基本信息

邱维宝，研究员，博导
中国科学院深圳先进技术研究院
电子邮件： wb.qiu@siat.ac.cn
通信地址： 深圳市南山区西丽深圳大学城学苑大道1068号
邮政编码： 518055


部门/实验室：医工所
个人简介


















生物医学超声技术以其无创、无辐射、易于使用和经济性好等优点，已成为临床应用最广泛的诊疗技术之一。
项目组定位于新型医学超声关键技术，组建了深圳市超声成像与治疗技术重点实验室，研究内容涵盖超声换能器、超声成像算法和超声仪器装备；面向新型的临床疾病诊疗需求，开展高分辨率超声成像和低强度超声治疗等技术研究，并推动相关技术的产业转化，带动我国医学超声技术发展。
项目组已发表JCR二区以上SCI文章39篇其中IEEE Trans文章21篇；共申请32项发明专利（已授权16项）；项目组研发的多项生物医学超声新技术完成了产业转化。




















教育经历

2004年7月获得合肥工业大学测控技术及仪器专业学士学位；
2007年3月获得天津大学测试计量技术及仪器专业硕士学位；
2012年1-5月美国南加州大学超声传感器研究中心访问，学习高分辨超声系统及换能器技术；

2012年10月获得香港理工大学生物医学工程博士学位；


工作经历

2007-2009工作于中兴通讯股份有限公司，先后任职硬件/FPGA工程师、项目经理；
2012年8月加入中国科学院深圳先进技术研究院-医工所-影像中心，任副研究员；
2018年2月晋升为研究员，博士生导师；
2019年1月深圳市超声成像与治疗技术重点实验室，主任。



学术兼职






IEEE Transactions on Ultrasonics, Ferroelectrics, and Frequency Control，副主编(Associate Editor)；
IEEE International Ultrasonics Symposium (IUS) 国际超声年会, Technical Program Committee (TPC) Member；
IEEE Senior member；
IEEE-UFFC Society Special Topic School, Waves and Transducers, Organizer and teaching faculty；
中国医学装备协会/超声装备技术分会/超声换能器专委会，副主任委员；
中国医学装备协会/超声装备技术分会，常务委员；
中国康复医学会/脑功能检测与调控康复专业委员会，常务委员；
中国超声医学工程学会/仪器工程开发专委会，委员；
中国医师协会/超声分子影像与人工智能专委会，委员；
中国仪器仪表学会/显微仪器分会，理事；
中国科学院青促会成员；
广东省生物医学工程学会青年学术分会，副主任委员；
广东省生物医学工程学会，委员。







人才获奖
2014年中国科学院王宽诚教育基金获得者；
2015年参与获得中国科学院科技促进发展奖；
2015年参与获得广东省科技进步一等奖；
2015年入选深圳市海外高层次人才“孔雀计划”B类引进人才；
2015年广东省基金获得者；
2016年“深圳市青年科技奖”获得者；
2017年广东省特支计划青年拔尖人才获得者。


研究内容

















主要研究方向为新型医学超声方法及系统：


1）高分辨率血管内超声成像方法及系统


为心血管疾病提供超声成像工具。团队已经开发并产业转化的血管内超声成像关键技术：图(a)血管内超声成像原理；(b)高频超声成像系统平台主机；(c)血管内超声换能器，直径小于1毫米，中心频率大于40MHz;(d)成像调试时的电路及软件；(e)离体血管超声及光声成像图。


相关文章：
[1][M. Su, Z. Zhang], J. Hong, Y. Huang, P. Mu, Y. Yu, R. Liu, S. Liang, H. Zheng*, and W. Qiu*, “Cable shared dual-frequency catheter for intravascular ultrasound”, IEEE Trans. Ultrason. Ferroelectr. Freq. Control. vol. 66, no. 5, pp. 849-856, May. 2019. (IF: 2.989).
[2] [J. Hong, M. Su, Y. Yu], Z. Zhang, R. Liu, Y. Huang, P. Mu, H. Zheng*, and W. Qiu*, “A dual-mode imaging catheter for intravascular ultrasound application”, IEEE Transactions on Medical Imaging. vol. 38, no. 3, pp. 657-663, Mar. 2019. (IF: 7.816)
[3]Z. Zhang, F. Li, R. Chen, T. Zhang, X. Cao, S. Zhang, T. Shrout, H. Zheng, K. K. Shung, M. S. Humayun,W. Qiu*, and Q. Zhou*, “High performance ultrasound needle transducer based on modified PMN-PT ceramic with ultrahigh clamped dielectric permittivity”,IEEE Trans. Ultrason. Ferroelectr. Freq. Control. vol. 65, no. 2, pp. 223-230, Feb. 2018. (IF: 2.743)
[4]W. Qiu*, X. Wang, Y. Chen, Q. Fu, M. Su, L. Zhang, J. Xia, J. Dai, Y. Zhang, and H. Zheng*, “Modulated excitation imaging system for intravascular ultrasound”,IEEE Transactions on Biomedical Engineering,vol. 64, no. 8, pp. 1935-1942, Aug 2017. (IF: 3.577)
[5] W. Qiu, Y. Chen, X. Li, Y. Yu, W. F. Cheng, F. K. Tsang, Q. Zhou, K. K. Shung, J. Dai, and L. Sun*, “An open system for intravascular ultrasound imaging,” IEEE Trans. Ultrason. Ferroelectr. Freq. Control, vol. 59, no. 10, pp. 2201-2209, 2012. (IF: 1.822)
[6]W. Qiu, Y. Yu, F. K. Tsang, and L. Sun*, “A multi-functional, reconfigurable pulse generator for high frequency ultrasound imaging,” IEEE Trans. Ultrason. Ferroelectr. Freq. Control, vol. 59, no. 7, pp. 1432-1442, July, 2012. (IF: 1.822)


2）高分辨内窥超声成像方法及装置


为肠道疾病提供高分辨率成像方法。团队开发的新型内窥超声成像技术：图(a) 超声内镜示意图；(b)成像扫描方案；(c) 原理样机，基于LiNbO₃单晶材料开发的35MHz超声成像器件;(d)离体小肠成像图，纵向分辨率小于60微米。


相关文章：
[1]W. Qiu*, J. Xia, Y. Shi, P. Mu, X. Wang, M. Gao, C. Wang, Y. Xiao, G. Yang, J. Liu, L. Sun, and H. Zheng*, “A delayed-excitation data acquisition method for high-frequency ultrasound imaging”,IEEE Transactions on Biomedical Engineering. vol. 65, no. 1, pp. 15-20, Jan. 2018. (IF: 4.491).
[2] X. Wang, V. Seetohul, R. Chen, M. Qian, Z. Shi, G. Yang, P. Mu, C. Wang, Z. Huang, Q. Zhou, H. Zheng, S. Cochran, and W. Qiu*, “Development of a mechanical scanning device with high-frequency ultrasound transducer for ultrasonic capsule endoscopy”, IEEE Transactions on Medical Imaging, vol. 36, no. 9, pp. 1922-1929, Sep. 2017. (IF: 3.942)
[3]W. Qiu, Y. Yu, F. K. Tsang, and L. Sun*, “An FPGA based open platform for ultrasound biomicroscopy,”IEEE Trans. Ultrason. Ferroelectr. Freq. Control, vol. 59, no. 7, pp. 1558-1567, July, 2012. (IF: 1.822)




3）超声脑成像技术与系统


为脑科学研究提供新的超声成像方法和工具。(a) 阵列超声控制电子系统开发； (b) 高性能超声换能器；(c)新型超声系统整机； (d) 胶质瘤模型B模式超声成像图；(e) 新型平面波复合超声脑血流成像图。


相关文章：
[1] J. Xia, Y. Yang, C. Hu, R. Meng, Q. Jiang, R. Liu, Y. Yu, Z. Sheng, F. Yan, L. Zhang, Z. Shi, H. Zheng, and W. Qiu*, “Evaluation brain tumor in small animals using plane-wave-based power Doppler imaging”, Ultrasound in Medicine and Biology. vol. 45, no. 3, pp. 811-822, Mar. 2019. (IF: 2.645)
[2] [Z. Zhang, R. Chen], B. Wang, T. Zhang, M. Su, R. Liu, J. Yang, X. Cao, Y. Li, H. Zheng, K. K. Shung, M. S. Humayun, Q. Zhou*, and W. Qiu*, “Development of a high-frequency KNN ceramic based lead-free linear array ultrasonic transducer”, IEEE Trans. Ultrason. Ferroelectr. Freq. Control. vol. 65, no. 11, pp. 2113-2120, Nov. 2018. (IF: 2.704)
[3] W. Qiu*, J. Xia, Y. Shi, P. Mu, X. Wang, M. Gao, C. Wang, Y. Xiao, G. Yang, J. Liu, L. Sun, and H. Zheng*, “A delayed-excitation data acquisition method for high-frequency ultrasound imaging”, IEEE Transactions on Biomedical Engineering. vol. 65, no. 1, pp. 15-20, Jan. 2018. (IF: 3.577)
[4] [W. Qiu, Y. Yu], F. K. Tsang, H. Zheng*, and L. Sun*, "A novel modulated excitation imaging system for micro-ultrasound," IEEE Transactions on Biomedical Engineering, vol. 60, no. 7, pp. 1884-1890, 2013. (IF: 2.233
[5] W. Qiu, Y. Yu, H. R. Chabok, C. Liu, F. K. Tsang, Q. Zhou, K. K. Shung, H. Zheng, and L. Sun*, “A flexible annular array imaging platform for micro-ultrasound,” IEEE Transactions on Ultrasonics Ferroelectrics and Frequency Control, vol. 60, no. 1, pp. 178-86, 2013. (IF: 1.503)


4）无创超声神经调控技术及系统


为脑科学研究提供无创神经调控工具。(a)团队研发的超声神经刺激便携式专用系统; (b)新型阵列式超声调控系统；(c)大规模通道(2048通道)阵列超声调控系统；(d)香港城市大学视网膜刺激应用；(e)上海交通大学神经调控实验；(f)中科院心理所猴子刺激实验；(g)国际著名杂志《Nature》正刊报道了团队开展的神经调控仪器开发工作；(h)系统技术已经应用到的科研单位。


相关文章：
[1] [G. Li, W. Qiu, Z. Zhang], Q. Jiang, M. Su, R. Cai, Y. Li, F. Cai, Z. Deng, D. Xu, H. Zhang, and H. Zheng*, “Noninvasive ultrasonic neuromodulation in freely moving mice”, IEEE Transactions on Biomedical Engineering. vol. 66, no. 1, pp. 217-224, Jan. 2019. (IF: 4.288)
[2][G. Li,W. Qiu], J. Hong, Q. Jiang, M. Su, P. Mu, G. Yang, Y. Li, C.Wang,H. Zhang, H. Zheng*, “Imaging-Guided Dual-Target Neuromodulation of the Mouse Brain Using Array Ultrasound”,IEEE Trans. Ultrason. Ferroelectr. Freq. Control. vol. 65, no. 9, pp. 1583-1589, Sep. 2018. (IF: 2.743)
[3] [Q. Jiang, G. Li], H. Zhao, W. Sheng, L. Yue, M. Su, S. Weng, L. Chan, Q. Zhou, M. S. Humayun, W. Qiu*, and H. Zheng*, “Temporal neuromodulation of retinal ganglion cells by low-frequency focused ultrasound stimulation”, IEEE Transactions on Neural Systems and Rehabilitation Engineering. vol. 26, no. 5, pp. 969-976, May. 2018. (IF: 3.41)
[4]W. Qiu, J. Zhou, Y. Chen, M. Su, G. Li, H. Zhao, S. Cao, D. Meng, C. Wang, Y. Xiao, K. H. Lam, J. Dai, and H. Zheng*, “A portable ultrasound system for non-invasive ultrasonic neuro-stimulation”, IEEE Transactions on Neural Systems and Rehabilitation Engineering. vol. 25, no. 12, pp. 2509-2515, Dec. 2017. (IF: 3.41)
[5][M. Gao, Y. Yu], H. Zhao, G. Li, H. Jiang, C. Wang, F. Cai, L. Chan, B. Chiu, W. Qian, W. Qiu*, and H. Zheng*, “A simulation study of ultrasonic retinal prosthesis with a novel contact-lens array for non-invasive retinal stimulation”, IEEE Transactions on Neural Systems and Rehabilitation Engineering. vol. 25, no. 9, pp. 1605-11, Sep. 2017. (IF: 3.41)



















代表性科研项目



1) 国家自然科学基金青年基金：基于50-100MHz 高频率超声的血管内高分辨率成像方法研究，课题负责人
2)国家自然科学基金面上基金：基于双模血管内超声的易损斑块弹性及周边血流成像研究，课题负责人
3) 国家自然科学基金重大仪器研制基金项目：基于超声辐射力的深部脑刺激与神经调控仪器研制，核心成员
4)中科院前沿重点拔尖青年项目：基于高频率超声(20-50MHz)的在体小动物脑血流成像方法与系统研究，课题负责人
5) 广东省自然科学基金基金：基于平面波技术的高频超声成像方法及其在脑科学领域的应用研究，课题负责人
6) 广东省自然科学基金自由申请：基于血管内高分辨率超声成像的动脉斑块识别评估方法研究，课题负责人
7) 深圳市国际合作项目：基于高分辨率超声的内窥胶囊成像技术研究，课题负责人
8) 企业委托横向项目, 生物力学超声测量装置，课题负责人







教授课程
1) 生物医学超声成像；2) 生物医学超声换能器。

期刊文章







[1] Q. Zhang, X. Pang, Z. Zhang, M. Su, J. Hong, H. Zheng, W. Qiu, and K. H. Lam, "Miniature Transducer Using PNN-PZT-based Ceramic for Intravascular Ultrasound", IEEE Trans. Ultrason. Ferroelectr. Freq. Control, vol. 66, no. 6, pp. 1102-1109, Jun. 2019. (IF: 2.989).
[2] [M. Su, Z. Zhang], J. Hong, Y. Huang, P. Mu, Y. Yu, R. Liu, S. Liang, H. Zheng*, and W. Qiu*, “Cable shared dual-frequency catheter for intravascular ultrasound”, IEEE Trans. Ultrason. Ferroelectr. Freq. Control. vol. 66, no. 5, pp. 849-856, May. 2019. (IF: 2.989).
[3] Y. Yu, Z. Zhang, F. Cai, M. Su, Q. Jiang, Q. Zhou, M. S. Humayun, W. Qiu*, and H. Zheng*, A Novel Racing Array Transducer for Noninvasive Ultrasonic Retinal Stimulation: A Simulation Study, Sensors, vol. 19, no. 8, 1825, 2019. (IF: 3.031).
[4] Z. Zhang, W. Qiu, H. Gong, G. Li, Q. Jiang, P. Liang, H. Zheng*, and P. Zhang*, “Low-intensity ultrasound suppresses low-Mg²⁺-induced epileptiform discharges in juvenile mouse hippocampal slices”, Journal of Neural Engineering, vol. 16, 036006, 2019. (IF: 4.551)
[5] C. Liu, M. Xing, B. Cong, C. Qiu, D. He, C. Wang, Y. Xiao, T. Yin, M. Shao, W. Qiu, T. Ma, X. Gong, X. Chen, H. Zheng, R. Zheng, and L. Song, "In vivo transrectal imaging of canine prostate with a sensitive and compact handheld transrectal array photoacoustic probe for early diagnosis of prostate cancer", Biomed. Opt. Express, vol. 10, no. 4, pp. 1707-1717, 2019. (IF: 3.91)
[6] [J. Hong, M. Su, Y. Yu], Z. Zhang, R. Liu, Y. Huang, P. Mu, H. Zheng*, and W. Qiu*, “A dual-mode imaging catheter for intravascular ultrasound application”, IEEE Transactions on Medical Imaging. vol. 38, no. 3, pp. 657-663, Mar. 2019. (IF: 7.816)
[7] J. Xia, Y. Yang, C. Hu, R. Meng, Q. Jiang, R. Liu, Y. Yu, Z. Sheng, F. Yan, L. Zhang, Z. Shi, H. Zheng, and W. Qiu*, “Evaluation brain tumor in small animals using plane-wave-based power Doppler imaging”, Ultrasound in Medicine and Biology. vol. 45, no. 3, pp. 811-822, Mar. 2019. (IF: 2.205).
[8] [G. Li, W. Qiu, Z. Zhang], Q. Jiang, M. Su, R. Cai, Y. Li, F. Cai, Z. Deng, D. Xu, H. Zhang, and H. Zheng*, “Noninvasive ultrasonic neuromodulation in freely moving mice”, IEEE Transactions on Biomedical Engineering. vol. 66, no. 1, pp. 217-224, Jan. 2019. (IF: 4.491)
[9] [Z. Zhang, R. Chen], B. Wang, T. Zhang, M. Su, R. Liu, J. Yang, X. Cao, Y. Li, H. Zheng, K. K. Shung, M. S. Humayun, Q. Zhou*, and W. Qiu*, “Development of a KNN Ceramic-Based Lead-Free Linear Array Ultrasonic Transducer”, IEEE Trans. Ultrason. Ferroelectr. Freq. Control. vol. 65, no. 11, pp. 2113-2120, Nov. 2018. (IF: 2.989).
[10] F. Guo, Y. Wang, Z. Huang, W. Qiu, Z. Zhang, Z. Wang, J. Dong, B. Yang, and W. Cao “Magnesium Alloy Matching Layer for PMN-PT Single Crystal Transducer Applications”, IEEE Trans. Ultrason. Ferroelectr. Freq. Control. vol. 65, no. 10, pp. 1865-1872, Oct. 2018. (IF: 2.989)
[11] H. Liu*, C. Tsai, C. Jan, H. Chang, S. Huang, M. Li, W. Qiu, and H. Zheng, “Design and implementation of a transmit/receive ultrasound phased array for brain applications”, IEEE Trans. Ultrason. Ferroelectr. Freq. Control. vol. 65, no. 10, pp. 1756-1767, Oct. 2018. (IF: 2.989)
[12] H. Zhang, T. Wang, W. Qiu, Y. Han, Q. Sun, J. Zeng, F. Yan, H. Zheng, Z. Li*, and M. Gao, “Monitoring the Opening and Recovery of the Blood–Brain Barrier with Noninvasive Molecular Imaging by Biodegradable Ultra-small Cu2–xSe Nanoparticles”, Nano Letters. vol. 18, no. 8, pp. 4985-4992, Jul. 2018. (IF: 12.279)
[13] [J. Ye, S. Tang, L. Meng], X. Li, X. Wen, S. Chen, L. Niu, X. Li, W. Qiu, H. Hu, M. Jiang, S. Shang, Q. Shu, H. Zheng*, S. Duan, and Y. Li*, “Ultrasonic control of neural activity through activation of the mechanosensitive channel MscL”, Nano Letters. vol. 18, no. 7, pp. 4148-4155, Jun. 2018. (IF: 12.279)
[14] [G. Li, W. Qiu], J. Hong, Q. Jiang, M. Su, P. Mu, G. Yang, Y. Li, C. Wang, H. Zhang, H. Zheng*, “Imaging-guided dual-target neuromodulation of the mouse brain using array ultrasound”, IEEE Trans. Ultrason. Ferroelectr. Freq. Control. vol. 65, no. 9, pp. 1583-1589, Sep. 2018. (IF: 2.989)
[15] [Q. Jiang, G. Li], H. Zhao, W. Sheng, L. Yue, M. Su, S. Weng, L. Chan, Q. Zhou, M. S. Humayun, W. Qiu*, and H. Zheng*, “Temporal neuromodulation of retinal ganglion cells by low-frequency focused ultrasound stimulation”, IEEE Transactions on Neural Systems and Rehabilitation Engineering. vol. 26, no. 5, pp. 969-976, May. 2018. (IF: 3.478)
[16] Z. Zhang, F. Li, R. Chen, T. Zhang, X. Cao, S. Zhang, T. Shrout, H. Zheng, K. K. Shung, M. S. Humayun, W. Qiu*, and Q. Zhou*, “High performance ultrasound needle transducer based on modified PMN-PT ceramic with ultrahigh clamped dielectric permittivity”, IEEE Trans. Ultrason. Ferroelectr. Freq. Control. vol. 65, no. 2, pp. 223-230, Feb. 2018. (IF: 2.989)
[17] W. Qiu*, J. Xia, Y. Shi, P. Mu, X. Wang, M. Gao, C. Wang, Y. Xiao, G. Yang, J. Liu, L. Sun, and H. Zheng*, “A delayed-excitation data acquisition method for high-frequency ultrasound imaging”, IEEE Transactions on Biomedical Engineering. vol. 65, no. 1, pp. 15-20, Jan. 2018. (IF: 4.491).
[18] W. Qiu, J. Zhou, Y. Chen, M. Su, G. Li, H. Zhao, S. Cao, D. Meng, C. Wang, Y. Xiao, K. H. Lam, J. Dai, and H. Zheng*, “A portable ultrasound system for non-invasive ultrasonic neuro-stimulation”, IEEE Transactions on Neural Systems and Rehabilitation Engineering. vol. 25, no. 12, pp. 2509-2515, Dec. 2017. (IF: 3.972)
[19] [M. Gao, Y. Yu], H. Zhao, G. Li, H. Jiang, C. Wang, F. Cai, L. Chan, B. Chiu, W. Qian, W. Qiu*, and H. Zheng*, “Simulation Study of an Ultrasound Retinal Prosthesis With a Novel Contact-Lens Array for Noninvasive Retinal Stimulation”, IEEE Transactions on Neural Systems and Rehabilitation Engineering. vol. 25, no. 9, pp. 1605-11, Sep. 2017. (IF: 3.972)
[20] X. Wang, V. Seetohul, R. Chen, M. Qian, Z. Shi, G. Yang, P. Mu, C. Wang, Z. Huang, Q. Zhou, H. Zheng, S. Cochran, and W. Qiu*, “Development of a mechanical scanning device with high-frequency ultrasound transducer for ultrasonic capsule endoscopy”, IEEE Transactions on Medical Imaging, vol. 36, no. 9, pp. 1922-1929, Sep. 2017. (IF: 6.131)
[21] W. Qiu*, X. Wang, Y. Chen, Q. Fu, M. Su, L. Zhang, J. Xia, J. Dai, Y. Zhang, and H. Zheng*, “Modulated excitation imaging system for intravascular ultrasound”, IEEE Transactions on Biomedical Engineering, vol. 64, no. 8, pp. 1935-1942, Aug 2017. (IF: 4.288)
[22] C. Wang, Y. Xiao, J. Xia, W. Qiu*, and H. Zheng*, “Effects of Non-Elevation-Focalized Linear Array Transducer on Ultrasound Plane-Wave Imaging”, Sensors, 16, 1906, 2016. (IF: 2.677)
[23] [Y. Xiao, Y. Yu], L. Niu, M. Qian, Z. Deng, W. Qiu, and H. Zheng*, Quantitative evaluation of peripheral tissue elasticity for ultrasound-detected breast lesions, Clinical Radiology, vol. 71, no. 9, pp. 896-904, 2016. (IF: 2.141)
[24] [H. Fang, Y. Chen], C. M. Wong, W. Qiu, J. Dai*, Q. Li, and Q. Yan, “Anodic aluminum oxide AAO-epoxy composite acoustic matching layers for ultrasonic transducer application”, Ultrasonics, vol. 70, pp. 29-33, 2016. (IF: 2.327)
[25] G. Li, H. Zhao, H. Zhou, F. Yan, Y. Wang, C. Xu, C. Wang, L. Niu, L. Meng, S. Wu, H. Zhang, W. Qiu*, and H. Zheng*, “Improved anatomical specificity of non-invasive neuro-stimulation by high frequency (5 MHz) ultrasound”, Scientific Reports, 6,24738, 2016. (IF: 4.259)
[26] [W. Qiu*, C. Wang], Y. Li, J. Zhou, G. Yang, Y. Xiao, G. Feng, Q. Jin, P. Mu, M. Qian, and H. Zheng*, “A scanning-mode 2D shear wave imaging (s2D-SWI) system for ultrasound elastography”, Ultrasonics, vol. 62, pp. 89-96, Sep, 2015. (IF: 1.954)
[27] Y. Yu, W. Qiu, B. Chiu, and L. Sun*, "Feasibility of multiple micro-particle trapping--A simulation study", Sensors, vol. 15, no. 3, pp. 4958-74, 2015. (IF: 2.033)
[28] [W. Qiu, Y. Chen], C. M. Wong, B. Liu, J. Dai*, and H. Zheng*, “A novel dual-frequency imaging method for intravascular ultrasound applications”, Ultrasonics, vol. 57, pp. 31-35, Mar, 2015. (IF: 1.954)
[29] [Y. Chen, W. Qiu], K. H. Lam, B. Liu, X. Jiang, H. Zheng, H. S. Luo, H. L. W. Chan, and J. Dai*, “Focused intravascular ultrasonic probe using dimpled transducer elements”, Ultrasonics, vol. 56, pp. 227-231, Feb, 2015. (IF: 1.954)
[30] [Y. Chen, K. H. Lam], D. Zhou, Q. Yue, Y. Yu, J. Wu, W. Qiu, L. Sun, C. Zhang, H. Luo, H. L. W. Chan, and J. Dai*, “High performance relaxor-based ferroelectric single crystals for ultrasonic transducer applications”, Sensors, vol. 14, no. 8, pp. 13730-58, Jul, 2014. (IF: 2.245)
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专利
授权专利：

1) 邱维宝，于妍妍，孙雷，“超声波成像系统及成像方法”，专利申请号：5.6
2) 邱维宝，韩韬，郑海荣，朱国乾，旋转控制装置、旋转控制回撤系统和超声成像系统，发明专利，授权公告号：CNB, 授权公告日:2015.04.08
3) 邱维宝,朱国乾,郑海荣,韩韬,机械扇形摆动装置, 发明专利，授权公告号:CNB,授权公告日:2015.09.16.
4) 郑海荣,邱维宝,黎国锋,梁长虹,内窥式鼻咽癌超声成像装置及方法, 发明专利，授权公告号:CNB,授权公告日:2015.07.29
5) 王丛知，曾成志，郑海荣，明妍，杨培德，杨戈，肖杨，李永川，钱明，邱维宝，减少生理活动对医学成像或测量结果干扰的装置及方法，发明专利，授权公告号:CNB,授权公告日:2014.12.17
6) 王丛知，杨培德，郑海荣，曾成志，杨戈，肖杨，李永川，明妍，钱明，邱维宝，生物组织粘弹性测量方法和系统，发明专利，授权公告号:CNB,授权公告日:2014.12.10
7) 郑荣琴,李凯,张成祥,李志成,邱维宝,超声耦合剂输送器，实用新型专利，授权公告号, CNU, 授权公告日, 2015.08.05
8) 郑海荣,李永川,苏敏,钱明,邱维宝, 一种单阵元神经刺激低频超声换能器, 实用新型专利，专利申请号：9.2, 授权公告日, 2016.03.09
9) 郑海荣，邱维宝、周娟、曹寿国、孟德、苏敏、黎国锋、一种超声神经刺激设备及系统，实用新型，专利申请号：0.0，申请日：2015-12-03，授权公告日, 2016.05.04。
10) 邱维宝，牟培田，肖杨，张雪，郑海荣，基带波束合成超声成像方法及其系统，发明专利，申请号：0.X 申请日：2013-11-19，授权公开号 B，授权公开日 2016-06-08
11) 张雪，郑海荣，肖杨，邱维宝，牟培田，李彦明，一种基于超声弹性图像的弹性应变评估方法和系统，申请号：6.6 申请日：2013-06-09，授权公开号，B，授权公开日，2016-07-06
12) 叶为镪，邱维宝，郑海荣，基于平面波的超声温度成像方法，申请号：8.0，申请日：2014-12-31，授权公开号，B，授权公开日，2016-09-21


专利申请:
13) 邱维宝，牟培田，吴米龙，郑海荣，基于USB3.0的超声数据处理及传输装置和方法、超声诊断系统，申请号：2.X，申请日：2013-8-21
14) 邱维宝, 叶宗英，郑海荣，一种估算流体速度的系统和方法，申请号：4.6，申请日：2014-07-21。
15) 邱维宝, Alexander Cochran（亚历山大.科克伦），胡丽，黄志红，王杏颖，郑海荣，胶囊内窥镜，申请号：0.1，申请日：2014-12-12。
16) 王丛知、郑海荣、杨戈、肖杨、邱维宝，一种用于生物组织弹性测量的剪切波速度估计方法，申请号：8.X，申请日：2014-12-25。
17) 郑海荣、王丛知、邱维宝、钱明、肖杨，一种超声穿颅聚焦的方法，申请号：4.X，申请日：2014-12-31。
18) 郑海荣 邱维宝 周娟 史志谦，超声波传感器阵列的激励装置，申请号：8.5，申请日：2014-12-31。
19) 郑海荣，邱维宝，黎国锋，一种超声刺激神经组织的装置，专利申请号：5.4，申请日：2015-5-15。
20) 郑海荣，牛丽丽，刘新，孟龙，邱维宝，钱明，蔡飞燕，肖杨，王丛知，声敏感离子通道遗传操作方法及系统，专利申请号：5.8, 申请日：2015-9-14。
21) 郑海荣、李永川、苏敏、钱明、邱维宝，一种单阵元神经刺激低频超声换能器，基于厚度模式的单阵元脑刺激超声低频换能器，实用新型，专利申请号：9.2，申请日：2015-9-14。
22) 郑海荣、李飞、蔡飞燕、孟龙、王辰、张成祥、邱维宝、李永川、严飞、牛丽丽、耿刘峰、徐超伟，基于人工结构声场的微流体系统及操控微粒的方法，专利申请号：3.3，申请日：2015-10-10。
23) 郑海荣、李永川、苏敏、钱明、邱维宝，基于径向模式的单阵元超声低频换能器，发明专利，专利申请号：专利申请号：6.9，申请日：2015-11-06。
24) 邱维宝、苏敏、赵慧霞、王晶瑶、李永川、郑海荣，一种基于二维面阵探头的视网膜刺激设备，发明专利，专利申请号：9.9，申请日：2015-11-23。
25) 郑海荣、李永川、刘西宁、钱明、苏敏、邱维宝, 超声探头及其制备方法，发明专利，专利申请号：2.5，申请日：2015-11-27。
26) 邱维宝，王杏颖，胡丽，郑海荣，一种超声胶囊内窥镜，发明专利，专利申请号：5.0，申请日：2015-12-15。
27) 郑海荣、钱明、李永川、邱维宝、牛丽丽、王丛知，一种基于大规模面阵元的超声脑刺激或调控方法及装置。发明专利，专利申请号：9.0，申请日：2015-12-25。
28) 邱维宝、苏敏、赵慧霞、王晶瑶、李永川、郑海荣，超声视网膜刺激设备，发明专利，专利申请号：0.9，申请日：2015-12-29。
29) 郑海荣、邱维宝、苏敏、黎国锋、钱明、李永川，头戴式超声刺激设备及系统，发明专利，专利申请号：4.8，申请日：2015-12-31。
30) 郑海荣、刘西宁、李永川、钱明、苏敏、邱维宝，超声探头背衬成型装置、治具及制造方法、超声探头背衬成型装置及治具，实用新型，专利申请号：3.9，申请日：2016-01-14。
31) 邱维宝，牟培田，郑海荣，一种延迟激励超声成像方法、装置及延迟激励系统，发明专利，专利申请号：6.2，申请日：2016-4-22。


实验室招聘



实验室长期招收硕士研究生/博士研究生/博士后
请感兴趣的同学直接联系我：wb.qiu@siat.ac.cn


主要研究方向为：
1、医学超声成像与图像处理；
2、超声电子电路及仪器开发；
3、高性能超声换能器开发。