使用 13C 磁共振代谢成像鉴别放射性坏死与脑肿瘤。

Differentiating Radiation Necrosis from Brain Tumor Using Hyperpolarized Carbon-13 MR Metabolic Imaging.

机构信息

Department of Radiology, Chonnam National University, 42 Jaebongro, Donggu, Gwangju, 61469, South Korea.

Department of Radiology, Chonnam National University Hospital, 42 Jaebongro, Donggu, Gwangju, 61469, South Korea.

出版信息

Mol Imaging Biol. 2021 Jun;23(3):417-426. doi: 10.1007/s11307-020-01574-w. Epub 2021 Jan 13.

DOI:10.1007/s11307-020-01574-w

PMID:33442835

Abstract

PURPOSE

Differentiation between radiation-induced necrosis and tumor recurrence is crucial to determine proper management strategies but continues to be one of the central challenges in neuro-oncology. We hypothesized that hyperpolarized C MRI, a unique technique to measure real-time in vivo metabolism, would distinguish radiation necrosis from tumor on the basis of cell-intrinsic metabolic differences. The purpose of this study was to explore the feasibility of using hyperpolarized [1-C]pyruvate for differentiating radiation necrosis from brain tumors.

PROCEDURES

Radiation necrosis was initiated by employing a CT-guided 80-Gy single-dose irradiation of a half cerebrum in mice (n = 7). Intracerebral tumor was modeled with two orthotopic mouse models: GL261 glioma (n = 6) and Lewis lung carcinoma (LLC) metastasis (n = 7). C 3D MR spectroscopic imaging data were acquired following hyperpolarized [1-C]pyruvate injection approximately 89 and 14 days after treatment for irradiated and tumor-bearing mice, respectively. The ratio of lactate to pyruvate (Lac/Pyr), normalized lactate, and pyruvate in contrast-enhancing lesion was compared between the radiation-induced necrosis and brain tumors. Histopathological analysis was performed from resected brains.

RESULTS

Conventional MRI exhibited typical radiographic features of radiation necrosis and brain tumor with large areas of contrast enhancement and T2 hyperintensity in all animals. Normalized lactate in radiation necrosis (0.10) was significantly lower than that in glioma (0.26, P = .004) and LLC metastatic tissue (0.25, P = .00007). Similarly, Lac/Pyr in radiation necrosis (0.18) was significantly lower than that in glioma (0.55, P = .00008) and LLC metastasis (0.46, P = .000008). These results were consistent with histological findings where tumor-bearing brains were highly cellular, while irradiated brains exhibited pathological markers consistent with reparative changes from radiation necrosis.

CONCLUSION

Hyperpolarized C MR metabolic imaging of pyruvate is a noninvasive imaging method that differentiates between radiation necrosis and brain tumors, providing a groundwork for further clinical investigation and translation for the improved management of patients with brain tumors.

摘要

目的

区分放射性坏死和肿瘤复发对于确定适当的治疗策略至关重要，但它仍然是神经肿瘤学的核心挑战之一。我们假设，作为一种独特的测量活体实时代谢的技术，极化 C MRI 可以根据细胞内在的代谢差异来区分放射性坏死和肿瘤。本研究旨在探索使用极化 [1-C] 丙酮酸区分放射性坏死和脑肿瘤的可行性。

方法

通过 CT 引导的 80-Gy 半脑单次照射，在小鼠中引发放射性坏死（n = 7）。颅内肿瘤采用两种原位小鼠模型进行建模：GL261 神经胶质瘤（n = 6）和 Lewis 肺转移癌（n = 7）。在接受治疗后大约 89 天和 14 天，分别对接受极化 [1-C] 丙酮酸注射的放射性坏死和肿瘤荷瘤小鼠进行 C 3D 磁共振波谱成像数据采集。在对比增强病变中，比较了乳酸/丙酮酸（Lac/Pyr）比值、归一化乳酸和丙酮酸。对切除的大脑进行组织病理学分析。

结果

常规 MRI 显示了放射性坏死和脑肿瘤的典型放射学特征，所有动物均有大面积的对比增强和 T2 高信号。放射性坏死中的归一化乳酸（0.10）明显低于神经胶质瘤（0.26，P = 0.004）和 LLC 转移组织（0.25，P = 0.00007）。同样，放射性坏死中的 Lac/Pyr（0.18）明显低于神经胶质瘤（0.55，P = 0.00008）和 LLC 转移（0.46，P = 0.000008）。这些结果与组织学发现一致，即肿瘤负荷大脑高度细胞化，而照射大脑则表现出与放射性坏死修复变化一致的病理标志物。

结论

丙酮酸的极化 C 磁共振代谢成像是非侵入性成像方法，可以区分放射性坏死和脑肿瘤，为进一步的临床研究和转化提供了基础，以改善脑肿瘤患者的治疗效果。

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使用 13C 磁共振代谢成像鉴别放射性坏死与脑肿瘤。

Differentiating Radiation Necrosis from Brain Tumor Using Hyperpolarized Carbon-13 MR Metabolic Imaging.

机构信息

出版信息

PURPOSE

PROCEDURES

RESULTS

CONCLUSION

目的

方法

结果

结论

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