The careful selection of zwitterionic nanoparticle coating results in rapid and efficient cell labeling for imaging‐based cell tracking

Aggregate Pub Date : 2024-07-09 DOI:10.1002/agt2.609
Nicholas D. Calvert, Luciana Yu, Olivia C. Sehl, Julia J. Gevaert, Natasha N. Knier, Angelie Rivera‐Rodriguez, Clara S. Goulet, Nitara Fernando, Samantha Flood, Carlos M. Rinaldi‐Ramos, Paula J. Foster, Adam J. Shuhendler
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Abstract

The increased clinical application of cell‐based therapies has resulted in a parallel increase in the need for non‐invasive imaging‐based approaches for cell tracking, often through labeling with nanoparticles. An ideal nanoparticle for such applications must be biologically compatible as well as readily internalized by cells to ensure adequate and stable cell loading. Surface coatings have been used to make nanoparticle trackers suitable for these purposes, but those currently employed tend to have cytotoxic effects. Zwitterionic ligands are known to be biocompatible and antifouling; however, head‐to‐head evaluation of specific zwitterionic ligands for cell loading has not yet been explored. Magnetic particle imaging (MPI) detects superparamagnetic iron oxide nanoparticles (SPIONs) using time‐varying magnetic fields. Because MPI can produce high‐contrast, real‐time images with no tissue depth limitation, it is an ideal candidate for in vivo cell tracking. In this work, we have conjugated hard (permanently charged) and soft (pKa‐dependently charged) biomimetic zwitterionic ligands to SPIONs and characterized how these ligands changed SPION physicochemical properties. We have evaluated cellular uptake and subcellular localization between zwitterions, how the improvement in cell uptake generated stronger MPI signal for smaller numbers of cells, and how these cells can be tracked in an animal model with greater sensitivity for longer periods of time. Our best‐performing surface coating afforded high cell loading within 4 h, with full signal retention in vivo over 7 days.

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精心选择的滋养型纳米粒子涂层可实现快速高效的细胞标记,用于基于成像的细胞追踪
随着细胞疗法临床应用的增加,对基于成像的非侵入性细胞跟踪方法的需求也随之增加,这种方法通常是通过纳米粒子标记来实现的。用于此类应用的理想纳米粒子必须与生物相容,并易于被细胞内化,以确保充分和稳定的细胞负载。为了使纳米粒子跟踪器适用于这些用途,人们使用了表面涂层,但目前使用的涂层往往具有细胞毒性作用。众所周知,聚合离子配体具有生物相容性和防污性;然而,目前尚未对用于细胞负载的特定聚合离子配体进行正面评估。磁粉成像(MPI)利用时变磁场检测超顺磁性氧化铁纳米粒子(SPIONs)。由于 MPI 可以生成高对比度的实时图像,且不受组织深度限制,因此是体内细胞追踪的理想选择。在这项工作中,我们将硬性(永久带电)和软性(pKa 依赖性带电)仿生齐聚物配体连接到 SPIONs 上,并描述了这些配体如何改变 SPIONs 的理化特性。我们评估了滋养剂之间的细胞摄取和亚细胞定位情况、细胞摄取的改善如何在细胞数量较少的情况下产生更强的 MPI 信号,以及如何在动物模型中以更高的灵敏度对这些细胞进行更长时间的跟踪。我们性能最好的表面涂层可在 4 小时内实现高细胞负载,并在体内完全保留信号 7 天。
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