2024年1月18日 (四) 23:02的最新版本

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 = 射频致热 =
-{{文章展开|name=The physics of MRI safety|prefix=磁共振小组/磁共振兼容|toggled=从物理原理出发描述磁共振安全性的综述文章，对理解物理本质比较有帮助。}}
 == 射频致热评估 ==
-{{文章展开|name=A Technique to Evaluate MRI-induced Electric Fields at the Ends of Practical Implanted Lead|prefix=磁共振小组/磁共振兼容|toggled=基于互易定理与惠更斯原理提出一种有效评估植入物金属导线局部感应电场或感应电压新技术，解耦微观尺度金属导线模拟/测量与宏观人体模拟，简化导线MRI感应加热和植入物感应电压估计过程。}}
 === 核磁测温 ===
-{{文章展开|name=Investigation of artifacts and optimization in proton resonance frequency thermometry towards heating risk monitoring of implantable medical devices in magnetic resonance imaging|prefix=磁共振小组/磁共振兼容|toggled=基于PRF的植入物温升的实时监控策略}}
+{{文章展开|name=Investigation of artifacts and optimization in proton resonance frequency thermometry towards heating risk monitoring of implantable medical devices in magnetic resonance imaging|prefix=磁共振小组/磁共振兼容|toggled=基于PRF的植入物温升的实时监控策略|Citation_=4}}
 === 线圈建模 ===
-{{文章展开|name=Constructing a Digital Twin of the Birdcage Coil in an MR Scanner by Map Matching: For Radio Frequency Heating Evaluation of Implantable Medical Devices|prefix=磁共振小组/磁共振兼容|toggled=一种基于MRI系统的简单高效的射频测试环境建模方法}}
+{{文章展开|name=Constructing a Digital Twin of the Birdcage Coil in an MR Scanner by Map Matching: For Radio Frequency Heating Evaluation of Implantable Medical Devices|prefix=磁共振小组/磁共振兼容|toggled=一种基于MRI系统的简单高效的射频测试环境建模方法|Citation_=3}}
 === 传递函数理论 ===
-{{文章展开|name=Calculation of MRI-induced heating of an implanted medical lead wire with an electric field transfer function|prefix=磁共振小组/磁共振兼容|toggled=最早提出传递函数理论的文章，射频热效应评估领域的奠基性工作之一。将“输入”和“响应”解耦开来的思想，提供了一种可行的预测、评估方法。}}
+{{文章展开|name=Calculation of MRI-induced heating of an implanted medical lead wire with an electric field transfer function|prefix=磁共振小组/磁共振兼容|toggled=最早提出传递函数理论的文章，射频热效应评估领域的奠基性工作之一。将“输入”和“响应”解耦开来的思想，提供了一种可行的预测、评估方法。|Citation_=264}}
+{{文章展开|name=A Technique to Evaluate MRI-induced Electric Fields at the Ends of Practical Implanted Lead|prefix=磁共振小组/磁共振兼容|toggled=基于互易定理与惠更斯原理提出一种有效评估植入物金属导线局部感应电场或感应电压新技术，解耦微观尺度金属导线模拟/测量与宏观人体模拟，简化导线MRI感应加热和植入物感应电压估计过程。|Citation_=134}}
 === 传递函数测量 ===
-{{文章展开|name=Experimental setup for transfer function measurement to assess RF heating of medical leads in MRI: Validation in the case of a single wire|prefix=磁共振小组/磁共振兼容|toggled=简单有效的传递函数测量方法}}
+{{文章展开|name=Experimental setup for transfer function measurement to assess RF heating of medical leads in MRI: Validation in the case of a single wire|prefix=磁共振小组/磁共振兼容|toggled=简单有效的传递函数测量方法|Citation_=25}}
+{{文章展开|name=The physics of MRI safety|prefix=磁共振小组/磁共振兼容|toggled=从物理原理出发描述磁共振安全性的综述文章，对理解物理本质比较有帮助。|Citation_=170}}
 = 射频热电磁计算 =
-{{文章展开|name=RF-induced heating in tissue near bilateral DBS implants during MRI at 1.5 T and 3T: The role of surgical lead management|prefix=磁共振小组/磁共振兼容|toggled=研究了真实导线植入路径对射频热的影响}}
+{{文章展开|name=RF-induced heating in tissue near bilateral DBS implants during MRI at 1.5 T and 3T: The role of surgical lead management|prefix=磁共振小组/磁共振兼容|toggled=研究了真实导线植入路径对射频热的影响|Citation_=110}}
 = 梯度感应电压评估与预测 =
-{{文章展开|name=Predicting in vivo MRI Gradient-Field Induced Voltage Levels on Implanted Deep Brain Stimulation Systems Using Neural Networks|prefix=磁共振小组/磁共振兼容|toggled=运用神经网络的方法预测了植入AIMD患者人体的GIV大小}}
+{{文章展开|name=Predicting in vivo MRI Gradient-Field Induced Voltage Levels on Implanted Deep Brain Stimulation Systems Using Neural Networks|prefix=磁共振小组/磁共振兼容|toggled=运用神经网络的方法预测了植入AIMD患者人体的GIV大小|Citation_=4}}
 = 磁共振安全性 =
-{{文章展开|name=MRI-related heating of implants and devices: a review|prefix=磁共振小组/磁共振兼容|toggled=比较新的一篇综述，囊括了磁共振兼容评估中的个方面问题。}}
+{{文章展开|name=MRI-related heating of implants and devices: a review|prefix=磁共振小组/磁共振兼容|toggled=比较新的一篇综述，囊括了磁共振兼容评估中的个方面问题。|Citation_=100}}
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