功能性磁共振成像用钙反应造影剂。

IF 6.1 Q2 CHEMISTRY, PHYSICAL
Austin D C Miller, Harun F Ozbakir, Arnab Mukherjee
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引用次数: 9

摘要

钙离子是伴随神经活动和突触信号传导的关键第二信使之一。因此,生物体内钙波动的动态成像是发现记忆、决定行为和调节情绪状态的神经机制以及这些机制如何被神经系统疾病和脑损伤扰乱的基础技术。虽然光学技术在钙动力学的高分辨率成像方面已经很好地建立起来,但光穿透的物理限制阻碍了它们在完整脊椎动物全脑成像中的应用。与光学不同,磁共振成像(MRI)能够对各种大小的脊椎动物进行无创的大规模成像。这促使了几种传感器的发展,这些传感器利用创新的物理化学机制,使MRI对比对钙的细胞内和细胞外变化敏感。在这里,我们回顾了目前基于mri的钙传感器的最新技术,重点关注传感器性能的基本方面,体内应用以及与灵敏度相关的挑战。我们还强调了报告基因技术和基因传递交叉领域的创新如何为定位基因靶细胞中的钙活性开辟了潜在的机会,补充了小分子探针和纳米颗粒传感器的优势。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Calcium-responsive contrast agents for functional magnetic resonance imaging.

Calcium ions represent one of the key second messengers accompanying neural activity and synaptic signaling. Accordingly, dynamic imaging of calcium fluctuations in living organisms represents a cornerstone technology for discovering neural mechanisms that underlie memory, determine behavior, and modulate emotional states as well as how these mechanisms are perturbed by neurological disease and brain injury. While optical technologies are well established for high resolution imaging of calcium dynamics, physical limits on light penetration hinder their application for whole-brain imaging in intact vertebrates. Unlike optics, magnetic resonance imaging (MRI) enables noninvasive large-scale imaging across vertebrates of all sizes. This has motivated the development of several sensors that leverage innovative physicochemical mechanisms to sensitize MRI contrast to intracellular and extracellular changes in calcium. Here, we review the current state-of-the-art in MRI-based calcium sensors, focusing on fundamental aspects of sensor performance, in vivo applications, and challenges related to sensitivity. We also highlight how innovations at the intersection of reporter gene technology and gene delivery open potential opportunities for mapping calcium activity in genetically targeted cells, complementing the benefits of small molecule probes and nanoparticle sensors.

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