可弯曲纳米线提高了液体血流中细菌的捕获效率。

Bacterial capture efficiency in fluid bloodstream improved by bendable nanowires.

作者信息

Liu Lizhi, Chen Sheng, Xue Zhenjie, Zhang Zhen, Qiao Xuezhi, Nie Zongxiu, Han Dong, Wang Jianlong, Wang Tie

机构信息

Beijing National Laboratory for Molecular Sciences, Key Laboratory of Analytical Chemistry for Living Biosystems, Institute of Chemistry, Chinese Academy of Sciences, 100190, Beijing, China.

University of Chinese Academy of Sciences, 100049, Beijing, China.

出版信息

Nat Commun. 2018 Feb 6;9(1):444. doi: 10.1038/s41467-018-02879-9.

DOI:10.1038/s41467-018-02879-9

PMID:29410412

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5802748/

Abstract

Bacterial infectious diseases, such as sepsis, can lead to impaired function in the lungs, kidneys, and other vital organs. Although established technologies have been designed for the extracorporeal removal of bacteria, a high flow velocity of the true bloodstream might result in low capture efficiency and prevent the realization of their full clinical potential. Here, we develop a dialyzer made by three-dimensional carbon foam pre-grafted with nanowires to isolate bacteria from unprocessed blood. The tip region of polycrystalline nanowires is bent readily to form three-dimensional nanoclaws when dragged by the molecular force of ligand-receptor, because of a decreasing Young's moduli from the bottom to the tip. The bacterial capture efficiency was improved from ~10% on carbon foam and ~40% on unbendable single-crystalline nanowires/carbon foam to 97% on bendable polycrystalline nanowires/carbon foam in a fluid bloodstream of 10 cm s velocity.

摘要

细菌性传染病，如败血症，可导致肺、肾和其他重要器官功能受损。尽管已经设计出了用于体外清除细菌的现有技术，但真实血流的高流速可能会导致捕获效率低下，并阻碍其全部临床潜力的实现。在此，我们开发了一种由预接枝纳米线的三维碳泡沫制成的透析器，用于从未经处理的血液中分离细菌。由于从底部到尖端杨氏模量降低，多晶纳米线的尖端区域在被配体-受体的分子力拖动时很容易弯曲，形成三维纳米爪。在流速为10厘米/秒的流体血流中，细菌捕获效率从碳泡沫上的约10%和不可弯曲的单晶纳米线/碳泡沫上的约40%提高到了可弯曲的多晶纳米线/碳泡沫上的97%。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/b7ff/5802748/13e974015dc8/41467_2018_2879_Fig1_HTML.jpg

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可弯曲纳米线提高了液体血流中细菌的捕获效率。

Bacterial capture efficiency in fluid bloodstream improved by bendable nanowires.

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