Light-induced rolling of azobenzene polymer thin films for wrapping subcellular neuronal structures

IF 5.9 2区 化学 Q1 CHEMISTRY, MULTIDISCIPLINARY
Marta J. I. Airaghi Leccardi, Benoît X. E. Desbiolles, Anna Y. Haddad, Baju C. Joy, Chen Song, Deblina Sarkar
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Abstract

Neurons are essential cells composing our nervous system and orchestrating our body, thoughts, and emotions. Recently, research efforts have been focused on studying not only their collective structure and functions but also the single-cell properties as an individual complex system. Nanoscale technology has the potential to unravel mysteries in neuroscience and provide support to the neuron by measuring and influencing several aspects of the cell. As wearable devices interact with different parts of our body, we could envision a thousand times smaller interface to conform on and around subcellular regions of the neurons for unprecedented contact, probing, and control. However, a major challenge is to develop an interface that can morph to the extreme curvatures of subcellular structures. Here, we address this challenge with the development of a platform that conforms even to small neuronal processes. To achieve this, we produced a wireless platform made of an azobenzene polymer that undergoes on-demand light-induced folding with sub-micrometer radius of curvature. We show that these platforms can be fabricated with an adjustable form factor, micro-injected onto neuronal cultures, and can delicately wrap various morphologies of neuronal processes in vitro, toward obtaining seamless biointerfaces with an increased coupling with the cell membrane. Our in vitro testings did not show any adverse effects of the platforms in contact with the neurons. Additionally, for future functionality, nanoparticles or optoelectronic materials could be blended with the azobenzene polymer, and 2D materials on the platform surface could be safely folded to the high curvatures without mechanical failure, as per our calculations. Ultimately, this technology could lay the foundation for future integration of wirelessly actuated materials within or on its platform for neuromodulation, recording, and neuroprotection at the subcellular level. Neuronal behavior can be controlled by probing and modulating subcellular regions of the cells; however, developing an interface that can morph into the extreme curvatures of neurites is a major challenge. Here, the authors develop a wireless platform made of an azobenzene polymer that undergoes on-demand light-induced folding with an ultra-low curvature radius and wraps various morphologies of neuronal processes in vitro.

Abstract Image

用于包裹亚细胞神经元结构的偶氮苯聚合物薄膜的光诱导滚动。
神经元是构成我们神经系统的重要细胞,协调着我们的身体、思想和情感。最近,研究工作的重点不仅是研究神经元的整体结构和功能,还包括作为单个复杂系统的单细胞特性。纳米技术有可能揭开神经科学的神秘面纱,并通过测量和影响细胞的多个方面为神经元提供支持。随着可穿戴设备与身体不同部位的互动,我们可以设想在神经元的亚细胞区域上和周围使用小一千倍的界面,以实现前所未有的接触、探测和控制。然而,开发一种能适应亚细胞结构极端曲率的界面是一大挑战。在这里,我们通过开发一种甚至能适应小神经元过程的平台来应对这一挑战。为了实现这一目标,我们制作了一种由偶氮苯聚合物制成的无线平台,该平台可按需进行光诱导折叠,曲率半径可达亚微米级。我们的研究表明,这些平台的外形尺寸可调,可以微注射到神经元培养物上,并能在体外巧妙地包裹各种形态的神经元过程,从而获得与细胞膜耦合度更高的无缝生物界面。我们的体外测试表明,平台与神经元接触不会产生任何不良影响。此外,根据我们的计算,为了实现未来的功能,纳米粒子或光电材料可以与偶氮苯聚合物混合,平台表面的二维材料可以安全地折叠到高曲率,而不会出现机械故障。最终,这项技术将为未来在其平台内或平台上集成无线致动材料奠定基础,从而在亚细胞水平上实现神经调节、记录和神经保护。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Communications Chemistry
Communications Chemistry Chemistry-General Chemistry
CiteScore
7.70
自引率
1.70%
发文量
146
审稿时长
13 weeks
期刊介绍: Communications Chemistry is an open access journal from Nature Research publishing high-quality research, reviews and commentary in all areas of the chemical sciences. Research papers published by the journal represent significant advances bringing new chemical insight to a specialized area of research. We also aim to provide a community forum for issues of importance to all chemists, regardless of sub-discipline.
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