金纳米簇实现高效放射性同位素能量转移用于分子成像。

Efficient Radioisotope Energy Transfer by Gold Nanoclusters for Molecular Imaging.

机构信息

Department of Radiation Oncology, Stanford University, Stanford, CA, 94305, USA.

Stanford Nanocharacterization Laboratory, Stanford University, Stanford, CA, 94305, USA.

出版信息

Small. 2015 Aug 26;11(32):4002-8. doi: 10.1002/smll.201500907. Epub 2015 May 13.

DOI:10.1002/smll.201500907

PMID:25973916

Abstract

Beta-emitting isotopes Fluorine-18 and Yttrium-90 are tested for their potential to stimulate gold nanoclusters conjugated with blood serum proteins (AuNCs). AuNCs excited by either medical radioisotope are found to be highly effective ionizing radiation energy transfer mediators, suitable for in vivo optical imaging. AuNCs synthesized with protein templates convert beta-decaying radioisotope energy into tissue-penetrating optical signals between 620 and 800 nm. Optical signals are not detected from AuNCs incubated with Technetium-99m, a pure gamma emitter that is used as a control. Optical emission from AuNCs is not proportional to Cerenkov radiation, indicating that the energy transfer between the radionuclide and AuNC is only partially mediated by Cerenkov photons. A direct Coulombic interaction is proposed as a novel and significant mechanism of energy transfer between decaying radionuclides and AuNCs.

摘要

β发射同位素氟-18 和钇-90 被测试其刺激与血清蛋白结合的金纳米簇（AuNCs）的潜力。发现由医用放射性同位素激发的 AuNCs 是非常有效的电离辐射能量转移介质，适用于体内光学成像。用蛋白质模板合成的 AuNCs 将β衰变放射性同位素能量转换为组织穿透光学信号在 620nm 和 800nm 之间。从用锝-99m 孵育的 AuNCs 中未检测到光学信号，锝-99m 是一种纯 γ发射体，用作对照。AuNCs 的光发射与切伦科夫辐射不成比例，表明放射性核素与 AuNC 之间的能量转移仅部分由切伦科夫光子介导。提出了一种直接的库仑相互作用作为放射性核素衰变与 AuNCs 之间能量转移的新的和重要的机制。

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金纳米簇实现高效放射性同位素能量转移用于分子成像。

Efficient Radioisotope Energy Transfer by Gold Nanoclusters for Molecular Imaging.

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