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采用基于分形的定量分析的 7T 三维磁化率加权成像对脑胶质瘤分级。

Three-dimensional susceptibility-weighted imaging at 7 T using fractal-based quantitative analysis to grade gliomas.

机构信息

Center for Anatomy and Cell Biology, Department of Systematic Anatomy, Medical University of Vienna, Vienna, Austria.

出版信息

Neuroradiology. 2013 Jan;55(1):35-40. doi: 10.1007/s00234-012-1081-1. Epub 2012 Aug 18.

DOI:10.1007/s00234-012-1081-1
PMID:22903580
Abstract

INTRODUCTION

Susceptibility-weighted imaging (SWI) with high- and ultra-high-field magnetic resonance is a very helpful tool for evaluating brain gliomas and intratumoral structures, including microvasculature. Here, we test whether objective quantification of intratumoral SWI patterns by applying fractal analysis can offer reliable indexes capable of differentiating glial tumor grades.

METHODS

Thirty-six patients affected by brain gliomas (grades II-IV, according to the WHO classification system) underwent MRI at 7 T using a SWI protocol. All images were collected and analyzed by applying a computer-aided fractal image analysis, which applies the fractal dimension as a measure of geometrical complexity of intratumoral SWI patterns. The results were subsequently statistically correlated to the histopathological tumor grade.

RESULTS

The mean value of the fractal dimension of the intratumoral SWI patterns was 2.086 ± 0.413. We found a trend of higher fractal dimension values in groups of higher histologic grade. The values ranged from a mean value of 1.682 ± 0.278 for grade II gliomas to 2.247 ± 0.358 for grade IV gliomas (p = 0.013); there was an overall statistically significant difference between histopathological groups.

CONCLUSION

The present study confirms that SWI at 7 T is a useful method for detecting intratumoral vascular architecture of brain gliomas and that SWI pattern quantification by means of fractal dimension offers a potential objective morphometric image biomarker of tumor grade.

摘要

简介

高场和超高场磁共振的磁敏感加权成像(SWI)是评估脑胶质瘤和肿瘤内结构(包括微血管)的非常有用的工具。在这里,我们通过应用分形分析来测试对肿瘤内 SWI 模式的客观定量是否可以提供可靠的指标,以区分胶质瘤的等级。

方法

36 名患有脑胶质瘤(根据世界卫生组织分类系统为 II-IV 级)的患者在 7T 磁共振上进行了 SWI 检查。所有图像均通过计算机辅助分形图像分析进行采集和分析,该分析应用分形维数作为肿瘤内 SWI 模式的几何复杂性的度量。结果随后与组织病理学肿瘤分级进行统计学相关。

结果

肿瘤内 SWI 模式的分形维数平均值为 2.086±0.413。我们发现分形维数值在较高组织学分级组中呈上升趋势。值范围从 II 级胶质瘤的平均 1.682±0.278 到 IV 级胶质瘤的 2.247±0.358(p=0.013);组织病理学组之间存在总体统计学上的显著差异。

结论

本研究证实,7T 的 SWI 是检测脑胶质瘤肿瘤内血管结构的有用方法,并且通过分形维数对 SWI 模式进行定量提供了肿瘤分级的潜在客观形态计量学图像生物标志物。

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