Longitudinal Magnetic Resonance Imaging Tracking of Transplanted Neural Progenitor Cells in the Spinal Cord Utilizing the Bright-Ferritin Mechanism.

IF 5.4 2区 医学 Q1 CELL & TISSUE ENGINEERING
Zixiang Luo, Keyu Zhuang, Seong Jun Kim, Kyle D W Vollett, Zijian Lou, Jian Wang, Hai-Ying Mary Cheng, Mohamad Khazaei, Michael G Fehlings, Hai-Ling Margaret Cheng
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引用次数: 0

Abstract

Human neural progenitor cells (hNPCs) hold promise for treating spinal cord injury. Studies to date have focused on improving their regenerative potential and therapeutic effect. Equally important is ensuring successful delivery and engraftment of hNPCs at the injury site. Unfortunately, no current imaging solution for cell tracking is compatible with long-term monitoring in vivo. The objective of this study was to apply a novel bright-ferritin magnetic resonance imaging (MRI) mechanism to track hNPC transplants longitudinally and on demand in the rat spinal cord. We genetically modified hNPCs to stably overexpress human ferritin. Ferritin-overexpressing (FT) hNPCs labeled with 0.2 mM manganese provided significant T1-induced bright contrast on in vitro MRI, with no adverse effect on cell viability, morphology, proliferation, and differentiation. In vivo, 2 M cells were injected into the cervical spinal cord of Rowett nude rats. MRI employed T1-weighted acquisitions and T1 mapping on a 3 T scanner. Conventional short-term cell tracking was performed using exogenous Mn labeling prior to cell transplantation, which displayed transient bright contrast on MRI 1 day after cell transplantation and disappeared after 1 week. In contrast, long-term cell tracking using bright-ferritin allowed on-demand signal recall upon Mn supplementation and precise visualization of the surviving hNPC graft. In fact, this new cell tracking technology identified 7 weeks post-transplantation as the timepoint by which substantial hNPC integration occurred. Spatial distribution of hNPCs on MRI matched that on histology. In summary, bright-ferritin provides the first demonstration of long-term, on-demand, high-resolution, and specific tracking of hNPCs in the rat spinal cord.

利用Bright-Ferritin机制对脊髓中移植的神经祖细胞进行纵向磁共振成像追踪
人类神经祖细胞(hNPCs)有望治疗脊髓损伤。迄今为止的研究主要集中在提高其再生潜力和治疗效果上。同样重要的是确保 hNPCs 在损伤部位的成功输送和移植。遗憾的是,目前用于细胞追踪的成像解决方案都不适合在体内进行长期监测。本研究的目的是应用一种新型的明亮铁蛋白磁共振成像(MRI)机制,在大鼠脊髓中按需纵向追踪 hNPC 移植。我们对 hNPC 进行了基因改造,使其稳定地过表达人类铁蛋白。用 0.2 mM 锰标记的铁蛋白过表达(FT)hNPC 在体外磁共振成像中提供了显著的 T1 诱导亮对比度,对细胞活力、形态、增殖和分化没有不良影响。在体内,将 2 M 细胞注入 Rowett 裸鼠的颈脊髓。核磁共振成像采用 3 T 扫描仪进行 T1 加权采集和 T1 映射。传统的短期细胞追踪是在细胞移植前使用外源锰标记进行的,细胞移植后 1 天在核磁共振成像上显示一过性明亮对比,1 周后消失。相比之下,使用明亮铁蛋白进行长期细胞追踪可在补充锰后按需恢复信号,并精确观察存活的 hNPC 移植。事实上,这种新的细胞追踪技术将移植后 7 周确定为 hNPC 发生实质性整合的时间点。核磁共振成像上的 hNPC 空间分布与组织学上的分布一致。总之,明亮铁蛋白首次展示了对大鼠脊髓中hNPC的长期、按需、高分辨率和特异性追踪。
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来源期刊
Stem Cells Translational Medicine
Stem Cells Translational Medicine CELL & TISSUE ENGINEERING-
CiteScore
12.90
自引率
3.30%
发文量
140
审稿时长
6-12 weeks
期刊介绍: STEM CELLS Translational Medicine is a monthly, peer-reviewed, largely online, open access journal. STEM CELLS Translational Medicine works to advance the utilization of cells for clinical therapy. By bridging stem cell molecular and biological research and helping speed translations of emerging lab discoveries into clinical trials, STEM CELLS Translational Medicine will help move applications of these critical investigations closer to accepted best patient practices and ultimately improve outcomes. The journal encourages original research articles and concise reviews describing laboratory investigations of stem cells, including their characterization and manipulation, and the translation of their clinical aspects of from the bench to patient care. STEM CELLS Translational Medicine covers all aspects of translational cell studies, including bench research, first-in-human case studies, and relevant clinical trials.
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