用于图像引导放射治疗的四维图像配准

Four-dimensional image registration for image-guided radiotherapy.

作者信息

Schreibmann Eduard, Thorndyke Brian, Li Tianfang, Wang Jing, Xing Lei

机构信息

Department of Radiation Oncology, Stanford University School of Medicine, Stanford, CA 94305-5847, USA.

出版信息

Int J Radiat Oncol Biol Phys. 2008 Jun 1;71(2):578-86. doi: 10.1016/j.ijrobp.2008.01.042. Epub 2008 Apr 18.

DOI:10.1016/j.ijrobp.2008.01.042

PMID:18374499

Abstract

PURPOSE

Newly emerged four-dimensional (4D) imaging techniques such as 4D-computed tomography (CT), 4D-cone beam CT, 4D-magnetic resonance imaging, and 4D-positron emission tomography are effective tools to reveal the spatiotemporal details of patients' anatomy. To use the 4D data acquired under different conditions or using different modalities, an algorithm for registering 4D images must be in place. We developed an automated 4D-4D registration method to take advantage of 4D information.

METHODS AND MATERIALS

We used 4D-4D matching to find the appropriate three-dimensional anatomy in the fixed image for each phase of the moving image and spatially register them. A search algorithm was implemented to simultaneously find the best phase and spatial match of two 4D inputs. An interpolation scheme capable of deriving an image set based on temporally adjacent three-dimensional data sets was developed to deal with the situation in which the discrete temporal points of the two inputs do not coincide or correspond.

RESULTS

In a phantom study, our technique was able to reproduce the known "ground truth" with high spatial fidelity. The technique regenerated all deliberately introduced "missing" three-dimensional images at different phases of the input using temporal interpolation. In the registration of gated-magnetic resonance imaging and 4D-CT, the algorithm was able to select the appropriate CT phase. The technique was also able to register 4D-CT with 4D-cone beam CT and two 4D-CT scans acquired at different times. A spatial accuracy of <3 mm was achieved in 98% of voxels in all cases.

CONCLUSION

Automated 4D-4D registration can find the best possible spatiotemporal match between two 4D data sets and is useful for image-guided radiotherapy applications.

摘要

目的

新出现的四维（4D）成像技术，如4D计算机断层扫描（CT）、4D锥形束CT、4D磁共振成像和4D正电子发射断层扫描，是揭示患者解剖结构时空细节的有效工具。为了使用在不同条件下或使用不同模态获取的4D数据，必须有一个用于配准4D图像的算法。我们开发了一种自动4D-4D配准方法以利用4D信息。

方法和材料

我们使用4D-4D匹配来为运动图像的每个阶段在固定图像中找到合适的三维解剖结构，并在空间上对它们进行配准。实施了一种搜索算法以同时找到两个4D输入的最佳相位和空间匹配。开发了一种能够基于时间上相邻的三维数据集导出图像集的插值方案，以处理两个输入的离散时间点不一致或不对应的情况。

结果

在体模研究中，我们的技术能够以高空间保真度再现已知的“真实情况”。该技术使用时间插值在输入的不同阶段重新生成了所有故意引入的“缺失”三维图像。在门控磁共振成像和4D-CT的配准中，该算法能够选择合适的CT相位。该技术还能够将4D-CT与4D锥形束CT以及在不同时间获取的两次4D-CT扫描进行配准。在所有情况下，98%的体素实现了<3 mm的空间精度。

结论

自动4D-4D配准可以找到两个4D数据集之间尽可能好的时空匹配，并且对图像引导放射治疗应用很有用。

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用于图像引导放射治疗的四维图像配准

Four-dimensional image registration for image-guided radiotherapy.

作者信息

机构信息

出版信息

PURPOSE

METHODS AND MATERIALS

RESULTS

CONCLUSION

目的

方法和材料

结果

结论

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