厦门大学电子科学与技术学院导师介绍：蔡淑惠

  姓名：蔡淑惠
  职称、职位：教授、博导，电子科学系副系主任
  邮箱：shcai（AT）xmu.edu.cn
  电话：0592-2180839
  办公地点：物理大楼345
  学历：
  福州大学理学学士，物理化学专业；
  中国科学院福建物质结构研究所理学博士，物理化学专业。
  研究方向：
  核磁共振新技术及其应用
  主讲课程：
  文献信息检索与科技写作
  核磁共振基础（研究生课）
  成果奖励：
  郭岗，陈忠，蔡淑惠，杨永贵，蔡聪波. 慢性脑血管功能不全的MRI研究. 福建省科学技术进步奖三等奖，2012.
  郭岗，陈忠，蔡淑惠，杨永贵，蔡聪波，朱柳红. 慢性脑血管功能不全的MRI研究. 厦门市科学技术进步奖三等奖，2012.
  杨天和，陈忠，蔡淑惠，王馨，蔡聪波，林建忠. 医用全身扩散加权成像及其在肿瘤转移灶诊断中的应用. 福建省科学技术进步奖二等奖，2011.
  杨天和，陈忠，蔡淑惠，王馨，蔡聪波，林建忠. 医用全身扩散加权成像及其在肿瘤转移灶诊断中的应用. 厦门市科学技术进步奖一等奖，2010.
  福建省三八红旗手，2010.
  谢狄霖，陈忠，邓思珊，蔡淑惠，陈志伟. 核磁共振光谱技术应用于医药学研究. 福建省科学技术奖三等奖，2008.
  第十四届福建运盛青年科技奖，2007.
  第八届福建青年科技奖，2006.
  教育部新世纪优秀人才，2005.
  陈忠，蔡淑惠，钟健晖，万惠霖. 核磁共振新技术及其在化学和医学成像中的应用. 福建省科学技术奖二等奖，2003.
  课题项目：
  利用时空编码获得不均匀磁场下高质量单扫描MRI图像新方法，国家自然科学基金面上项目，2015.1-2018.12，主持.
  适用于自由呼吸状态下肝癌检查的时空编码磁敏感加权成像新技术开发，福建省科技计划项目，2016.4-2019.3，主持.
  代表作：
  论文
  [1]Chen L, Cai CB, Yang TH, Lin JZ, Cai SH*, Zhang JX*, Chen Z, 2017. Changes in brain iron concentration after exposure to high-altitude hypoxia measured by quantitative susceptibility mapping. NeuroImage, 147:488-499.
  [2]Huang JP, Zhang M, Lu JH, Cai CB, Cai SH*, 2017. A fast chemical exchange saturation transfer imaging scheme based on single-shot spatiotemporal encoding. Magnetic Resonance in Medicine, 77(5): 1786-1796.
  [3]Cai CB, Zeng YQ, Zhuang YC, Cai SH, Chen L, Ding XH, Bao LJ, Zhong JH*, Chen Z, 2017. Single-shot T2 mapping through OverLapping-Echo Detachment (OLED) Planar Imaging.IEEE Transactionson Biomedical Engineering, DOI:10.1109/TBME.2017.2661840.
  [4]Lu J, Shi YY, Cai SH*, Feng JH*, 2017. Metabolic responses of Haliotis diversicolor to Vibrio parahaemolyticus infection. Fish &Shellfish Immunology, 60:265-274.
  [5]Lu J, Feng JH*, Cai SH*, Chen Z, 2017. Metabolomic responses of Haliotis diversicolor to organotin compounds. Chemosphere, 168:860-869.
  [6]Zhao YR, Chen H, Feng JH*, Chen ZW, Cai SH*, 2017. 1H NMR-based compositional identification of different powdered infantformulas. Food Chemistry, 230:164-173.
  [7]Ye QM, Chen L, Qiu WQ, Lin LJ, Sun HJ, Cai SH, Wei ZL, Chen Z*, 2017. Accelerating two-dimensional nuclear magnetic resonance correlation spectroscopy via selective coherence transfer. The Journal of Chemical Physics, 146:014202.
  [8]Wei ZL#, Yang J#, Chen YH, Chen L, Cao SH, Cai SH, Lin YQ*, Chen Z*, 2016. Ultrafast multidimensional nuclear magnetic resonance technique: a proof of concept based on inverse-k-space for convenient and efficient performance. Applied Physics Letters, 108:084102.
  [9]Huang YQ, Lin YY, Cai SH, Yang Y, Sun HJ, Lin YQ*, Chen Z*, 2016. High-resolution nuclear magnetic resonance measurements in inhomogeneous magnetic fields: a fast two-dimensional J-resolved experiment. Journal of Chemical Physics, 144:104202.
  [10]Huang YQ*, Wang KY, Lai WN, Tan CH, Chen S, Cai SH, Chen Z, 2016. A 2D proton J-resolved NMR method for direct measurements on heterogeneous foods. Food Research International, 80:70-77.
  [11]Zhang T, Chen L, Huang JP, Li J, Cai SH*, Cai CB*, Chen Z, 2016. Ultrafast multi-slice spatiotemporally encoded MRI with slice-selectivedimension segmented. Journal of Magnetic Resonance, 269:138-145.
  [12]Chen L, Huang JP, Zhang T, Li J, Cai CB*, Cai SH*, 2016. Variable density sampling and non-Cartesian super-resolvedreconstruction for spatiotemporally encoded single-shot MRI. Journal of Magnetic Resonance, 272:1-9.
  [13]Lu J, Shi YY, Wang SH, Chen H, Cai SH*, Feng JH*, 2016. NMR-based metabolomic analysis of Haliotis diversicolor exposed tothermal and hypoxic stresses. Science of the Total Environment, 545-546:280-288.
  [14]Lu JH, Zhou JY, Cai CB, Cai SH*, Chen Z, 2015. Observation of true and pseudo NOE signals using CEST-MRI and CEST-MRS sequences with and without lipid suppression. Magnetic Resonance in Medicine, 73(4):1615-1622.
  [15]Chen L, Li J, Zhang M, Cai SH*, Zhang T, Cai CB*, Chen Z, 2015. Super-resolvedenhancing and edge deghosting (SEED) for spatiotemporally encoded single-shot MRI. Medical Image Analysis, 23:1-14.
  [16]Li J, Chen L, Cai SH*, Cai CB*, Zhong JH, Chen Z, 2015. Imaging with referenceless distortion correction and flexible regions of interest using single-shot biaxial spatiotemporally encoded MRI. NeuroImage, 105:93-111.
  [17]Huang YQ, Zhang ZY, Chen H, Feng JH, Cai SH, Chen Z*, 2015. A high-resolution 2D J-resolved NMR detection technique for metabolite analyses of biological samples. Scientific Reports, 5:8390.
  [18]Wei ZL, Lin LJ, Ye QM, Li J, Cai SH, Chen Z*, 2015. Discrete decoding based ultrafast multidimensional nuclear magneticresonance spectroscopy. Journal of Chemical Physics, 143:024201.
  [19]Chen Z*, Cai SH, Huang YQ, Lin YL, 2015. High-resolutionNMRspectroscopyininhomogeneousfields. Progress in Nuclear Magnetic Resonance Spectroscopy, 90-91:1-31.
  [20]Zhang ZY, Smith PES, Cai SH, Zheng ZY, Lin YL*, Chen Z*, 2015. Establishing resolution-improved NMR spectroscopy in high magnetic fields with unknown spatiotemporal variations. The Journal of Chemical Physics, 143(24):244201.
  [21]Liu GC, Qu XB, Cai SH, Zhang ZY, Chen ZW, Cai CB, Chen Z*, 2014. Fast 3D gradient shimming by only 2?2 pixels in XY planefor NMR-solution samples. Journal of Magnetic Resonance, 248:13-18.
  [22]Huang YQ, Cai SH, Zhang ZY, Chen Z*, 2014. High-resolution two-dimensional J-Resolved NMR spectroscopy for biological systems. Biophysical Journal, 106:2061-2070.
  [23]Zhang ZY, Huang YQ, Smith PES, Wang KY, Cai SH, Chen Z*, 2014. High-resolution heteronuclear multi-dimensional NMR spectroscopy in magnetic fields with unknown spatial variations. Journal of Magnetic Resonance, 242:49-56.
  [24]Li JQ, Zhou ZJ, Feng JH*, Cai SH, Gao JH, Chen Z*, 2014. NMR-based metabonomic analysis of MnO-embedded iron oxide nanoparticles as potential dual-modal contrast agents. Journal of Nanoparticle Research, 16(5):2411.
  [25]Lin YQ, Zhang QT, Wei ZL, Cai SH, Zhong JH, Chen Z*, 2014. Ultrafast localized two-dimensional magnetic resonance correlated spectroscopy via spatially encoded technique. Magnetic Resonance in Medicine, 71(3):903-910.
  [26]Chen L, Bao LJ, Li J, Cai SH*, Cai CB*, Chen Z, 2013. An aliasing artifacts reducing approach with random undersampling for spatiotemporally encoded single-shot MRI. Journal of Magnetic Resonance, 237:115-124.
  [27]Bao JF, Cui XH, Cai SH, Zhong JH, Cai CB, Chen Z*, 2013. Brown adipose tissue mapping in rats with combined intermolecular double-quantum coherence and Dixon water-fat MRI. NMR in Biomedicine, 26(12):1663-1671.
  [28]Zhang ZY, Chen H, Wu C, Wu R, Cai SH*, Chen Z*, 2013. Spatially encoded ultrafast high-resolution 2D homonulcear correlation spectroscopy in inhomogeneous fields. Journal of Magnetic Resonance, 227: 39-45.
  [29]Xu JJ, Liu CQ, Cai SH*, Dong JY, Li XJ*, JH Feng, Chen Z, 2013. Metabolomic profilings of urine and serum from high fat-fed rats via 1HNMR spectroscopy and pattern recognition. Applied Biochemistry and Biotechnology, 169:1250-1261.
  [30]Cai CB, Dong JY, Cai SH, Li J, Chen Y, Bao LJ, Chen Z*, 2013. An efficient de-convolution reconstruction method for spatiotemporal-encodingsingle-scan 2D MRI. Journal of Magnetic Resonance, 228:136-147.
  [31]Chen Y, Li J, Qu XB, Chen L, Cai CB*, Cai SH, Zhong JH, Chen Z*, 2013. Partial Fourier transform reconstruction for single-shot MRI with linear frequency-swept excitation. Magnetic Resonance in Medicine, 69:1326-1336.
  [32]Cai CB, Lin YL, Cai SH*, Sun HJ, Zhong JH, Chen Z*, 2012. Flat pancake distant dipolar fields for enhancement ofintermolecular multiple-quantum coherence signals. Journal of Chemical Physics, 136:094503.
  [33]Chen YS, Cai SH, Cai CB*, Cui XH, Chen Z*, 2012. High-resolution NMR spectroscopy in inhomogeneous fields via Hadamard encoded intermolecular double-quantum coherences. NMR in Biomedicine,25(9):1088-1094.
  [34]Xu JJ, Cai SH*, Li XJ, Dong JY*, Ding J, Chen Z, 2012. Statistical two-dimensional correlation spectroscopy of urine and serum from metabolomics data. Chemometrics and Intelligent Laboratory Systems,112:33-40.
  [35]Lin MJ, Lin YQ, Chen X*, Cai SH, Chen Z*, 2012.High-resolution adsorptive intermolecular multiple-quantum coherence NMR spectroscopyunder inhomogeneous fields. Journal of Magnetic Resonance, 214(1):289-295.
  [36]Cai CB, Gao FL, Cai SH, Huang YQ, Chen Z*, 2011. Fast high-resolution 2D correlation spectroscopy in inhomogeneous fieldsviaHadamard intermolecular multiple-quantum coherences technique.Journal of Magnetic Resonance, 211:162-169.
  [37]Lin YL, Zhang ZY, Cai SH, Chen Z*, 2011. High-resolution 2D J-resolved spectroscopy in inhomogeneous fields with two scans. Journal of the American Chemical Society, 133(20):7632-7635.
  [38]Lin MJ, Huang YQ, Chen X*, Cai SH, Chen Z*, 2011. High-resolution 2D NMR spectrain inhomogeneous fields based on intermolecular multiple-quantum coherences with efficient acquisition schemes. JournalofMagneticResonance, 208:87-94.
  [39]2011年以前的略
  发明专利
  [1]蔡淑惠，李敬，蔡聪波，陈林，陈忠. 基于单扫描正交时空编码磁共振成像的图像畸变校正方法. ZL201410057539.0.授权日2017.2.22.
  [2]蔡淑惠，李敬，蔡聪波，陈林，陈忠. 基于单扫描超快速正交时空编码的小视野磁共振成像方法. ZL201410057472.0.授权日2016.4.20.
  [3]刘光曹，陈忠，蔡淑惠. 核磁共振波谱仪上克服对流效应的梯度匀场方法. ZL201310249827.1.授权日2015.10.14.
  著作
  [1]Lin YL, Huang YQ, Cai SH, Chen Z, 2013. Intermolecular zero quantum coherence in NMR spectroscopy. Annual Reportson NMR Spectroscopy, Academic Press, Vol. 78, Chapter 5.
  [2]Chen Z*, Huang YQ, Lin YQ, Cai SH, 2011. Accurate measurements of small J coupling constants. Annual Reportson NMR Spectroscopy, Academic Press, Vol. 72, Chapter 4.