弹性模量的应变速率依赖性揭示纳米银颗粒诱导的细胞毒性

Q1 Engineering

Nanobiomedicine Pub Date : 2015-01-01 DOI:10.5772/61328

M. Caporizzo, Charles M. Roco, M. C. C. Ferrer, Martha E. Grady, Emmabeth Parrish, D. Eckmann, R. Composto

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引用次数: 15

摘要

用原子力显微镜以不同的速率进行力-位移测量，以评估用新型药物载体处理的THP-1细胞中细胞健康和细胞粘弹性之间的相关性。可变压痕率粘弹性分析(VIVA)用于确定已知表现出频率相关刚度的单元的松弛时间。VIVA符合荧光活力测定。这表明右旋糖酐-溶菌酶药物载体具有生物相容性，可以将浓缩的有毒物质(罗丹明或纳米银)递送到THP-1细胞的细胞质中。通过对弹性模量的频率依赖性进行建模，VIVA提供了三个细胞质粘弹性指标:低频模量、高频模量和粘度。罗丹明或银暴露的细胞毒性特征是弹性模量和细胞质粘度的频率无关的两倍增加，而细胞骨架松弛时间保持不变。这与银纳米颗粒已知的毒性机制一致，其中代谢应激导致细胞质刚性增加。可变压痕率粘弹性分析提出了一种简单的方法，以促进细胞之间的自一致比较。这对疾病的早期诊断和治疗至关重要。

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Strain-Rate Dependence of Elastic Modulus Reveals Silver Nanoparticle Induced Cytotoxicity

Force-displacement measurements are taken at different rates with an atomic force microscope to assess the correlation between cell health and cell viscoelasticity in THP-1 cells that have been treated with a novel drug carrier. A variable indentation-rate viscoelastic analysis, VIVA, is employed to identify the relaxation time of the cells that are known to exhibit a frequency dependent stiffness. The VIVA agrees with a fluorescent viability assay. This indicates that dextran-lysozyme drug carriers are biocompatible and deliver concentrated toxic material (rhodamine or silver nanoparticles) to the cytoplasm of THP-1 cells. By modelling the frequency dependence of the elastic modulus, the VIVA provides three metrics of cytoplasmic viscoelasticity: a low frequency modulus, a high frequency modulus and viscosity. The signature of cytotoxicity by rhodamine or silver exposure is a frequency independent twofold increase in the elastic modulus and cytoplasmic viscosity, while the cytoskeletal relaxation time remains unchanged. This is consistent with the known toxic mechanism of silver nanoparticles, where metabolic stress causes an increase in the rigidity of the cytoplasm. A variable indentation-rate viscoelastic analysis is presented as a straightforward method to promote the self-consistent comparison between cells. This is paramount to the development of early diagnosis and treatment of disease.

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来源期刊

Nanobiomedicine Biochemistry, Genetics and Molecular Biology-Biotechnology

CiteScore

6.80

自引率

0.00%

发文量

审稿时长

14 weeks

期刊介绍： Nanobiomedicine is an international, peer-reviewed, open access scientific journal that publishes research in nanotechnology as it interfaces with fundamental studies in biology, as well as its application to the fields of medicine. Nanobiomedicine covers all key aspects of this research field, including, but not limited to, bioengineering, biophysics, physical and biological chemistry, and physiology, as well as nanotechnological applications in diagnostics, therapeutic application, preventive medicine, drug delivery, and monitoring of human disease. Additionally, theoretical and modeling studies covering the nanobiomedicine fields will be considered. All submitted articles considered suitable for Nanobiomedicine are subjected to rigorous peer review to ensure the highest levels of quality. The review process is carried out as quickly as possible to minimize any delays in the online publication of articles. Submissions are encouraged on all topics related to nanobiomedicine, and its clinical applications including but not limited to: Nanoscale-structured biomaterials, Nanoscale bio-devices, Nanoscale imaging, Nanoscale drug delivery, Nanobiotechnology, Nanorobotics, Nanotoxicology, Nanoparticles, Nanocarriers, Nanofluidics, Nanosensors (nanowires, nanophotonics), Nanosurgery (dermatology, gastroenterology, ophthalmology, etc), Nanocarriers commercialization of nanobiomedical technologies, Market trends in the nanobiomedicine space, Ethics and regulatory aspects of nanobiomedicine approval, New perspectives of nanobiomedicine in clinical diagnostics, BioMEMS, Nano-coatings, Plasmonics, Nanoscale visualization.