研究领域：光电子与智能仪器，生物医学光子学，智能医学工程                                
国际学会成员：国际光学工程学会(SPIE)、IEEE、美国光学学会OSA等
国内学会委员：中国中医药信息学会抗衰老分会副会长；中国生物医学工程学会医学人工智能分会、生物医学光子学分会、传感技术分会的委员，天津医学影像技术研究会基础分会委员，中国医疗保健国际交流促进会临床工程与健康产业分会委员。
入选的专家库：国家健康科普专家库首批专家，国家科学技术奖励评审专家，国家自然科学基金委信息学部和医学部评审专家
SCI期刊编委: IEEE Access (工程技术，中科院JCR二区，副主编)
Sensors (仪器仪表类，中科院JCR二区)
Biomedical Engineering Online（副主编）
Microelectr. Reliability (电子可靠性老期刊)
J. Healthcare Eng, J. Spectroscopy
SCI期刊审稿人: BB, Sci. Rep., J. Biophotonics, Biomed. Opt. Express., Ieee Access,
J. Biomed. Opt., Microvas. Res., JIOHS, JMMSR, MR, JTCM等
国际高级学术会议组委: EDSSC2014 (Session chair), INEC2016 (Publication chair, Session chair), ISOTT 47th annual conference (Session Chair)，IRHE2019(Session Chair)
Cell-phone:18002127296\18080827206
Website：http://code.google.com/p/mcvm/
E-mail: liting@bme.cams.cn; t.li619@foxmail.com
研究兴趣
1.新型非介入式的光学医学检测/诊断/成像技术和光学治疗技术，主要包括近红外光谱术、扩散光谱成像、相关光谱术/成像、散斑成像、光调控技术、智能诊疗一体化及其机器人；
2.基于上述技术，研究神经科学、生理疾病信号、疾病诊断模型和疗效评估方法、人工智能；
3.应用光电子技术与仪器化，涉及交通安全、身份识别等领域所需的检测技术与仪器设计。
教育工作背景
2017.9至今：中国医学科学院生物医学工程所，研究员，智能诊疗技术实验室主任
2011.12-2017.9：电子科技大学，副教授，微电子与固体电子，生物医学工程
2016.01-2020.12：深圳GIMI研究院(二级事业单位)，新型监测与疗效评估技术研发部主任（兼职）
2010.7~2012.7：University of Kentucky, USA, Biomedical Optics, Postdoc.
Oregon Health & Science University, USA, Biomedical Optics, Postdoc.
2004.9~2010.6：华中科技大学-武汉光电国家实验室Britton Chance Center for Biomedical Photonics，生物医学光子学，生物医学工程，博士
2000.9~2004.7：华中科技大学，生物医学工程，学士
主要奖励
2020年度青年科技创新奖一等奖，彩客彩票
2019年Melvin H Kniseley Awardee (Melvin H Kniseley奖获得者，每年全球至多一名获奖者，自设奖以来来自中国的首位获奖者). In recognition for her persistent efforts and outstanding research on oxygen transport in deep tissue of human body by noninvasive optical technologies.
2019发表的论文“Noninvasive and sensitive optical assessment of brain death”被 AdvancedScienceNews.com头版播报
2019年度青年科技创新奖一等奖，彩客彩票
2019第三批天津市特殊支持人才计划高层次创新团队，智能康复机器人技术创新团队（省部级，带头人）
2018第五批天津市创新人才推进计划，中青年科技领军人才
2018天津市“131”创新型人才培养工程第二层次人才
2018发表的论文“Longtime driving induced cerebral hemodynamic elevation and behavior degradation as assessed…”获选Journal of Biophotonics封面文章
2018发表的综述“Clinical applications of near-infrared diffuse correlation spectroscopy and tomography for tissue blood flow monitoring and imaging”被SCI期刊Physiological Measurement选为Highlights of 2017.
2018国家重点研发计划智能机器人专项截瘫助行机器人总体组成员
2017大学生智能互联创新大赛全国一等奖团队导师，优秀导师
2016“华为杯”第十一届中国电子设计竞赛系列，荣获“最佳指导老师”荣誉称号
2015研发的光学无创休克监护仪获美国光学学会采访报道（该媒体十年来鲜见大陆的科技成果报道）、Phys Org、BusinessWire、OFweek、斯坦福-台湾生物医学网、电子科大主页报道等
2015电子科技大学，微固院士奖励基金，微固年度个人
2015大学生挑战杯科创大赛全国一等奖团队导师，优秀导师
2014深圳孔雀团队人才计划核心成员（排第一位）
2012美国Nirfast workshop奖金
2009Britton Chance Center for Biomedical Photonics 年度报告杰出奖（2/~180）
2006校研究生工作Super Star (3/全校)
项目
1.国家留学基金委资助，脑卒中的非侵入光学监测调控一体化，麻省理工学院哈佛大学健康科技中心，Wellman Center for Photomedcine, 201908110204, 出发后一年期, 2.7万美金，主持
2.国家自然科学基金面上项目，脑水肿的多参数非侵入式光学监测技术研究，81971660，2020/1-2023/12，55万元(直接费)，在研，主持
3.北京市重大专项课题，无创神经调控四维光电精准定位算法和智能传感关键技术研发，Z191100010618004 -2，2019/1~2020/12，180万元，在研，主持
4.国家重点研发计划“主动健康和老龄化科技应对”重点专项，新型代谢融合的无创动态血糖监测及电磁血糖调控技术研究，2018YFC2001100，2018/12-2021/11，581万元，在研，参入。
5.天津市特殊支持计划高层次人才创新团队，智能康复机器人技术，2018/09~2021/08，100万元，在研，主持
6.天津市自然科学基金重点项目，18JCZDJC32700，脑水肿的光学无创监测技术研发与临床应用研究，2018/08~2021/07，40万元，在研，主持
7. 国家自然科学基金面上项目，61675039，休克的光学无创监护技术及监测指标研究，2017/01~2020/12， 64万元(直接费)，在研，主持
8. 国家重点研发计划智能机器人专项，2017YFB1300301，多模态高分辨率的神经信号检测技术研究，2017/12-2020/11，663万元，在研，参加
9. 国家重点研发计划智能机器人专项，2017YFB1302305，临床训练测试与示范应用，2017/12-2020/11，282万元，在研，参加
10.中央高校基本科研业务费项目，ZYGX2016J052，深静脉血栓的光学无创监测技术研发，2016/12-2018/11，15万元，已结题，主持
11.深圳孔雀团队计划项目，新型靶向CART细胞的癌症基因治疗技术的研发与应用(KQTD20140630143254906) 2015.1-2019.12, 3000万元, 已结题，核心成员排第一
12.“一校一带”基金，A003023001019，光学无创人体监护系统，2016.10-2018.12，30万, 已结题，主持
13.微固院士奖励基金，2015年，电子科学与技术
14.深圳市孔雀团队人才计划，2014年，健康技术与工程
15.国家自然科学基金青年基金，61308114，高密度近红外光谱成像及其应用于视觉非随意注意研究，2014/01~2016/12，直接费27万元，已结题，主持
16.中央高校基本科研业务费项目，ZYGX2012J114，无线、抗运动干扰的脑功能近红外光谱术及警觉研究，2012/12-2014/11，8万元，已结题，主持
17.教育部博士点新教师基金，20130185120024，便携穿戴式近红外脑功能成像，2013/12-16/12，4万元，已结题，主持。
著作
[1] T. Li, Z. Liu, “Outlook and Challenges of Nano Devices, Sensors, and MEMS”, Springer, ISBN 978-3-319-50822-1/20824-5, 3/2017.
[2] 李婷，《生物医学光子传输》，武汉大学出版社, ISBN 978-7-307-15668-5，10/2015.
[3] 李婷，e-book《光在三维宏观非均匀介质中传输的蒙特卡罗模拟》， Google 2010（下载量超过1200人次）.
标准
1.信息技术 人工智能 机动车驾驶员状态视频采集系统规范. 团体标准T/CESA 1044-2019，中国电子工业标准化技术协会发布(发布日期：2019-04-01)。主要起草人：钱晨，…, 李婷等。
临床方案
胡勇，李婷. 截瘫助行机器人的有效性及安全性 临床训练测试与示范应用，编号：20198121708，发布时间：2019年6月6日
指南/指导原则/规范化体系建设
1.李婷，蒲江波，王依倩等起草，物理技术辅助脑卒中康复的临床指南，批准号：2019LCZN201，批准学会：中国中医药信息学会抗衰老分会，批准日期：2019-05-17.
2.李婷，俞梦孙，王依倩，吴玉祥等起草，睡眠障碍的物理技术监测评估指导原则，批准号：2019LCZN203，批准学会：中国中医药信息学会抗衰老分会，批准日期：2019-05-17.
3.李婷，欧阳晨曦，黄金蕊等起草，物理技术治疗冠心病的指导原则，批准号：2019LCZN204，批准学会：中国中医药信息学会抗衰老分会，欧美同学会医师协会血管分会，批准日期：2019-05-17.
4.李婷，黄金蕊，高晨阳等起草，激光治疗雄激素性脱发和斑秃的技术指南，批准号：2019LCZN206，批准学会：中国中医药信息学会抗衰老分会，批准日期：2019-05-17.
5.李婷，王依倩，吴钰祥等起草，物理治疗脊柱退行性疾病的临床应用指南，批准号：2019LCZN210，批准学会：中国中医药信息学会抗衰老分会，批准日期：2019-07-12.
SCI论文
[1]B. Pan, J. Pu, T. Li*, M. Zhao, and X. Yang, Online Non-invasive Assessment of Human Brain Death by Near-infrared Spectroscopy with Protocol of O2 Inspiration, Oxygen Transport to Tissue XXXVIII. Springer, Adv. Exp. Med. Biol., 2020. In Press.
[2]T. Li*, Y. Zhao, Y. Sun, K. Li, W. Li, M. Duan, and C. Gao, A Novel Approach to Access Capacities of Red Cells in Dissolving Oxygen and Carrying Oxygen Based on a Portable Near-infrared Spectroscopy Device, Blood, 134(supplement_1): 4792, 2019.
[3]T. Li*, B Pan, Y. Gao, X. Huang, J. Pu, and C. Huang, Noninvasive and wearable optical monitoring of brain death with aid of a protocol at differentiated fractions of oxygen inspired, Blood, 134(supplement_1): 5808, 2019.
[4]W. Liu, W. Chen, X. Fang, Y. Li, T. Li*, Monte Carlo Modelling of Photon Migration in Realistic Human Thoracic Tissues for Noninvasive Monitoring of Cardiac Hemodynamics, J. Biophotonics, 12(7): e201900148, 2019.
[5]X. Fang, H. Li, W. Liu, Y. Li, T. Li*, A parallel mode optimized GPU accelerated Monte Carlo model for light propagation in 3-D voxelized bio-tissues, IEEE Access, 7(1): 81593-81598, 2019.
[6]W. Wang, H. Su, Y. Wu, T. Zhou, T. Li*, Biosensing and biomedical applications of graphene: a review of current progress and future prospect, J. Electrochem. Society, 166(6):3696, 2019.
[7]T. Li*, Y. Shang, W. Ge, Optical Technologies for Healthcare and Wellness Applications, J. Healthcare Eng., 2019: 1321348, 2019.
[8]C. Gao, M. Wang, L. He, Y. He, T. Li*, Alternations of hemodynamic parameters during Chinese cupping therapy assessed by an embedded near-infrared spectroscopy monitor, Biomed. Opt. Express, 10(1):196-203, 2019.
[9]Z. Kong, T. Li, J. Luo, S. Xu*, Automatic tissue image segmentation based on image processing and deep learning, J. Healthcare Eng., 2019: 2912458, 2019
[10]W. Wang, H. Su, Y. Su, T. Li*, Current application of graphene in biomedicine, Nanomedicine: Nanotechnology, Biology and Medicine, suppl, 2019, in press.
[11]T. Li*, W. Wang, and Y. Su, A mobile health system with aid of noninvasive graphene biomedical sensors for multiple health parameters, Nanomedicine: Nanotechnology, Biology and Medicine, suppl, 2019, in press.
[12]B. Pan, C. Huang, X. Fang, X. Huang, T. Li*, Noninvasive and Sensitive Optical Assessment of Brain Death, J. Biophotonics, 12(3): e201800240, 2018.
[13]P. Wang, T. Li*, Which wavelength is optimal for transcranial low-level laser stimulation? J. Biophotonics, 11(8): e201800173, 2018.
[14]J. Li, J. Pu, H. Cui, X. Xie, S. Xu, T. Li, Y. Hu*, An online P300 brain computer interface based on tactile selective attention of somatosensory electrical stimulation, J. Med. Biol. Eng., 39(?):1-7, 2019.
[15]X. Wan, G. Li, T. Li, W. Yan, G. He, L. Lin, A review on M + N theory and its strategies to improve the accuracy of spectrochemical composition analysis of complex liquids, Appl. Spectr. Rev., 53(12):2018.
[16]X. Fang, B. Pan, W. Liu, Z. Wang, T. Li*, Effect of Scalp Hair Follicles on NIRS Quantification by Monte Carlo Simulation and Visible Chinese Human Dataset, IEEE Photonics J., 10(5): 3901110,2018.
[17]T. Li*, Y. Lin, F. Zhong, Y. Gao, Longtime driving induced cerebral hemodynamic elevation and behavior degradation as assessed by functional near-infrared spectroscopy and a voluntary attention test, J. Biophotonics, 11(8): e201800160, 2018.
[18]W. Wang, Y. Su, and T. Li*, Graphene nanosensor is sensitive to quantify different concentrations of mouse glial cells, Nanomedicine: Nanotechnology, Biology and Medicine, suppl, 2019, in press.
[19]W. Wang, Y. Su, and T. Li*, Nano-in-vitro detection of human cancer cells by graphene sensor, Nanomedicine: Nanotechnology, Biology and Medicine, suppl, 2019, in press.
[20]W. Liu, X. Fang, Q. Chen, Y. Li, T. Li*, Reliability analysis of an integrated device of ECG, PPG and pressure pulse wave for cardiovascular disease, Microelectronics Reliability, 87, 2018, 183-187.
[21]K. Zhao, N. Li, Boan Pan, T. Li*, Performance Assessment of the NIRS-Based Medical System of Evaluating Therapeutic Effect, Microelectronics Reliability, 87, 188-193, 2018.
[22]T. Li*, Z. Li, K. Zhao, B. Pan, Z. Wang, X. Yang, Reliability analysis of a mini-instrument for simultaneous monitoring water content, deep tissue temperature, and hemodynamic parameters, Microelectronics Reliability, 86:72-76, 2018.
[23]T. Li*, P. Wang, L. Qiu, X. Fang, and Y. Shang, Optimize illumination parameter of low-level laser therapy for hemorrhagic stroke by Monte Carlo simulation on Visible Human Dataset, IEEE Photonics J., 10(3):6100409,2018.
[24]K. Zhao, B. Pan, Z. Li, F. Zhong, P. Wang, T. Li*, Performance evaluation for a novel optoelectronic device for noninvasive monitoring thrombosis, Microelectronics Reliability, 84: 134-139, 2018.
[25]Y. Zhao#, G. Xu#, Y. Gao, T. Li*, A portable High-density absolute-measure NIRS imager for detecting prefrontal lobe response to driving fatigue, Microelectronics Reliability, 82: 197-203, 2018.
[26]K.  Zhao, Y.  Ji, Y.  Li, T.  Li*, Online Removal of Baseline Shift with a Polynomial Function for Hemodynamic Monitoring Using Near-infrared Spectroscopy. Sensors，18(1), 312, 2018.
[27]Y. Zhao, L. Qiu, Y. Sun, C. Huang, T. Li*, Optimal hemoglobin extinction coefficient dataset for near-infrared spectroscopy, Biomed. Opt. Express, 8(11):5151-5159, 2017.
[28]L. Wu, Y. Lin, and T. Li*, Effect of Human Brain Edema on Light Propagation: A Monte Carlo Modeling Based on the Visible Chinese Human Dataset, IEEE Photonics J.,9(5):1-10, 2017.
[29]B. Pan, T. Li*, Yan Li, G. Xu, A reliable integrative autocorrelator device for particle fluctuation rate monitoring, Microelectronics Reliability, 78:280-284, 2017(audio slides invited).
[30]P. Wang, J. Sun, Q. Jiang, T. Li*, Cooling-controlled and reliable driving module for Low-level light therapy LED helmet, Microelectronics Reliability, 78:370-373, 2017(audio slides invited).
[31]T. Li*, F. Zhong, B. Pan, Z. Li, C. Huang, Z. Deng, A Brief Review of OPT101 Sensor Application in Near-Infrared Spectroscopy Instrumentation for Intensive Care Unit Clinics, Sensors, 17(8):1701, 2017.Invited Review.
[32]F. Zhong, Z. Kong, G. Xu, T. Li*, High Robustness and stability of a developed novel laser acupuncture theranostic device, Microelectronics Reliability, 78: 401-405, 2017(audio slides invited).
[33]T. Li*, C. Xue, P. Wang, Y. Li, L. Wu, Photon penetration depth in human brain for light monitoring and treatment: A Realistic Monte Carlo Simulation Study, J. Innovative Opt. Health Sci., 10(6):1743002, 2017.
[34]Y. Zhao, L. Qiu, K. Zhao, K. Li, Y. Sun, L. Meng, Z. Huang, T. Li*, Effect of 850 nm on reliability of 735/805/850-nm LED involved Near-infrared Spectroscopy biomedical device, Microelectronics Reliability, 78: 406-410, 2017(audio slides invited).
[35]T. Li*, Y. Su, L. Wu, B. Pan, Y. Li, Reliability analysis of a newly developed detector for monitoring spine health, Microelectronics Reliability, 78:411-414, 2017.
[36]T. Li*, Y. Li, Y. Lin, Kai Li, Significant and sustaining elevation of blood oxygen induced by Chinese cupping therapy as assessed by near-infrared spectroscopy, Biomed. Opt. Express. 8(1),276205, 2017.
[37]Y. Shang, T. Li, G. Yu, Clinical applications of near-infrared diffuse correlation spectroscopy and tomography for tissue blood flow monitoring and imaging, Physiol. Meas., 38，R1-R26, 2017, Invited Review (获期刊评选为Highlights of 2017).
[38]T. Li*, Y. Sun, X. Chen, et al. Noninvasive diagnosis and therapeutic effect evaluation of deep vein thrombosis in clinics by NIR spectroscopy. J. Biomed. Opt. 20(1), 010502, 2015.
[39]T. Li1*, M. Duan1, Y. Zhao, G. Yu, Z. Ruan. Bedside monitoring of patients with shock using a portable spatially-resolved near-infrared spectroscopy. Biomed. Opt. Express, 6(9):3431-3436, 2015. (1Equally contributed)
[40]T. Li*, Y. Li, Y. Sun, M. Duan, L. Peng. Effect of head model on Monte Carlo modeling of spatial sensitivity distribution for functional near-infrared spectroscopy, J. Innovative Opt. Health Sci., 8(5): 1550024, 2015.
[41]Z. Ruan1, T. Li1, R. Ren et al, Monitoring tissue blood oxygen saturation in the internal jugular venous area by NIRS. Gene. Molecular Res., 14(1): 2920-2928, 2015. (1Equally contributed)
[42]T. Li*, Y. Zhao, Y. Sun, M. Duan. Effects of wavelength, beam type and size on cerebral low-level laser therapy by a Monte Carlo study on Visible Chinese Human. J. Innov. Opt. Health Sci., 8(1),154002, 2014.
[43]T. Li, Y. Lin, Y. Shang, L. He, C. Huang, M. Szabunio, G. Yu*. Simultaneous measurement of deep tissue blood flow and oxygenation using noncontact diffuse correlation spectroscopy flow-oximeter. Sci. Rep., 3,1358, 2013.
[44]T. Li*, H. Gong, Q. Luo. Visualization of light propagation in Visible Chinese Human head for functional near-infrared spectroscopy. J. Biomed. Opt., 2011, 16(4), 145001. (列在当期研究论文之首)
[45]T. Li, Q. Luo, H. Gong*. Gender-specific hemodynamics in prefrontal cortex during visual verbal working memory by near-infrared spectroscopy. Behav. Brain Res., 2010, 209: 148-153. (脑与行为领域Top期刊)
[46]T. Li, H. Gong, Q. Luo*. MCVM: Monte Carlo modeling of photon migration in voxelized media. J. Innov. Opt. Health Sci., 2010, 3(2): 91-102.
[47]T. Li, H. Gong, Q. Luo*. Assessing Working Memory in Real-life Situations with Functional Near-infrared Spectroscopy. J. Innov. Opt. Health Sci., 2009, 2(4): 423-430.
[48]T. Li, H. Gong, Q. Luo et al. Pinpoint source location for ocular nonselective attention with combination of ERP and fNIRI measurements. J. Innov. Opt. Health Sci., 2008, 1(2): 195-206.
[49]Y. Shang, T. Li, L. Chen, Y. Lin, M. Toborek, and G. Yu, Extraction of diffuse correlation spectroscopy flow index by integration of Nth-order linear model with Monte Carlo simulation. Appl. Phys. Lett., 104(9), 193703, 2014.
[50]K. R. Dhakal, L. Gu, T. Li, et al. Non-Scanning Fiber-Optic Near-Infrared Beam Led to Two-Photon Optogenetic Stimulation In-Vivo. Plosone, 9(11): e111488, 2014.
[51]J. Zhai, T. Li, H. Gong, et al. Hemodynamic and electrophysiological signals of conflict processing in the Chinese-character Stroop task: a simultaneous near-infrared spectroscopy and event-related potential study. J. Biomed. Opt., 2009, 14(5): 054022.
[52]龚辉, 李成军, 李婷等. 前额叶皮层工作记忆作用的近红外光学成像. 中国科学, G, 2007, 37(增刊): 110-117.
EI论文
[53]李婷*，黄金蕊，高晨阳，中国中医药信息学会抗衰老分会，激光治疗雄激素脱发和斑秃的技术指南，国际生物医学工程杂志，42(2): 95-99, 2019.
[54]李婷*，蒲江波，王依倩，中国中医药信息学会抗衰老分会，物理技术辅助脑卒中康复的临床指南，国际生物医学工程杂志，42(2): 100-108, 2019.
[55]李婷*, 欧阳晨曦，黄金蕊，中国中医药信息学会抗衰老分会，欧美同学会医师协会血管分会，物理技术治疗冠心病的实践指南，生命科学仪器，17(4): 13-21, 2019. (亮点论文)
[56]陈文静，包文，刘伟超，李婷*, 重症监护场景下的神经血管响应监测技术研究，生命科学仪器，16: 3-15, 2018.（特邀综述, 封面亮点文章）
[57]T. Li*. Noncontact and simultaneous measurements of blood flow and oxygenation in deep tissue. Prog. Biomed. Eng. China, s16-1, 2013.
[58]T. Li*, Z. Zhang, Y. Zheng. Algorithm establishment with model experiment for continuous-wave functional near-infrared spectroscopy, Appl. Mech. Mat., 138/139: 553-559, 2011.
[59]T. Li, H. Gong, Q. Luo et al. A study of non-selective ocular attention with fNIRS and ERP, Acta. Opt. Sinica., 27(3): 531-535, 2007.
[60]A. Wang, T. Li, Q. Luo et.al. Influence of Real Forearm Structure on Light Transport based on MCVM. Acta. Opt. Sinica, 2011, 31(2): 317002-1.
[61]H. Gong, T. Li, Y. Zheng, et al. A portable functional imaging instrument for psychology research based on near-infrared spectroscopy, Front. Optoelectro.in China, 2008, 1(3-4): 279-284.
[62]曹传花, 李婷, 龚辉. NIRS系统在生物组织中的探测深度研究. 生物医学工程研究, 2006, 1: 32-34.
[63]郑毅, 骆清铭, 李婷等. 适于脑功能活动检测的便携式近红外光谱仪的研制. 中国生物医学工程学报, 2007, 26(6): 898-902.
[64]龚辉, 李成军, 李婷等. 用近红外光谱术监测汉语阅读障碍儿童前额叶皮层活动. 中国生物医学工程进展, 2007.
[65]X. Fang, T. Li*, Convolutional deep network for light propagation in heterogeneous bio-tissues, Proc. SPIE, 10876: 108760R, 2019.
[66]Z. Wang, X. Fang, T. Li*, Accurate calculation and visualization of absorption dose for facial low-level light therapy, Proc. SPIE, 10851: 1085110, 2019.
[67]W. Liu, W. Chen, Y. Li, T. Li*, Photons transmission on thoracic tissues by Monte Carlo modeling based on the visible Chinese human dataset, Proc. SPIE, 10855: 108550R, 2019.
[68]T. Li*, B. Pan, Functional near infrared spectroscopy in the noninvasive assessment of brain death, 40th Annual International Conference of the IEEE Medicine & Biology Society (EMBC), 1538-1541, 2018.
[69]N. Li, T. Li*, Noninvasive optical diagnosis of low back pain with the aid of Chinese cupping procedure, Proc. SPIE, 10501:105010N, 2018.
[70]X. Li, T. Li*, Smartphone-based grading of apple quality, Proc. SPIE, 10485:1048514, 2018.
[71]K. Zhao, Y. Ji, B. Pan, T. Li*, Charactering baseline shift with 4th polynomial function for portable biomedical near-infrared spectroscopy device, Proc. SPIE, 10486: 1048616, 2018.
[72]N. Li, T. Li*, Design and performance test of NIRS-based spinal cord lesion detector, Proc. SPIE, 10484: 104840X, 2018.
[73]B. Pan, X. Fang, W. Liu, N. Li, K. Zhao, T. Li*, Monte Carlo simulation of near-infrared light propagation in realistic adult head models with hair follicles, Proc. SPIE, 10484: 1048414, 2018.
[74]Z. Li, T. Li*, Noninvasive optical monitoring multiple physiological parameters response to cytokine storm, Proc. SPIE, 10489: 104890N, 2018.
[75]X. Li, J. Xue, W. Li, T. Li*, Smartphone-based assessment of blood alteration severity, Proc. SPIE, 10485: 1048502, 2018.
[76]B. Pan, W. Liu, X. Fang, X. Huang, T. Li*, Which experimental model can sensitively indicate brain death by functional near-infrared spectroscopy? Proc. SPIE, 10484: 1048418, 2018.
[77]Z. Deng, Y. Gao, T. Li*, Comparison on driving fatigue related hemodynamics activated by auditory and visual stimulus, Proc. SPIE, 10480: 104800A, 2018.
[78]Z. Li, X. Li, T. Li*, Noninvasive monitoring local variations of fever and edema on human: potential for point-of-care inflammation assessment, Proc. SPIE, 10479: 104790D, 2018.
[79]B. Pan, W. Liu, X. Fang, K. Zhao, T. Li*, Vena cava filters and thrombolytic therapeutic monitoring based on functional near-infrared spectroscopy for deep vein thrombosis, Proc. SPIE, 10484: 104840V, 2018.
[80]P. Wang, J. Sun, L. Meng, Z. Li, T. Li*, Therapeutic effect of forearm low level light treatment on blood flow, oxygenation, and oxygen consumption, Proc. SPIE, 10477: 1047707, 2018.
[81]Z. Kong, J. Luo, S. Xu, T. Li*, Automatical and accurate segmentation of cerebral tissues in fMRI dataset with combination of image processing and deep learning, Proc. SPIE, 10485: 104850A, 2018.
[82]Z. Deng, Y. Gao, T. Li*, Low-frequency oscillation amplitude elevation of prefrontal cerebral hemodynamics with driving duration during prolonged driving test, Proc. SPIE, 10481: 104810Y, 2018.
[83]B. Pan, F. Zhong, K. Zhao, T. Li*, Design and reliability analysis of a novel laser acupuncture device, Proc. SPIE, 10477: 104770N, 2018.
[84]P. Wang, J. Sun, Z. Li, T. Li*, Low level light therapy on stroke with a portable and illumination-parameter adjustable LED helmet: a review, Proc. SPIE, 10480: 1048003, 2018.
[85]Z. Kong, J. Luo, S. Xu, T. Li*, Automatic tissue image segmentation based on image processing and deep learning, Proc. SPIE, 10481: 104811T, 2018.
[86]B. Pan, F. Zhong, X. Huang, L. Pan, S. Lu, and T. Li*, Evaluation and diagnosis of brain death by Functional near-infrared spectroscopy, Proc. Of SPIE,10054: 100541B-1, 2017.
[87]P. Wang, B. Pan, and F. Zhong, and T. Li*, A visible Chinese human-combined Monte Carlo simulation study on low-level therapy of stroke, Proc. Of SPIE, 10066:100660C,2017.
[88]B. Pan, P. Wang, Y. Li, Y. Gao, and T. Li*, Thrombolytic therapeutic effect monitoring based on functional near-infrared spectroscopy, Proc. Of SPIE, 10054: 100540R, 2017.
[89]F. Zhong, T. Li*, B. Pan, and P. Wang, 3D Monte Carlo simulation of light propagation for laser acupuncture and optimization of illumination parameters, Proc. Of SPIE, 10048: 100480H, 2017.
[90]T. Li*, K. Li, A noninvasive device for simultaneous monitoring arterial and venous blood oxygenation and its test in vacuum-based cupping therapy, IEEE International Nanoelectronics Conference (INEC), 2016: 1-2.
[91]T. Li*, F. Zhong, Near-infrared spectroscopy-based detector in specified clinics, IEEE International Nanoelectronics Conference (INEC), 2016: 1-2.
[92]T. Li*, Y. Su, Design and reliability analysis of a novel detector for monitoring spine disease, IEEE International Nanoelectronics Conference (INEC), 2016: 1-2.
[93]Q. Cao, C. Gao, Y. Wang, T. Li*, The motion capture data glove device for virtual surgery, IEEE International Nanoelectronics Conference (INEC), 2016: 1-2.
[94]Y. Li, X. Dong, Q. Li, T. Li*, Low-frequency oscillation evaluation modeling of functional brain activity potential, IEEE International Nanoelectronics Conference (INEC), 2016: 1-2.
[95]W. Ge, Y. Liu, X. Xiao, T. Li*, A design for three-dimensional visualized detector of space's nuclear radioactivity. IEEE International Nanoelectronics Conference (INEC), 2016: 1-2.
[96]K. Li, B. Pan, Y. Gao, Z. Ruan and T. Li*, A novel method to estimate oxygen saturation of the internal jugular vein blood, Proc. of SPIE, 96981: 96981F-7,2016.
[97]B. Pan, K. Li, Y. Gao, Z. Ruan and T. Li*, Which blood oxygen can sensitively indicate shock severity?, Proc. of SPIE, 96981: 96981E-6, 2016.
[98]Y. Sun and T. Li*, Multi-channel photon migration study in visible Chinese human muscle for optical detection of deep vein thrombosis, Proc. of SPIE,97061: 97061N-7 (2016)
[99]Y. Sun and T. Li*, Shed a light of wireless technology on portable mobile design of NIRS, Proc. of SPIE,96990: 96990W-9 (2016)
[100]Y. Gao, B. Pan, K. Li and T. Li*, Shed a light in fatigue detection with near-infrared spectroscopy during long-lasting driving, Proc. of SPIE,96901: 96901T-6 (2016)
[101]P. Wang, Y. Gao, X. Chen and T. Li*, Illumination-parameter adjustable and illumination-distribution visible LED helmet for low-level light therapy on brain injury, Proc. of SPIE, 97000: 97000S-7 (2016)
[102]Y. Su, T. Li* and Y. Sun, Reliability analysis of instrument design of noninvasive bone marrow disease detector, Proc. of SPIE, 96894: 96894R-8 (2016)
[103]Y. Su and T. Li*, Noninvasive optical measurement of bone marrow lesions: a Monte Carlo study on visible human dataset, Proc. of SPIE, 97061: 970615-8 (2016)
[104]Y. Su and T. Li*, A portable cross-shape near-infrared spectroscopic detector for bone marrow lesions diagnosis, Proc. of SPIE, 96894: 96894K-7 (2016)
[105]T. Li*, Y. Sun, X. Chen, Y. Zhao. Noninvasive diagnosis and continuous monitoring of thrombosis in clinics by near-infrared spectroscopy. Proc. of SPIE,9313, 931318-2, 2015.
[106]T. Li*, Y. Zhao, Y. Sun, K. Li, W. Li, C. Zhang, J. Liu. Calibration of NIRS-measured hemodynamics with best-matched hemoglobin extinction coefficients and group statics on human-blood-model data. Proc. of SPIE, 9315, 931508-2, 2015.
[107]T. Li*, Y. Zhao, Y. Sun, Y. Gao, Y. Su, Y. Hetian, M. Chen. Near-infrared spectroscopy assessment of divided visual attention task-invoked cerebral hemodynamics during prolonged true driving. Proc. of SPIE, 9305, 93052I-1, 2015.
[108]T. Li*, Y. Zhao, K. Li, Z. Ruan, M. Duan, Y. Sun. Study on shock monitoring using a space-resolved NIRS. Proc. of SPIE PIBM, 2014.
[109]T. Li*, Y. Zhao, Y. Sun, K. Li. A portable High-density absolute-measure NIRS imager for detecting prefrontal lobe activity under fatigue driving. Proc. of SPIE PIBM, 2014.
[110]T. Li*, Y. Zhao, K. Li, Y. Sun, M. Duan, W. Li. Does 805 nm contribute to precision of measurements of blood oxygenation at using 735/805/850- nm LED? Proc. of SPIE PIBM, 2014.
[111]T. Li*, Y. Zhao, K. Li, Y. Sun, M. Duan, W. Li. Which published Extinction coefficient dataset matched the best with the Asians? Proc. of SPIE PIBM, 2014.
[112]T. Li*, Y. Zhao, M. Duan, K. Li, Y. Sun. Wavelength, beamsize and type dependencies of cerebral low-level light therapy: A Monte Carlo simulation study. Proc. of SPIE, 8928, 89280Q, 2014.
[113]T. Li*, Y. Zhao,Y. Sun, K. Li. Noninvasive optical evaluation of low frequency oscillation in prefrontal cortex hemodynamics during verbal working memory. Proc. of SPIE, 8932, 8932091, 2014.
[114]T. Li*. Comparison between Continuous and Discrete absorption weighting for Monte Carlo modeling photon transport in tissue. Intern. Conf. Comput. Network Tech., V14-204, 2011.
[115]T. Li*, Z. Zhang, Y. Zheng. Algorithm Establishment with model experiment for continuous-wave functional near-infrared spectroscopy. International conference on Future Biomedical Information Engineering, 2010, 70-73.
[116]H. Tejeda, T. Li, S. Mohanty. Comparison between Bessel and Gaussian beam propagation for in-depth optogenetic stimulation. Proc. of SPIE, 85860G,2013.
[117]M. Gu, K. Dhakal, T. Li et al. Shinning new light on Optogenetics. Proc. of SPIE, 8207: 820764, 2012. (被Nature Photonics 2012, 6: 222-223评述)
[118]D. S. Gareau, T. Li, S. L. Jacques et al. Inhomogeneous Monte Carlo simulations of dermoscopic spectroscopy. Proc. of SPIE, 8225: 82251B, 2012.
[119]J. Zhai, T. Li, H. Gong, et al. Simultaneous functional near-infrared brain imaging and event-related potential studies of Stroop effect, Proc. of SPIE, 2009, 7161: 71613D.
[120]Z. Zhang, T. Li, H. Gong, et al. Study the left prefrontal cortex activity of Chinese children with dyslexia in phonological processing by NIRS. Proc. of SPIE, 2006, 6078: 607833.
[121]L. Li, P. Du, T. Li, et al. Design and evaluation of a simultaneous fNIRS/ERP instrument. Proc. of SPIE, 2007, 6434: 643429.
[122]T. Li, H. Gong, Q. Luo et al. FRAP data processing with three-exponential fitting method. Proc. of SPIE, 2005, 5696: 159-167.
国际学术交流
[1] Ting Li, Oral presentation, “Online noninvasive assessment of human brain death by Near-infrared Spectroscopy with protocol at varied fraction of inspired O2”, ISOTT 47th Annual Conference, New Mexico, USA, July 27-31th, 2019.
[2] Ting Li, Invited Talk, “Effect of voc and big-LED screen on human brain function for Healthy building ”, Forum prior Healthy Building Conference，Changsha，July 6th, 2019.
[2] Ting Li, Invited Talk, “noninvasive optical monitoring in deep tissue: from Bench to clinics”, 中国生物医学工程学会生物医学光子学分会换届大会，海口，April 26-28th, 2019.
[2] Ting Li, Invited Talk, “适于多生理参数穿戴监测的体温检测技术”, 华为运动健康论坛，深圳，April 11-12th, 2019.
[3] X. Fang, T. Li*, Oral presentation, Convolutional deep network for light propagation in heterogeneous bio-tissues, SPIE Photonics West, 2019.1.31-2.6, San Francisco.
[4] Z. Wang, X. Fang, T. Li*, Poster presentation, Accurate calculation and visualization of absorption dose for facial low-level light therapy, SPIE Photonics West, 2019.1.31-2.6, San Francisco.
[5] W. Liu, W. Chen, Y. Li, T. Li*, Poster presentation, Photons transmission on thoracic tissues by Monte Carlo modeling based on the visible Chinese human dataset, SPIE Photonics West, 2019.1.31-2.6, San Francisco.
[6] Ting Li, Invited Talk, “4-D Near-infrared light propagation modeling and its application”, 中国生命电子学会年会，武汉，November 13-16th, 2018.
[7] Ting Li, Invited Talk, “多模态检测技术的心肌缺血诊断与预测研究”，中国生命电子学会年会，武汉，November 13-16th, 2018
[8] Ting Li, Invited Talk, “Functional Near-infrared Spectroscopy/tomography of Deep Tissue Hemodynamics: From Bench to Clinics”, 中国生物医学工程联合学术年会, Shenzhen, September 20-22th, 2018
[9] Ting Li, Invited Talk, “Near-infrared light in noninvasive deep tissue monitoring: from lab to hospital”, IEEE OGC 2018, Shenzhen, September 4-6th, 2018
[10] Ting Li, Oral presentation, “functional near-infrared spectroscopy: Achievements in theory, instrumentation, and application”, 中国生物医学工程青年论坛, Tianjin, August 3-5, 2018
[11] Ting Li, Oral presentation, “Noninvasive optical assessment of brain death by custom fNIRS”, IEEE EMBC 40th Annual Conference, Hunululu, Hawaii, USA, July 17-21, 2018
[12] Ting Li, Invited Talk, “Optical monitoring and treatment for deep tissue hemodynamics and 4-D light transport modeling in biological tissues”, Multidisciplinary cross academic Federation, Nankai University, June 10th, 2018.
[13] Ting Li, Invited Talk, “NIRS/DCS for deep tissue hemodynamics: from lab to hospitals”, International Forum for Health Electronics, Beijing, June 4th, 2018
[14] Ting Li, Invited Talk, “NIRS/DCS for deep tissue hemodynamics monitoring and treatment: from bench to clinics”, International Symposium for Medical Photonics, Beijing, June 1st-3rd, 2018
[15] Ting Li, Invited Talk, ‘Noninvasive optical technology for Chinese Medicine’, Asia Pacific Laser Symposium, Xian, May 28-31, 2018.
[16] T. Li*, Oral presentation, Noninvasive optical diagnosis of low back pain with the aid of Chinese cupping procedure, SPIE Photonics West, 2018.1.27-2.1, San Francisco.
[17] T. Li*, Oral presentation, Smartphone-based grading of apple quality, SPIE Photonics West, 2018.1.27-2.1, San Francisco.
[18] T. Li*, Poster presentation, Charactering baseline shift with 4th polynomial function for portable biomedical near-infrared spectroscopy device, SPIE Photonics West, 2018.1.27-2.1, San Francisco.
[19] T. Li*, Oral presentation, Design and performance test of NIRS-based spinal cord lesion detector, SPIE Photonics West, 2018.1.27-2.1, San Francisco.
[20] T. Li*, Oral presentation, Monte Carlo simulation of near-infrared light propagation in realistic adult head models with hair follicles, SPIE Photonics West, 2018.1.27-2.1, San Francisco.
[21] T. Li*, Oral presentation, Noninvasive optical monitoring multiple physiological parameters response to cytokine storm, SPIE Photonics West, 2018.1.27-2.1, San Francisco.
[22] T. Li*, Oral presentation, Smartphone-based assessment of blood alteration severity, SPIE Photonics West, 2018.1.27-2.1, San Francisco.
[23] T. Li*, Poster presentation, Which experimental model can sensitively indicate brain death by functional near-infrared spectroscopy? SPIE Photonics West, 2018.1.27-2.1, San Francisco.
[24] T. Li*, Oral presentation, Comparison on driving fatigue related hemodynamics activated by auditory and visual stimulus, SPIE Photonics West, 2018.1.27-2.1, San Francisco.
[25] T. Li*, Oral presentation, Noninvasive monitoring local variations of fever and edema on human: potential for point-of-care inflammation assessment, SPIE Photonics West, 2018.1.27-2.1, San Francisco.
[26] T. Li*, Oral presentation, Vena cava filters and thrombolytic therapeutic monitoring based on functional near-infrared spectroscopy for deep vein thrombosis, SPIE Photonics West, 2018.1.27-2.1, San Francisco.
[27] T. Li*, Oral presentation, Therapeutic effect of forearm low level light treatment on blood flow, oxygenation, and oxygen consumption, SPIE Photonics West, 2018.1.27-2.1, San Francisco.
[28] T. Li*, Oral presentation, Automatical and accurate segmentation of cerebral tissues in fMRI dataset with combination of image processing and deep learning, SPIE Photonics West, 2018.1.27-2.1, San Francisco.
[29] T. Li*, Oral presentation, Low-frequency oscillation amplitude elevation of prefrontal cerebral hemodynamics with driving duration during prolonged driving test, SPIE Photonics West, 2018.1.27-2.1, San Francisco.
[30] T. Li*, Oral presentation, Design and reliability analysis of a novel laser acupuncture device, SPIE Photonics West, 2018.1.27-2.1, San Francisco.
[31] T. Li*, Oral presentation, Low level light therapy on stroke with a portable and illumination-parameter adjustable LED helmet: a review, SPIE Photonics West, 2018.1.27-2.1, San Francisco.
[32] T. Li*, Poster presentation, Automatic tissue image segmentation based on image processing and deep learning, SPIE Photonics West, 2018.1.27-2.1, San Francisco.
[25] T. Li, Invited Talk, ‘Functional Near-infrared spectroscopy/tomography of Deep Tissue Hemodynamics: Application on Thrombosis and Shock’, CMACHC(中国心脏大会暨中国血管大会), Beijing, 2017.8.12.
[26] T. Li, Oral presentation, ‘3D Monte Carlo simulation of light propagation for laser acupuncture and optimization of illumination parameters,’ SPIE Photonics West, 2017.1, San Francisco.
[27] T. Li, Poster presentation, ‘Evaluation and diagnosis of brain death by functional near-infrared spectroscopy,’ SPIE Photonics West, 2017.1, San Francisco.
[28] T. Li, Oral presentation, ‘A visible Chinese human-combined Monte Carlo simulation study on low-level light therapy of stroke,’ SPIE Photonics West, 2017.1, San Francisco.
[29] T. Li, Oral presentation, ‘Thrombolytic therapeutic effect monitoring based on functional near-infrared spectroscopy,’ SPIE Photonics West, 2017.1, San Francisco.
[30] T. Li, Invited Talk, ‘Functional Near-infrared spectroscopy/tomography of Deep Tissue Hemodynamics for Monitoring and Treatment’ Beihang International Scholar conference, 2016.12, Beijing
[31] T. Li, Invited Talk, ‘Functional Near-infrared spectroscopy/tomography’ Behang University, 2016.9, Beijing
[32] T. Li, Invited Talk, ‘Near-infrared spectroscopy/tomography for medical monitoring and treatment,’ Chinese Academy of Medical Sciences and Peking Union Medical College, 2016.7, Tianjin
[33] T. Li, Invited Talk, ‘Near-infrared spectroscopy-based detector for specified clinics,’ INEC, 2016.5, Chengdu.
[34] T. Li, Oral presentation, ‘A portable cross-shape near-infrared spectroscopic detector for bone marrow lesions diagnosis,’ SPIE Photonics West, 2016.2, San Francisco.
[35] T. Li, Oral presentation, ‘Reliability analysis of instrument design of noninvasive bone marrow disease detector,’ SPIE Photonics West, 2016.2, San Francisco.
[36] T. Li, Invited Talk, ‘Which blood oxygen index can sensitively indicate shock severity?’, SPIE Photonics West, 2016.2, San Francisco.
[37] T. Li, Oral presentation, ‘A novel method to estimate oxygen saturation of the internal jugular vein blood’, SPIE Photonics West, 2016.2, San Francisco.
[38] T. Li, Oral presentation, ‘Illumination-parameter adjustable and illumination-distribution visible LED helmet for low-level light therapy on brain injury’, SPIE Photonics West, 2016.2, San Francisco.
[39] Y. Su and T. Li*, Oral presentation, “A portable cross-shape near-infrared spectroscopic detector for bone marrow lesions diagnosis,” SPIE Photonics West, 2016.2, San Francisco.
[40] Y. Sun and T. Li*, Poster presentation, “Multi-channel photon migration study in visible Chinese human muscle for optical detection of deep vein thrombosis,” SPIE Photonics West, 2016.2, San Francisco.
[41] Y. Sun and T. Li*, Poster presentation, “Shed a light of wireless technology on portable mobile design of NIRS,” SPIE Photonics West, 2016.2, San Francisco.
[42] Y. Gao, B. Pan, K. Li and T. Li*, Poster presentation, “Shed a light in fatigue detection with near-infrared spectroscopy during long-lasting driving,” SPIE Photonics West, 2016.2, San Francisco.
[43] T. Li, Invited talk, ‘From bench to clinics: Biomedical optical devices’, IEEE OECC, 2015.7, Shanghai.
[44] T. Li, Oral presentation, ‘Noninvasive diagnosis and continuous monitoring of thrombosis in clinics by near-infrared spectroscopy’, SPIE Photonics West, 2015.2, San Francisco.
[45] T. Li, Oral presentation, ‘Calibration of NIRS-measured hemodynamics with best-matched hemoglobin extinction coefficients and group statics on human-blood-model data’, SPIE Photonics West, 2015.2, San Francisco.
[46] T. Li, Poster presentation, ‘Near-infrared spectroscopy assessment of divided visual attention task-invoked cerebral hemodynamics during prolonged true driving’. SPIE Photonics West, 2015.2, San Francisco.
[47] T. Li, Invited talk, ‘Study on monitoring shock with space-resolved NIRS’, PIBM, 2014, 6, Wuhan.
[48] T. Li, Yue Zhao, Yunlong Sun, Kai Li. Poster presentation, ‘A portable High-density absolute-measure NIRS imager for detecting prefrontal lobe activity under fatigue driving’, PIBM, 2014, 6, Wuhan.
[49] T. Li, Yue Zhao, Kai Li, Yunlong Sun, MeixueDuan, Wenjie Li. Poster presentation, ‘Does 805 nm contribute to precision of measurements of blood oxygenation at using 735/805/850- nm LED?’, PIBM, 2014, 6, Wuhan.
[50] T. Li, Yue Zhao, Kai Li, Yunlong Sun, MeixueDuan, Wenjie Li. Poster presentation, ‘Which published Extinction coefficient dataset matched the best with the Asians?’ , PIBM, 2014,6, Wuhan.
[51] T. Li, invited talk, ’Near-infrared light stimulation and monitoring in biomedicine’, distinguished young researcher symposium, Engineering College, Zhongshan University, 2014, 4.
[52] T. Li, Oral presentation, ‘Wavelength, beamsize and type dependencies of cerebral low-level light therapy: A Monte Carlo simulation study’, SPIE Photonics West, 2014.2, San Francisco.
[53] T. Li, Oral presentation, ‘Noninvasive optical evaluation of low frequency oscillation in prefrontal cortex hemodynamics during verbal working memory’, SPIE Photonics West, 2014.2, San Francisco.
[54] T. Li, Invited talk, ‘Noncontact diffuse correlation spectroscopy flow-oximeter for simultaneous measurement of deep tissue blood flow and oxygenation’, IEEE IEDMS 2013, Taiwan.
[55] T. Li, Oral presentation, ‘Noncontact and simultaneous measurements of blood flow and oxygenation in deep tissue’, Annual conference for Biomedical Engineering in China 2013, Cheng Du.
[56] T. Li, Invited talk, ’Near-infrared light monitoring and treatment’, 2012, 10, Life Science &Technology College, University of Electronic Science &Technology.
[57] T. Li, Oral presentation, ‘Effect of cerebral cortex sulci on near-infrared light propagation during monitoring and treatment’, Biomed. Opt. OSA 2012, BW4B.6, Miami, Florida.
[58] T. Li, Poster presentation, ‘Gender-specific hemodynamics in prefrontal cortex during verbal working memory task by near-infrared spectroscopy’, Biomed. Opt. OSA 2012, JM3A.25, Miami, Florida.
[59] T. Li, Invited talk, ‘Near-infrared spectroscopy & light propagation’, Nirfast workshop, 2012, Miami, Florida (Achieved $500 award)
[60] T. Li, Invited talk, ‘4-D modeling of light propagation in biological tissue’, IEEE ISOT 2011, Hongkong.
专利等知识产权
[1]李婷 高晨阳，一种通用光学生理信号检测探头装置，发明专利，201811516202.6
[2]高晨阳 李婷，基于小间距参考通道的表层干扰在线去除装置及其方法，发明专利，201910316291.8
[3]李婷 高晨阳，拔罐疗法中的血液动力学参数检测系统及其疗效评估方法. 发明专利，201811266861.9，实用新型，授权号：CN 209269674 U
[4]李婷 王鹏波，一种高精度的带有负反馈的三维智能平移台. 发明专利，201711222534.9；实用新型，授权号：201721623363.6
[5]李迎新 刘伟超 申岱 李婷，一种基于线性幅值谱的心率变异性分析方法. 发明专利，201811176436.0
[6]李婷 黄家泰 王志远，基于单片机控制的近红外LED面膜. 发明专利，201811343918.0；实用新型，201821757735.9
[7]李婷 潘柏安，非侵入式脑死亡检测评估仪器. 发明专利，201711222326.9；实用新型，201721623364.0.
[8]李婷 王鹏波，一种用于脑血管病治疗的无创光学仪器. 发明专利，201810062113.2，实用新型201820107233.5.
[9]李婷 潘伯安，一种无创光学脑组织氧代谢的测量方法. 发明专利，201810062054.9.
[10]李婷 孟令康 李明程 王蔚然 邢超, 可移动式疲劳驾驶监测仪. 发明专利, 201710505305.1.
[11]李婷李耀先孙源良赵瑞辉, 基于云计算的支持隐私保护的个性化搜索系统. 发明专利, 201611222786.7.
[12]李婷 孙源良 李耀先 王赋翼 王鹏飞,基于行为特征的隐私安全保护系统. 发明专利,201611225684.0.
[13]李婷 苏宇. 发明专利, 一种非侵入式脊柱骨髓病变检测仪, 201510953275.1.
[14]李婷何田依依刘俊鹏潘伯安,混合和中央静脉氧饱和度的光学无创检测方法. 发明专利,201510148066.x.
[15]李婷邹文博张笑天李凯, 一种混合和中央静脉氧饱和度的光学无创检测方法. 发明专利,201510148310.2.
[16]李婷陈敏李凯可穿戴设备. 发明专利,201510149674.2.
[17]李婷赵越李凯高原朱厉阳. 一种人体深层组织温度测量仪及测量方法. 发明专利, 授权号: 201410717936.6.
[18]李婷苏宇等. 近红外光谱人体血液动力学检测装置及运动干扰的消除方法. 发明专利, 201410650522.6.
[19]李婷孙云龙等. 一种非侵入式血栓检测仪. 发明专利, 201410636048.1
[20]李婷高原等. 一种便携式光学无创乳腺自查仪. 发明专利, 201410632514.9.
[21]李婷李凯等. 一种光学非侵入式休克监护仪及其检测方法. 发明专利, 201410449443.9.
[22]李婷 胡晓翔 李文杰. 用于治疗脑疾病的近红外光治疗仪. 发明专利, ZL201410450333.4.
[23]李婷赵越等. 一种用于外科手术的微创手术刀. 发明专利, 授权号: ZL201410366477.1.
[24]李婷赵越等. 一种手术缝合器. 发明专利, 201410365930.7.
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[26]李婷. 人体组织血氧饱和度绝对量检测装置及其方法. 发明专利, 20130644371.9.
[27]李婷, 赵越, 孙云龙等. 一种局部脑组织血氧饱和度绝对量检测装置及检测方法. 发明专利, 201310726021.7.
[28]李婷, 赵越, 李凯等. 一种局部脑组织血氧血容绝对量检测装置及检测方法. 发明专利, 授权号: ZL201310727464.8.
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[30]李婷, 龚辉, 骆清铭. 光在生物组织中传输特性的定量蒙特卡罗模拟方法. 发明专利, 授权号: ZL 200810047962.7.
[31]李婷, 龚辉, 骆清铭等. 一种实现近红外脑功能检测仪测量同步的方法和装置. 发明专利, 授权号: ZL 200810306739.X.
[32]李婷, 龚辉，骆清铭等. 一种光学多参数生理监测仪. 发明专利,授权号: ZL 200910303109.1.
[33]李婷, 龚辉, 骆清铭. 获取稳态/瞬态光漫射特性的分析系统及方法. 发明专利, 授权号: ZL 200910300161.1.
[34]李婷, 龚辉, 骆清铭. 近红外医学检测仪多通道/多台机同步控制系统及方法. 发明专利,  授权号: ZL 200910300164.5.
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授课偏好
生物医学光子学、医疗仪器设计、医学人工智能、高级语言程序设计、信号处理与统计分析等。