适航性
磁小体
示踪剂
魔术(望远镜)
磁粉成像
化学
磁粉探伤
粒子(生态学)
核磁共振
纳米技术
材料科学
物理
地质学
磁性纳米粒子
磁铁矿
核物理学
古生物学
生物
地图学
生态学
地理
天文
纳米颗粒
作者
Lei Li,Chan F. Zhao,Zhiyuan Zhao,Dong‐Wook Han,Yidong Liao,Yanjun Liu,Sijia Liu,Xiaohua Jia,Jiesheng Tian,Qing Liu,Xin Feng,Jie Tian
出处
期刊:
[Cold Spring Harbor Laboratory]
日期:2024-12-09
标识
DOI:10.1101/2024.12.04.626925
摘要
Abstract Magnetic particle imaging (MPI) enables real-time, sensitive and quantitative visualization of magnetic tracers’ spatial distribution, augmenting the capability of in vivo imaging technologies. Previous tracer studies in MPI have primarily focused on superparamagnetic nanoparticles; however, their non-ideal sigmoidal magnetization response limits the spatial resolution. Here we demonstrate the utilization of magnetically induced magnetosome chain (MAGiC) as a novel superferromagnetic MPI tracer, exhibiting a 25-fold improvement in resolution and a 91-fold enhancement in signal intensity compared to the commercial tracer VivoTrax+™. The spatial resolution of MPI was pushed to an unprecedented 80 μm under a 4 T/m gradient field. Additionally, MAGiC can be precisely controlled using magnetic fields, enabling it to function as a MPI trackable microrobot. We provided a theoretical model elucidating MAGiC’s unique properties, and validated its imaging and actuation performance through phantom studies and in vivo experiments. As a high-performance MPI tracer and magnetic microrobot with exceptional capabilities, MAGiC holds tremendous potential for diverse applications including cell tracking, targeted drug delivery as well as therapeutic interventions.
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