磁共振成像/直线加速器集成

MRI/linac integration.

作者信息

Lagendijk Jan J W, Raaymakers Bas W, Raaijmakers Alexander J E, Overweg Johan, Brown Kevin J, Kerkhof Ellen M, van der Put Richard W, Hårdemark Björn, van Vulpen Marco, van der Heide Uulke A

机构信息

Department of Radiotherapy, University Medical Center Utrecht, Heidelberglaan, The Netherlands.

出版信息

Radiother Oncol. 2008 Jan;86(1):25-9. doi: 10.1016/j.radonc.2007.10.034. Epub 2007 Nov 26.

DOI:10.1016/j.radonc.2007.10.034

PMID:18023488

Abstract

PURPOSE/OBJECTIVES: In radiotherapy the healthy tissue involvement still poses serious dose limitations. This results in sub-optimal tumour dose and complications. Daily image guided radiotherapy (IGRT) is the key development in radiation oncology to solve this problem. MRI yields superb soft-tissue visualization and provides several imaging modalities for identification of movements, function and physiology. Integrating MRI functionality with an accelerator can make these capacities available for high precision, real time IGRT.

DESIGN AND RESULTS

The system being built at the University Medical Center Utrecht is a 1.5T MRI scanner, with diagnostic imaging functionality and quality, integrated with a 6MV radiotherapy accelerator. The realization of a prototype of this hybrid system is a joint effort between the Radiotherapy Department of the University of Utrecht, the Netherlands, Elekta, Crawley, U.K., and Philips Research, Hamburg, Germany. Basically, the design is a 1.5 T Philips Achieva MRI scanner with a Magnex closed bore magnet surrounded by a single energy (6 MV) Elekta accelerator. Monte Carlo simulations are used to investigate the radiation beam properties of the hybrid system, dosimetry equipment and for the construction of patient specific dose deposition kernels in the presence of a magnetic field. The latter are used to evaluate the IMRT capability of the integrated MRI linac.

CONCLUSIONS

A prototype hybrid MRI/linac for on-line MRI guidance of radiotherapy (MRIgRT) is under construction. The aim of the system is to deliver the radiation dose with mm precision based on diagnostic quality MR images.

摘要

目的/目标：在放射治疗中，健康组织的受照情况仍然对剂量构成严重限制。这导致肿瘤剂量欠佳以及出现并发症。每日影像引导放射治疗（IGRT）是放射肿瘤学中解决这一问题的关键进展。磁共振成像（MRI）能产生极佳的软组织可视化效果，并提供多种用于识别运动、功能和生理状况的成像模式。将MRI功能与加速器相结合，可使这些能力用于高精度实时IGRT。

设计与结果

乌得勒支大学医学中心正在构建的系统是一台1.5T MRI扫描仪，具备诊断成像功能和质量，与一台6MV放射治疗加速器集成在一起。这个混合系统原型的实现是荷兰乌得勒支大学放射治疗科、英国克劳利的医科达公司以及德国汉堡的飞利浦研究公司共同努力的结果。基本上，该设计是一台1.5T飞利浦Achieva MRI扫描仪，其带有一个Magnex封闭式磁体，周围环绕着一台单能（6MV）医科达加速器。蒙特卡罗模拟用于研究混合系统的辐射束特性、剂量测定设备，并用于构建存在磁场情况下患者特定的剂量沉积内核。后者用于评估集成MRI直线加速器的调强放射治疗（IMRT）能力。

结论

用于放射治疗在线MRI引导（MRIgRT）的混合MRI/直线加速器原型正在建设中。该系统的目标是基于诊断级质量的MR图像，以毫米精度输送辐射剂量。

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MRI/linac integration.磁共振成像/直线加速器集成

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Dosimetry for the MRI accelerator: the impact of a magnetic field on the response of a Farmer NE2571 ionization chamber.MRI加速器的剂量测定：磁场对Farmer NE2571电离室响应的影响。

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Experimental verification of magnetic field dose effects for the MRI-accelerator.MRI加速器磁场剂量效应的实验验证

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磁共振成像/直线加速器集成

MRI/linac integration.

作者信息

机构信息

出版信息

DESIGN AND RESULTS

CONCLUSIONS

设计与结果

结论

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