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地方课题4提交
四、项⽬已取得的学术成果
| 序号 | 论⽂篇名或专著名 | 作者 | 刊名或出版社 | 出版年份 | 卷号(期号) | 开始⻚码 | 结束⻚码 | 是否为SCI/EI | 是否为NATURE/SCIENCE/CELL主刊 |
|---|---|---|---|---|---|---|---|---|---|
| 1 | Smart stimuli-responsive injectable gels and hydrogels for drug delivery and tissue engineering applications:A review | Salehi S, Naghib S M, Garshasbi H R, et al | Frontiers in Bioengineering and Biotechnology | 2023 | 11 | 1104126 | 1104126 | 是 | 否 |
| 2 | Polyphenol-mediated hyaluronicacid/tannic acidhydrogel with short gelation timeand high adhesion strength foraccelerateing wound healing | Jin X, Wei C, Li K, et al | Carbohydrate Polymers | 2024 | 342 | 122372 | 122372 | 是 | 否 |
| 3 | Advances in MXene-based triboelectric nanogenerators | Ghorbanzadeh S, Zhang W | Nano Energy | 2024 | 125 | 109558 | 109558 | 是 | 否 |
| 4 | Machine learning method for extracting elastic modulus of cells | Zhou G, Chen M, Wang C, et al | Biomechanics and Modeling in Mechanobiology | 2022 | 21(5) | 1603 | 1612 | 是 | 否 |
| 5 | Macroporous polyvinylalcohol-tannic acid hydrogel with high strengthand toughness for cartilage replacement | Li H, Li J, Li T, et al | Journal of Materials Science | 2022 | 57(17) | 8262 | 8275 | 是 | 否 |
| 6 | Interconnected porous N-doped carbon coated cobalt/iron oxides core shell nanocomposites for superior lithium storage anode | Dong D, Zhang W, Gong W, et al | Journal of Alloys and Compounds | 2021 | 862 | 158044 | 158044 | 是 | 否 |
| 7 | Real-world efficacy and safety of TACE plus camrelizumab and apatinib in patients with HCC(CHANCE2211): a propensity scorematching study | Jin Z C, Zhong B Y, Chen J J, et al | European radiology | 2023 | 33(12) | 8669 | 8681 | 是 | 否 |
| 8 | How woodpecker protects its brain from concussionduring pecking compared with chickenand pigeon | Li Y, Zhang W, Meng Q L, et al | AIP Advances | 2020 | 10(6) | 1 | 1 | 是 | 否 |
| 9 | 液态介质环境对乳腺癌细胞弹性模量的影响 | Sun, W., Ma, J., Yu, J., Wu, C., & Zhang, W | 医用生物力学 | 2021 | 36(3) | 448 | 452 | 否 | 否 |
| 10 | A multiple catheter tips trackingmethod in X‐ray fluoroscopy images by a new lightweight segmentation network and Bay esian filtering | Tang H, Li H K, Yang C F, et al | The International Journal of Medical Robotics and Computer Asisted Surgery | 2023 | 19(6) | 2569 | 2569 | 是 | 否 |
| 11 | Clinical practice of transarterial chemoembolization for hepatocellular carcinoma | Lu J, Zhao M, Arai Y, et al | Hepatobiliary surgery and nutrition | 2021 | 10(5) | 661 | 661 | 是 | 否 |
| 12 | Electrical stimulation promotes endocytosis of magnetic nanoparticles by cancer cells | Wang C, Zhou G, Guo X, et al | Small | 2024 | 20(46) | 2403381 | 2403381 | 是 | 否 |
| 13 | Embedding expertise knowledge into inverse treatment planning for low‐dose‐rate brachytherapy of hepatic malignancies | Zhu J, Wang C, Teng S, et al | Medical Physics | 2024 | 51(1) | 348 | 362 | 是 | 否 |
| 14 | Imaging microglia surveillance during sleep-wake cycles in freely behaving mice | Gu X, Zhao Z, Chen X,et al | Elife | 2023 | 12 | 86749 | 86749 | 是 | 否 |
| 15 | Locoregional treatmentsfor hepatocellular carcinoma: Current evidenceand future directions | Inchingolo R, Posa A, Mariappan M, et al | World journal of gastroenterology | 2019 | 25(32) | 4614 | 4628 | 是 | 否 |
| 16 | Injectable composite hydrogel based on carbon particles for photothermal therapy of bone tumor and bone regeneration | Wei C, Jin X, Wu C, et al | Journalof Materials Science & Technology | 2022 | 118 | 64 | 72 | 是 | 否 |
| 17 | Graphene-based nanomaterials for stimuli-sensitive controlled delivery of the rapeutic molecules | Khakpour E, Salehi S, NaghibS M, et al | Frontiers in Bioengineering and Biotechnology | 2023 | 11 | 1129768 | 1129768 | 是 | 否 |
| 18 | A customizable cost-effective design for printed circuit board-based nanolayered gold screen-printed electrode: From fabrication to bioapplications | Ghorban zadeh S, Naghib S M, Sadr A, et al | Frontiers in Bioengineering and Biotechnology | 2022 | 10 | 1036224 | 1036224 | 是 | 否 |
| 19 | Simulating evaluation method on heating performances of magnetic nanoparticles with temperature-dependent heating efficiencies in tumorhyperthermia | Ding S W, Wu C W, Yu X G, et al | Magnetochemistry | 2022 | 8(6) | 63 | 63 | 是 | 否 |
| 20 | Effect of Al3+ doping on magnetic properties of Zn-Mn ferrite nanoparticles for magnetic induction hyperthermia. Journal of Magnetism and Magnetic Materials | Yu X, Rahman M M, Yang R, et al | Journal of Magnetism and Magnetic Materials | 2024 | 591 | 171724 | 171724 | 是 | 否 |
| 21 | Carbon spheres with high photothermal conversion efficiency for photothermal therapy of tumor | Wei C, Jin X, Wu C, et al | Diamond and related materials | 2022 | 126 | 109048 | 是 | 否 | |
| 22 | Synthesis of zinc ferrite particles with high saturation magnetization for magnetic induction hyperthermia | Al-Areqi A R, Yu X, Yang R, et al | Journal of Magnetism and Magnetic Materials | 2023 | 579 | 1 | 1 | 是 | 否 |
| 23 | Effect of Cr3+ doping on magnetic properties of Zn-Mg ferrite nanoparticles | Yu X, Yang R, Wu C, et al | Magnetochemistry | 2023 | 9(7) | 181 | 181 | 是 | ^返回顶部 |
| 24 | Customized hydrogel forsustained release of highly water- soluble drugs | Jin X, Wei C, Wu C, et al | ACS omega | 2022 | 7(10) | 8493 | 8497 | 是 | 否 |
| 25 | Gastric fluid- induced double network hydrogel with high swelling ratio and long-termmechanical stability | Jin X, Wei C, Wu C, et al | Composites Part B: Engineering | 2022 | 236 | 109816 | 109816 | 是 | 否 |
| 26 | Gastroretentive core–shell hydrogel assembly for sustained release of metform in hydro chloride | Jin X,Wei C,Wu C, et al | European Polymer Journal | 2022 | 170 | 111155 | 111155 | 是 | 否 |
| 27 | The heating efficiency of magnetic nanoparticles underan alternating magnetic field | Yu X, Yang R,Wu C, et al | Scientific Reports | 2022 | 12(1) | 16055 | 16055 | 是 | 否 |
| 28 | Effect of Mg doping on magnetic induction heating of Zn–Co ferrite nanoparticles | Yang R, Yu X, Li H, et al | Journal of Alloys and Compounds | 2021 | 851 | 156907 | 156907 | 是 | 否 |
五、项目申请专利情况
| 序号 | 专利题名 | 专利申请者(所有者) | 专利国别 | 专利号 | 公告(公开)日期 | 获取和访问路径 |
|---|---|---|---|---|---|---|
| 1 | 一种基于涡流效应的中高频交变磁场强度的测量方法 | 张伟;余小刚;吴承伟 | 中国 | CN112684388B | 2021-10-15 | 国家知识产权局 |
| 2 | 一种自控温热疗磁性水凝胶手动植入装置 | 滕皋军; 陆建; 王澄; 陈世佳 | 中国 | CN118526262A | 2024-08-23 | 国家知识产权局 |
| 3 | 一种磁热放射性复合粒子及其制备方法 | 滕皋军; 陆建; 陈彬大; 王澄;朱海东 | 中国 | CN118436780A | 2024-08-06 | 国家知识产权局 |
| 4 | 一种可注射自控温磁性水凝胶的磁热疗系统 | 滕皋军; 陆建; 张伟; 王澄; 朱海东 | 中国 | CN118236630A | 2024-06-25 | 国家知识产权局 |
| 5 | 顶针推送装置 | 陆骊工; 滕皋军; 王澄; 陈晓东; 李华; 朱光宇; 朱海东; 何旭新 | 中国 | CN116637286A | 2023-08-25 | 国家知识产权局 |
| 6 | 经软式超声内镜植入的复合粒子磁热疗-放疗系统 | 陆建; 滕皋军 | 中国 | CN118543041A | 2024-08-27 | 国家知识产权局 |
| 7 | 粒子植入肿瘤内放疗剂量规划方法、系统及介质 | 滕皋军; 朱建军; 王澄; 李迟迟 | 中国 | CN113181563B | 2023-01-03 | 国家知识产权局 |
| 8 | 放射性粒子连续注入装置 | 滕皋军; 陆建; 王澄 | 中国 | CN112603476A | 2021-04-06 | 国家知识产权局 |
| 9 | 放射粒子内放疗介入手术机器人的多脏器分割方法及介质 | 朱建军; 王澄; 滕皋军 | 中国 | CN113192025B | 2025-03-04 | 国家知识产权局 |
| 10 | 一种ICG/Fe(III)- NBs纳米气泡、制备方法及应用 | 杨莉; 滕皋军; 顾宁; 张卫华; 安艳丽 | 中国 | CN118370818A | 2024-07-23 | 国家知识产权局 |
| 11 | 基于多注意力的肝脏血管分割方法及系统 | 滕皋军; 朱建军; 王澄; 陆建 | 中国 | CN113409320A | 2021-09-17 | 国家知识产权局 |
| 12 | 一种可降解的组合物及其制备方法和应用 | 朱海东; 滕皋军; 刘琳琳; 陆骊工; 陈磊; 王澄; 陆建 | 中国 | CN113289075B | 2022-09-30 | 国家知识产权局 |
地方课题2提交
四、项⽬已取得的学术成果
| 序号 | 论⽂篇名或专著名 | 作者 | 刊名或出版社 | 出版年份 | 卷号(期号) | 开始⻚码 | 结束⻚码 | 是否为SCI/EI | 是否为NATURE/SCIENCE/CELL主刊 |
|---|---|---|---|---|---|---|---|---|---|
| 1 | A Precise Calibration Method for the Robot- Assisted Percutaneous Puncture System | Li J, Li M, Zeng Q, et al | Electronics | 2023 | 12(23) | 4857 | 4857 | 是 | 否 |
| 2 | An adaptive control method and learning strategy for ultrasound- guided puncture robot | Li T, Zeng Q, Li J, et al | Electronics | 2024 | 13(3) | 580 | 580 | 是 | 否 |
| 3 | Iterative stripe artifact correction framework for TOF- MRA | Li N, Zhou S, Zhao G, et al | Computers in Biology and Medicine | 2021 | 134 | 104456 | 104456 | 是 | 否 |
| 4 | Semi- supervised segmentation of coronary DSA using mixed networks and multi- strategies | Pu Y, Zhang Q, Qian C, et al | Computers in Biology and Medicine | 2023 | 156 | 106493 | 106493 | 是 | 否 |
| 5 | Context- aware network fusing transformer and V-Net for semi-supervised segmentation of 3D left atrium | Zhao C, Xiang S, Wang Y, et al | Expert Systems with Applications | 2023 | 214 | 119105 | 119105 | 是 | 否 |
| 6 | Towards real time guide wire shape extraction in fluoroscopic sequences: a two phase deep learning scheme to extract sparse curvilinear structures | Chen K, Qin W, Xie Y, et al | Computerized Medical Imagingand Graphics | 2021 | 94 | 101989 | 101989 | 是 | 否 |
| 7 | Deformable transformer for endoscopic videosuper- resolution | Song X, Tang H, Yang C, et al | Biomedical Signal Processing and Control | 2022 | 77 | 103827 | 103827 | 是 | 否 |
| 8 | Online hard patch mining using shape models and bandit algorithm formulti-organ segmentation | He J, Zhou G, Zhou S, et al | Ieee Journal of Biomedical and Health Informatics | 2021 | 26(6) | 2648 | 2659 | 是 | 否 |
| 9 | A novel multi-D oF surgical robotic system for brachytherapy onliver tumor: design and control | Lin X, Zhou S, Wen T, et al | International Journal of Computer Assisted Radiology and Surgery | 2021 | 16(6) | 1003 | 1014 | 是 | 否 |
| 10 | Guidewire simulation of endovascular intervention: A systematic review | Qiu J, Ming J, Qian C, et al | The International Journal of Medical Robotics and Computer Assisted Surgery | 2022 | 18(6) | 2444 | 2444 | 是 | 否 |
| 11 | DIOR: Deep iterative optimization- based residual- learning for limited-angle CT reconstruction | Hu D, Zhang Y, Liu J, et al | IEEE Transactions on Medical Imaging | 2022 | 41(7) | 1778 | 1790 | 是 | 否 |
| 12 | A multiple catheter tips tracking method in X ‐ray fluoroscopy images by a new lightweight segmentation network and Bayesian filtering | Tang H, Li H K, Yang C F, et al | The International Journal of Medical Robotics and Computer Assisted Surgery | 2023 | 19(6) | 2569 | 2569 | 是 | 否 |
| 13 | An improved matrix ‐ based endovascular guidewire position simulation using fusiform ternary tree | Qiu J, Lyu T, Chen Y, et al | The International Journal of Medical Robotics and Computer Assisted Surgery | 2020 | 16(6) | 1 | 11 | 是 | 否 |
| 14 | Evaluation of mechanical properties of poly (l ‐lactic acid) braided stents with axial stiffeners | Zhao G, Liu Q, Tian Y, et al | Journal of Applied Polymer Science | 2022 | 139(23) | 52242 | 52242 | 是 | 否 |
| 15 | Dlgnet: A dual-branch lesion-aware network with the supervised gaussian mixture model for colon lesions classification in colonoscopy images | Wang K N, Zhuang S, Ran Q Y, et al | Medical Image Analysis | 2023 | 87 | 102832 | 102832 | 是 | 否 |
| 16 | Discriminativ e feature representation for Noisy image quality assessment | Gu Y, Tang H, Lv T, et al | Multimedia Tools and Applications | 2020 | 79 | 7783 | 7809 | 是 | 否 |
| 17 | Evaluation of poly (L-lactic acid)monofilament swith high mechanical performance in vitro degradation | Zhao G, Wang B, Li X, et al | Journal of Materials Science | 2022 | 57(11) | 6361 | 6371 | 是 | 否 |
| 18 | Influence of parameters on mechanical properties of poly (L ‐ lactic acid) helical stents | Zhao G,Liu J, Liu M, et al | Journalof Biomedical Materials Research Part B: Applied Biomaterials | 2022 | 110(7) | 1705 | 1712 | 是 | 否 |
| 19 | Strengthen oriented poly (L-lactic acid)monofilaments via mechanical training | Zhang Y, Dong X, Zhang C, et al | International Journal of Biological Macromolecules | 2024 | 263 | 129975 | 129975 | 是 | 否 |
| 20 | Modified Theoretical Model Predicts Radial Support Capacity of Polymer Braided Stents | Hu X, Liu Q, Chen L, et al | Computer Methods and Programs in Biomedicine | 2024 | 246 | 108063 | 108063 | 是 | 否 |
| 21 | Strength and toughness of semicrystalline polymer fibers: Influenceof molecular chain entanglement | Zhang C, Liu W, Ma S, et al | Polymer | 2024 | 304 | 127119 | 127119 | 是 | 否 |
| 22 | Design strategy of poly(L ‐ lactic acid)mixed braided stent: The influence of braiding ratio of thick and thin monofilaments | Zhang C, Hu X, Wang B, et al | Journal of Applied Polymer Science | 2024 | 141(11) | 55100 | 55100 | 是 | 否 |
| 23 | Different properties of poly (L-lactic acid) monofilaments and its corresponding braided springs after constrained and unconstrained annealing | Zhao G, Ma S, Li X, et al | Journal of Biomaterials Applications | 2022 | 37(3) | 517 | 526 | 是 | 否 |
| 24 | Key factors of mechanical strength and toughness in oriented poly (L-lactic acid) monofilaments for a bioresorbable self- expanding stent | Wang B, Liu M, Liu J, et al | Langmuir | 2022 | 38(44) | 13477 | 13487 | 是 | 否 |
| 25 | Mixed-braided stent: An effective way to improve comprehensiv e mechanical properties of poly (L-lactic acid)self- expandable braided stent | Liu M, Tian Y, Cheng J, et al | Journal of the Mechanical Behavior of Biomedical Materials | 2022 | 128 | 105123 | 105123 | 是 | 否 |
| 26 | Incorporating the Hybrid Deformable Model for Improving the Performance of Abdominal CT Segmentation via Multi- Scale Feature Fusion Network | Liang X, Li N, Zhang Z, et al | Medical Image Analysis | 2021 | 73 | 102156 | 102156 | 是 | 否 |
| 27 | Dissected aorta segmentation using convolutional neural networks | Lyu T, Yang G, Zhao X, et al | Computer methods and programs in biomedicine | 2021 | 211 | 106417 | 106417 | 是 | 否 |
| 28 | Convolutional squeeze-and-excitation network for ECG arrhythmia detection | Ge R, Shen T, Zhou Y, et al | Artificial Intelligence in Medicine | 2021 | 121 | 102181 | 102181 | 是 | 否 |
| 29 | Tagnet: A transformer-based axial guided network for bile duct segmentation | Zhou G Q, Zhao F, Yang Q H, et al | Biomedical Signal Processing and Control | 2023 | 86 | 105244 | 105244 | 是 | 否 |
五、项目申请专利情况
| 序号 | 专利题名 | 专利申请者(所有者) | 专利国别 | 专利号 | 公告(公开)日期 | 获取和访问路径 |
|---|---|---|---|---|---|---|
| 1 | 一种基于扩散模型与生成对抗网络的图像分割方法及装置 | 蒲尧; 张智清; 钱程; 曾泉; 周寿军; 李涛; 郑福琛 | 中国 | CN117314930A | 2023-12-29 | 国家知识产权局 |
| 2 | 超声机器人扫描控制方法、装置、设备及存储介质 | 李涛; 周寿军; 曾泉; 钱程; 曾伟斌; 蒲尧 | 中国 | CN116175584A | 2023-05-30 | 国家知识产权局 |
| 3 | 一种基于扩散模型与生成对抗网络的图像分割方法及装置 | 蒲尧; 张智清; 钱程; 曾泉; 周寿军; 李涛; 郑福琛 | 中国 | CN117314930A | 2023-12-29 | 国家知识产权局 |
| 4 | 一种穿刺活检针 | 安超; 吴沛宏; 郑福琛; 周寿军; 钱程; 曾泉 | 中国 | CN221730798U | 2024-09-20 | 国家知识产权局 |
| 5 | 机械臂参数辨识补偿方法及系统 | 曾伟斌; 周寿军; 李涛; 曾泉 ; 李声啸; 蒲尧 | 中国 | CN116442215A | 2023-07-18 | 国家知识产权局 |
| 6 | 超声机器人扫描控制方法、装置、设备及存储介质 | 李涛; 周寿军; 曾泉; 钱程; 曾伟斌; 蒲尧 | 中国 | CN116175584A | 2023-05-30 | 国家知识产权局 |
| 7 | 一种导丝推送装置和血管介入机器人 | 钱程; 曾泉; 周寿军 | 中国 | CN115671509B | 2024-11-15 | 国家知识产权局 |
| 8 | 图像分割模型训练方法、装置、设备及存储介质 | 蒲尧; 周寿军 | 中国 | CN115375706A | 2022-11-22 | 国家知识产权局 |
| 9 | 一种超声辅助扫查手术机器人控制方法及系统 | 李涛; 曾泉; 周寿军; 钱程 | 中国 | CN115227404A | 2022-10-25 | 国家知识产权局 |
| 10 | 一种机械臂光学定位方法及装置 | 曾伟斌; 曾泉; 周寿军; 李声啸; 王浩乾 | 中国 | CN117084785A | 2023-11-21 | 国家知识产权局 |
| 11 | 一种基于超声图像的穿刺针实时检测方法及装置 | 余韩梅; 钱程; 周寿军; 赵福星; 陈静涛; 蒲尧 | 中国 | CN114820650A | 2022-07-29 | 国家知识产权局 |
| 12 | 一种穿刺针平面的实时重建方法及装置 | 李声啸; 曾泉; 周寿军 | 中国 | CN116797650A | 2023-09-22 | 国家知识产权局 |
| 13 | 一种面向腔道粒子支架释放的机器人系统 | 钱程; 陈静涛; 周寿军 | 中国 | CN113941082B | 2023-11-14 | 国家知识产权局 |
| 14 | 一种CT兼容的肺部穿刺活检系统及方法 | 陈静涛; 钱程; 周寿军; 曾泉 | 中国 | CN113940733B | 2023-08-15 | 国家知识产权局 |
| 15 | 一种困难样本挖掘方法、系统、终端以及存储介质 | 贺建安; 周寿军; 游超云 | 中国 | CN113920079B | 2024-11-15 | 国家知识产权局 |
| 16 | 一种血管中心线提取方法、系统、终端以及存储介质 | 游超云; 周寿军; 贺建安 | 中国 | CN113902689B | 2024-10-25 | 国家知识产权局 |
| 17 | 一种面向胆道穿刺的机器人穿刺定位方法及装置 | 陈静涛; 周寿军; 钱程; 曾泉 ; 林晓锋; 温铁祥 | 中国 | CN113558735A | 2021-10-29 | 国家知识产权局 |
| 18 | 一种肝及肝肿瘤的医学图像分割方法、系统、终端以及存储介质 | 齐恒; 周寿军; 李娜 | 中国 | CN114881910A | 2022-08-09 | 国家知识产权局 |
| 19 | 超声穿刺针 | 陈静涛; 周寿军; 滕皋军 | 中国 | CN213722285U | 2021-07-20 | 国家知识产权局 |
| 20 | 超声穿刺针 | 陈静涛; 滕皋军; 周寿军 | 中国 | CN111265289A | 2020-06-12 | 国家知识产权局 |
| 21 | 基于肝内血管配准的手术导航系统 | 温铁祥; 王澄; 周寿军; 李迟迟; 王磊; 张毅 ; 陆建 | 中国 | CN112971982B | 2022-08-19 | 国家知识产权局 |
| 22 | 一种基于CT与DSA的3D-2D血管弹性配准方法 | 贺建安; 陈阳 | 中国 | CN114419117A | 2022-04-29 | 国家知识产权局 |
| 23 | 一种基于深度序列信息融合的冠脉造影图像分割方法 | 陈阳;高雨枫;周寿军 | 中国 | CN113592766B | 2022-09-02 | 国家知识产权局 |
| 24 | 一种X射线透视图像下基于深度分割网络和最短路径算法的导丝分割方法 | 陈阳; 李浩凯 | 中国 | CN113269788B | 2024-03-29 | 国家知识产权局 |
| 25 | 一种基于频域监督和动态卷积的临床图像中病变区域分割方法 | 王浩林; 周光泉; 王凯妮 | 中国 | CN116797615A | 2023-09-22 | 国家知识产权局 |
| 26 | 一种基于自适应频域学习和抗混叠复数卷积的临床图像病变分类方法 | 周光泉; 王凯妮 | 中国 | CN116309542B | 2026-02-13 | 国家知识产权局 |