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大鼠脑中钆金纳米颗粒标记细胞的超高分辨率磁共振显微镜检查。

Ultra-high resolution magnetic resonance microscopy of gadolinium gold nanoparticle-labeled cells in the rat brain.

作者信息

Kisel Alena, Luo Minrui, Bailey Matthew D, Ghuman Harman, Rotz Matthew, Campos Vinícius P, Vieira Marcelo A C, Hitchens T Kevin, Meade Thomas J, Modo Michel

机构信息

Department of Radiology, McGowan Institute for Regenerative Medicine, University of Pittsburgh 3025 East Carson St Pittsburgh Pennsylvania USA

Department of Chemistry Evanston Illinois 60208 USA

出版信息

Chem Sci. 2025 Jun 3. doi: 10.1039/d5sc01588j.

DOI:10.1039/d5sc01588j
PMID:40469767
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12131069/
Abstract

Mapping the distribution of cells within a tissue using MR imaging has remained a significant challenge for the field. Cellular MRI can trace cells within tissue, but typically does not achieve the resolution necessary to define a cell's precise anatomical location. To detect cells with ultra-high resolution MRI, a high relaxivity intracellular contrast agent is required. Localizing this contrast within its biological context also necessitates an isotropic spatial resolution corresponding to the size of a cell's cytoplasm (∼20 μm) to place it within its biological context. We here demonstrate that gadolinium gold nanoparticles (GdAuNP) induce a high T-weighted cellular MRI contrast at ultra-high magnetic fields (9.4 T, and 11.7 T) that affords labelled cell detection at very high resolutions (150, 100, 50, and 20 μm). A 20 μm 3D gradient-echo image (400 minutes scan) combined with MR image denoising robustly visualized the distribution of labeled cells in the rat brain. Signal averaging (NA = 5) also consistently afforded the detection of labeled cells. Positive T-weighted contrast was confirmed to be caused by GdAuNP using histology. Immunohistochemistry confirmed the presence of GdAuNP almost entirely inside cells, primarily those of the neuronal lineage. Histology verified that the MR images accurately visualized individual cells' distribution within their anatomical context. Cellular resolution MRI of GdAuNP-labeled cells hence affords new avenues to investigate how individual cells contribute to the development, repair, and regeneration of tissues.

摘要

利用磁共振成像(MR成像)来描绘组织内细胞的分布,一直是该领域的一项重大挑战。细胞磁共振成像能够追踪组织内的细胞,但通常无法达到确定细胞精确解剖位置所需的分辨率。为了用超高分辨率磁共振成像检测细胞,需要一种高弛豫率的细胞内造影剂。在其生物学环境中定位这种造影剂还需要与细胞细胞质大小(约20μm)相对应的各向同性空间分辨率,以便将其置于生物学环境中。我们在此证明,钆金纳米颗粒(GdAuNP)在超高磁场(9.4T和11.7T)下能诱导出高T加权细胞磁共振成像对比度,从而能够在非常高的分辨率(150、100、50和20μm)下检测标记细胞。结合磁共振图像去噪的20μm三维梯度回波图像(400分钟扫描)能可靠地显示大鼠脑中标记细胞的分布。信号平均(NA = 5)也始终能够检测到标记细胞。通过组织学证实,正T加权对比度是由GdAuNP引起的。免疫组织化学证实GdAuNP几乎完全存在于细胞内,主要是神经元谱系的细胞。组织学验证了磁共振图像能够准确显示单个细胞在其解剖环境中的分布。因此,GdAuNP标记细胞的细胞分辨率磁共振成像为研究单个细胞如何促进组织的发育、修复和再生提供了新途径。

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