Characterization of polyethyleneglycol-stabilized, manganese-substituted hydroxylapatite (MnHA-PEG). A potential MR blood pool agent.

Acta radiologica. Supplementum Pub Date : 1997-01-01
K Adzamli, R B Dorshow, M R Hynes, D L Nosco, M D Adams
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Abstract

Purpose: To optimize the performance (or efficacy) of a potential particulate blood pool agent for MR angiography by varying the particle size. The colloidal system under investigation was polyethylene glycol-stabilized manganese-substituted hydroxylapatite (MnHA-PEG).

Material and methods: Several MnHA-PEG formulations were prepared using various length PEGs (MW = 140-2000). Products were characterized in vitro by dynamic light scattering (DLLS), field flow fractionation (FFF), and relaxometry; and in vivo by blood clearance kinetics in rabbits, and by analytical electron microscopy (EM).

Results: The particle size distribution (PSD) consisted only of small particles (approximately 10-nm diameter) when approximately 40 mo1% PEG was used. At approximately 20 mo1% PEG, larger particles (approximately 100 nm), which are aggregates of the small ones, were also present. The water proton relaxation profiles of the particles in plasma were different from that of the free Mn2+. In plasma, the large aggregates were broken down into the smaller particles which were stable. Although the small particles were efficient relaxation enhancing agents, they were cleared from the blood approximately 3 times faster than the approximately 100-nm diameter aggregates, probably as a consequence of leakage into the extravascular space. Variation of PEG size had no effect on particle characteristics or on blood clearance. Analytical EM of rabbit liver specimens indicated some retention of Mn in mitochondria at the time point when Mn content of other subcellular structures returned to baseline.

Conclusion: DLLS and FFF are complementary techniques for sizing particulate MR contrast media. Small MnHA particles are more efficient T1-shortening agents than large ones but they are prone to leakage from the vascular space. Within the MW range explored, the length of PEG molecule had no effect on blood clearance of the MnHA particles. Larger aggregates of MnHA-PEG break down into stable small particles in plasma. Mn clears from the subcellular structures within hepatocytes within 60 min after i.v. MnHA-PEG administration except from the mitochondria in which it appears to accumulate.

聚乙二醇稳定锰取代羟基磷灰石(MnHA-PEG)的表征。一种潜在的MR血池试剂。
目的:通过改变颗粒大小来优化一种潜在的颗粒血池剂用于MR血管造影的性能(或疗效)。所研究的胶体体系是聚乙二醇稳定锰取代羟基磷灰石(MnHA-PEG)。材料和方法:用不同长度的peg(分子量为140-2000)制备了几种MnHA-PEG配方。通过动态光散射(dls)、场流分馏(FFF)和弛缓仪对产物进行体外表征;在家兔体内通过血液清除动力学和分析电子显微镜(EM)检测。结果:当使用约40 mo1% PEG时,粒径分布(PSD)仅由小颗粒(直径约10 nm)组成。在约20mo1% PEG时,也存在较大的颗粒(约100nm),它们是小颗粒的聚集体。等离子体中粒子的水质子弛豫谱与游离的Mn2+不同。在等离子体中,大的聚集体被分解成更小的稳定粒子。虽然小颗粒是有效的松弛增强剂,但它们从血液中清除的速度比直径约100纳米的聚集体快约3倍,这可能是渗漏到血管外空间的结果。PEG大小的变化对颗粒特性和血液清除率没有影响。兔肝标本的分析电镜显示,当其他亚细胞结构的锰含量恢复到基线水平时,线粒体中有一定的锰保留。结论:dls和FFF是颗粒状磁共振造影剂分级的互补技术。小的MnHA颗粒比大的MnHA颗粒是更有效的t1缩短剂,但它们容易从血管间隙渗漏。在所探索的分子量范围内,PEG分子的长度对MnHA颗粒的血液清除率没有影响。较大的MnHA-PEG聚集体在等离子体中分解成稳定的小颗粒。在静脉注射MnHA-PEG后60分钟内,肝细胞内的亚细胞结构中Mn被清除,线粒体中Mn似乎在积聚。
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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