The Insertion Mechanism of a Living Cell Determined by the Stress Segmentation Effect of the Cell Membrane during the Tip–Cell Interaction

Fan, Na; Jiang, Hai; Ye, Zhiyi; Wu, Guiyong; Kang, Yuejun; Wang, Qun; Ran, Xiaolin; Guo, Jian; Zhang, Guocheng; Wang, Guixue; Peng, Bei

doi:10.1002/smll.201703868

Cited by 15 publications

(14 citation statements)

References 45 publications

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“…An atomic force microscope (AFM; Nanowizard II BioAFM, JPK, Germany) was used to determine the surface Young's modulus of VSMCs. The performed method was carried out as previously reported [ 24 ]. And, force curves were analyzed using JPK software.…”

Section: Methodsmentioning

confidence: 99%

A novel mechanism of inhibiting in-stent restenosis with arsenic trioxide drug-eluting stent: Enhancing contractile phenotype of vascular smooth muscle cells via YAP pathway

Zhao

Zang

Yin

et al. 2021

Bioactive Materials

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Objective Arsenic trioxide (ATO or As 2 O 3 ) has beneficial effects on suppressing neointimal hyperplasia and restenosis, but the mechanism is still unclear. The goal of this study is to further understand the mechanism of ATO's inhibitory effect on vascular smooth muscle cells (VSMCs). Methods and results Through in vitro cell culture and in vivo stent implanting into the carotid arteries of rabbit, a synthetic-to-contractile phenotypic transition was induced and the proliferation of VSMCs was inhibited by ATO. F-actin filaments were clustered and the elasticity modulus was increased within the phenotypic modulation of VSMCs induced by ATO in vitro . Meanwhile, Yes-associated protein (YAP) nuclear translocation was inhibited by ATO both in vivo and in vitro . It was found that ROCK inhibitor or YAP inactivator could partially mask the phenotype modulation of ATO on VSMCs. Conclusions The interaction of YAP with the ROCK pathway through ATO seems to mediate the contractile phenotype of VSMCs. This provides an indication of the clinical therapeutic mechanism for the beneficial bioactive effect of ATO-drug eluting stent (AES) on in-stent restenosis (ISR).

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Section: Methodsmentioning

confidence: 99%

A novel mechanism of inhibiting in-stent restenosis with arsenic trioxide drug-eluting stent: Enhancing contractile phenotype of vascular smooth muscle cells via YAP pathway

Zhao

Zang

Yin

et al. 2021

Bioactive Materials

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“…The functions of these nanoscale platforms for cell penetration can be based on nanoarray or individual functional nanostructure. Atomic force microscopy (AFM) or micromanipulators are common tool to assist single nanoprobe devices (e.g., nanowire) to record and regulate the intracellular activities [ 59 , 60 ]. It is meaningful to perform the high spatiotemporal resolution sensing and operating in single cells for exploring the cellular micro/nano-environment, detecting intracellular biochemical indicators, and revealing the intercellular differences at a subcellular/nanoscale resolution.…”

Section: Semi-implantable Device For Cell Applicationsmentioning

confidence: 99%

Semi-Implantable Bioelectronics

et al. 2022

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Developing techniques to effectively and real-time monitor and regulate the interior environment of biological objects is significantly important for many biomedical engineering and scientific applications, including drug delivery, electrophysiological recording and regulation of intracellular activities. Semi-implantable bioelectronics is currently a hot spot in biomedical engineering research area, because it not only meets the increasing technical demands for precise detection or regulation of biological activities, but also provides a desirable platform for externally incorporating complex functionalities and electronic integration. Although there is less definition and summary to distinguish it from the well-reviewed non-invasive bioelectronics and fully implantable bioelectronics, semi-implantable bioelectronics have emerged as highly unique technology to boost the development of biochips and smart wearable device. Here, we reviewed the recent progress in this field and raised the concept of “Semi-implantable bioelectronics”, summarizing the principle and strategies of semi-implantable device for cell applications and in vivo applications, discussing the typical methodologies to access to intracellular environment or in vivo environment, biosafety aspects and typical applications. This review is meaningful for understanding in-depth the design principles, materials fabrication techniques, device integration processes, cell/tissue penetration methodologies, biosafety aspects, and applications strategies that are essential to the development of future minimally invasive bioelectronics.

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“…[ 31–34 ] Cell penetrating platforms can be differentiated by the number of nanoneedles used and the individual functionality of each nanoneedle. Single nanoneedle‐based devices, especially equipped with atomic force microscopy (AFM) or micromanipulators, [ 35,36 ] have long been deployed to insert into cells and probe or manipulate intracellular activities. Unfortunately, these nanoprobes are restricted by their low throughput, and unsuited to treating a large population of cells simultaneously.…”

Section: Introductionmentioning

confidence: 99%

Nanoneedle Platforms: The Many Ways to Pierce the Cell Membrane

He¹,

Hu²,

et al. 2020

Adv Funct Materials

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Establishing techniques to efficiently and nondestructively access the intracellular milieu is essential for many biomedical and scientific applications, ranging from drug delivery, to electrical recording, to biochemical detection. Cell penetration using nanoneedle arrays is currently a research focus area because it not only meets the increasing therapeutic demands of cell modifications and genome editing, but also provides an ideal platform for tracking long-term intracellular information. Although the precise mechanism driving membrane penetration by nanoneedle arrays is still unclear, the low cytotoxicity, wide range of delivered materials, diverse cell type targets, and simple material structures of nanoneedle arrays make these splendid platforms for cell access. Here, the recent progress in this field is reviewed by examining device architectures and discussing mechanisms for nanoneedle penetration, and the major studies demonstrating the most general applicability of nanoneedle arrays, typical methodologies to access the intracellular environment using nanoneedles with spontaneous or assisted penetration modes, as well as biosafety aspects are presented. This review should be valuable for deeply understanding the materials fabrication principles, device designs, cell penetration methodologies, biosafety aspects, and application strategies of nanoneedle array-based systems that are of crucial importance for the development of future practical biomedical platforms.

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The Insertion Mechanism of a Living Cell Determined by the Stress Segmentation Effect of the Cell Membrane during the Tip–Cell Interaction

Cited by 15 publications

References 45 publications

A novel mechanism of inhibiting in-stent restenosis with arsenic trioxide drug-eluting stent: Enhancing contractile phenotype of vascular smooth muscle cells via YAP pathway

A novel mechanism of inhibiting in-stent restenosis with arsenic trioxide drug-eluting stent: Enhancing contractile phenotype of vascular smooth muscle cells via YAP pathway

Semi-Implantable Bioelectronics

Nanoneedle Platforms: The Many Ways to Pierce the Cell Membrane

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