基于Kalman滤波和生物传热模型的实时磁共振温度成像精度提升

doi:10.16511/j.cnki.qhdxxb.2019.22.039

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摘要磁共振温度成像能够为肿瘤热疗消融提供实时、全局的温度场监控，是保障消融安全、有效进行的重要技术手段。然而，临床中磁共振温度成像信噪比较低，该现象在选用快速成像序列时尤为严重。针对这一问题，该文提出了基于Kalman滤波和生物传热模型对磁共振温度成像进行滤波的方法。该方法将生物传热模型改写成Kalman滤波方法的状态转移矩阵形式，并将模拟温度和磁共振测温值相结合，以获得具有高精度和高信噪比的估计温度。临床仿真实验表明，该方法能将测温均方根误差从6℃降至2℃；仿体实验表明，测量值与真实值的均方根误差从1.927℃下降到0.735℃，且信噪比显著提升。

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	吴锦超
	仇诗涵
	李沐恒
	韦兴
	陈秉耀
	应葵

关键词 ：核磁共振成像, 磁共振温度成像, 生物传热模型, Kalman滤波

Abstract：Magnetic resonance temperature imaging is an important technique to ensure safe and effective use of tumor hyperthermia ablation by providing real-time, global temperature field monitoring. In clinical trials, however, the signal-to-noise ratio (SNR) of magnetic resonance temperature imaging is relatively low, with the signal quality degrading more with fast imaging sequences. To solve this problem, a bio-heat transfer based Kalman filtering model is developed for magnetic resonance temperature imaging where the bio-heat transfer equation is transformed into the form of a Kalman state transition matrix. Then the simulated temperature is combined with the measured temperature to create an accurate, high SNR estimated temperature. Clinical simulations show that this method reduces the temperature measurement root mean square error from 6℃ to 2℃ and the physical phantom experiment shows that this method reduces the root mean square error of the measured temperature and the true temperature from 1.927℃ to 0.735℃ while significantly improving the SNR.

Key words： magnetic resonance imaging magnetic resonance temperature imaging bio-heat transfer model Kalman filter

收稿日期: 2019-04-10 出版日期: 2020-04-03

基金资助:国家自然科学基金项目（61571257）

通讯作者: 应葵,副教授,E-mail:yingkui@tsinghua.edu.cn E-mail: yingkui@tsinghua.edu.cn

引用本文:

吴锦超, 仇诗涵, 李沐恒, 韦兴, 陈秉耀, 应葵. 基于Kalman滤波和生物传热模型的实时磁共振温度成像精度提升[J]. 清华大学学报（自然科学版）, 2020, 60(4): 334-340.
WU Jinchao, QIU Shihan, LI Muheng, WEI Xing, CHEN Bingyao, YING Kui. Kalman filtering and bio-heat transfer model based real-time MR temperature imaging for increased accuracy. Journal of Tsinghua University(Science and Technology), 2020, 60(4): 334-340.

链接本文:

http://jst.tsinghuajournals.com/CN/10.16511/j.cnki.qhdxxb.2019.22.039 或 http://jst.tsinghuajournals.com/CN/Y2020/V60/I4/334

图１ (网络版彩图)温度矩阵变换成温度列向量示意图

图２ (网络版彩图)矩阵计算过程示意图

图３生物传热模型与磁共振测温 K a l ma n滤波算法

图４ (网络版彩图)临床数据仿真实验示意图

图５ (网络版彩图)相位模拟示意图

图６仿体实验设计图

图７ (网络版彩图)临床数据仿真实验结果对比

图８ S B S方法和 BHT Ｇ K a l ma n方法重建结果与金标准图之间在不同时间帧的 RMS E值

图９ (网络版彩图)仿体实验重建结果对比

图１０ (网络版彩图)仿体实验温度曲线

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