使用(64)Cu 标记的纤维连接蛋白结构域与 EGFR 过表达肿瘤异种移植物:分子成像。
Use of (64)Cu-labeled fibronectin domain with EGFR-overexpressing tumor xenograft: molecular imaging.
机构信息
Department of Radiology and Molecular Imaging Program, Stanford University, Stanford, CA 94305, USA.
出版信息
Radiology. 2012 Apr;263(1):179-88. doi: 10.1148/radiol.12111504. Epub 2012 Feb 17.
PURPOSE
To assess the ability of an engineered epidermal growth factor receptor (EGFR)-binding fibronectin domain to serve as a positron emission tomographic (PET) probe for molecular imaging of EGFR in a xenograft mouse model.
MATERIALS AND METHODS
An EGFR-binding fibronectin domain (fibronectin abbreviated to Fn when bound) was site-specifically labeled with copper 64 ((64)Cu) (8 MBq/nmol). Copper 64-Fn binding was tested in cell cultures with varying EGFR expression. Stability in human and mouse serum was measured in vitro. Animal experiments were approved by the Stanford University Institutional Animal Care and Use Committee. Copper 64-Fn (approximately 2 MBq) was used for PET in mice (n = 5) bearing EGFR-overexpressing xenografted tumors (approximately 5-10 mm in diameter). Results of tomography were compared with those of ex vivo gamma counting of dissected tissues. Statistical analysis was performed with t tests and adjustment for multiple comparisons.
RESULTS
Copper 64-Fn exhibited EGFR-dependent binding to multiple cell lines in culture. The tracer was stable for 24 hours in human and mouse serum at 37°C. The tracer exhibited good tumor localization (3.4% injected dose [ID]/g ± 1.0 [standard deviation] at 1 hour), retention (2.7% ID/g ± 0.6 at 24 hours), and specificity (8.6 ± 3.0 tumor-to-muscle ratio, 8.9 ± 4.7 tumor-to-blood ratio at 1 hour). Specific targeting was verified with low localization to low-expressing MDA-MB-435 tumors (0.7% ID/g ± 0.8 at 1 hour, P = .018); specificity was further demonstrated, as a nonbinding control fibronectin had low localization to EGFR-overexpressing xenografts (0.8% ID/g ± 0.2 at 1 hour, P = .013).
CONCLUSION
The stability, low background, and target-specific tumor uptake and retention of the engineered fibronectin domain make it a promising EGFR molecular imaging agent. More broadly, it validates the fibronectin domain as a potential scaffold for a generation of various molecular imaging agents.
目的
评估一种工程化的表皮生长因子受体(EGFR)结合型纤维连接蛋白结构域作为正电子发射断层扫描(PET)探针,用于异种移植小鼠模型中 EGFR 的分子成像。
材料与方法
将 EGFR 结合型纤维连接蛋白结构域(与 EGFR 结合时简写为 Fn)进行特异性放射性标记,使用铜 64(64Cu)(8MBq/nmol)。在具有不同 EGFR 表达水平的细胞培养物中测试铜 64-Fn 的结合情况。在体外测量人血清和小鼠血清中的稳定性。动物实验获得斯坦福大学机构动物护理和使用委员会的批准。使用约 2MBq 的铜 64-Fn (n=5)进行 EGFR 过表达异种移植肿瘤(直径约 5-10mm)的 PET。将断层扫描结果与解剖组织的体外伽马计数结果进行比较。使用 t 检验和多重比较调整进行统计分析。
结果
铜 64-Fn 在多种培养的细胞系中表现出 EGFR 依赖性结合。在 37°C 下,该示踪剂在人血清和小鼠血清中 24 小时内稳定。该示踪剂具有良好的肿瘤定位(1 小时时为 3.4%注入剂量[ID]/g±1.0[标准差])、保留率(24 小时时为 2.7%ID/g±0.6)和特异性(1 小时时肿瘤与肌肉的比值为 8.6±3.0,肿瘤与血液的比值为 8.9±4.7)。通过低表达 MDA-MB-435 肿瘤的低定位(1 小时时为 0.7%ID/g±0.8,P=0.018)验证了特异性靶向,非结合对照纤维连接蛋白对 EGFR 过表达异种移植物的低定位进一步证实了这一点(1 小时时为 0.8%ID/g±0.2,P=0.013)。
结论
该工程化纤维连接蛋白结构域的稳定性、低背景以及靶特异性肿瘤摄取和保留使其成为一种很有前途的 EGFR 分子成像剂。更广泛地说,它验证了纤维连接蛋白结构域作为多种分子成像剂的潜在支架。
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