Magnetic characterization of superparamagnetic nanoparticles pulled through model membranes.

Biomagnetic Research and Technology Pub Date : 2007-01-04 DOI:10.1186/1477-044X-5-1

Allison L Barnes, Ronald A Wassel, Fadee Mondalek, Kejian Chen, Kenneth J Dormer, Richard D Kopke

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引用次数: 42

Abstract

Background: To quantitatively compare in-vitro and in vivo membrane transport studies of targeted delivery, one needs characterization of the magnetically-induced mobility of superparamagnetic iron oxide nanoparticles (SPION). Flux densities, gradients, and nanoparticle properties were measured in order to quantify the magnetic force on the SPION in both an artificial cochlear round window membrane (RWM) model and the guinea pig RWM.

Methods: Three-dimensional maps were created for flux density and magnetic gradient produced by a 24-well casing of 4.1 kilo-Gauss neodymium-iron-boron (NdFeB) disc magnets. The casing was used to pull SPION through a three-layer cell culture RWM model. Similar maps were created for a 4 inch (10.16 cm) cube 48 MGOe NdFeB magnet used to pull polymeric-nanoparticles through the RWM of anesthetized guinea pigs. Other parameters needed to compute magnetic force were nanoparticle and polymer properties, including average radius, density, magnetic susceptibility, and volume fraction of magnetite.

Results: A minimum force of 5.04 x 10(-16) N was determined to adequately pull nanoparticles through the in-vitro model. For the guinea pig RWM, the magnetic force on the polymeric nanoparticles was 9.69 x 10-20 N. Electron microscopy confirmed the movement of the particles through both RWM models.

Conclusion: As prospective carriers of therapeutic substances, polymers containing superparamagnetic iron oxide nanoparticles were succesfully pulled through the live RWM. The force required to achieve in vivo transport was significantly lower than that required to pull nanoparticles through the in-vitro RWM model. Indeed very little force was required to accomplish measurable delivery of polymeric-SPION composite nanoparticles across the RWM, suggesting that therapeutic delivery to the inner ear by SPION is feasible.

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通过模型膜的超顺磁性纳米颗粒的磁性表征。

背景:为了定量比较体外和体内靶向递送的膜转运研究，需要表征超顺磁性氧化铁纳米颗粒(SPION)的磁诱导迁移性。在人工耳蜗圆窗膜(RWM)模型和豚鼠圆窗膜(RWM)模型中，测量了磁通密度、梯度和纳米粒子特性，以量化SPION上的磁力。方法:绘制24口4.1千高斯钕铁硼(NdFeB)圆盘磁体套管产生的磁密度和磁梯度的三维图。使用套管将SPION通过三层细胞培养RWM模型。一个4英寸(10.16厘米)的立方体48 MGOe钕铁硼磁铁也绘制了类似的图，该磁铁用于将聚合物纳米颗粒通过麻醉豚鼠的RWM。计算磁力所需的其他参数包括纳米粒子和聚合物的性质，包括平均半径、密度、磁化率和磁铁矿的体积分数。结果:确定了5.04 × 10(-16) N的最小力可以使纳米颗粒充分通过体外模型。对于豚鼠RWM，聚合纳米粒子的磁力为9.69 x 10-20 n，电子显微镜通过两种RWM模型证实了粒子的运动。结论:含超顺磁性氧化铁纳米颗粒的聚合物可以成功地通过活的RWM，作为治疗物质的潜在载体。实现体内转运所需的力明显低于通过体外RWM模型所需的力。事实上，聚合物-SPION复合纳米颗粒通过RWM的可测量递送只需要很小的力，这表明SPION向内耳的治疗递送是可行的。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Biomagnetic Research and Technology

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