Weldon School of Biomedical Engineering, Purdue University, West Lafayette, IN, USA.
Chemphyschem. 2010 Dec 3;11(17):3664-72. doi: 10.1002/cphc.201000397.
Longitudinal and transverse relaxation times of multicomponent nanoparticle (NP) chains are investigated for their potential use as multifunctional imaging agents in magnetic resonance imaging (MRI). Gold NPs (ca. 5 nm) are arranged linearly along double-stranded DNA, creating gold NP chains. After cutting gold NP chains with restriction enzymes (EcoRI or BamHI), multicomponent NP chains are formed through a ligation reaction with enzyme-cut, superparamagnetic NP chains. We evaluate the changes in relaxation times for different constructs of gold-iron oxide NP chains and gold-cobalt iron oxide NP chains using 300 MHz (1)H NMR. In addition, the mechanism of proton relaxation for multicomponent NP chains is examined. The results indicate that relaxation times are dependent on the one-dimensional structure and the amount of superparamagnetic NP chains present in the multicomponent constructs. Multicomponent NP chains arranged on double-stranded DNA provide a feasible method for fabrication of multifunctional imaging agents that improve relaxation times effectively for MRI applications.
研究了多组分纳米粒子(NP)链的纵向和横向弛豫时间,以将其作为磁共振成像(MRI)中的多功能成像剂使用。金 NPs(约 5nm)沿双链 DNA 线性排列,形成金 NP 链。用限制性内切酶(EcoRI 或 BamHI)切割金 NP 链后,通过酶切的超顺磁 NP 链的连接反应形成多组分 NP 链。我们使用 300MHz(1)H NMR 评估了不同结构的金-氧化铁 NP 链和金-钴氧化铁 NP 链的弛豫时间的变化。此外,还研究了多组分 NP 链质子弛豫的机制。结果表明,弛豫时间取决于一维结构和多组分结构中存在的超顺磁 NP 链的数量。排列在双链 DNA 上的多组分 NP 链为制造多功能成像剂提供了一种可行的方法,可有效提高 MRI 应用中的弛豫时间。