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Ligand-Induced Atomically Segregation-Tunable Alloy Nanoprobes for Enhanced Magnetic Resonance Imaging

Zeyu Liang, Shangzhi Xie, Qiyue Wang, Bo Zhang, Lin Xiao, Chenhan Wang, Xun Liu, Ying Chen, Shengfei Yang, Hui Du, Yufan Qian, Daishun Ling, Lian‐Ming Wu, Fangyuan Li

2024ACS Nano19 citationsDOI

Abstract

Bimetallic iron-noble metal alloy nanoparticles have emerged as promising contrast agents for magnetic resonance imaging (MRI) due to their biocompatibility and facile control over the element distribution. However, the inherent surface energy discrepancy between iron and noble metal often leads to Fe atom segregation within the nanoparticle, resulting in limited iron–water molecule interactions and, consequently, diminished relaxometric performance. In this study, we present the development of a class of ligand-induced atomically segregation-tunable alloy nanoprobes (STAN) composed of bimetallic iron–gold nanoparticles. By manipulating the oxidation state of Fe on the particle surface through varying molar ratios of oleic acid and oleylamine ligands, we successfully achieve surface Fe enrichment. Under the application of a 9 T MRI system, the optimized STAN formulation, characterized by a surface Fe content of 60.1 at %, exhibits an impressive r 1 value of 2.28 mM –1 ·s –1, along with a low r 2/ r 1 ratio of 6.2. This exceptional performance allows for the clear visualization of hepatic tumors as small as 0.7 mm in diameter in vivo, highlighting the immense potential of STAN as a next-generation contrast agent for highly sensitive MR imaging.

Topics & Concepts

Materials scienceMagnetic resonance imagingNanotechnologyAlloyLigand (biochemistry)ChemistryMetallurgyRadiologyReceptorMedicineBiochemistryNanoparticle-Based Drug DeliveryNanocluster Synthesis and ApplicationsCharacterization and Applications of Magnetic Nanoparticles
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