在磁性纳米粒子的加热和成像中考虑生物聚集。

Michael L Etheridge, Katie R Hurley, Jinjin Zhang, Seongho Jeon, Hattie L Ring, Christopher Hogan, Christy L Haynes, Michael Garwood, John C Bischof
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引用次数: 0

摘要

众所周知,纳米粒子在生物学和医学中的应用会产生聚集现象;然而,纳米粒子的表征通常是在分散良好的水性条件下进行的。在这里,我们系统地描述了聚集对氧化铁纳米粒子(IONPs)在非理想生物系统中交变磁场诱导加热和磁共振(MR)成像性能的影响。具体来说,我们研究了在磷酸盐缓冲盐水和胎牛血清悬浮液以及凝胶和细胞中,由 ~10 nm 主颗粒组成但聚合体流体力学尺寸从 50 nm 到 700 nm 不等的 IONP 聚合体的行为。我们发现,与聚集程度相关的加热效果最多可降低 50%。为了量化聚集体形态,我们结合使用了流体力学半径分布、固有粘度和电子显微镜测量方法,将聚集体描述为分形尺寸在 1.8-2.0 范围内的准分形实体。重要的是,我们能够将观察到的磁场诱导加热的减少与核磁共振成像中纵向弛豫速率(R1)的相应减少联系起来,而与聚集的程度无关。最后,我们展示了这种强大的新成像方法在体内的原理性应用,为预测临床癌症热疗中的加热情况提供了重要工具。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Accounting for biological aggregation in heating and imaging of magnetic nanoparticles.

Accounting for biological aggregation in heating and imaging of magnetic nanoparticles.

Accounting for biological aggregation in heating and imaging of magnetic nanoparticles.

Accounting for biological aggregation in heating and imaging of magnetic nanoparticles.

Aggregation is a known consequence of nanoparticle use in biology and medicine; however, nanoparticle characterization is typically performed under the pretext of well-dispersed, aqueous conditions. Here, we systematically characterize the effects of aggregation on the alternating magnetic field induced heating and magnetic resonance (MR) imaging performance of iron oxide nanoparticles (IONPs) in non-ideal biological systems. Specifically, the behavior of IONP aggregates composed of ~10 nm primary particles, but with aggregate hydrodynamic sizes ranging from 50 nm to 700 nm, was characterized in phosphate buffered saline and fetal bovine serum suspensions, as well as in gels and cells. We demonstrate up to a 50% reduction in heating, linked to the extent of aggregation. To quantify aggregate morphology, we used a combination of hydrodynamic radii distribution, intrinsic viscosity, and electron microscopy measurements to describe the aggregates as quasifractal entities with fractal dimensions in the 1.8-2.0 range. Importantly, we are able to correlate the observed decrease in magnetic field induced heating with a corresponding decrease in longitudinal relaxation rate (R1) in MR imaging, irrespective of the extent of aggregation. Finally, we show in vivo proof-of-principle use of this powerful new imaging method, providing a critical tool for predicting heating in clinical cancer hyperthermia.

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来源期刊
TECHNOLOGY
TECHNOLOGY ENGINEERING, MULTIDISCIPLINARY-
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