Falconieri Alessandro相关文献与解析，生知库

Coppini Allegra, Cappello Valentina, Nasrin Syeda Rubaiya, Falconieri Alessandro, Mualem Oz, Saper Gadiel, Shefi Orit, Hess Henry, Kakugo Akira, Raffa Vittoria

神经科学

发表日期：2026

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The Extremely Low Mechanical Force Generated by Nano-Pulling Induces Global Changes in the Microtubule Network, Nuclear Morphology, and Chromatin Transcription in Neurons.

纳米拉力产生的极低机械力可引起神经元微管网络、核形态和染色质转录的全局变化。

期刊:Small

影响因子:12.1

doi:10.1002/smll.202503011

Falconieri Alessandro, Da Palmata Lorenzo, Cappello Valentina, Schmidt Tiziana Julia Nadjeschda, Folino Pietro, Storti Barbara, Bizzarri Ranieri, Raffa Vittoria

神经科学

发表日期：2025

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Can repetitive mechanical motion cause structural damage to axons?

重复的机械运动会对轴突造成结构性损伤吗？

期刊:Frontiers in Molecular Neuroscience

影响因子:3.8

doi:10.3389/fnmol.2024.1371738

Coppini, Allegra; Falconieri, Alessandro; Mualem, Oz; Nasrin, Syeda Rubaiya; Roudon, Marine; Saper, Gadiel; Hess, Henry; Kakugo, Akira; Raffa, Vittoria; Shefi, Orit

发表日期：2024

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Editorial: Perspectives in neuroscience: mechanical forces for the modulation of axonal mechanics and nerve regeneration

社论：神经科学展望：机械力对轴突力学和神经再生的调节作用

期刊:Frontiers in Molecular Neuroscience

影响因子:3.8

doi:10.3389/fnmol.2024.1453190

Raffa, Vittoria; Shefi, Orit; Falconieri, Alessandro

发表日期：2024

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Manipulation of Axonal Outgrowth via Exogenous Low Forces

利用外源性低力调控轴突生长

期刊:International Journal of Molecular Sciences

影响因子:4.9

doi:10.3390/ijms21218009

De Vincentiis, Sara; Falconieri, Alessandro; Scribano, Vincenzo; Ghignoli, Samuele; Raffa, Vittoria

信号转导

发表日期：2020

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Piconewton Mechanical Forces Promote Neurite Growth.

皮牛顿级机械力促进神经突生长

期刊:Biophysical Journal

影响因子:3.1

doi:10.1016/j.bpj.2018.10.009

Raffa Vittoria, Falcone Francesca, De Vincentiis Sara, Falconieri Alessandro, Calatayud Maria P, Goya Gerardo F, Cuschieri Alfred

神经科学

发表日期：2018

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Molecular resilience of neurons to repetitive mechanical compression.

神经元对重复机械压缩的分子弹性。

The Extremely Low Mechanical Force Generated by Nano-Pulling Induces Global Changes in the Microtubule Network, Nuclear Morphology, and Chromatin Transcription in Neurons.

纳米拉力产生的极低机械力可引起神经元微管网络、核形态和染色质转录的全局变化。

Can repetitive mechanical motion cause structural damage to axons?

重复的机械运动会对轴突造成结构性损伤吗？

Editorial: Perspectives in neuroscience: mechanical forces for the modulation of axonal mechanics and nerve regeneration

社论：神经科学展望：机械力对轴突力学和神经再生的调节作用

Manipulation of Axonal Outgrowth via Exogenous Low Forces

利用外源性低力调控轴突生长

Piconewton Mechanical Forces Promote Neurite Growth.

皮牛顿级机械力促进神经突生长