张珏 - 北京大学

个人简介

工作经历 2023年北京大学国家生物医学成像科学中心数据系统与成果转化顾问 2023年北大-科杰华乐生物医学与数据工程联合实验室主任 2023年北京大学分子医学南京转化研究院副院长 2021年北京大学国家生物医学成像科学中心超声超分辨成像 PI 2019年入选北京市战略人才团队成员 2018年北京大学分子医学南京转化研究院数据中心主任 PI 2017年中国食品药品企业质量安全促进会检测技术委员会副主任委员 2009- 至今, 北京大学前沿交叉学科研究院生物医学跨学科研究中心博士生导师 2007- 至今, 北京大学工学院生物力学与医学工程副教授，博士生导师 2006-2007, 美国Old Dominion University Frank Reidy 生物电研究中心访问学者 2003-2006, 北京大学力学与工程科学系讲师 1998-2000, 加拿大OPI公司 (Calgary) 中方技术总监 1997-1998, 方正奥德证券事业部技术总监 1993-1996, 广东省珠海电力工业局工程部助理工程师教育经历 2003年北京大学力学与工程科学系获工程力学理学博士学位 2000年北京大学力学与工程科学系获实验力学理学硕士学位 1993年中国农业大学建筑工程系获工学学士学位

研究领域

1) 生物力学/医学学信号与图像分析 (Medical Signals & Image Analysis) 2) 临床功能核磁共振成像 (Clinical fMRI Pulse Sequence & RF Coil Design) 3) 等离子体医学以及纳秒脉冲电场 (Plasma Medicine & Nanosecond Pulsed Electric Field)

近期论文

查看导师最新文章（温馨提示：请注意重名现象，建议点开原文通过作者单位确认）

[1] Enhanced Acoustic Droplet Vaporization through the Active Magnetic Accumulation of Drug-Loaded Magnetic Particle-Encapsulated Nanodroplets (MPE-NDs) in Cancer Therapy, Nano Letters, 2022，doi.org/10.1021/acs.nanolett.2c02580 [2]Arterial Labeling Ultrasound Subtraction Angiography (ALUSA) Based on Acoustic Phase-change Nanodroplets, Small,2022,18 (12) 2105989 [3] Blinking Acoustic Nanodroplets Enabling Fast Super-resolution Ultrasound Imaging, ACS Nano,2021, 15(10) 16913–16923 [4] Ultrasound Microvascular Imaging Based on Super‐Resolution Radial Fluctuations, Ultrasound in Medicine & Biology, 2020, 8:53223-53231 [5] Cold Plasma gas loaded microbubbles as a novel ultrasound contrast agent, Nanoscale, 2019,11,1123-1130 [6] Flow Artifact Removal in Carotid Wall Imaging based on Black- and Gray- Blood Dual Contrast Images Subtraction, Magnetic Resonance in Medicine 2017,77(4):1612-1618 [7] Simultaneous Dynamic R2, R2' and R2* Measurement using Periodic π Pulse Shifting Multi-echo Asymmetric Spin Echo (psMASE) Sequence and Moving Estimation Strategy: A Feasibility Study for Lower Extremity Muscle, Magnetic Resonance in Medicine, 2017,77(2):766–773 [8] Turbo fast three‐dimensional carotid artery black‐blood MRI by combining three‐dimensional MERGE sequence with compressed sensing, Magnetic Resonance in Medicine, 2013,70(5):1347-1352 [9] Quantitative cerebral blood flow (CBF) mapping and Functional Connectivity of Postherpetic Neuralgia Pain (PHN): A Perfusion fMRI study, Pain, 2013,154:110–118 [10] Intranasal Insulin Enhanced Resting-State Functional Connectivity of Hippocampal Regions of in Type 2 Diabetes, Diabetes, 2015,64(3): 1025-1034 [11] Apparent Diffusion Coefficients of Metabolites in patients with MELAS Using Diffusion Weighted Magnetic Resonance Spectroscopy, American Journal of Neuroradiology, 2012,32(5): 898-902 [12] Quantitative Assessment of External Carotid Artery Territory Supply with Modified Vessel Encoded Arterial Spin Labeling, American Journal of Neuroradiology, 2012,33(7):1380-1386 [13] Direct current stimulation over the human sensorimotor cortex modulates the brain's hemodynamic response to tactile stimulation, European Journal of Neuroscience, 2015,42(3): 1933-1940 [14] Quantitative Coordination Evaluation for Duchenne Muscular Dystrophy Children, Chaos, 2020, 30(2):023116 [15] Encoding of Social Novelty by Sparse GABAergic Neural Ensembles in the Prelimbic Cortex, Science Advances, 2022 DOI: 10.1126/sciadv.abo4884 [16] Su-MICL: Severity-Guided Multiple Instance Curriculum Learning for Histopathology Image Interpretable Classification, IEEE Transactions on Medical Imaging, 2022，doi: 10.1109/TMI.2022.3188326