

Bo, Guillaume De; Gall, Malcolm A. Y.; Kuschel, Sonja; Winter, Julien De; Gerbaux, Pascal; Leigh, David A.

doi:10.1038/s41565-018-0105-3

Cited by 119 publications

(63 citation statements)

References 32 publications

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“…Leigh et al described a molecular machine that moves a substrate between different activating sites. 31,32 Anderson et al reported the template-directed synthesis of a porphyrin nanoball. 33 Fujita et al prepared palladium metal complexes and used them as catalyst carriers.…”

Section: Introductionmentioning

confidence: 99%

Assembly of Metallacages into Soft Suprastructures with Dimensions of up to Micrometers and the Formation of Composite Materials

et al. 2018

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This work provides a platform for the rapid generation of superstructure assemblies with a wide range of lengths that can be used to access a variety of metal–organic complex-based soft superstructures. Metallacage-based microneedles that are nanometers in diameter and millimeters in length were generated in dichloromethane and ethyl acetate; their size could be controlled by adjusting the ratio of the two solvents. Interestingly, microflower structures could be formed by further assembly of the microneedles during solvent evaporation. Our study establishes a feasible method designed to broaden the range of suprastructures with emissions from blue and green to red through the co-assembly of lysine-modified perylene. Similar to the co-assembly of lysine-modified perylene with microflowers, chlorophyll-a and vitamin B12 were introduced into the microflowers during the assembly process, which may be exploited in studies of energy capture and nerve repair in the future

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Section: Introductionmentioning

confidence: 99%

Assembly of Metallacages into Soft Suprastructures with Dimensions of up to Micrometers and the Formation of Composite Materials

et al. 2018

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“…These proteins comprise a motor domain, capable of moving directionally along a track by consuming a fuel (ATP), and a docking domain capable of picking up or releasing appropriate cargos on command. The design and construction of artificial molecular machines that can actively transport molecular or ionic substrates along specific directions, or across membranes, is a fascinating goal for nanoscientists, and may disclose unconventional routes in catalysis, smart materials, energy conversion and storage, and medical therapy . Outstanding examples of molecular robots capable of transporting and sorting cargos have been developed by engineering DNA architectures .…”

Section: Transport Of Molecular Cargosmentioning

confidence: 99%

Photoactivated Artificial Molecular Machines that Can Perform Tasks

et al. 2020

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The ORCID identification number(s) for the author(s) of this article can be found under https://doi.org/10.1002/adma.201906064.Research on artificial photoactivated molecular machines has moved in recent years from a basic scientific endeavor toward a more applicative effort. Nowadays, the prospect of reproducing the operation of natural nanomachines with artificial counterparts is no longer a dream but a concrete possibility. The progress toward the construction of molecular-machinebased devices and materials in which light irradiation results in the execution of a task as a result of nanoscale movements is illustrated here. After a brief description of a few basic types of photoactivated molecular machines, significant examples of their exploitation to perform predetermined functions are presented. These include switchable catalysts, nanoactuators that interact with cellular membranes, transporters of small molecular cargos, and active joints capable of mechanically coupling molecular-scale movements. Investigations aimed at harnessing the collective operation of a multitude of molecular machines organized in arrays to perform tasks at the microscale and macroscale in hard and soft materials are also reviewed. Surfaces, gels, liquid crystals, polymers, and self-assembled nanostructures are described wherein the nanoscale movement of embedded molecular machines is amplified, allowing the realization of muscle-like actuators, microfluidic devices, and polymeric materials for light energy transduction and storage.

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“…The latest addition to this conceptual journey in the molecular world can be found in this issue in a Letter by De Bo et al 1 . The authors have made a molecule that can synthesize a second molecule, which in turn assumes a characteristic conformation that can catalyse the formation of a third molecule.…”

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confidence: 92%

Things molecules can do

2018

Nature Nanotech

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An artificial molecular machine that builds an asymmetric catalyst

Cited by 119 publications

References 32 publications

Assembly of Metallacages into Soft Suprastructures with Dimensions of up to Micrometers and the Formation of Composite Materials

Assembly of Metallacages into Soft Suprastructures with Dimensions of up to Micrometers and the Formation of Composite Materials

Photoactivated Artificial Molecular Machines that Can Perform Tasks

Things molecules can do

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