Mechanotransduced chiroptical differentiation of neural stem cells
Chiral photons can accelerate the differentiation of neural stem cells into neurons in vitro and in vivo when DNA-bridged chiral assemblies of gold nanoparticles are tightly entangled with the cells’ cytoskeletal fibres.
Published in Bioengineering & Biotechnology
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Chief Editor, Nature Biomedical Engineering, Nature Research
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Life Sciences > Biological Sciences > Biotechnology
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Nature Biomedical Engineering
This journal aspires to become the most prominent publishing venue in biomedical engineering by bringing together the most important advances in the discipline, enhancing their visibility, and providing overviews of the state of the art in each field.
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The cover illustrates the differentiation of neural stem cells into neurons via the transduction of chiral photons into force by DNA-bridged chiral assemblies of gold nanoparticles entangled with the neurons’ cytoskeletal fibres.
Image: Hua Kuang and Chuanlai Xu (Jiangnan University), and Nicholas Kotov (University of Michigan). Cover Design: Alex Wing.