欧美精品在欧美一区二区,天天干天天干天天干,亚洲精品福利视频,成人免费在线视频网站

  • 2024.6.26 學(xué)術(shù)報告:?jiǎn)捂淒N...
    2024-06-21
  • 2024.5.30學(xué)術(shù)報告:中國人...
    2024-05-24
  • 2024.5.24學(xué)術(shù)報告:環(huán)境與...
    2024-05-21

會(huì )員登錄

用戶(hù)名:
密碼:

生物醫學(xué)工程學(xué)系

許海燕

 

許海燕課題組



 負責人:許海燕,研究員/博士生導師

研究領(lǐng)域:納米生物材料與轉化醫學(xué)

      主要學(xué)習、工作經(jīng)歷:

    本科和研究生畢業(yè)于中國科技大學(xué)應用化學(xué)系,1985年獲理學(xué)學(xué)士學(xué)位,1988年獲理學(xué)碩士學(xué)位。1988-1995年在北京化工大學(xué)高分子科學(xué)與工程系工作。1995年加入中國醫學(xué)科學(xué)院基礎醫學(xué)研究所生物醫學(xué)工程系。曾于1994年在日本大阪市立工業(yè)技術(shù)研究所研修(JICA項目);1999-2000年在美國匹茲堡大學(xué)McGowan Institute of Regenerative MedicineMcGowan再生醫學(xué)研究院)William R. Wagner實(shí)驗室工作,從事生物材料表面分子修飾與抗凝血功能研究。

聯(lián)系方式:電話(huà):010-69156437Email: xuhy (AT) pumc.edu.cn

 



科研方向:

[1]      多肽及其偶聯(lián)物研發(fā),發(fā)展抗腫瘤治療新方法,針對白血病、胰腺癌、乳腺癌等

[2]      藥物遞送系統,主要包括陽(yáng)離子多糖、貴金屬合金、膠束和脂質(zhì)體等,用于核酸藥物、多肽藥物、小分子化藥的靶向遞送

[3]      具有電、磁、力響應性的納米結構復合材料的設計與制備,用于調控細胞行為、提高醫療器械表面生物相容性、以及引導組織再生與大塊缺損組織的修復,主要包括骨、肌肉、心肌等

[4]      納米材料毒理學(xué)效應與臨床安全應用,重點(diǎn)探索和研究具有醫學(xué)應用轉化潛力的納米材料的生物學(xué)效應,如對免疫系統、血管內皮的作用及分子機制

 

教學(xué)工作:

[1]      擔任北京協(xié)和醫學(xué)院研究生《納米醫學(xué)概論》課程負責人。個(gè)人授課內容:緒論、納米技術(shù)在再生醫學(xué)和免疫治療中的研究與應用

[2]      北京協(xié)和醫學(xué)院研究生課程《生物醫學(xué)工程概論》、《生理學(xué)的物理分析》、《心血管生理學(xué):基礎與臨床》中部分授課任務(wù),授課內容主要包括:生物材料與人工器官和再生醫學(xué)、生物材料物理學(xué)與組織再生、生物材料及醫療器械在心血管系統中的應用研究。

[3]      北京協(xié)和醫學(xué)院臨床醫學(xué)本科課程《生物醫學(xué)工程》部分授課任務(wù),授課內容:生物材料、人工器官、組織工程與再生醫學(xué)

 

主要社會(huì )兼職:

    中國生物醫學(xué)工程學(xué)會(huì )理事/納米醫學(xué)與工程分會(huì )主委(2023-/女科技工作者委員會(huì )主任委員(2019-)、Committee member of WiMBE, IFMBE(國際醫學(xué)與生物工程聯(lián)合會(huì ))(2023-)、 中國生物物理學(xué)會(huì )理事及納米生物學(xué)分會(huì )委員、中國微米納米技術(shù)學(xué)會(huì )納米科學(xué)技術(shù)分會(huì )常務(wù)理事、北京生物醫學(xué)工程學(xué)會(huì )常務(wù)理事、全國專(zhuān)業(yè)標準化技術(shù)委員會(huì )委員及健康、安全與環(huán)境工作組副組長(cháng)兼秘書(shū)長(cháng)、《基礎醫學(xué)與臨床》、《中國生物醫學(xué)工程學(xué)報》、《國際生物醫學(xué)工程學(xué)雜志》和《北京生物醫學(xué)工程》編輯委員會(huì )委員。

 

課題組成員



  劉健,工學(xué)博士,研究員/博士生導師

19921996年就讀于北京理工大學(xué)化工與材料學(xué)院高分子材料與工程專(zhuān)業(yè),獲學(xué)士學(xué)位。20022009年在日本京都大學(xué)高分子化學(xué)專(zhuān)業(yè)攻讀碩士、博士學(xué)位,從事高分子修飾富勒烯衍生物在腫瘤的光動(dòng)力學(xué)治療及腫瘤診斷中的應用、再生骨組織分子影像學(xué)研究,獲得京都大學(xué)工學(xué)博士學(xué)位。2009-2011年在日本京都大學(xué)再生醫科學(xué)研究所擔任博士后研究員,從事非病毒高分子載體系統的構筑及細胞基因轉導干細胞的分化誘導的研究。20114月作為海外人才引進(jìn)中國醫學(xué)科學(xué)院基礎醫學(xué)研究所生物醫學(xué)工程系。






聯(lián)系方式:電話(huà):010-69156437Email: liujian (AT) ibms.pumc.edu.cn

 

研究方向:藥物/基因遞送系統、組織工程與再生醫學(xué)

1)藥物/基因遞送系統:

普通藥物缺乏特異性,為了發(fā)揮藥效必須依賴(lài)于大劑量給藥,這是造成藥物副作用的主要原因。最理想的是能夠在恰當的時(shí)機,將恰當劑量的藥物遞送到恰當的部位,這就是藥物遞送系統(Drug Delivery SystemDDS)的目的。通過(guò)DDS,可以實(shí)現藥物的緩釋、延長(cháng)代謝時(shí)間、促進(jìn)吸收、及實(shí)現靶向給藥,而這些的實(shí)現又都離不開(kāi)對藥物進(jìn)行修飾或包被的生物材料。而且,任何具有生理活性的物質(zhì)都可以被視為藥物,不僅包括小分子藥物,而且包括蛋白、核酸藥物;不僅包括治療藥物、而且包括診斷、預防藥物。本研究方向主要是從生物材料的視角,對治療(包括基因治療)、診斷(如核磁、超生造影劑)、及預防(疫苗、免疫輔劑)的DDS進(jìn)行研究。

2)組織工程與再生醫學(xué):

身體的大多數細胞都是附著(zhù)在由蛋白質(zhì)、多糖等構成的細胞外支架上增殖、分化、并發(fā)揮其正常生理作用的。因此,當發(fā)生大的組織缺損時(shí),單純依靠在缺損部位填充細胞很難獲得理想的組織再生,因而需要為細胞提供一個(gè)臨時(shí)的支架、以促進(jìn)其在目標部位的增殖與分化。本研究方向主要目的是設計、創(chuàng )造三維或多孔結構的可降解性構造體(人工細胞外支架),同時(shí)利用DDS技術(shù)釋放適當的生長(cháng)因子或核酸分子,從而促進(jìn)細胞的增殖、并控制其分化方向。利用這些技術(shù)、可以實(shí)現血管、骨、脂肪等組織的再生誘導治療、并且為干細胞的分化誘導等基礎生物醫學(xué)研究提供必要的工具及技術(shù)。

教學(xué)工作:

擔任北京協(xié)和醫學(xué)院臨床醫學(xué)專(zhuān)業(yè)本科生《生物醫學(xué)工程學(xué)》、研究生《生物醫學(xué)工程概論》、《電子技術(shù)在生物醫學(xué)中的應用》的課程負責人;承擔研究生課程《納米醫學(xué)概論》的部分授課任務(wù)。

 


研究生期間發(fā)表的科研論文:

1. Liu Jian, Jo Jun-ichiro, Kawai Yuko, Aoki Ichio, Tanaka Chuzo, Yamamoto  Masaya, Tabata Yasuhiko, Preparation of polymer-based multimodal imaging agent to visualize the process of bone regeneration. Journal of Controlled Release, 2012, 157(3): 398-405

2. Liu Jian, Tabata Yasuhiko, Effect of modification manner on the photodynamic antitumor activity of C60 modified with pullulan., J Biomater Sci Polym Ed, 2011, 22(16): 2147-2163

3. Liu Jian, Tabata Yasuhiko, Photodynamic Antitumor Activity of Fullerene Modified with Poly(ethylene glycol) with Different Molecular Weights and Terminal Structures., J Biomater Sci Polym Ed, 2011, 22: 297-312

4. Liu Jian, Tabata Yasuhiko, Photodynamic therapy of fullerene modified with pullulan on hepatoma cells., J Drug Target, 2010, 18(8): 602-610

5. Liu Jian, Ohta Shin-ichi, Sonoda Akinaga, Yamada Masatoshi, Yamamoto Masaya, Nitta Norihisa, Murata Kiyoshi, Tabata Yasuhiko, Preparation of PEG-conjugated fullerene containing Gd3+ ions for photodynamic therapy, J controlled release. 2007, 117(1): 104-110


 

 



  孟潔,博士,研究員/研究生導師

2002年畢業(yè)于山東大學(xué)醫學(xué)院臨床醫學(xué)專(zhuān)業(yè),獲得醫學(xué)學(xué)士學(xué)位;2007年畢業(yè)于北京協(xié)和醫學(xué)院生物醫學(xué)工程學(xué)系,獲得理學(xué)博士學(xué)位。同年進(jìn)入中國醫學(xué)科學(xué)院基礎醫學(xué)研究所生 物醫學(xué)工程學(xué)系工作。2014年在CMB項目資助下赴美國霍華德醫學(xué)院分子影像中心進(jìn)修。

聯(lián)系方式:010-69156437Email: mengjie (AT) ibms.pumc.edu.cn

   





研究方向:

    [1] 納米毒理學(xué)、納米材料免疫學(xué)效應及在抗腫瘤治療中的應用;

      [2] 納米結構材料對細胞行為的調控機制及應用于組織工程和再生醫學(xué)

   

教學(xué)工作:

擔任北京協(xié)和醫學(xué)院研究生《生理學(xué)的物理分析》的課程負責人;承擔北京協(xié)和醫學(xué)院臨床醫學(xué)專(zhuān)業(yè)本科生《生物醫學(xué)工程》、研究生《生物醫學(xué)工程概論》和《納米醫學(xué)概論》的部分授課任務(wù)。

 



   溫濤,博士,副研究員

  2010年本科畢業(yè)于東南大學(xué)生物醫學(xué)工程專(zhuān)業(yè),2015年畢業(yè)于中國科學(xué)院大學(xué)國家納米科學(xué)中心,獲物理化學(xué)博士學(xué)位。20158月進(jìn)入基礎醫學(xué)研究所生物醫學(xué)工程系工作。

研究方向:

    金屬基納米結構材料設計、制備及其在體外檢測與診斷、分子影像方面的應用基礎研究。

教學(xué)工作:承擔北京協(xié)和醫學(xué)院臨床醫學(xué)專(zhuān)業(yè)本科生《生物醫學(xué)工程》、研究生課程《生物醫學(xué)工程概論》、《納米醫學(xué)概論》和《電子技術(shù)在生物醫學(xué)中的應用》的部分授課任務(wù)。

聯(lián)系方式:010-69156437Email: went (AT) ibms.pumc.edu.cn

 


博士研究生期間部分代表性論文

1. Wen T, He W, Chong Y, Liu Y, Yin J-J, Wu X. Exploring environment-dependent effects of Pd nanostructures on reactive oxygen species (ROS) using electron spin resonance (ESR) technique: implications for biomedical applications. Phys Chem Chem Phys., 2015, 17, 24937-24943.

2. Li Y#, Wen T#, Zhao R, Liu X, Ji T, Wang H, Shi X, Shi J, Wei J, Zhao Y, Wu X, Nie G. Localized Electric Field of Plasmonic Nanoplatform Enhanced Photodynamic Tumor Therapy. ACS Nano, 2014, 8, 11529-11542.

3. Wen T, Hou S, Yan J, Zhang H, Liu W, Ji Y, Wu X. L-Cysteine-Induced Chiroptical Activity in Assemblies of Gold Nanorods and Its Use in Ultrasensitive Detection of Copper Ions.RSC Advances, 2014, 4, 45159–45162.

4. Wen T, Zhang H, Tang X, Chu W, Liu W, Ji Y, Hu Z, Hou S, Hu X, Wu X. Copper Ion Assisted Reshaping and Etching of Gold Nanorods: Mechanism Studies and Applications. J. Phys. Chem. C, 2013, 117, 25769-25777.

5. Wen T, Hu Z, Liu W, Zhang H, Hou S, Hu X, Wu X. Copper ions-assisted growth of gold nanorods in seed-mediated growth: significant narrowing of size distribution via tailoring reactivity of seeds. Langmuir, 2012, 28, 17517–17523.


 


  王濤,博士,助理研究員

2014年本科畢業(yè)于南開(kāi)大學(xué)生物技術(shù)專(zhuān)業(yè),獲理學(xué)學(xué)士學(xué)位;2019年畢業(yè)于北京協(xié)和醫學(xué)院基礎學(xué)院生物醫學(xué)工程系,獲理學(xué)博士學(xué)位。20197月至20218月在中國醫學(xué)科學(xué)院基礎醫學(xué)研究所進(jìn)行博士后研究。20219月進(jìn)入基礎醫學(xué)研究所生物醫學(xué)工程系工作。2023年獲衛健委副研究員資格。

研究方向:

基于納米技術(shù)的氧化應激調控及抗腫瘤治療策略研究

教學(xué)工作:

承擔北京協(xié)和醫學(xué)院研究生《生理學(xué)的物理分析》的部分授課任務(wù)。



聯(lián)系方式:

Tel010-69156940

E-mailWangTao940215 (AT) 126.com 

 

 

    實(shí)驗室歷年研究生和博士后:

    ----畢業(yè)生:

郭小天、孟潔(小)、孟潔(大)、何朝輝、韓昭昭、張潔、齊小謹、加福民、楊曼、許振、校搏(臨床醫學(xué)八年制)、程雪蓮、張衛奇、李瀟瑾、馬強、楊棽、郭花、劉會(huì )可、張靜、王川、代亞麗、王晶、郝綏綏、聶欣、沈姚熠、楊揚、王濤、謝麗菲、吳鳳新、徐學(xué)蓋、杜麗帆、孟祥輝、賈夢(mèng)帆、葛洋洋、韓博、賴(lài)馨寧、楊?lèi)?ài)云、許仕琳、閆豆豆、王田、張雪、劉青橋、孫博、胡雪純、李宛清、郝博雅、黃鑫、曾菲

----在校研究生:

張美晨、胡雪純、蒙藝靈、彭雪璐、劉暄欣、王嘯峽、于夢(mèng)帆、朱可、吳航、姜川梅、胡贊、姚婧、冶明、楊隱、楊帆

----在站博士后:許仕琳(2022年度協(xié)和青年學(xué)者支持計劃)

----出站博士后:雷晶、王濤

 

 

職工合影2023
2023年夏季課題組職工合影

 

2023秋末合影

2023年秋季畢業(yè)答辯會(huì )合影

 

 

IMG_9115

2022年夏季畢業(yè)合影

 

IMG_7050

2021年夏季畢業(yè)合影

 

IMG_E4317

2020年夏季畢業(yè)合影

 

 

Selected Publications

 

第一部分:納米醫學(xué)與抗腫瘤治療

Part 1: Nanomedicine & Anti-tumor therapies

 

1. Wang T, Zhang W, Chen W, Meng J, Hu Q, Liu J, Wen T, Han B*, Xu H*. As4S4 nanoparticles promote effective terminal erythropoiesis in bone marrow mononuclear cells from patients with myelodysplastic syndromes. Nano Today. 2023; 52: 101965

2. Meng Y#, Zhou J#, Liu X, Zeng F, Wen T*, Meng J, Liu J, Xu H*. CXC Chemokine Receptor Type 4 Antagonistic Gold Nanorods Induce Specific Immune Responses and Long-Term Immune Memory to Combat Triple-Negative Breast Cancer. ACS Applied Materials & Interfaces. 2023; 15(15):18734–18746.

3. Zhang S, Wang T, Xue J, Xu H*, Wu S*. Hydrogen Bonding Principle-Based Molecular Design of a Polymer Excipient and Impacts on Hydrophobic Drug Properties: Molecular Simulation and Experiment. Biomacromolecules. 2023; 24(4): 1675-1688.

4. Huimin Wang, Hong Deng, Menghan Gao, Yiyi Zhang, Runmeng Liu, Wei Hou, Haiyan Xu*, Weiqi Zhang*. Radiotherapy Potentiates the P?Selectin Targeted Cancer Drug Delivery Based on a Cisplatin and Mitoxantrone Coassembled Fucoidan Nanogel. ACS Materials Letters 2023; 5(10): 2843-2851.

5. Hong Deng, Xue Yang, Huimin Wang, Menghan Gao, Yiyi Zhang, Runmeng Liu, Haiyan Xu*, Weiqi Zhang*. Tailoring the surface charges of iron-crosslinked dextran nanogels towards improved tumor-associated macrophage targeting. Carbohydrate Polymers 2023; 325(17):  121585.

6. Zhang M#, Ge Y#, Xu S, Fang X, Meng J, Yu L, Wang C, Liu J, Wen T, Yang Y, Wang C, Xu H. Nanomicelles co-loading CXCR4 antagonist and doxorubicin combat the refractory acute myeloid leukemia. Pharmacol Res. 2022 Nov; 185:106503.

7. Xu S, Zhang M, Fang X, Hu X, Xing H, Yang Y, Meng J, Wen T, Liu J, Wang J, Wang C*, Xu H*. CD123 Antagonistic Peptides Assembled with Nanomicelles Act as Monotherapeutics to Combat Refractory Acute Myeloid Leukemia. ACS Appl Mater Interfaces. 2022 Aug 31; 14(34): 38584-38593.

8. Tian Wang, Boya Hao, Shilin Xu, Jie Meng, Tao Wen, Jian Liu*, Haiyan Xu*. Effective RNAi in leukemia cells is enhanced by spermine-modified pullulancombined with desloratadine. Carbohydrate Polymers. 2022; 292: 119646.

9. Wang T, Zhang X, Jia M, Yang A, Liu J, Wen T, Meng J*, Xu H*. Hydrophilic Realgar Nanocrystals Prolong the Survival of Refractory Acute Myeloid Leukemia Mice Through Inducing Multi-Lineage Differentiation and Apoptosis. Int J Nanomedicine. 2022 May 16; 17: 2191-2202.

10. Yu L#, Wang R#, Wen T#, Liu L, Wang T, Liu S, Xu H*, Wang C*. Peptide Binder with High-Affinity for the SARS-CoV-2 Spike Receptor-Binding Domain. ACS Appl Mater Interfaces. 2022 Jun 29; 14(25): 28527-28536.

11. Ruan L, Lu L, Zhao X, Xiong W, Xu H, Wu S. Effects of natural antioxidants on the oxidative stability of Eucommia ulmoides seed oil: Experimental and molecular simulation investigations. Food Chem. 2022 Jul 30; 383:132640.

12. Xu S, Zhang M, Fang X, Meng J, Xing H, Yan D, Liu J, Yang Y, Wen T, Zhang W, Wang J*, Wang C*, Xu H*. A novel CD123-targeted therapeutic peptide loaded by micellar delivery system combats refractory acute myeloid leukemia. J Hematol Oncol. 2021 Nov 13; 14(1): 193.

13. Tao Wang, Xiaocui Fang, Tao Wen, Jian Liu, Zhaoyi Zhai , Zhiyou Wang, Jie Meng, Yanlian Yang, Chen Wang*, Haiyan Xu*. Synthetic Neutralizing Peptides Inhibit the Host Cell Binding of Spike Protein and Block Infection of SARS-CoV-2. J Med Chem. 2021 Oct 14; 64(19): 14887-14894.

14. Bo Han#, Tao Wang#, Zhigang Xue, Tao Wen, Ling Lu, Jie Meng, Jian Liu, Sizhu Wu, Jianchun Yu*, Haiyan Xu*. Elemene Nanoemulsion Inhibits Metastasis of Breast Cancer by ROS Scavenging. International Journal of Nanomedicine 2021; 16, 6035-6048

15. Fei Kong, Huiyuan Bai, Ming Ma, Chen Wang, Haiyan Xu*, Ning Gu*, Yu Zhang*. Fe3O4@Pt nanozymes combining with CXCR4 antagonists to synergistically treat acute myeloid leukemia. NanoToday 2021; 37, 101106.

16. Bai H, Sun Q, Kong F, Dong H, Ma M, Liu F, Wang C, Xu H, Gu N, Zhang Y. Zwitterion-functionalized hollow mesoporous Prussian blue nanoparticles for targeted and synergetic chemo-photothermal treatment of acute myeloid leukemia. J Mater Chem B. 2021 Jul 7; 9(26): 5245-5254.

17. Huiyuan Bai, Tao Wang, Fei Kong, Meichen Zhang, Zhuoxuan Li, Linlin Zhuang, Ming Ma, Fangzhou Liu, Chen Wang, Haiyan Xu*, Ning Gu*, Yu Zhang*. CXCR4 and CD44 Dual-Targeted Prussian Blue Nanosystem with Daunorubicin Loaded for Acute Myeloid Leukemia Therapy, Chemical Engineering Journal, 2021, 405, 126891.

18. 王田, 許仕琳, 王濤, 溫濤, 孟潔, 劉健, 許海燕. 精胺-普魯蘭聯(lián)合地氯雷他定介導的NOTCH1沉默對急性T淋巴細胞白血病細胞系Jurkat的影響. 基礎醫學(xué)與臨床2021, 41(6): 786-791

19. 孫博, 蒙藝靈, 溫濤, 孟潔, 劉健, 許海燕. 多肽修飾的金納米顆粒對小鼠三陰性乳腺癌細胞的靶向光熱效應研究. 北京生物醫學(xué)工程 2021, 40 (5), 441-446.

20. Meng J#, Ge Y#, Xing H#, Wei H, Xu S, Liu J, Yan D, Wen T, Wang M, Fang X, Ma L, Yang Y, Wang C*, Wang J*, Xu H*. Synthetic CXCR4 Antagonistic Peptide Assembling with Nanoscaled Micelles Combat Acute Myeloid Leukemia. Small, 2020; 12(45): 23084-23091.

21. Yan D#, Wei H#, Lai X, Ge Y, Xu S, Meng J, Wen T, Liu J, Zhang W*, Wang J*, Xu H*. Co-delivery of homoharringtonine and doxorubicin boosts therapeutic efficacy of refractory acute myeloid leukemia. Journal of Controlled Release. 2020, 327: 766-778.

22. Wen T#, Yang A#, Wang T, Jia M, Lai X, Meng J, Liu J, Han B, Xu H*. Ultra-small platinum nanoparticles on gold nanorods induced intracellular ROS fluctuation to drive megakaryocytic differentiation of leukemia cells. Biomater Sci, 2020; 8(22): 6204-6211.

23. Wang T#, Dong H#, Zhang M, Wen T, Meng J, Liu J, Li Z, Zhang Y*, Xu H*. Prussian blue nanoparticles induced myeloid leukemia cells differentiate towards red blood cells by nanozyme activities. Nanoscale 2020, 12, 23084.

24. Zhang W#, Han B#, Lai X, Xiao C, Xu S, Meng X, Li Z, Meng J, Wen T, Yang X, Liu J*, Xu H*. Stiffness of cationized gelatin nanoparticles is a key factor determining RNAi efficiency in myeloid leukemia cells. Chemical Communications. 2020; 56 (8): 1255-1258.

25. Ji S, Yang X, Chen X, Li A, Yan D, Xu H, Fei H*. Structure-tuned membrane active Ir-complexed oligoarginine overcomes cancer cell drug resistance and triggers immune responses in mice. Chemical Science. 2020; 11 (34): 9126-9133.

26. Zu R#, Fang X#, Lin Y, Xu S, Meng J, Xu H*, Yang Y*, Wang C*. Peptide-enabled receptor-binding-quantum dots for enhanced detection and migration inhibition of cancer cells. J Biomater Sci Polym Ed. 2020; 31(12): 1604-1621.

27. Kaiyue Zhang, Xiaocui Fang, Qing You, Yuchen Lin, Lilusi Ma, Shilin Xu, Yangyang Ge, Haiyan Xu*, Yanlian Yang*, and Chen Wang*. Novel Peptide-directed Liposomes for Targeted Combination Therapy of Breast Tumor. Mater. Adv., 2020, 1, 3483

28. Fang X, Zhang K, Jiang M, Ma L, Liu J, Xu H*, Yang Y*, Wang C*. Enhanced lymphatic delivery of nanomicelles encapsulating CXCR4-recognizing peptide and doxorubicin for the treatment of breast cancer. Int J Pharm., 2020 Dec 18; 594:120183.

29. Lu L, Luo K, Yang W, Zhang S, Wang W, Xu H*, Wu S*. Insight into the anti-aging mechanisms of natural phenolic antioxidants in natural rubber composites using a screening strategy based on molecular simulation. RSC Advances. 2020; 10, 21318.

30. Li H#, Wen T#, Wang T, Ji Y, Shen Y, Chen J, Xu H*, Wu X*. In Vivo Metabolic Response upon Exposure to Gold Nanorod Core/Silver Shell Nanostructures: Modulation of Inflammation and Upregulation of Dopamine. International Journal of Molecular Sciences. 2020 Jan 8; 21(2): 384.

31. Lanlan Yu, Wenbo Zhang, Wendi Luo, Robert L. Dupont, Yang Xu, Yibing Wang, Bin Tu, Haiyan Xu, Xiaoguang Wang, Qiaojun Fang*, Yanlian Yang, Chen Wang, Chenxuan Wang*. Molecular recognition of human islet amyloid polypeptide assembly by selective oligomerization of thioflavin T. Sci. Adv. 2020 Aug 5; 6(32): eabc1449.

32. Liu X, Liu J, Liu D, Han Y, Xu H, Liu L, Leng X, Kong D. A cell-penetrating peptide-assisted nanovaccine promotes antigen cross-presentation and anti-tumor immune response. Biomater Sci. 2019 Dec 1; 7(12): 5516-5527.

33. Zhang J , Liu D , Liu J , Han Y , Xu H , Leng X , Kong D , Liu L. Hybrid spherical nucleotide nanoparticles can enhance the synergistic anti-tumor effect of CTLA-4 and PD-1 blockades. Biomater Sci. 2020 Sep 7; 8(17): 4757-4766.

34. Wang T, Wen T, Li H, Han B, Hao S, Wang C, Ma Q, Meng J, Liu J, Xu H. Arsenic sulfide nanoformulation induces erythroid differentiation in chronic myeloid leukemia cells through degradation of BCR-ABL. Int J Nanomedicine. 2019 Jul 22; 14: 5581-5594.

35. Wang T, Meng J*, Wang C, Wen T, Jia M, Ge Y, Xie L, Hao S, Liu J, Xu H*. Inhibition of Murine Breast Cancer Metastases by Hydrophilic As4S4 Nanoparticles Is Associated With Decreased ROS and HIF-1α Downregulation. Front Oncol. 2019 Apr 26; 9: 333.

36. Mengfan Jia#, Tao Wang#, Shilin Xu, Jian Liu, Tao Wen, Jie Meng*, Haiyan Xu*. Arsenic Sulfide Nanoformulation Induces Megakaryocytic Differentiation through Histone Deacetylase Inhibition. Advanced Therapeutics. 2019 Nov 21; 3, 1900151.

37. Xie L, Yang Y, Meng J, Wen T, Liu J*, Xu H*. Cationic polysaccharide spermine-pullulan drives tumor associated macrophage towards M1 phenotype to inhibit tumor progression. Int J Biol Macromol. 2018 Nov 13; 123:1012-1019.

38. Meng M, Xue H, Lei J, Wang Q, Liu J, Li Y, Sun T, Xu H, Jin Z*. A novel approach to monitoring the efficacy of anti-tumor treatments in animal models: combining functional MRI and texture analysis. BMC Cancer. 2018 Aug 20; 18(1): 833.

39. 楊揚, 孟潔. 溫濤, 陳博, 劉飛, 顧寧, 許海燕, 于薇*, 劉健*. uPAR靶向性MRI探針的制備及其與乳腺癌細胞靶向結合的研究. 中國生物醫學(xué)工程學(xué)報2018: 37(4): 481-488

40. Zhang W, Meng X, Liu H, Xie L, Liu J*, Xu H*. Ratio of Polycation and Serum Is a Crucial Index for Determining the RNAi Efficiency of Polyplexes. ACS Appl Mater Interfaces. 2017 Dec 20; 9(50): 43529-43537.

41. Hua Guo, Yangyang Ge, Xiaojin Li, Yanlian Yang, Jie Meng, Jian Liu, Chen Wang*, Haiyan Xu*. Targeting the CXCR4/CXCL12 axis with the peptide antagonist E5 to inhibit breast tumor progression. Signal Transduction and Targeted Therapy 2017; 2, 17033

42. Wang J, Xie L, Wang T, Wu F, Meng J, Liu J*, Xu H*. Visible light-switched cytosol release of siRNA by amphiphilic fullerene derivative to enhance RNAi efficacy in vitro and in vivo. Acta Biomater. 2017; 59: 158-169.

43. Fang X, Xie H, Duan H, Li P, Yousaf M, Xu H*, Yang Y*, Wang C*. Anti-tumor activity of nanomicelles encapsulating CXCR4 peptide antagonist E5. PLoS One. 2017 Aug 9; 12(8): e0182697.

44. Ma Q#, Wang C#, Li X, Guo H, Meng J, Liu J*, Xu H*. Fabrication of water-soluble polymer-encapsulated As4S4 to increase oral bioavailability and chemotherapeutic efficacy in AML mice. Sci Rep. 2016; 6:29348

45. Yang S, Meng J, Yang Y, Liu H, Wang C, Liu J, Zhang Y, Wang C*, Xu H*. A HSP60-targeting peptide for cell apoptosis imaging. Oncogenesis. 2016; 5:e201.

46. Meng J, Guo F, Xu H, Liang W, Wang C*, Yang XD*. Combination Therapy using Co-encapsulated Resveratrol and Paclitaxel in Liposomes for Drug Resistance Reversal in Breast Cancer Cells in vivo. Sci Rep. 2016; 6: 22390.

47. Duan H, Zhu L, Hou J, Peng J, Xie H, Lin Y, Liu C, Li W, Xu H*, Wang C*, Yang Y*. Dual-affinity peptide mediated inter-protein recognition. Org Biomol Chem. 2016 Dec 28; 14(48): 11342-11346.

48. Wen T, Wamer WG, Subczynski WK, Hou S, Wu X, Yin JJ*. Enhancement of Paramagnetic Relaxation by Photoexcited Gold Nanorods. Sci Rep. 2016; 6:24101

49. 劉會(huì )可#, 張衛奇#, 孟潔, 劉健*, 許海燕*. 血清蛋白與陽(yáng)離子多糖的質(zhì)量比對RNAi效率的調控作用研究. 中國科學(xué):生命科學(xué). 2016; 46:744-750.

50. 王晶, 謝麗菲, 孟潔, 劉健*, 許海燕*. 陰離子化高分子包覆非病毒載體提高有血清環(huán)境下RNA干擾效率的研究. 中國生物醫學(xué)工程學(xué)報. 2016; 35(4): 445-452.

51. Li X#, Guo H#, Duan H, Yang Y, Meng J, Liu J, Wang C*, Xu H*. Improving chemotherapeutic efficiency in acute myeloid leukemia treatments by chemically synthesized peptide interfering with CXCR4/CXCL12 axis. Sci Rep. 2015; 5:16228.

52. Meng J, Liu Y, Gao S, Lin S, Gu X, Pomper MG, Wang PC, Shan L*. A bivalent recombinant immunotoxin with high potency against tumors with EGFR and EGFRvIII expression. Cancer Biol Ther. 2015; 16(12): 1764-1774.

53. Meng J, Li X, Wang C, Guo H, Liu J, Xu H*. Carbon nanotubes activate macrophages into a M1/M2 mixed status: recruiting na?ve macrophages and supporting angiogenesis. ACS Appl Mater Interfaces 2015; 7(5): 3180-3188.

54. Zhang W, Liu J*, Tabata Y, Meng J, Xu H*. The effect of serum in culture on RNAi efficacy through modulation of polyplexes size. Biomaterials 2014; 35(1): 567-577.

55. Li X, Guo H, Yang Y, Meng J, Liu J, Wang C*, Xu H*. A designed peptide targeting CXCR4 displays anti-acute myelocytic leukemia activity in vitro and in vivo. Sci Rep. 2014 Oct 14; 4: 6610.

56. Zhang W, Ji Y, Wu X*, Xu H*. Trafficking of Gold Nanorods in Breast Cancer Cells: Uptake, Lysosome Maturation, and Elimination. ACS Appl Mater Interfaces 2013; 5(19): 9856-9865. 

57. Zhang L, Zhao S, Duan J, Hu Y, Gu N, Xu H, Yang XD*. Enhancement of DC-mediated anti-leukemic immunity in vitro by WT1 antigen and CpG co-encapsulated in PLGA microparticles. Protein & Cell. 2013; 4(12):887-9.

58. Yang M, Meng J, Cheng X, Lei J, Guo H, Zhang W, Kong H, Xu H*. Multiwalled carbon nanotubes interact with macrophages and influence tumor progression and metastasis. Theranostics 2012; 2(3): 258-70.

59. Zhang W, Ji Y, Meng J, Wu X, Xu H*. Probing the behaviors of gold nanorods in metastatic breast cancer cells based on UV-vis-NIR absorption spectroscopy. PLoS One 2012; 7(2): e31957.

60. Zhang W#, Meng J#, Ji Y, Li X, Kong H, Wu X, Xu H*. Inhibiting metastasis of breast cancer cells in vitro using gold nanorod-siRNA delivery system. Nanoscale 2011; 3(9): 3923-2932

61. Yu C#, Hu Y#, Duan J, Yuan W, Wang C, Xu H, Yang XD*. Novel aptamer-nanoparticle bioconjugates enhances delivery of anticancer drug to MUC1-positive cancer cells in vitro. PLoS One 2011; 6(9): e24077.

62. Sun Z#, Liu Z#, Meng J, Meng J, Duan J, Xie S, Lu X, Zhu Z, Wang C, Chen S, Xu H*, Yang XD*. Carbon nanotubes enhance cytotoxicity mediated by human lymphocytes in vitro. PLoS One 2011; 6(6): e21073.

63. Meng J#, Yang M#, Jia F, Kong H, Zhang W, Wang C, Xing J, Xie S, Xu H*. Subcutaneous injection of water-soluble multi-walled carbon nanotubes in tumor-bearing mice boosts the host immune activity. Nanotechnology 2010; 21(14): 145104.

64. Sun Z#, Wang W#, Meng J, Chen S, Xu H*, Yang XD*. (Letter to Editor) Multi-walled carbon nanotubes conjugated to tumor protein enhance the uptake of tumor antigens by human dendritic cells in vitro. Cell Res. 2010 Oct; 20(10): 1170-3.

65. Sun Z#, Wang W#, Wang R, Duan J, Hu Y, Ma J, Zhou J, Xie S, Lu X, Zhu Z, Chen S, Zhao Y, Xu H, Wang C, Yang XD*. Aluminum nanoparticles enhance anticancer immune response induced by tumor cell vaccine. Cancer Nanotechnol. 2010; 1(1-6): 63-69.

66. Jia F#, Wu L#, Meng J, Yang M, Kong H, Liu T*, Xu H*. Preparation, characterization and fluorescent imaging of multi-walled carbon nanotube–porphyrin conjugate, Journal of Materials Chemistry 2009; 19(47): 8950-8957.

67. Meng J#, Meng J#, Duan J, Kong H, Wang C, Xie S, Chen S, Xu H*, Yang XD*. Carbon Nanotubes Conjugated to Tumor Lysate Protein Enhance the Efficacy of an Anti-tumor Immunotherapy. Small 2008; 4(9): 1364-1370.

68. 何朝輝, 邢建民, 孔樺, 許海燕*. 載硫酸慶大霉素聚乳酸納米粒制備的正交設計及體外釋藥行為研究. 生物醫學(xué)工程學(xué)雜志 2009; 26(2):351-355.

69. 孟潔, 楊曼, 王超英, 孔樺, 王睿, 王琛, 解思深, 許海燕*. 水溶液中分散的多壁碳納米管與血液蛋白質(zhì)分子的作用研究. 新型炭材料 2007; 22(3): 218-226.

70. 孟潔, 宋禮, 孔樺, 王朝英, 解思深, 許海燕*. 血漿蛋白分子在單壁碳納米管無(wú)紡膜表面吸附行為的研究. 生物醫學(xué)工程學(xué)雜志 2007; 24(1): 55-60.

71. 郭小天, 孟潔, 孔樺, 宋禮, 王朝英, 何朝輝, 許海燕*, 解思深. 單壁碳納米管無(wú)紡膜表面的PEG修飾及蛋白質(zhì)吸附研究. 中國生物醫學(xué)工程學(xué)報 2006; 24(6): 438-441.


 

第二部分:生物材料與組織工程/再生醫學(xué)

Part 2: Biomaterials & regenerative medicine

 

  1. 1. Jie Meng#, Bo Xiao#, Fengxin Wu#, Lihong Sun, Bo Li, Wen Guo, Xuechun Hu, Xuegai Xu, Tao Wen, Jian Liu*, Haiyan Xu*. Co-axial fibrous scaffolds integrating with carbon fiber promote cardiac tissue regeneration post myocardial infarction. Materials Today Bio. 2022; 16(5): 100415

    2. Hu X, Liu W, Sun L, Xu S, Wang T, Meng J, Wen T, Liu Q, Liu J*, Xu H*. Magnetic Nanofibrous Scaffolds Accelerate the Regeneration of Muscle Tissue in Combination with Extra Magnetic Fields. Int J Mol Sci. 2022 Apr 18; 23(8): 4440.

    3. 校搏, 胡雪純, 劉健, 黃宇光, 許海燕*. 皮下植入聚乳酸/明膠/碳纖維多孔導電凝膠的生物相容性研究. 北京生物醫學(xué)工程2023; 42(4): 355-360.

    4. 郝博雅, 曾菲, 溫濤, 孟潔, 許海燕*, 劉健*. 咖啡酸改性明膠水凝膠制備及其抗氧化功能. 基礎醫學(xué)與臨床2022; 42(7): 1035-1041.

    5. 劉青橋, 郝博雅, 劉文昊, 童元建, 周航, 劉健, 許海燕. 碳纖維/磁性納米顆粒/高分子共軸纖維復合支架構建及其對成纖維細胞的作用研究. 北京生物醫學(xué)工程2022; 41(1):1-7.

    6. 校搏, 許仕琳, 吳鳳新, 劉煊欣, 黃宇光, 許海燕*. 導電性聚乙烯醇復合水凝膠對巨噬細胞和血管內皮細胞的作用研究. 中國生物醫學(xué)工程學(xué)報2022; 41(6): 717-723.

    7. 賴(lài)馨寧, 校博, 黃宇光, 許海燕, 許力*, 劉健*. 導尿管表面局麻藥物緩釋涂層的形成及其鎮痛效果研究. 中國生物醫學(xué)工程學(xué)報202140(6): 82-88.

    8. 徐學(xué)蓋, 吳鳳新, 高愛(ài)軍, 孟潔, 溫濤, 劉健, 徐樑華*, 許海燕*. 三維多孔電磁復合支架構建與理化表征. 中國生物醫學(xué)工程學(xué)報2019; 38(4): 447-453.

    9. Hao S#, Zhang Y#, Meng J, Liu J, Wen T, Gu N*, Xu H*. Integration of a Superparamagnetic Scaffold and Magnetic Field to Enhance the Wound-Healing Phenotype of Fibroblasts. ACS Appl Mater Interfaces 2018 Jul 11; 10(27): 22913-22923.

    10. Fengxin Wu#, Aijun Gao#, Jian Liu, Yaoyi Shen, Panpan Xu, Jie Meng, Tao Wen, Lianghua Xu*, Haiyan Xu*. High modulus conductive hydrogels enhance in vitro maturation and contractile function of primary cardiomyocytes for uses in drug screening. Advanced Healthcare Materials 2018 Nov 28; Doi/10.1002/adhm.201800990

    11. Suisui Hao#, Yaoyi Shen#, Haoan Wu#, Jie Meng, Lifei Xie, Tao Wen, Ning Gu, Jian Liu*, Yu Zhang,* Haiyan Xu*. Modulatory Effects of the Composition and Structure on the Osteogenic Enhancement for Superparamagnetic Scaffolds. Eng. Sci., 2018; 4, 100-110. DOI: 10.30919/es8d782 (Front cover)

    12. Hao S#, Meng J#, Zhang Y, Liu J, Nie X, Wu F, Yang Y, Wang C*, Gu N*, Xu H*. Macrophage phenotypic mechanomodulation of enhancing bone regeneration by superparamagnetic scaffold upon magnetization. Biomaterials 2017; 140:16-25.

    13. 校搏,郝綏綏,吳鳳新,孟潔,張宇,劉健,黃宇光,顧寧,許海燕*. 磁響應性三元復合材料制備及引導骨缺損修復的研究. 中國生物醫學(xué)工程學(xué)報2015; 34(3):330-336.

    14. Meng J#, Xiao B#, Zhang Y, Liu J, Xue H, Lei J, Kong H, Huang Y, Jin Z, Gu N*, Xu H*. Super-paramagnetic responsive nanofibrous scaffolds under static magnetic field enhance osteogenesis for bone repair in vivo. Sci Rep. 2013; 3:2655.

    15. Meng J, Cheng X, Kong H, Yang M, Xu H*. Preparation and biocompatibility evaluation of polyurethane filled with multiwalled carbon nanotubes. J Nanosci Nanotechnol. 2013; 13(2): 1467-1471.

    16. Meng J#, Zhang Y#, Qi X, Kong H, Wang C. Xu Z. Xie S, Gu N* Xu H*. Paramagnetic nanofibrous composite films enhance the osteogenic responses of pre-osteoblast cells. Nanoscale 2010; 2(12): 2565-2569.

    17. Meng J#, Han Z#, Kong H, Qi X, Wang C, Xie S, Xu H*. Electrospun aligned nanofibrous composite of MWCNT/polyurethane to enhance vascular endothelium cells proliferation and function. J Biomed Mater Res A. 2010; 95(1): 312-320

    18. Meng J#, Kong H#, Han Z, Wang C, Zhu G, Xie S, Xu H*. Enhancement of nanofibrous scaffold of MWNTs/polyurethane composite to the fibroblasts growth and biosynthesis. J Biomed Mater Res A 2009; 88(1): 105-116.

    19. Han Z, Kong H, Meng J, Wang C, Xie S, Xu H*. Electrospinning of aligned Carbon nanotubes-Polyurethane composite scaffold for endothelial cells growth. J Nanosci Nanotech 2009; 9(2): 1400-1402

    20. Meng J, Song L, Meng J, Kong H, Zhu G, Wang C, Xu L, Xie S, Xu H*. Using single-walled carbon nanotubes nonwoven films as scaffolds to enhance long-term cell proliferation in vitro. J Biomed Mater Res A. 2006; 79(2): 298-306

    21. Xu H, Kaar JL, Russell AJ, Wagner WR*. Characterizing the modification of surface proteins with poly (ethylene glycol) to interrupt platelet adhesion. Biomaterials 2006; 27(16): 3125-3135.

    22. Meng J, Kong H, Xu HY*, Song L, Wang CY, Xie SS. Improving the blood compatibility of polyurethane using carbon nanotubes as fillers and its implications to cardiovascular surgery. J Biomed Mater Res A. 2005; 74(2): 208-14.

    23. Meng J, Song L, Xu H*, Kong H, Wang C, Guo X, Xie S. Effects of single-walled carbon nanotubes on the functions of plasma proteins and potentials in vascular prostheses. Nanomedicine: Nanotechnology, Biology, and Medicine 2005; 1(2): 136-142.

    24. 孟潔, 郭小天, 孔樺, 楊曼, 許振, 許海燕*. 碳納米管/聚氨酯復合材料的制備及生物相容性評價(jià). 基礎醫學(xué)與臨床 2010; 30(9): 897-901.

    25. 齊曉謹, 孟潔, 孔樺, 吳曉春*, 許海燕*. 表面納微米溝槽結構對成纖維細胞黏附和骨架重排的促進(jìn)作用. 中國生物醫學(xué)工程學(xué)報2009; 27(12): 899-903.

    26. 韓昭昭, 孔樺, 孟潔, 王超英, 朱廣瑾, 解思深, 許海燕*. 取向納米纖維支架引導內皮細胞生長(cháng)的作用研究. 高等學(xué)校化學(xué). 2008; 29(5): 1070-1073.

    27. 孟潔,孔樺,韓昭昭,王朝英,朱廣瑾,解思深,許海燕*. 聚氨酯/碳納米管復合材料電紡絲支架對成纖維細胞生長(cháng)的促進(jìn). 中國組織工程與臨床康復2008; 12(49): 9691-9694.

    28. 孟潔, 宋禮, 孔樺, 王朝英, 朱廣瑾, 徐樑華, 解思深, 許海燕*. 細胞在單壁碳納米管無(wú)紡膜支架上的生長(cháng)行為. 高等學(xué)校化學(xué)學(xué)報2007; 28(4): 476-480

    29. 孟潔, 宋禮, 孔樺, 王朝英, 郭小天, 許海燕*, 解思深. 單壁碳納米管無(wú)紡膜的抗凝血性能及其對血液系統中植入性假體的意義. 新型碳材料2004; 19(3):166-170.

    30. 許海燕, 孔樺, 楊子彬*. 利用等離子體表面接枝技術(shù)提高醫用聚氨酯血液相容性的研究. 中國生物醫學(xué)工程學(xué)報2003; 22(6): 533-536

    31. 許海燕,孔樺,楊子彬*. 聚氨酯/碳納米纖維復合材料的結構和抗凝血性能. 材料研究學(xué)報2003; 17(2): 127-131.

    32. 許海燕*, 孔樺, 藺嫦燕, 李冰一. 聚氨酯/納米碳復合材料表面的血液相容性研究. 中國醫學(xué)科學(xué)院學(xué)報2002; 24(2): 114-7

    33. 孔樺, 許海燕*, 藺嫦燕, 李冰一, 王景. 納米碳改性聚氨酯復合材料的表面抗凝血性能.基礎醫學(xué)與臨床2002; 22(2): 113-116

    34. Xu H, Kong H, Yang Z*. The Preparation of Nanoscale Composite of Polyurethane to Decrease Platelet Deposition on the Surface. Chinese Journal of Biomedical Engineering English Edition2001; 10(4): 194


 

第三部分:納米材料毒理學(xué)與臨床安全應用

Part 3 Biological Effects of nanomaterials and safety application

 

  1. 1. Zhang X, Kong F, Wang T, Huang X, Li W, Zhang M, Wen T, Liu J, Zhang Y, Meng J, Xu H. Iron oxide nanoparticles cause surface coating- and core chemistry-dependent endothelial cell ferroptosis. Nanotoxicology. 2023 Jan 20:1-15. doi: 10.1080/17435390.2022.2154176.

    2. Yang A, Wen T*, Hao B, Meng Y, Zhang X, Wang T, Meng J, Liu J, Wang J, Xu H*. Biodistribution and Toxicological Effects of Ultra-Small Pt Nanoparticles Deposited on Au Nanorods (Au@Pt NRs) in Mice with Intravenous Injection. International Journal of Nanomedicine 2022, 17, 5339-5351.

    3. Ruan L, Lu L, Zhao X, Xiong W, Xu H*, Wu S*. Effects of natural antioxidants on the oxidative stability of Eucommia ulmoides seed oil: Experimental and molecular simulation investigations. Food Chem. 2022 Jul 30; 383:132640.

    4. Zhang S, Zhang X, Meng J, Lu L, Du S, Xu H*, Wu S*. Study on the Effect of Polymer Excipients on the Dispersibility, Interaction, Solubility, and Scavenging Reactive Oxygen Species of Myricetin Solid Dispersion: Experiment and Molecular Simulation. ACS Omega. 2022 Jan 3; 7(1): 1514-1526.

    5. Geng H, Ren Y, Qin G, Wen T*, Liu Q, Xu H, He W*. Ti3C2 nanosheets with broad-spectrum antioxidant activity for cytoprotection against oxidative stress. RSC Adv. 2022 Apr 8; 12(18): 11128-11138.

    6. Xie Q#, Wen T#, Yang A, Zhang X, Chen B, Meng J, Liu J, Gu N*, Xu H*. A Contrast Examination of Proinflammatory Effects on Kidney Function for γ-Fe2O3 NP and Gadolinium Dimeglumine. Int J Nanomedicine. 2021; 16: 2271-2282.

    7. 張雪, 孔非, 溫濤, 張宇, 許海燕, 孟潔. 氧化鐵納米顆粒引起肝血竇內皮細胞損傷及其機制研究. 中國生物醫學(xué)工程學(xué)報2021, 40(5): 582-589

    8. Li H#, Wen T#, Wang T, Ji Y, Shen Y, Chen J, Xu H*, Wu X*. In Vivo Metabolic Response upon Exposure to Gold Nanorod Core/Silver Shell Nanostructures: Modulation of Inflammation and Upregulation of Dopamine. International Journal of Molecular Sciences.   2020; 21 2: 384.

    9. Lu L, Luo K, Yang W, Zhang S, Wang W, Xu H, Wu S. Insight into the anti-aging mechanisms of natural phenolic antioxidants in natural rubber composites using a screening strategy based on molecular simulation. RSC Adv. 2020 Jun 4; 10(36): 21318-21327.

    10. Wen T#, Du L#, Chen B, Yan D, Yang A, Liu J, Gu N, Meng J*, Xu H*. Iron oxide nanoparticles induce reversible endothelial-to-mesenchymal transition in vascular endothelial cells at acutely non-cytotoxic concentrations. Part Fibre Toxicol. 2019 Jul 12; 16(1): 30.

    11. Wen T#, Yang A#, Piao L, Hao S, Du L, Meng J, Liu J, Xu H*. Comparative study of in vitro effects of different nanoparticles at non-cytotoxic concentration on the adherens junction of human vascular endothelial cells. Int J Nanomedicine. 2019 Jun 18; 14: 4475-4489.

    12. Tao Wen#, Doudou Yan#, Jie Meng, Jian Liu and Haiyan Xu*. The Enzyme-Like Property and Photocatalytic Effect on α, α-Diphenyl-b-Picrylhydrazyl (DPPH) of CuPt Nanocomposite. Catalysts 2019, 9, 813; doi:10.3390/catal9100813

    13. 楊?lèi)?ài)云#, 溫濤#, 武昊安, 苗玉清, 孟潔, 劉健, 張宇, 樊海明, 許海燕*. 不同磁性納米材料對血管內皮細胞作用的對比研究. 北京生物醫學(xué)工程2018; 37 (3): 235-240.

    14. 杜麗帆 張宇 楊?lèi)?ài)云 溫濤 劉健 孟潔 許海燕. 二巰基丁二酸修飾的Fe3O4納米顆粒對人血管內皮細胞的作用研究. 北京生物醫學(xué)工程2019383):221-226.

    15. Yang M#, Nie X#, Meng J*, Liu J, Sun Z, Xu H*. Carbon Nanotubes Activate Limulus Amebocyte Lysate Coagulation by Interface Adsorption. ACS Appl Mater Interfaces. 2017 Mar 15; 9(10): 8450-8454.

    16. Lin CX, Yang SY, Gu JL, Meng J, Xu HY, Cao JM*. The acute toxic effects of silver nanoparticles on myocardial transmembrane potential, I(Na) and I(K1) channels and heart rhythm in mice. Nanotoxicology. 2017 Aug 23:1-11.

    17. Li H, Tan XQ, Yan L, Zeng B, Meng J, Xu HY, Cao JM*. Multi-walled carbon nanotubes act as a chemokine and recruit macrophages by activating the PLC/IP3/CRAC channel signaling pathway. Sci Rep. 2017; 7(1): 226.

    18. Guo H#, Zhang J#, Boudreau M, Meng J, Yin JJ, Liu J*, Xu H*. Intravenous administration of silver nanoparticles causes organ toxicity through intracellular ROS-related loss of inter-endothelial junction. Part Fibre Toxicol. 2016; 13:21.

    19. Wen T, Zhang H, Chong Y, Wamer WG, Yin JJ, Wu, X*. Probing hydroxyl radical generation from H2O2 upon Plasmon excitation of gold nanorods using electron spin resonance: Molecular oxygen-mediated activation. Nano Res. 2016; 9:1663.

    20. Meng J, Ji Y, Liu J, Cheng X, Guo H, Zhang W, Wu X*, Xu H*. Using gold nanorods core/silver shell nanostructures as model material to probe biodistribution and toxic effects of silver nanoparticles in mice. Nanotoxicology 2014; 8(6): 686-696

    21. Tan XQ#, Cheng XL#, Zhang L, Wu BW, Liu QH, Meng J, Xu HY, Cao JM*. Multi-walled carbon nanotubes impair Kv4.2/4.3 channel activities, delay membrane repolarization and induce bradyarrhythmias in the rat. PLoS One 2014; 9(7): e101545.

    22. Yang N#, Liu Y#, Ji Y, Ren Z, Meng J, Ji C, Liu J, Zheng J, Wu X*, Zuo P*, Xu H*. Motor coordination dysfunction induced by gold nanorods core/silver shell nanostructures in mice: disruption in mitochondrial transport and neurotransmitter release. RSC Adv. 2014; 4, 59472-59480.

    23. Cheng X#, Zhang W#, Ji Y, Meng J, Guo H, Liu J, Wu X*, Xu H*. Revealing silver cytotoxicity using Au nanorods/Ag shell nanostructures: disrupting cell membrane and causing apoptosis through oxidative damage. RSC Adv. 2013; 3, 2296-2305.

    24. Meng J#, Cheng X#, Liu J, Zhang W, Li X, Kong H, Xu H*. Effects of long and short carboxylated or aminated multiwalled carbon nanotubes on blood coagulation. PLoS One 2012; 7(7): e38995.

    25. Cheng X#, Zhong J#, Meng J, Yang M, Jia F, Xu Z, Kong H, Xu H*. Characterization of Multiwalled Carbon Nanotubes Dispersing in Water and Association with Biological Effects. Journal of Nanomaterials 2011; Article ID 938491, 12 pages

    26. Meng J, Yang M, Jia F, Xu Z, Kong H, Xu H*. Immune responses of BALB/c mice to subcutaneously injected multi-walled carbon nanotubes. Nanotoxicology 2011; 5(4): 583-91.

    27. Yang M, Meng J, Mao X, Yang Y, Cheng X, Yuan H, Wang C, Xu H*. Carbon nanotubes induce secondary structure changes of bovine albumin in aqueous phase. J Nanosci Nanotechnol. 2010; 10(11): 7550-3.

    28. Li C#, Liu H#, Sun Y#, Wang H, Guo F, Rao S, Deng J, Zhang Y, Miao Y, Guo C, Meng J, Chen X, Li L, Li D, Xu H*, Wang H*, Li B, Jiang C*. PAMAM nanoparticles promote acute lung injury by inducing autophagic cell death through the Akt-TSC2-mTOR signaling pathway. J Mol Cell Biol. 2009; 1(1): 37-45.

    29. Meng J#, Yang M#, Song L, Kong H, Wang C, Wang R, Wang C, Xie S, Xu H*. Concentration control of carbon nanotubes in aqueous solution and its influence on the growth behavior of fibroblasts. Colloids and Surfaces B: Biointerfaces 2009; 71(1): 148-153.

    30. Zhong J, Meng J, Liang X, Song L, Zhao T, Xie S, Ibrahim K, Qian H, Wang J, Guo J, Xu H*, Wu Z*. XANES study of phenylalanine and glycine adsorption on single-walled carbon nanotubes. Materials Letters 2009; 63:431-433.

    31. Zhong J#, Song L#, Meng J, Gao B, Chu W, Xu H, Luo Y, Guo J, Marcellif A, Xie S*, Wu Z*. Bio–nano interaction of proteins adsorbed on single-walled carbon nanotubes. Carbon 2009; 47: 967-973.

    32. Meng J, Song L, Zhong J, Wang C, Kong H, Wu Z, Xu H*, Xie S. Comparison of adsorption behavior for fibrinogen and albumin on single walled carbon nanotubes nonwoven. Solid State Phenomena 2007; 121-123:781-784.

    33. Song L, Meng J, Zhong J, Liu L, Dou X, Liu D, Zhao X, Luo S, Zhang Z, Xiang Y, Xu H, Zhou W, Wu Z*, Xie S*. Human fibrinogen adsorption onto single-walled carbon nanotube films. Colloids Surf B Biointerfaces. 2006; 49(1): 66-70.


 

第四部分:綜述文章

  1. 1. Jie Meng, Xuechun Hu, Tao Wen, Tao Wang, Jian Liu*, Haiyan Xu*. Interactions to plasm protein and application potentials of carbon nanotubes in blood-contacting medical devices. Nano Research 2023, 16: 12506-12515.

    2. 范克龍*, 高利增*, 魏輝*, 江冰*, 王大吉*, 張若飛, 賀久洋, 孟祥芹, 王卓然, 樊慧真, 溫濤, 段德民, 陳雷, 姜偉, 蘆宇, 蔣冰, 魏詠華, 李唯, 袁野, 董海姣, 張鷺, 洪超儀, 張紫霞, 程苗苗, 耿欣, 侯桐陽(yáng), 侯亞欣, 李建茹, 湯國恒, 趙越, 趙菡卿, 張帥, 謝佳穎, 周子君, 任勁松, 黃興祿*, 高興發(fā)*, 梁敏敏*, 張宇*, 許海燕*, 曲曉剛*, 閻錫蘊*. 納米酶. 化學(xué)進(jìn)展. 2023, 35 (1), 1-87.

    3. 蒙藝靈, 溫濤*, 許海燕. 光熱療法中熱休克蛋白的抑制策略及其研究進(jìn)展. 中國生物醫學(xué)工程學(xué)報 2023, 42 (2), 229-234.

    4. Zhang M, Xu H. Peptide-assembled nanoparticles targeting tumor cells and tumor microenvironment for cancer therapy. Front Chem. 2023 Jan 24; 11: 1115495.

    5. 胡雪純,許海燕. 納米材料組織工程支架在女性生殖系統再生中的應用研究. 基礎醫學(xué)與臨床. 2022; 42(1): 26-32.

    6. Tao Wang, Haiyan Xu*. Multi-faced roles of reactive oxygen species in anti-tumor T cell immune responses and combination immunotherapy. Exploration of Medicine. 2022; 3: 77-98

    7. 許仕琳, 許海燕*. CD123靶向抑制劑在急性髓細胞白血病治療中的新進(jìn)展. 國際輸血及血液學(xué)雜志. 2021; 44(2): 122-131.

    8. 許仕琳,許海燕*. 雙特異性抗體及納米技術(shù)在腫瘤免疫治療中的應用研究(特邀評述). 合成生物學(xué). 2021; 1-17, doi: 10.12211/2096-8280.2021-045.

    9. 溫濤, 高潔, 王孝平, 許海燕*. 健康、安全與環(huán)境納米技術(shù)標準化研究進(jìn)展. 中國科學(xué):生命科學(xué). 2020; 50(07): 766-777.

    10. 高利增#, 梁敏敏#, 溫濤#, 魏輝, 張宇, 范克龍, 曲曉剛, 顧寧, 龐代文, 許海燕*, 閻錫蘊*. 納米酶標準術(shù)語(yǔ). 中國科技術(shù)語(yǔ). 2020; 22(6): 21-24

    11. 許海燕*,郭花. 納米銀材料的安全性評價(jià)與管理規范初探. 中國材料進(jìn)展2016; 35(409): 36-39.

    12. 郝綏綏, 許海燕*. 創(chuàng )傷環(huán)境巨噬細胞表型的時(shí)空相關(guān)性及其對生物材料支架引導組織再生與修復的意義. 中國生物醫學(xué)工程學(xué)報2015; 34(4): 475-480.

    13. 劉會(huì )可,許海燕*. AXL在腫瘤轉移和耐藥中的作用及干預策略研究進(jìn)展. 基礎醫學(xué)與臨床2015; 36(1): 112-115

    14. Haiyan Xu and Ning Gu. Magnetic responsive scaffolds and magnetic fields in bone repair and regeneration. Front. Mater. Sci. 2014; 8(1): 20-31

    15. Zhang W, Xu H. Tailoring the RNAi efficiency of polyplexes. Bioengineered. 2014 May-Jun; 5(3):152-154.

    16. 呂曉蓉,李超,王東亮,許海燕,吳樹(shù)仙,郭大軍,梁興杰. 納米藥物國際發(fā)展態(tài)勢. 科學(xué)觀(guān)察 2013; (8) 3: 53-57

    17. Haiyan XU*. Recent Patents on Nanostructured Scaffolds for Bone Tissue Repair and Regeneration (invited review). Recent Patents on Nanomedicine. 2011; 1(1): 73-84

    18. 孟潔, 許海燕*. 納米材料在分子影像學(xué)研究中的應用進(jìn)展(邀請). 中國生物醫學(xué)工程學(xué)報. 2011; 30(1): 1-5

    19. Haiyan Xu*, Jie Meng, Hua Kong. What are carbon nanotubes’ roles in anti-tumor therapies? (invited review) Sci China Chem. 2010, 53(11): 2250-2256.

    20. 張衛奇, 許海燕*. 碳納米管作為核酸類(lèi)物質(zhì)轉運載體的研究進(jìn)展. 生物物理學(xué)報2010; 26(8): 662-672

    21. 許振, 許海燕*. 基于組織工程應用的生長(cháng)因子/高分子納米粒子傳遞系統的研究進(jìn)展. 國際生物醫學(xué)工程學(xué)雜志2011; 34(1): 39-42

    22. 齊小謹, 許海燕*. 無(wú)機納米粒子在基因運載方面的應用研究進(jìn)展. 生物醫學(xué)工程學(xué)雜志2009; 26 (6): 1376-1379

    23. 加福民, 許海燕*. 碳納米管進(jìn)入細胞的機制及其在細胞中的定位研究進(jìn)展. 生物醫學(xué)工程學(xué)雜志2010; 27(1): 198-201

    24. 楊曼, 許海燕*. 納米粒子在免疫治療方面的應用潛能和研究現狀. 生物醫學(xué)工程學(xué)雜志 2009; 26(1): 187-190

    25. 韓昭昭, 許海燕*. 動(dòng)態(tài)力學(xué)因素在組織工程中的作用. 生物醫學(xué)工程學(xué)雜志 2008; 25(3): 716-719

    26. 孟潔, 朱廣瑾, 許海燕*. 納米拓撲結構的構建以及對細胞行為的影響. 生物醫學(xué)工程學(xué)雜志2007; 24(3): 685-689

    27. 孟潔, 孔樺, 朱廣瑾, 許海燕*. 納米纖維結構支架的構建及其對再生醫學(xué)的意義. 基礎醫學(xué)與臨床2006; 26(7): 689-693.

    28. 許海燕*. 納米技術(shù)在醫學(xué)領(lǐng)域的應用研究進(jìn)展(邀請). 中華醫學(xué)雜志2006; 86(8): 505-

    29. 何朝輝, 孔樺, 許海燕*. 藥物和基因載體樹(shù)枝狀大分子的生物學(xué)效應和表面修飾的 研究進(jìn)展. 中國醫學(xué)科學(xué)院學(xué)報2006; 28(4): 590-595

    30. 郭小天, 許海燕*. 碳納米管及其復合材料在生物醫學(xué)領(lǐng)域的研究進(jìn)展. 生物醫學(xué)工程學(xué)雜志2006; 23(2): 438-441.

    31. 許海燕*. 納米生物醫學(xué)的研究進(jìn)展與發(fā)展趨勢. 中國生物醫學(xué)工程學(xué)報2006; 24(6): 643-648

    32. 孟潔, 許海燕*. 生物材料與血液相互作用過(guò)程的研究進(jìn)展. 生物醫學(xué)工程學(xué)雜志 2005; 22 (6): 1271-1274.

    33. 黃飛, 徐樑華*, 許海燕. 樹(shù)枝狀大分子在生物醫學(xué)領(lǐng)域的研究進(jìn)展. 生物醫學(xué)工程學(xué)雜志2005; 22(1): 197-201

    34. 許海燕, 孔樺, 楊子彬*. 抗凝血高分子材料的研究進(jìn)展及其在心血管系統中的應用,高分子材料科學(xué)與工程2001; 17(5):167


    專(zhuān) 著(zhù)

    1. 許海燕等編著(zhù). 《生物醫學(xué)工程學(xué)》. 科學(xué)出版社. 20216. 北京.ISBN 978-7-03-069041-8

    2. Nanotechnology in Regenerative Medicine and Drug Delivery Therapy. Edited by Haiyan Xu & Ning Gu. Springer 2020. doi: 10.1007/978-981-15-5386-8 (ISBN: 978-981-15-5385-1)

    3. Haiyan Xu, Jie Meng, Qiang Ma, Xiaojin Li. Immunological responses induced by carbon nanotubes exposed to skin, gastric and intestinal system. Chapter 12 in Biomedical Application and Toxicology of Carbon Nanomaterials. Edited by Chunying Chen and Haifang Wang. Wiley-VCH Verlag GmbH & Co. KgaA. 2016 (ISBN 978-7-03-041828-9)

    4. 顧寧, 許海燕主編.《生物醫用納米材料對細胞的作用》. 科學(xué)出版社. 2014. 北京. (ISBN 978-7-03-041831-9)

    5. 許海燕. 碳納米管對免疫細胞的作用及其在抗腫瘤免疫治療中的應用前景.《生物醫用納米材料對細胞的作用》第14. 顧寧, 許海燕主編. 科學(xué)出版社. 2014. 北京.

    6. 孟潔. 納米粒子對細胞信號通路的影響.《生物醫用納米材料對細胞的作用》第11. 顧寧, 許海燕主編. 科學(xué)出版社. 2014. 北京.

    7. 許海燕. 納米材料的佐劑效應及其在腫瘤免疫治療中的應用.《納米材料新特性及生物醫學(xué)應用》第7. 閻錫蘊編著(zhù).科學(xué)出版社. 2014. 北京.

    8. 許海燕等編著(zhù)《生物醫藥納米載體》. 科學(xué)出版社. 20123. 北京 (ISBN 978-7-03-033425-1)

    9. 孟潔, 雷晶. 納米載體在分子影像學(xué)中的應用研究.《納米生物醫藥載體》第9. 許海燕等編著(zhù). 科學(xué)出版社. 2012. 北京.

    10. 許海燕, 王琛主編. 《納米生物醫學(xué)技術(shù)》. 中國協(xié)和醫大出版社. 20096月于北京



 

發(fā)明專(zhuān)利

  1. 1. 許海燕,王琛,孟潔,劉健,楊延蓮,溫濤,方小翠. 多肽P12在制備CXCR4 拮抗劑和治療胰腺癌的藥物中的應用. 申請號:2023111946779,申請日:20230915.

    2. 許海燕,王琛,王濤,楊延蓮,劉健,溫濤,孟潔,方小翠. SARS-CoV-2刺突蛋白特異性結合的多肽、多肽組合物及其制備方法與應用. 國際專(zhuān)利申請號:PCT/CN2022/078627,申請日期:202231.

    3. 王晨軒,于蘭蘭,王若楠,許海燕,溫濤. 一種親和肽在準備抗病毒藥物中的應用. 國家發(fā)明專(zhuān)利. 授權號:ZL2021 1 0178816.3. 申請日期:202129.

    4. 王晨軒,于蘭蘭,王若楠,許海燕,溫濤. 一種新型冠狀病毒主蛋白酶的親和肽M1及其應用. 授權號:ZL202110231722.8. 申請日:202132.

    5. 王晨軒,于蘭蘭,王若楠,許海燕,溫濤. 一種親和肽M5穩定的金納米顆粒及其制備方法和用途. 授權號:ZL202110529881.6. 申請日:2021514.

    6. 許海燕,王琛,許仕琳,楊延蓮,孟潔,劉健,溫濤. CD123蛋白特異性結合的多肽、多肽復合物、共遞送系統及其制備方法與應用. 國家發(fā)明專(zhuān)利授權:202010571978.9;國際專(zhuān)利申請號:PCT/CN2021/101405

    7. 許海燕,王琛,王濤,楊延蓮,劉健,溫濤,孟潔,方小翠. SARS-CoV-2刺突蛋白特異性結合的多肽組合物及其制備方法與應用. 授權號:ZL 202110224822.8,申請日期:202132.

    8. 許海燕、王琛、王濤、楊延蓮、溫濤、劉健、孟潔、方小翠. SARS-CoV-2刺突蛋白特異性結合的多肽KVp-C及其制備方法與應用. 授權號:ZL 202110224251.8,申請日期:202131.

    9. 許海燕、王琛、王濤、楊延蓮、劉健、孟潔、溫濤、方小翠. SARS-CoV-2刺突蛋白特異性結合的多肽KVp-N及其制備方法與應用. 授權號:ZL 202110224252.2,申請日期:202131.

    10. 許海燕、王琛、王濤、楊延蓮、孟潔、溫濤、劉健、方小翠. SARS-CoV-2刺突蛋白特異性結合的多肽KVp-R及其制備方法與應用. 授權號:ZL 202110224800.1,申請日期:202131.

    11. 溫濤, 許海燕, 楊?lèi)?ài)云, 孟潔, 劉健. 含鉑顆粒在制備誘導白血病細胞分化的藥物和/或醫療產(chǎn)品中的應用. 申請號:202010947496.9

    12. 許海燕,閆豆豆,孟潔,劉健,溫濤,葛洋洋. 一種雙藥共遞送系統及其制備方法與應用. 授權:ZL 201910151138.4. 國際專(zhuān)利申請號:PCT/CN2020/076891

    13. 王琛,許海燕,楊延蓮,劉健,江妹,謝麗菲. 靶向特異性多肽及其應用. 申請號:CN201910817056. 申請日:2019830.

    14. 劉健, 許海燕,謝麗菲,孟潔. 作為免疫增強劑的精胺修飾的普魯蘭多糖. 國家發(fā)明專(zhuān)利,授權:ZL 201810671581X

    15. 許海燕,馬強,王川,劉健,孟潔. 水溶性雄黃固體分散體及其制備方法與應用. 國家發(fā)明專(zhuān)利. 授權號:ZL201510324572x.

    16. 許海燕,劉健,王濤,韓冰,孟潔,溫濤. 水溶性雄黃固體分散體在制備骨髓造血干/祖細胞紅系分化誘導劑中的應用. 申請號:201810321323.9; 國際專(zhuān)利申請號:PCT/CN2019/082256

    17. 王琛,許海燕,楊棽,孟潔,劉健,楊延蓮. 一種用于體內外凋亡成像探針的多肽及其用途. 國家發(fā)明專(zhuān)利. CN201510501800.6.

    18. 王琛,段鴻洋,楊延蓮,許海燕,李瀟瑾,郭花,謝含儀,于越. 一種抑制腫瘤轉移和治療白血病的多肽和多肽復合物、其制備方法及其應用. 國際申請號:PCT/CN2015/083021. 美國授權:US10,258,669B2;歐洲授權:15824964.9.

    19. 王琛,段鴻洋,楊延蓮,謝含儀,許海燕,李瀟瑾. 一種抑制腫瘤轉移的多肽及其應用. 國家發(fā)明專(zhuān)利. ZL201910797124X

    20. 王琛 方小翠 楊延蓮 段鴻洋 許海燕. 一種多肽納米膠束及其制備方法和應用. 國家發(fā)明專(zhuān)利. 2015109204189

    21. 王琛,方小翠,楊延蓮,段鴻洋,許海燕,李瀟瑾,孟潔. 一種多肽和化療藥物聯(lián)合的載藥膠柬及其制備方法和應用. 國家發(fā)明專(zhuān)利. 2015109208175

    22. 王琛,段鴻洋,楊延蓮,許海燕,李瀟瑾,郭花,謝含儀,于越. 一種抑制腫瘤轉移和治療白血病的多肽和多肽復合物、其制備方法及其應用. 國家發(fā)明專(zhuān)利. CN201410497974.

    23. 王琛,楊延蓮,許海燕,李瀟瑾,張衛奇,孟潔,王晨軒. 一種增強腫瘤細胞對抗腫瘤藥物敏感性的多肽及其應用. 國家發(fā)明專(zhuān)利. CN 201310298419.

    24. 許海燕、孔樺、齊小謹、顧寧、張宇. 一種磁性復合材料及其在骨組織再生和修復中的應用. 國家發(fā)明專(zhuān)利. ZL 2009102115850

    25. 許海燕,孟潔,孔樺. 碳納米管在制備抗腫瘤免疫治療藥物的免疫促進(jìn)劑中的應用. 國家發(fā)明專(zhuān)利. ZL 200810102322.

    26. 許海燕,孟潔,孔樺. 制備高濃度穩定碳納米管水溶液的方法. 國家發(fā)明專(zhuān)利. ZL 2008101023217

    27. 許海燕、孔樺、孟潔. 一種用于血液環(huán)境中的碳納米管/高分子復合材料及其制備方法與應用. 國家發(fā)明專(zhuān)利. ZL 2004100479065


 

學(xué)術(shù)會(huì )議交流

----邀請報告---

  1. 1. 許海燕. 碳纖維/水凝膠導電復合材料促進(jìn)心肌組織修復的作用研究. 2023醫用材料與分子影像會(huì )議暨天津市生物醫學(xué)工程學(xué)會(huì )納米生物醫學(xué)專(zhuān)委會(huì )年會(huì )20231215-16日,天津

    2. 許海燕. 細胞器定位的金納米棒及用于腫瘤免疫治療研究. 第六屆細胞生物信息學(xué)研討會(huì )20231129-30日,上海

    3. 許海燕.  Evaluation Considerations of Biological Effects for Iron Oxide Nanoparticles on Vascular Endothelial Cells. ChinaNanomedicine 2023 The 5th International Conference on Nanomedicine of China 2023114-6日,廣州

    4. 劉健. 導電/超順磁復合高分子支架促肌肉組織再生. 2023中國生物材料大會(huì )20231012-15 ,重慶

    5. 許海燕. 納米酶術(shù)語(yǔ)、標準化、質(zhì)控標準 中國生物物理學(xué)會(huì )納米酶分會(huì ). 2023納米酶高峰論壇2023106-9

    6. 許海燕. 電磁復合材料對細胞行為調控及促進(jìn)組織再生作用研究. 2023年干細胞與組織工程高峰論壇2023923-24

    7. 許海燕. The effect of As4S4 nanoparticles to induce multiple-lineage differentiation and post-differentiation apoptosis in leukemia and myelodysplastic syndromes. 9th International Conference on Nanoscience and Technology ChinaChinaNANO 20232023826-28日,北京

    8. 劉健. 針對白血病細胞的納米核酸遞送系統. 中國生物物理學(xué)會(huì )納米生物學(xué)分會(huì )第九屆學(xué)術(shù)年會(huì )2023821-24日,湖北恩施

    9. 許海燕. CXCR4 antagonistic peptides and chemotherapeutics co-delivery system for uses in refractory leukemia treatment. 第十七屆中國國際多肽學(xué)術(shù)會(huì )議2023614-16日,天津.

    10. 劉健. 精胺-普魯蘭聯(lián)合地氯雷他定增強對白血病細胞的RNA干擾效率. 2023中國生物醫學(xué)工程大會(huì )暨創(chuàng )新醫療峰會(huì ). 2023520江蘇蘇州

    11. 溫濤. 細胞器靶向的金納米棒偶聯(lián)物光熱免疫治療三陰性乳腺癌. 2023中國生物醫學(xué)工程大會(huì )暨創(chuàng )新醫療峰會(huì )第四屆BME她論壇. 2023521江蘇蘇州

    12. 許海燕. 氧化鐵納米顆粒誘導血管內皮細胞鐵死亡的機制研究. 中國毒理學(xué)會(huì )特種醫學(xué)毒理學(xué)專(zhuān)業(yè)委員會(huì )和納米毒理專(zhuān)業(yè)委員會(huì )聯(lián)合學(xué)術(shù)大會(huì )202356-8日,重慶.

    13. 許海燕. 小尺寸引出新效應:雄黃納米晶對白血病的誘導分化治療作用研究. 2022年中國生物醫學(xué)工程大會(huì )暨創(chuàng )新醫療峰會(huì ). 納米醫學(xué)分會(huì )場(chǎng)邀請報告. 2022411. (線(xiàn)上)

    14. 孟潔. 雄黃納米晶對急性髓細胞白血病誘導分化治療作用. 2022年中國生物醫學(xué)工程大會(huì )暨創(chuàng )新醫療峰會(huì ). 第三屆BME她論壇邀請報告. 2022412. (線(xiàn)上)

    15. 許海燕. CXCR4CD123拮抗與難治性急性髓系白血病治療研究. 2021首屆國際胸部腫瘤錢(qián)塘峰會(huì ),基礎分會(huì )場(chǎng)邀請報告. 20211218日(線(xiàn)上)

    16. Haiyan XU. Antagonistic peptide nanomicelles targeting CXCR4 to combat refractory acute myeloid leukemia. 第四屆國際納米藥物大會(huì )(China Nanomedicine 2021,納米生物技術(shù)分會(huì )場(chǎng)邀請報告). 20211112-15日(線(xiàn)上)

    17. Haiyan Xu. CD123 antagonistic peptide-loaded nanomicelles combat refractory acute myeloid leukemia. The 8th Japan-China Symposium on Nanomedicine. June 11-12, 2021, Webmeeting. Sponsored by Mie University, Japan.

    18. Jie Meng. Water dissolvable Arsenic sulfide nanoformulation realized the induction therapy in the refractory AML mouse model through inhibiting the activity of HDAC. The 8th Japan-China Symposium on Nanomedicine. June 11-12, 2021, Webmeeting. Sponsored by Mie University, Japan.

    19. Tao Wang. Prussian blue nanoparticles induce myeloid leukemia cells to differentiate into red blood cells through nanozyme activities. The 8th Japan-China Symposium on Nanomedicine. June 11-12, 2021, Webmeeting. Sponsored by Mie University, Japan.

    20. 許海燕. 靶向CD123蛋白的多肽納米藥物及其對白血病治療作用的研究. 微納米技術(shù)與醫療健康創(chuàng )新大會(huì )(2021)暨中國微米納米技術(shù)學(xué)會(huì )第五屆微米納米技術(shù)應用創(chuàng )新大會(huì ). 2021528-31. 上海.

    21. 孟潔. CXCR4拮抗多肽納米膠束抗白血病作用研究. 第二屆全國生物磁學(xué)與磁性納米材料學(xué)術(shù)會(huì )議暨第九屆納米醫學(xué)全國博士生論壇. 20201212-14.

    22. 許海燕. 腫瘤治療用CXCR4拮抗多肽. 中關(guān)村科技成果轉化火花活動(dòng)——中國醫學(xué)科學(xué)院藥物研究院專(zhuān)場(chǎng)現場(chǎng)路演活動(dòng). 20201124日,北京.

    23. 劉健. 納米技術(shù)助力髓系白血病治療. 北京地區廣受關(guān)注學(xué)術(shù)成果報告會(huì )(生物醫學(xué)工程領(lǐng)域). 20201118, 北京.

    24. 許海燕. 化學(xué)合成CXCR4拮抗多肽納米膠束對急性髓系白血病的治療研究. 微納米技術(shù)與醫療健康創(chuàng )新大會(huì )暨中國微米納米技術(shù)學(xué)會(huì )第四屆微米納米技術(shù)應用創(chuàng )新大會(huì ). 20201024-26. 廈門(mén)(分會(huì )場(chǎng)邀請報告)

    25. Haiyan Xu. CXCR4 antagonistic peptide for Leukemia treatment. 2019 International Conference of Innovative Medicines. Hangzhou, Oct 30-Nov 1, 2019 (分論壇邀請報告)

    26. 劉健. 力學(xué)性質(zhì)對明膠納米顆粒siRNA遞送效果的影響. 2019中國生物醫學(xué)工程大會(huì )暨創(chuàng )新醫療峰會(huì )(BME2019. 20191114-16, 濟南(分會(huì )場(chǎng)邀請報告).

    27. 許海燕. 新型化學(xué)合成CXCR4拮抗多肽及其納米膠束制劑的抗白血病功效研究. 第一屆生物醫藥創(chuàng )新高峰論壇. 20191018-20日,天津(分論壇邀請報告)

    28. 許海燕. 應用導電性復合材料構建原代心肌細胞片. 2019年納米和表面科學(xué)與技術(shù)全國會(huì )議. 2019107-10日,蘇州(分會(huì )場(chǎng)邀請報告)

    29. 許海燕. 應用超順磁性納米材料和外加磁場(chǎng)調控組織再生的免疫環(huán)境和細胞行為. 2019生物醫用磁學(xué)納米技術(shù)研討會(huì )暨第八屆全國生物與醫學(xué)納米技術(shù)博士生學(xué)術(shù)論壇. 2019915. 南京(邀請報告)

    30. 劉健. 針對巨噬細胞的靶向成像及免疫治療研究. 第七屆生物醫用磁學(xué)納米技術(shù)研討會(huì )暨第八屆全國生物與醫學(xué)納米技術(shù)博士生學(xué)術(shù)論壇. 2019914-16, 南京(邀請報告)

    31. Haiyan Xu. Interaction of inorganic nanoparticles to vascular endothelial cells and implication to biomedicine. China-Nano 2019, Aug 17-19, 2019. Beijing(分會(huì )場(chǎng)邀請報告)

    32. 許海燕. 碳纖維增強導電水凝膠構建及其對心肌細胞的作用. 合肥光源2019年用戶(hù)學(xué)術(shù)年會(huì ). 2019726. 呼和浩特(分會(huì )場(chǎng)邀請報告)

    33. Haiyan Xu. Nano-micelles for co-delivery of doxorubicin and homoharringtonine for the treatment of acute myeloid leukem. The 7th China-Japan Symposium of Nanomedicine. May 24-26, 2019. Xi’an

    34. 許海燕. Hydrophilic As4S4 nanoparticles inhibit metastasis of murine breast cancer through downregulating reactive oxygen species in the tumor microenvironment. 2019 中國生物物理學(xué)會(huì )納米生物學(xué)分會(huì )學(xué)術(shù)年會(huì )暨創(chuàng )新納米藥物雄安論壇. 2019424-28. 河北大學(xué)

    35. 許海燕. 應用納米技術(shù)發(fā)展髓系白血病治療新方法. 2019年全國納米醫學(xué)與工程高峰論壇. 2019419-20. 天津(分論壇邀請報告)

    36. 許海燕. 親水性雄黃納米顆粒通過(guò)調控ROS誘導白血病細胞分化和凋亡. 中國化學(xué)會(huì )第31屆學(xué)術(shù)年會(huì ). 201854-8, 杭州.(分會(huì )場(chǎng)邀請報告)

    37. Haiyan Xu. Integration of super-paramagnetic scaffold and magnetic field to modulate immunological microenvironment for enhancing bone tissue regeneration. The 3rd International Symposium on Immuno-biomaterials. June 4, 2018. Nankai University. (邀請)

    38. 許海燕. 基于導電高模量水凝膠體外構建心肌樣組織. Wiley-南開(kāi)大學(xué)生物材料與生物系統聯(lián)合研討會(huì ) 暨1st Symposium on Healthcare and Biosystem. 201897日,天津. (邀請)

    39. 許海燕. 化學(xué)合成CXCR4拮抗多肽納米膠束的抗白血病功能研究. 納米科學(xué)技術(shù)分會(huì )第五屆年會(huì )暨2018’全國納米生物與醫學(xué)學(xué)術(shù)會(huì )議. 20181025-28, 鄭州. (分會(huì )場(chǎng)邀請報告)

    40. Haiyan Xu. Integration of super-paramagnetic scaffold and magnetic field to modulate immunological microenvironment and mesenchymal stem cells for enhancing bone tissue regeneration. 6th Japan-China Symposium on Nanomedicine. May 26-28, 2018. 日本島根大學(xué). (邀請)

    41. Jian Liu. The Gen Delivery and Immunotherapy Activities of Pullulan-Sperimine. 6th Japan-China Symposium on Nanomedicine. May 26-28, 2018. 日本島根大學(xué). (邀請)

    42. Haiyan Xu. Effects of Low Dose Exposure with a Small Library of Nanoparticles on the Adherens Junction of Vascular Endothelial Cells. Asian Conference on Nanoscience & Nanotechnology (Asia-NANO 2018). Oct 18-21, 2018. Qingdao (分會(huì )場(chǎng)邀請報告)

    43. Haiyan Xu. Characterizations for interactions between nanoparticles and biosystems in aqueous solutions. The 7th International Conference on Nanoscience & Technology (ChinaNANO 2017), 2017-8-28~31, Beijing. (Invited)

    44. 許海燕. 應用納米技術(shù)改善天然藥物功效的研究. 2017生物醫學(xué)工程大會(huì ), 2017-04-20~22, 北京 (邀請).

    45. 許海燕. Super-paramagnetic Scaffolds Modulate bone defects repair by enhancing osteogenesis and modulating Macrophages Function under Magnetic Fields. 中國微納米技術(shù)學(xué)會(huì )納米科學(xué)技術(shù)分會(huì )第四屆年會(huì )暨2016國際納米生物與醫學(xué)學(xué)術(shù)會(huì )議2016-12-7~10,福州 (邀請).

    46. Haiyan Xu. Super-paramagnetic Scaffolds Modulate the Function of Macrophages under the Static Magnetic Field. The 4th Japan-China Symposium on nanomedicine. Kitakyusyu city. 2016-05-13. (Invited)

    47. Haiyan Xu. Targeting CXCR4/CXCL12 axis to improve chemotherapeutics efficiency in acute myeloid leukemia treatments by synthesized peptide E5. 2nd International Conference on Nanomedicine of China (China Nanomedicine 2016). 2016-10-18~21, Wuhan. (Invited)

    48. Haiyan Xu. Regulatory Effects of Carbon Nanotubes on the Macrophage Phenotype and Implications to Anti-tumor Immune Therapies. The Second International Symposium on Immuno-biomaterials. Aug 29-31, 2015. Tianjin. (Invited)

    49. Haiyan Xu. Chemo-sensitization of acute myeloid leukemia using chemically synthesized novel peptide interfering CXCR4/CXCL12 axis. The 3rd China-Japan Symposium on Nanomedicine. June 18-20, 2015. Beijing. (Invited)

    50. Haiyan Xu. Regulatory Effects of Carbon Nanotubes on the Macrophage Phenotype and Implications to Anti-tumor Immune Therapies. ACS AMI Symposium. April 12-14, 2015. Beijing. (Invited)

    51. Haiyan Xu. A Peptide Antagonist Disrupting CXCR4/CXCL12 Interaction and Enhancing Chemotherapy Sensitivity of Leukemia Cells. Fourth U.S.-China Symposium on Nanomedicine. Washington DC. Oct. 15-17, 2014. (Invited)

    52. Haiyan Xu. A designed peptide disrupts CXCR4/CXCL12 cross-talking resulting in anti-acute myelocytic leukemia efficacy in vitro and in vivo. 中日韓A3癌癥納米醫學(xué)會(huì )議. 201491-5. 日本仙臺. (邀請).

    53. 許海燕. Paramagnetic Responsive Nanofibrous Scaffolds Synergizing with Static Magnetic Field Enhance Osteogenesis for Bone Repair: Concept Proof in vitro and in Vivo. The 2nd Japan-China Symposium on Nanomedicine. May 15-18, 2014. Hirushima. (Invited)

    54. 許海燕. 超順磁響應性支架構建與表征及促進(jìn)骨組織再生效應的研究. 2015第四屆全國生物與醫學(xué)納米技術(shù)暨博士生學(xué)術(shù)論壇. 蘇州. 2015711-13. (邀請).

    55. 許海燕. 超順磁響應性納米復合材料及其誘導骨缺損修復的研究.第二屆中國納米科學(xué)技術(shù)分會(huì )納米生物材料專(zhuān)業(yè)委員會(huì )年會(huì ). 20141118-20. 福州. (邀請).

    56. 許海燕. 靶向CXCR4新型多肽聯(lián)合化療藥對急性髓系白血病及乳腺癌的作用研究. 2014全國納米生物與醫學(xué)學(xué)術(shù)會(huì )議. 2014115-8. 成都. (邀請).

    57. Haiyan Xu. Revealing Silver Nanoparticles Toxicity Using Au Nanorod Core/Ag Shell Nanostructures in Vitro and in Vivo. The 7th International Conference on Materials for Advanced Technologies 2013 (ICMAT 2013). June 30-July 5, 2013. Singapore. (Invited)

    58. 許海燕. 碳納米管的抗腫瘤免疫佐劑效應研究. 北京生物醫學(xué)工程學(xué)會(huì )2012學(xué)術(shù)年會(huì ). 20121215. 北京. (邀請).

    59. 孟潔. 碳納米管生物醫學(xué)應用研究進(jìn)展. 《碳納米管復合導電劑》國家標準和相應國際標準研討會(huì ). 20121115-16. 常州. (邀請).

    60. Haiyan Xu. Multiwalled Carbon Nanotubes Activated Macrophages into Unique status: Neither M1 nor M2. 中美腫瘤納米技術(shù)和納米醫學(xué)前沿研討會(huì )(香山科學(xué)會(huì )議). 2012124-8. 北京. (邀請).

    61. Haiyan Xu. Silver Nanorods Disrupt Cell Membrane and Affect Kidney Function in Mice by Subcutaneous Administration. International Nanotoxicology 2012. Sept 5-7, 2012. Beijing. (Invited).

    62. 許海燕. 納米銀的細胞毒性及其對腎臟功能的影響. 《納米制成材料或納米技術(shù)相關(guān)企業(yè)和實(shí)驗室職業(yè)衛生防護指南》標準框架討論會(huì ). 2012925-30. 青島. 邀請報告.

    63. 許海燕. 納米佐劑及其對腫瘤免疫治療的意義. 2012全國生物與醫學(xué)納米技術(shù)博士生學(xué)術(shù)論壇. 2012710-11. 蘇州. (邀請).

    64. Haiyan XU. Interactions of carbon nanotubes to macrophages and implication to tumor microenvironment (Oral). International Conference on Nanoscience & Technology, China 2011 (China Nano 2011). Sept 7-9, 2011, Beijing. (Invited)

    65. Haiyan XU. Immunological Characterization and Application Potentials of Carbon Nanotubes in Anti-tumor Immune Therapy (Invited). The Second Joint U.S.-China Symposium on Cancer Nanotechnology and Nanomedicine. September 16-18, 2010 at the Loews Madison Hotel in Washington, DC. (Invited)

    66. Haiyan Xu. Nanostructured Composites for Bone or Vascular Tissue Engineering. 第八屆中韓生物材料與納米生物技術(shù)研討會(huì ). 20101215-19日于韓國平昌.Invited

    67. 許海燕. 納米材料在分子影像學(xué)方面的研究. 北京放射科學(xué)術(shù)交流大會(huì ). 201095日于北京.(分會(huì )場(chǎng)邀請報告)

    68. 許海燕. 碳納米管免疫學(xué)效應及在抗腫瘤免疫治療研究. 中國微納米技術(shù)學(xué)會(huì )納米科學(xué)技術(shù)分會(huì )第二屆年會(huì )暨2010全國納米生物與醫學(xué)學(xué)術(shù)會(huì )議2010114-7日,湖北武漢.(邀請)

    69. 許海燕. The Effects of Nanostructured Materials Pertaining to Biomedical Application. 第五屆海峽兩岸納米科學(xué)與技術(shù)研討會(huì ). 200612811日于香港科技大學(xué). (邀請)

    70. 許海燕,強伯勤?. 仿生細胞外基質(zhì)的構建及其對引導組織再生與修復的作用. 第二屆納米與生物交叉科學(xué)研討會(huì )(云頂會(huì )議). 200653-7日于廈門(mén). (特邀)

    71. Haiyan Xu. Characterization of oxidized water-soluble carbon nanotubes and their immunological properties. (Invited) The German-China Bi-lateral Forum on Frontier of Nanotechnology and Nano-standardization. Sept 4-8, 2009 Lanzhou, China. (Invited)

    72. Haiyan Xu. Immunological effects of multiwalled carbon nanotubes in mice. 第十一次中國生物物理學(xué)術(shù)大會(huì )暨第九屆全國會(huì )員代表大會(huì ). 2009712-16日于桂林. (邀請)

    73. Haiyan Xu. Regulatory effect of nanofibrous structure and surface chemistry on cells behaviors. 第七屆海峽兩岸納米科學(xué)與技術(shù)研討會(huì ). 2009726-81日于貴陽(yáng). (邀請)

    74. Haiyan Xu. Nanostructured biomaterials for implants and scaffolds (Invited). Regenerative Medicine Conference. May 2009, Beijing. Hosted by The New York Academy of Sciences and Chinese Academy of Medical Sciences. (Invited)

    75. Haiyan Xu. Nanofibrous structure-cell interaction and the implications on tissue engineering scaffolds. (Invited symposium). 1st Annual IEEE International Conference on Nano/Molecular Medicine & Engineering. Macau, Aug 6-9, 2007. (Invited)

    76. Haiyan Xu. Effect of nanofibrous scaffold of carbon nanotubes/polyurethane composite on fibroblast growth and biosynthesis. (Oral). China NANO 2007 (China International Conference on Nanoscience & Technology), June 4-7, 2007 in Beijing. (Invited)

    77. Haiyan Xu. Characterization and dispersion of MWNTs and its competitive adsorption to fibrinogen and albumin in aqueous (Poster). China NANO 2007 (China International Conference on Nanoscience & Technology), June 4-7, 2007 in Beijing. (Invited)

    78. 許海燕. 碳納米管對蛋白分子和細胞作用的研究. 第四屆海峽兩岸納米科學(xué)與技術(shù)研討會(huì ). 200582225日于麗江. (邀請)

    79. 許海燕. 納米結構物質(zhì)對血液和免疫系統作用的初步探索. 243次香山科學(xué)會(huì )議:納米尺度物質(zhì)的生物效應(納米安全性.20041130日~122日于北京. (邀請)

    80. Haiyan Xu. Biological responses to nanomaterials and their implications to medical care. 2004中美納米科技研討會(huì )(The first China-U.S. Symposium on nanoscale Science and Technology. May 17-19, 2004, Beijing, China. (Invited)


 

----口頭報告----

  1. 1. 孟潔. CXCR4 antagonist E5 Combat the Refractory Acute Myeloid Leukemia in Nanomicelle.  ChinaNanomedicine 2023 The 5th International Conference on Nanomedicine of China 2023114-6日,廣東省廣州市

    2. 許仕琳. CD123拮抗多肽納米膠束對難治性急性髓細胞白血病的治療作用研究,中國化學(xué)會(huì )第33屆學(xué)術(shù)年會(huì )2023617-20日,山東省青島市.

    3. 孟潔. Iron oxide nanoparticles cause endothelial cell ferroptosis dependent on surface coating and core chemistry2023中國生物醫學(xué)工程大會(huì )暨創(chuàng )新醫療峰會(huì )2023518-23日,分會(huì )場(chǎng)口頭報告,江蘇省蘇州市.

    4. 蒙藝靈. CXCR4拮抗多肽修飾的金納米棒靶向內質(zhì)網(wǎng)光熱免疫治療三陰性乳腺癌,2023中國生物醫學(xué)工程大會(huì )暨創(chuàng )新醫療峰會(huì )2023518-21日,江蘇省蘇州市

    5. 張美晨. 拮抗多肽與阿霉素共載納米膠束提高白血病治療功效和降低心肌毒性研究,博士論壇專(zhuān)場(chǎng)報告,中國毒理學(xué)會(huì )特種醫學(xué)毒理學(xué)專(zhuān)業(yè)委員會(huì )和納米毒理專(zhuān)業(yè)委員會(huì )聯(lián)合學(xué)術(shù)大會(huì )202356-8日,重慶.

    6. 王濤. 水溶性雄黃納米晶在髓系惡性疾病治療中的應用及機理研究,微納米技術(shù)與醫療健康創(chuàng )新大會(huì )(2022)暨中國微米納米技術(shù)學(xué)會(huì )第六屆微米納米技術(shù)應用創(chuàng )新大會(huì ) 2023422-24, 上海

    7. 孟潔. 氧化鐵納米顆粒引起內皮細胞鐵死亡及機理研究,中國毒理學(xué)會(huì )第十次全國毒理學(xué)大會(huì )202348-11日,分會(huì )場(chǎng)口頭報告,珠海.

    8. 胡雪純. 植入材料原位磁力操控促進(jìn)肌肉組織再生和缺損修復研究. 第三屆全國生物磁學(xué)與磁學(xué)納米材料學(xué)術(shù)會(huì )議暨第十二屆全國生物與醫學(xué)納米技術(shù)博士生學(xué)術(shù)論壇202342-4日,浙江慈溪

    9. 蒙藝靈. CXCR4拮抗多肽修飾的金納米棒靶向內質(zhì)網(wǎng)光熱免疫治療三陰性乳腺癌,2023第三屆全國生物磁學(xué)與磁性納米材料學(xué)術(shù)會(huì )議暨第十二屆全國生物與醫學(xué)納米技術(shù)博士生學(xué)術(shù)論壇202342-4日,浙江慈溪.

    10. 王濤. 雄黃納米晶在髓系白血病治療中的應用及機理研究. 2022生物物理大會(huì ),河南開(kāi)封(口頭報告)

    11. 胡雪純. Magnetic Nanofibrous Scaffolds Accelerate the Regeneration of Muscle Tissue in Combination with Extra Magnetic Fields. 全國生物制造工程學(xué)術(shù)年會(huì )暨生物制造國際研討會(huì ). 2022116. 北京

    12. 王濤. 中藥雄黃在白血病治療中的應用及機理研究. 中華醫學(xué)會(huì )第一次全國中西整合血液學(xué)學(xué)術(shù)會(huì )議. 202172-3. 昆明

    13. 孟潔. Synthetic CXCR4 antagonistic peptide assembling with nanoscaled micelles combat acute myeloid leukemia. 中國生物物理學(xué)會(huì )納米生物學(xué)會(huì )第七屆年會(huì ). 202163-7. 秦皇島

    14. 溫濤. 超小鉑納米顆粒包覆的金納米棒納米酶誘導髓系白血病細胞向巨核系分化. 2021年中國生物物理學(xué)會(huì )納米酶分會(huì )年會(huì )暨第一屆中國納米酶大會(huì ). 2021525-28. 長(cháng)春

    15. 王濤. 普魯士藍納米酶誘導紅系終末分化及其機理研究. 2021年中國生物物理學(xué)會(huì )納米酶分會(huì )年會(huì )暨第一屆中國納米酶大會(huì ). 2021525-28. 長(cháng)春

    16. 王濤. 人工合成中和多肽阻斷SARS-CoV-2感染宿主細胞. 微納米技術(shù)與醫療健康創(chuàng )新大會(huì )(2021)暨中國微米納米技術(shù)學(xué)會(huì )第五屆微米納米技術(shù)應用創(chuàng )新大會(huì ). 2021529-31. 上海

    17. 王濤. 普魯士藍納米酶誘導紅系終末分化及其機理研究. 第二屆全國生物磁學(xué)與磁性納米材料學(xué)術(shù)會(huì )議暨第九屆納米醫學(xué)全國博士生論壇. 20201212-14.

    18. 楊?lèi)?ài)云. 具有活性氧調控功能的鉑納米顆粒在誘導白血病細胞分化方面的作用研究. 第二屆全國生物磁學(xué)與磁性納米材料學(xué)術(shù)會(huì )議暨第九屆納米醫學(xué)全國博士生論壇. 20201212-14.

    19. 閆豆豆. 雙藥共載納米膠束的制備及其在難治性急性髓系白血病治療中的應用研究. 第二屆全國生物磁學(xué)與磁性納米材料學(xué)術(shù)會(huì )議暨第九屆納米醫學(xué)全國博士生論壇. 20201212-14.

    20. 王濤,賈夢(mèng)帆,韓冰,溫濤,王川,孟潔,劉健,許海燕. 雄黃納米膠束制劑誘導髓系白血病細胞分化新功效及其分子機理研究. 2019中國生物醫學(xué)工程大會(huì )暨創(chuàng )新醫療峰會(huì )(BME2019. 20191114-16日,濟南.

    21. 溫濤. Core-shell Au@Pt Nanostructures Induced Autophagy-mediated Megakaryocytes Differentiation in Leukemia K562 Cells. 第一屆亞洲藥劑學(xué)青年學(xué)者論壇. 2019920-22, 成都.

    22. 孟潔. 新型雄黃納米劑型的抗腫瘤作用及機理研究. 第十四屆全國醫藥衛生青年科技論壇. 20191023-25, 遵義.(優(yōu)秀獎)

    23. 賈夢(mèng)帆, 許海燕. 親水性雄黃納米制劑對CML細胞系分化和凋亡的誘導作用. 第七屆生物醫用磁學(xué)納米技術(shù)研討會(huì )暨第八屆全國生物與醫學(xué)納米技術(shù)博士生學(xué)術(shù)論壇. 2019-9-14~16,南京.

    24. Fengxin Wu, Xuegai Xu1, Aijun Gao2, Jian Liu1, Tao Wen1, Jie Meng1, Lianghua Xu*, Haiyan Xu*. Conductive 3D scaffolds composed of carbon fiber and coaxial electrospun nanofiber enhance the vascularization of cardiac-like tissue in vitro. Dalian. 中國生物材料大會(huì )暨國際先進(jìn)生物材料大會(huì ). Aug 24-26, 2019 (International Session Oral).

    25. 劉健. 針對腫瘤相關(guān)巨噬細胞的免疫調控治療. 2019中國生物材料大會(huì )暨國際先進(jìn)生物材料大會(huì ). 2019824-26, 大連.

    26. 劉健. 巨噬細胞極化狀態(tài)的調控及其在腫瘤免疫治療中的應用. 2019中國材料大會(huì ). 2019710-14, 成都.(分會(huì )場(chǎng)口頭報告)

    27. 孟潔. Iron oxide nanoparticles induce reversible endothelial-to-mesenchymal transition. 2019第四屆國際再生醫學(xué)材料大會(huì ). 2019612-16, 武漢.

    28. 溫濤. Core-shell Au@Pt nanostructures induced autophagy-mediated differentiation in leukemia K562 cells. 第四屆國際再生醫學(xué)材料大會(huì ). 2019612-16, 武漢.

    29. 溫濤. 不同磁性納米材料對血管內皮細胞連接的影響. 第二屆全國環(huán)境納米技術(shù)及生物效應學(xué)術(shù)研討會(huì ). 2018418-20, 合肥.

    30. 孟潔. 氧化鐵納米顆粒對血管內皮細胞功能的影響. 2019年中國生物物理學(xué)會(huì )納米生物學(xué)分會(huì ). 2019424-28, 保定.

    31. 孟潔. 納米佐劑調控T細胞活化作用研究. 第二屆全國環(huán)境納米技術(shù)及生物效應學(xué)術(shù)研討會(huì ). 2018418-20, 合肥.

    32. 劉健. uPAR靶向性SPIO在動(dòng)脈粥樣硬化斑塊檢測中的應用. 磁生物學(xué)和磁性材料學(xué)術(shù)會(huì )議. 201863-5, 蘇州.

    33. 孟潔. 超順磁性納米纖維支架促進(jìn)骨修復研究. 2018中國生物醫學(xué)工程學(xué)會(huì )天津青年論壇. 201883-5, 天津.

    34. 溫濤. Effects of Low Dose Exposure with a Small Library of Nanoparticles on the Adherens Junction of Vascular Endothelial Cells. 第十六次中國暨國際生物物理大會(huì ). 2018824-27, 成都.

    35. 溫濤. 貴金屬核殼納米顆粒對K562細胞的影響. 納米科學(xué)技術(shù)分會(huì )第五屆年會(huì )暨2018’全國納米生物與醫學(xué)學(xué)術(shù)會(huì )議. 20181025-28, 鄭州.

    36. 劉健. 精胺修飾普魯蘭多糖的抗腫瘤免疫治療作用. 納米科學(xué)技術(shù)分會(huì )第五屆年會(huì )暨2018’全國納米生物與醫學(xué)學(xué)術(shù)會(huì )議. 20181025-28, 鄭州.

    37. 孟潔. 雄黃固體分散劑在乳腺癌治療中的應用研究. 納米科學(xué)技術(shù)分會(huì )第五屆年會(huì )暨2018’全國納米生物與醫學(xué)學(xué)術(shù)會(huì )議. 20181025-28, 鄭州.

    38. 許海燕. Mechanomodulation of immune cells phenotype to enhance bone tissue regeneration by scaffolds upon magnetization. The 8th WACBE World Congress on Bioengineering. 2017-7-30~8-2, Hong Kong.

    39. 孟潔. Carbon nanotubes reverse immune suppression of BMDCs. The 8th WACBE World Congress on Bioengineering. 2017-7-30~8-2, Hong Kong.

    40. 吳鳳新,許海燕. Carbon fiber reinforced polyvinyl alcohol hydrogel for cardiac tissue regeneration. The 8th WACBE World Congress on Bioengineering. 2017-7-30~8-2, Hong Kong.

    41. 王濤, 許海燕. 親水性雄黃納米制劑對慢性髓系白血病細胞的作用研究. 第五屆生物醫用磁學(xué)納米技術(shù)研討會(huì )暨第六屆全國生物與醫學(xué)納米技術(shù)博士生論壇. 2017-5-20~22,蘇州.

    42. 楊?lèi)?ài)云, 許海燕. 不同磁性納米材料對血管內皮細胞氧化應激和內皮細胞連接的影響. 第五屆生物醫用磁學(xué)納米技術(shù)研討會(huì )暨第六屆全國生物與醫學(xué)納米技術(shù)博士生論壇. 2017-5-20~22,蘇州.

    43. 韓博, 許海燕. 欖香烯乳液對小鼠乳腺癌模型的影響. 第五屆生物醫用磁學(xué)納米技術(shù)研討會(huì )暨第六屆全國生物與醫學(xué)納米技術(shù)博士生論壇. 蘇州, 2017-5-20~22.

    44. 孟潔. Carbon nanotubes activate limulus amebocyte lystate coagulation. 中國微納米技術(shù)學(xué)會(huì )納米科學(xué)技術(shù)分會(huì )第四屆年會(huì )暨2016國際納米生物與醫學(xué)學(xué)術(shù)會(huì )議. 2016-12-7~10, 武漢.

    45. 孟潔. Synergistic promotion of interferon-γ mRNA expression in activated Jurkat T cell by carbon nanotubes. 2nd International Conference on Nanomedicine of China (ChinaNanomedicine 2016). 2016-10-18~21, 福州.

    46.  孟潔. Carbon Nanotube Activate Amebocyte Lysate. Tissue Engineering & Regenerative Medicine International Society-Asia Pacific Meeting (Termis-AP 2016). 2016-09-03~07, Taiwan.

    47.  許海燕. Enhancing bone regeneration using super-paramagnetic nanofibrous scaffolds under applied static magnetic fields. The Fall Meeting of MRS 20152015-12-02, Boston

    48. 許海燕. CXCR4/CXCL12軸的新型合成多肽提高AML化療效果的動(dòng)物實(shí)驗研究. 中華醫學(xué)會(huì )第十三次全國白血病?淋巴瘤學(xué)術(shù)會(huì )議. 哈爾濱. 2015717-20.

    49. 張靜. 陽(yáng)離子化明膠微球的制備及其在基因遞送中的應用研究. 2015第四屆全國生物與醫學(xué)納米技術(shù)暨博士生學(xué)術(shù)論壇. 蘇州. 2015711-13.

    50. 王晶. 新型光控釋納米核酸載體在基因治療中的應用. 2015第四屆全國生物與醫學(xué)納米技術(shù)暨博士生學(xué)術(shù)論壇. 蘇州. 2015711-13.

    51. 郭花. 新型靶向CXCR4多肽聯(lián)合化療藥治療急性髓系白血病小鼠模型的研究. 2015第四屆全國生物與醫學(xué)納米技術(shù)暨博士生學(xué)術(shù)論壇. 蘇州. 2015711-13.

    52. 孟潔. Carbon nanotubes activate macrophages into a unique status: recruiting na?ve macrophages and supporting angiogenesis. 2014全國納米生物與醫學(xué)學(xué)術(shù)會(huì )議. 2014115-8. 成都.

    53. 楊棽. Study of a synthetic peptide probe for apoptosis imaging. 2014全國納米生物與醫學(xué)學(xué)術(shù)會(huì )議. 2014115-8. 成都.

    54. 張靜. Preparation and in vitro gene silencing studies of cationized gelatin nanoparticles. 2014年中國藥物制劑大會(huì ). 2014919-22. 長(cháng)沙

    55. 李瀟瑾. CXCR4拮抗多肽在白血病治療中的應用研究. 中華醫學(xué)會(huì )第十三次全國血液學(xué)學(xué)術(shù)會(huì )議. 201496-8. 北京.

    56. 王川. 雄黃新劑型對K562細胞的作用研究. 第三屆全國納米生物與醫學(xué)博士生學(xué)術(shù)論壇. 2014825-28. 江蘇吳江.

    57. 劉會(huì )可. 血清蛋白對siRNA復合物顆粒尺寸及RNA干擾效率的影響. 第三屆全國納米生物與醫學(xué)博士生學(xué)術(shù)論壇. 2014825-28. 江蘇吳江.

    58. Haiyan Xu. Macrophage Activation Induced by Carbon Nanotubes: Implications to Tumor Immune Therapy (Oral). The 7th International Conference on Materials for Advanced Technologies 2013 (ICMAT 2013). June 30-July 5, 2013. Singapore.

    59. Jie Meng. Paramagnetic Responsive Nanofibrous Scaffolds Synergizing with Static Magnetic Field Enhance Osteogenesis for Bone Repair: Concept Proof in Vivo. The 7th International Conference on Materials for Advanced Technologies 2013 (ICMAT 2013). June 30-July 5, 2013. Singapore.

    60. 張衛奇等. 金納米棒-siRNA復合物抑制人乳腺癌MDA-MB-231細胞的遷移. 北京生物醫學(xué)工程學(xué)會(huì )2012學(xué)術(shù)年會(huì ). 20121215. 北京.

    61. 李瀟瑾. CXCR4拮抗多肽在白血病治療中的應用研究. 2012全國生物與醫學(xué)納米技術(shù)博士生學(xué)術(shù)論壇. 2012710 -11. 蘇州.  

    62. 張衛奇. 金納米棒-siRNA復合物抑制人乳腺癌MDA-MB-231細胞的遷移. 2012全國生物與醫學(xué)納米技術(shù)博士生學(xué)術(shù)論壇. 2012710 -11. 蘇州.

    63. Jie Meng. A novel paramagnetic nanofibrous composite films as a potential bone substitute. The 3rd Aisan Biomaterials Congress. Sept 15-17, 2011. Busan, Korea.

    64. Jian Liu. Biological Effects of PAR-1 siRNA Complexed with Cationized pullulan on Breast Cancer Cells. The 3rd Aisan Biomaterials Congress. Sept 15-17, 2011. Busan, Korea.

    65. Haiyan Xu. implication to tumor microenvironment. International Conference on Nanoscience & Technology, China 2011 (ChinaNano 2011). Sept 7-9, 2011. Beijing, China.

    66. 孟潔. 分子靶標納米氧化鐵顆粒胰腺癌細胞的磁共振成像(口頭報告),2010年中華醫學(xué)會(huì )全國第四屆分子影像學(xué)學(xué)術(shù)會(huì )議20109月,湖南長(cháng)沙

    67. Jie Meng Man Yang, Fumin Jia, Hua Kong, Chaoying Wang, Rui Wang, Jianmin Xing, Sishen Xie, Chen Wang, and Haiyan Xu. Carbon nanotubes stimulate the immune response to inhibit tumor growth in mice. (Oral) International Conference on Nanoscience & Technology, Chinanano 2009. Sept 2-4, 2009

    68. Zhaozhao Han, Hua Kong, Jie Meng, Xiaojin Qi, Chaoying Wang, Sishen Xie, and Haiyan Xu. Regulatory effect of nanofibrous structure and carbon nanotubes on the growth and anticoagulant function of vascular endothelium cells. (Oral) International Conference on Nanoscience & Technology, Chinanano 2009. Sept 2-4, 2009

    69. Jie Meng, M Yang, H Kong, C Y Wang, R Wang, C Wang, S S Xie, H Y Xu?. Preparation, Characterization and Cellular Biological Impact of Water Soluble Multiwalled Carbon Nanotubes (Oral) 7屆亞洲泛太平洋醫學(xué)和生物醫學(xué)工程學(xué)術(shù)會(huì )議APMBE 2008. 20084月于北京

    70. Zhaozhao Han, Hua Kong, Jie Meng, Chaoying Wang, Sishen Xie, 3Haiyan Xu1?. Electrospun aligned nanofibrous scaffold of Polyurethane for endothelial cells growth. (Oral) 7屆亞洲泛太平洋醫學(xué)和生物醫學(xué)工程學(xué)術(shù)會(huì )議APMBE 2008. 20084月于北京

    71. Jie Meng, Man Yang, Chaoying Wang, Hua Kong, Rui Wang, Chen Wang, Sishen Xie, Haiyan Xu?. Water-soluble functionalized MWNTs and their interactions to some proteins and cells. (Oral). 1st Annual IEEE International Conference on Nano/Molecular Medicine & Engineering. Macau, Aug 6-9, 2007

    72. Jie MengLi SongJie MengHua Kong, Guangjin Zhu, Lianghua Xu, Sishen Xie, Haiyan Xu?. Using Single-walled carbon nanotubes nonwoven films as scaffolds to en long-term cell proliferation in vitro(分會(huì )報告). The 5th International Congress of Pathophysiology第五屆國際病理生理學(xué)大會(huì )). 2006628日~71日于北京.

    73. Jie Meng1, Li Song, Hua Kong, Haiyan Xu?, Xiaotian Guo, Chaoying Wang and Sishen Xie. Comparison of Adsorption Behaviors for Fibrinogen and Albumin on Single Walled Carbon nanotubes Nonwoven. (Oral). International Conference on Nanoscience & Technology, ChinaNANO 2005, June 9-11, 2005 in Beijing.


 

----壁報交流----

  1. 1. 胡雪純. 化學(xué)組成和微觀(guān)結構對磁性復合支架誘導成骨作用的影響. 2023中國生物材料大會(huì )20231012-15日,重慶

    2. 孟潔. CD123 Antagonistic Peptides Assembled with Nanomicelles Act as Monotherapeutics to Combat Refractory Acute Myeloid Leukemia. The 17th Chinese International Peptide Symposium2023614-16日,天津

    3. 溫濤*,楊?lèi)?ài)云,孟潔,劉健,王建華,許海燕*. 沉積超小Pt納米顆粒的Au納米棒(Au@Pt)在小鼠體內的分布和毒理學(xué)效應. 中國毒理學(xué)會(huì )第十次全國毒理學(xué)大會(huì )202348-11日,廣東省珠海市

    4. 胡雪純. Magnetic Nanofibrous Scaffolds Accelerate the Regeneration of Muscle Tissue in Combination with Extra Magnetic Fields. 全國生物制造工程學(xué)術(shù)年會(huì )暨生物制造國際研討會(huì )2023318-19日,北京

    5. 張美晨,CXCR4拮抗多肽和阿霉素共載膠束提高難治性急性髓系白血病療效并降低心臟毒性. 中華醫學(xué)會(huì )第十七次全國血液學(xué)學(xué)術(shù)會(huì )議2022923-25日,上海國家會(huì )展中心(壁報交流)

    6. 張雪,孟潔,許海燕. 氧化鐵納米顆粒引起肝血竇內皮細胞損傷及其機制研究.中國生物物理學(xué)會(huì )納米生物學(xué)會(huì )第七屆年會(huì ). 202163-7. 秦皇島(快閃報告)

    7. 王濤. 普魯士藍納米酶通過(guò)調控細胞內ROS誘導紅系終末分化. 微納米技術(shù)與醫療健康創(chuàng )新大會(huì )(2021)暨中國微米納米技術(shù)學(xué)會(huì )第五屆微米納米技術(shù)應用創(chuàng )新大會(huì ). 2021528-31. 上海

    8. 許仕琳,張美晨,閆豆豆,劉健,孟潔,溫濤,楊延蓮,邢海燕,王建祥,王琛*,許海燕*. CD123拮抗多肽在急性髓系白血病治療中的應用研究. 第二屆全國生物磁學(xué)與磁性納米材料學(xué)術(shù)會(huì )議暨第九屆納米醫學(xué)全國博士生論壇. 20201212-14. 南京

    9. 張雪,許仕琳,王田,溫濤,劉健,孟潔*,張宇*,許海燕*. 氧化鐵納米顆粒引起內皮細胞膜通透性改變及其機制. 第二屆全國生物磁學(xué)與磁性納米材料學(xué)術(shù)會(huì )議暨第九屆納米醫學(xué)全國博士生論壇. 20201212-14. 南京

    10. 王田, 王濤, 溫濤, 孟潔, 劉健*, 許海燕*. 精胺-普魯蘭介導 siRNA 沉默白血病細胞 Notch1 信號通路的研究. 第二屆全國生物磁學(xué)與磁性納米材料學(xué)術(shù)會(huì )議暨第九屆納米醫學(xué)全國博士生論壇. 20201212-14. 南京

    11. 張美晨,王濤,董海姣,溫濤,孟潔,劉健,張宇*,許海燕*. 普魯士藍納米顆粒誘導急性髓系白血病細胞分化研究. 第二屆全國生物磁學(xué)與磁性納米材料學(xué)術(shù)會(huì )議暨第九屆納米醫學(xué)全國博士生論壇. 20201212-14. 南京

    12. 葛洋洋,許仕琳,邢海燕,方小翠,閆豆豆,孟潔,楊延蓮,魏輝,王建祥,王琛*,許海燕*. CXCR4拮抗多肽與化療藥共載膠束對急性髓系白血病的治療作用研究. 中華醫學(xué)會(huì )第16次血液學(xué)學(xué)術(shù)會(huì )議. 2020924-26日杭州(線(xiàn)上+線(xiàn)下). (墻報展示)

    13. 閆豆豆,魏輝,賴(lài)馨寧,葛洋洋,許仕琳,孟潔,溫濤,劉健,張衛奇,王建祥*,許海燕*. 共遞送高三尖杉酯堿和阿霉素納米膠束的制備及其對難治性急性髓系白血病的治療作用研究. 中華醫學(xué)會(huì )第16次血液學(xué)學(xué)術(shù)會(huì )議. 2020924-26日杭州(線(xiàn)上+線(xiàn)下). (墻報展示)

    14. 王濤,孟潔,許海燕*. Therapeutic effects and mechanisms of Realgar Nano-formulation in cancer treatment. 2019僑界精英創(chuàng )新創(chuàng )業(yè)(中國·杭州)峰會(huì )暨國際創(chuàng )新藥物會(huì )議.20191031-111日,杭州.

    15. 溫濤, 許海燕*. 金納米顆粒組裝體對動(dòng)脈粥樣硬化易損斑塊的靶向光聲成像研究. 第十四屆全國醫藥衛生青年科技論壇. 20191023-25, 遵義.

    16. 王濤, 許海燕. Inhibition of murine breast cancer metastases by hydrophilic As4S4 nanoparticles is associated with decreased ROS. 第一屆亞洲藥劑學(xué)青年學(xué)者論壇. 2019920-22, 成都.

    17. 許仕琳,許海燕靶向CD123的人工合成多肽在急性髓系白血病中的應用研究博士生論壇. 第七屆生物醫用磁學(xué)納米技術(shù)研討會(huì )暨第八屆全國生物與醫學(xué)納米技術(shù)博士生學(xué)術(shù)論壇. 2019914-16, 南京.

    18. 楊?lèi)?ài)云,許海燕. 雙金屬Au@Pt納米顆粒在人白血病細胞分化和凋亡誘導中的應用. 第七屆生物醫用磁學(xué)納米技術(shù)研討會(huì )暨第八屆全國生物與醫學(xué)納米技術(shù)博士生學(xué)術(shù)論壇. 2019914-16, 南京.(海報二等獎)

    19. 葛洋洋,許海燕. CXCR4拮抗多肽E5AML1-ETO白血病小鼠治療研究. 第七屆生物醫用磁學(xué)納米技術(shù)研討會(huì )暨第八屆全國生物與醫學(xué)納米技術(shù)博士生學(xué)術(shù)論壇. 2019914-16, 南京. (海報三等獎)

    20. 韓博, 許海燕. Therapeutic effects and underlying mechanisms of liposome formulation of elemene on mouse breast cancer. 17次中國暨國際生物物理大會(huì ). 201982-5, 天津.

    21. 閆豆豆,許海燕. Fabrication and evaluation of drug co-delivery micellar formulation for the treatment of acute myeloid leukemia. 第八屆國際納米科學(xué)和技術(shù)會(huì )議. 2019817-19日,北京.

    22. Doudou Yan, Yangyang Ge, Jie Meng, Tao Wen, Jian Liu, Haiyan Xu*. Fabrication and evaluation of drug co-delivery micellar formulation for the treatment of acute myeloid leukemia. AACR New Horizon 2019 May 3-5, Shenzhen, China

    23. Yangyang Ge#, Jie Meng#, Haiyan Xing#, Hui Wei, Shilin Xu, Jian Liu, Chen Wang*, Min Wang, Jianxiang Wang*, Haiyan Xu*. Antitumor activity of CXCR4 peptide antagonist E5 on AML1-ETO mouse model. AACR New Horizon 2019 May 3-5, Shenzhen, China

    24. 許仕琳,許海燕. A novel synthetic peptide targeting CD123 in acute myeloid leukemia. The 7th China-Japan Symposium Nano-medicine(第七屆中日納米醫學(xué)研討會(huì )). 2019524-26, 西安.

    25. 楊?lèi)?ài)云, 許海燕. Bimetallic Au@Pt nanoparticle’s application for differentiation and apoptosis induction in human leukemia cell. The 7th China-Japan Symposium Nano-medicine(第七屆中日納米醫學(xué)研討會(huì )). 2019524-26, 西安.

    26. Tao Wang, Haiyan Xu. Hydrophilic As4S4 nanoparticles inhibit K562 cell activity through ROS modulation and autophagy induction. 美國癌癥協(xié)會(huì )第109次年會(huì )(AACR2018April 14-18, 2018.

    27. 劉健. Magnetic modulation of immunological microenvironment inside scaffolds to enhance bone tissue regeneration. 第五屆國際組織工程及再生醫學(xué)學(xué)會(huì )世界大會(huì )(TERMIS. 201894-7日,日本京都.

    28. 楊?lèi)?ài)云,許海燕. 納米顆粒介導ROS對血管內皮細胞作用的比較研究. 納米科學(xué)技術(shù)分會(huì )第五屆年會(huì )暨2018全國納米生物與醫學(xué)學(xué)術(shù)會(huì )議. 20181025-28, 鄭州.

    29. 閆豆豆,許海燕. 雙藥共遞送膠束構建及其在急性髓系白血病治療中的應用研究. 第七屆全國生物與醫學(xué)納米技術(shù)博士生論壇. 2018628-30日,西安.

    30. 許仕琳,許海燕. 靶向AML耐藥相關(guān)蛋白CD123的多肽功效研究. 第七屆全國生物與醫學(xué)納米技術(shù)博士生論壇. 2018628-30日,西安.

    31. 葛洋洋,許海燕. Targeting the interaction between CXCR4/SDF-1α by a peptide nano-therapeutics to overcome chemo-resistance in breast tumor. 6th Japan-China Symposium on Nanomedicine. May 26-28, 2018. 日本島根大學(xué).

    32. 謝麗菲,許海燕. Spermine-modified pullulan modulates macrophages polarize towards to M1 phenotype in tumor microenvironment. 6th Japan-China Symposium on Nanomedicine. May 26-28, 2018. 日本島根大學(xué).

    33. 溫濤, 許海燕. Effects of Different Magnetic Nanoparticles on the Connectivity of Vascular Endothelial Cells. The 7th International Conference on Nanoscience & Technology (ChinaNANO 2017) . 2017-8-28~31, Beijing.

    34. 孟潔, 許海燕. CXCR4拮抗多肽在造血干細胞動(dòng)員方面的研究. 第十四次全國白血病.淋巴瘤學(xué)術(shù)會(huì )議. 2017-7-13~15, 哈爾濱.

    35. 王濤, 許海燕. 親水性雄黃納米制劑的制備及其對髓系白血病的治療功效. 第十四次全國白血病.淋巴瘤學(xué)術(shù)會(huì )議. 2017-7-13~15, 哈爾濱.

    36. 孟潔, 許海燕. 水分散碳納米管引起鱟試劑假陽(yáng)性結果.2017生物醫學(xué)工程大會(huì ). 2017-04-20~22, 北京.ü

    37. 溫濤, 許海燕. 分子氧介導的光激發(fā)金納米棒活化過(guò)氧化氫. 2017生物醫學(xué)工程大會(huì ). 2017-04-20~22, 北京.

    38. 王川, 許海燕. 雄黃新劑型制備及其抗急性髓系白血病功效研究. 2017生物醫學(xué)工程大會(huì ). 2017-04-20~22, Beijing.

    39. 張靜,許海燕. 陽(yáng)離子化明膠微球介導的CXCR4siRNA在乳腺癌細胞中的RNA干擾研究. 2017生物醫學(xué)工程大會(huì ).2017-04-20~22, 北京.

    40. 葛洋洋, 許海燕. CXCR4拮抗多肽E5逆轉乳腺癌細胞耐藥的作用研究. 2017生物醫學(xué)工程大會(huì ). 2017-04-20~22, 北京.ü

    41. 郝綏綏,許海燕. 超順磁性復合材料協(xié)同磁場(chǎng)對巨噬細胞功能的作用研究. 2017生物醫學(xué)工程大會(huì ). 2017-04-20~22, 北京.ü

    42. 代亞麗, 許海燕. 碳納米管逆轉樹(shù)突狀細胞的免疫抑制作用初探. 2017生物醫學(xué)工程大會(huì ). 2017-04-20~22, 北京. ü

    43. 吳鳳新, 許海燕. 碳纖維復合水凝膠制備及在心肌缺損研究中的應用. 2017生物醫學(xué)工程大會(huì ).2017-04-20~22, Beijing.ü

    44. 楊?lèi)?ài)云, 許海燕. 不同材料對心血管內皮細胞氧化應激和內皮細胞連接的影響. 2017生物醫學(xué)工程大會(huì ). 2017-04-20~22, 北京.ü

    45. 韓博, 許海燕. 欖香烯注射液與E5聯(lián)合用藥對小鼠乳腺癌模型的影響. 2017生物醫學(xué)工程大會(huì ). 2017-04-20~22, Beijing.

    46. 王濤, 許海燕. 親水性雄黃納米制劑對慢性髓系白血病細胞的作用研究. 2017生物醫學(xué)工程大會(huì ). 2017-04-20~22, Beijing

    47. 孟潔, 許海燕. Carbon Nanotubes Activate Macrophages into a M1/M2 Mixed Status: Recruiting Naiv? e Macrophages and Supporting Angiogenesis. 2016世界生命科學(xué)大會(huì ). 2016-11-1~3, Beijing.

    48. 聶欣, 許海燕. Carbon Nanotubes Activate Limulus Amebocyte Lysate Coagulation. 2016世界生命科學(xué)大會(huì ). 2016-11-1~3, Beijing.

    49. 王川, 許海燕. Fabrication of polymer-encapsulated As4S4 to increase chemotherapeutic efficacy in AML mice.2016世界生命科學(xué)大會(huì ). 2016-11-1~3, Beijing.ü

    50.  張靜, 許海燕. Preparation and in vitro gene silencing studies of cationized gelatin nanoparticles. 2016世界生命科學(xué)大會(huì )2016-11-1~3, Beijing.

    51. 葛洋洋, 許海燕. Targeting the interaction between CXCR4/SDF-1α by a peptide nanotherapeutics to inhibit breast tumour progression. 2nd International Conference on Nanomedicine of China (ChinaNanomedicine 2016). 2016-10-18~21, 武漢.

    52. 王濤, 許海燕. As4S4 nanoparticles encapsulated by amphiphilic polymer induce erythroid differentiation and cell cycle arrest in K562 cells. 2nd International Conference on Nanomedicine of China (ChinaNanomedicine 2016). 2016-10-18~21, 武漢.

    53. 代亞麗, 孟潔, 許海燕. 碳納米管直接激活鱟試劑. 2nd International Conference on Nanomedicine of China (ChinaNanomedicine 2016). 2016-10-18~21. 武漢.

    54. 郝綏綏, 許海燕. Super-paramagnetic scaffolds modulate the function of macrophages under the static magnetic field. Tissue Engineering & Regenerative Medicine International Society- Asia Pacific Meeting (Termis-AP 2016). 2016-09-03~07, Taiwan.

    55. 吳鳳新, 許海燕. 碳纖維復合水凝膠制備及與心肌細胞相容性初探. 2016年國際華人納米醫學(xué)研討會(huì )暨第五屆全國生物與醫學(xué)納米技術(shù)博士生學(xué)士論壇. 2016.6.16-18, 蘇州.

    56. Jie Meng. Surface Modification of Carbon Nanotubes Modulate Immune Response with Potential Application in Tumor Immunotherapy. The 3rd China-Japan Symposium on Nanomedicine. June 18-20, 2015. Beijing.

    57. Chen Yang. Study of a synthetic peptide probe for apoptosis imaging. American Association for Cancer Research (AACR) Annual Meeting 2015. Philadelphia. April 18-22, 2015.

    58. Jie Meng. Surface Modification of Carbon Nanotubes Modulate Immune Response with Potential application in Tumor Immunotherapy. The 6th International Conference on Nanoscience and Technology ChinaNANO2015. Beijing. Sept 3-5, 2015.

    59. Huike Liu. The influence of serum protein to particle size of siRNA complex and the efficiency of RNAi. The 6th International Conference on Nanoscience and Technology ChinaNANO2015. Beijing. Sept 3-5, 2015.

    60. Chuan Wang. Improving the bioavailability and anti-CMLchemotherapeutic efficiency of realgar using Co-Extrusiong. The 6th International Conference on Nanoscience and Technology ChinaNANO2015. Beijing. Sept 3-5, 2015.

    61. Jing Zhang. Preparation of cationized gelatin nanoparticles and in vitro gene delivery study. The 6th International Conference on Nanoscience and Technology ChinaNANO2015. Beijing. Sept 3-5, 2015.

    62. 馬強,許海燕. 利用固體分散技術(shù)提高雄黃生物利用度及其抗白血病功效的研究. 中華醫學(xué)會(huì )第十三次全國白血病?淋巴瘤術(shù)議. 哈爾濱. 2015717 -20.

    63. 郝綏綏,許海燕. 磁響應性支架協(xié)同靜態(tài)弱磁場(chǎng)促進(jìn)骨再生的研究. 2015第四屆全國生物與醫學(xué)納米技術(shù)暨博士生學(xué)術(shù)論壇. 蘇州. 2015711-13.

    64. Jie Meng. Enhancing Bone Regeneration Using Super-paramagnetic Responsive Nanofibrous Scaffolds under Magnetic Field. 2015國際再生醫學(xué)材料大會(huì ). 武漢. 201564-8.

    65. 郝綏綏,許海燕. 超順磁性復合材料制備及細胞相容性研究. 2014全國納米生物與醫學(xué)學(xué)術(shù)會(huì )議. 2014115-8. 成都.

    66. 郭花,許海燕. 靶向CXCR4的新型多肽抑制乳腺癌腫瘤細胞遷移和提高腫瘤細胞對化療藥敏感性研究. 2014全國納米生物與醫學(xué)學(xué)術(shù)會(huì )議. 2014115-8. 成都.

    67. 馬強,許海燕. 雄黃新劑型對白血病細胞系K562HL-60的作用研究. 2014全國納米生物與醫學(xué)學(xué)術(shù)會(huì )議. 2014115-8. 成都.

    68. 郭花,許海燕. 新型CXCR4拮抗多肽聯(lián)合化療藥治療白血病的研究. 中華醫學(xué)會(huì )第十三次全國血液學(xué)學(xué)術(shù)會(huì )議. 北京. 201496-8.

    69. Xiaojin Li. A novel designed small peptide disrupts interaction of CXCR4/CXCL12 and enhances chemotherapy sensitivity of leukemia cells in stromal microenvironment. American Association for Cancer Research (AACR) Annual Meeting 2014. San Diego. April 4-9, 2014.

    70. 孟潔. 碳納米管-聚氨酯復合材料生物相容性研究. 北京生物醫學(xué)工程學(xué)會(huì )2012學(xué)術(shù)年會(huì ). 20121215. 北京.

    71. 李瀟瑾,許海燕. CXCR4拮抗多肽在白血病治療中的應用研究. 北京生物醫學(xué)工程學(xué)會(huì )2012學(xué)術(shù)年會(huì ). 20121215. 北京.

    72. Xuelian Cheng. Size and surface chemistry Effects of multiwalled carbon nanotubes on blood coagulation. Nanotoxicology 2012. Sept 5-7, 2012. Beijing.

    73. Weiqi Zhang. TEM observation of Gold nanorods entering into lysosome maturation in human breast cancer cells. Nanotoxicology 2012. Sept 5-7, 2012. Beijing.

    74. 李瀟瑾,許海燕. CXCR4拮抗多肽對白血病細胞HL60作用研究. 2012年中華醫學(xué)會(huì )全國血液學(xué)年會(huì ). 20129. 蘇州.

    75. Jie Meng, Haiyan Xu. Interaction of carbon nanotubes with macrophages in tumor microenvironment. 103rd Annual Meeting of the American Association for Cancer Research (AACR2012), Chicago. April 1-5, 2012.

    76. 孟潔,楊曼,加福民,許振,孔樺,許海燕. 皮下注射碳納米管90天內小鼠重要臟器病理學(xué)改變研究(墻報). 中國微納米技術(shù)學(xué)會(huì )納米科學(xué)技術(shù)分會(huì )第二屆年會(huì )暨2010’全國納米生物與醫學(xué)學(xué)術(shù)會(huì )議. 2010114-7日,湖北武漢

    77. 齊小謹,孟潔,張宇,許振,孔樺,顧寧,許海燕. 磁性納米纖維復合材料的制備及對成骨過(guò)程的作用研究(墻報)。中國微納米技術(shù)學(xué)會(huì )納米科學(xué)技術(shù)分會(huì )第二屆年會(huì )暨2010’全國納米生物與醫學(xué)學(xué)術(shù)會(huì )議. 2010114-7日,湖北武漢

    78. 楊曼,孟潔,許振,孔樺,許海燕. 水分散性多壁碳納米管對補體系統作用的研究(墻報)。中國微納米技術(shù)學(xué)會(huì )納米科學(xué)技術(shù)分會(huì )第二屆年會(huì )暨2010’全國納米生物與醫學(xué)學(xué)術(shù)會(huì )議. 2010114-7日,湖北武漢

    79. 程雪蓮, 孟潔, 鐘俊, 加福民, 楊曼, 孔樺, 許海燕. 水中分散多壁碳納米管的理化表征與分析(墻報)。中國微納米技術(shù)學(xué)會(huì )納米科學(xué)技術(shù)分會(huì )第二屆年會(huì )暨2010’全國納米生物與醫學(xué)學(xué)術(shù)會(huì )議. 20101147日,湖北武漢

    80. 張衛奇, 孟潔,紀英路,李瀟瑾,楊曼,孔樺,吳曉春,許海燕. 金納米棒-siRNA復合物沉默乳腺癌細胞PAR-1表達的研究(墻報)。中國微納米技術(shù)學(xué)會(huì )納米科學(xué)技術(shù)分會(huì )第二屆年會(huì )暨2010’全國納米生物與醫學(xué)學(xué)術(shù)會(huì )議. 20101147日,湖北武漢

    81. Haiyan Xu. Safety and standardization of biomedical nanomaterials in China. (Invited) NCI (US) and China Workshop on Cancer Nanotechnology and Nanomedicine. Nov 11, 2009 Beijing

    82. Zaozhao Han, Hua Kong, Jie meng, Chaoying Wang, Sishen Xie, Haiyan Xu?. Electrospinning of aligned Carbon nanotubes-Polyurethane composite scaffold for endothelial cells growth. (Poster). ChinaNANO 2007 (China International Conference on Nanoscience & Technology), June 4-7, 2007 in Beijing.

    83. Jie Meng, Jie Meng, Li Song, Hua Kong, Zhaohui He, Sishen Xie, Haiyan Xu?. Characterization of multi walled carbon nanotubes in aqueous and Biological impact on cells living behavior(墻報). 5th International Congress of Pathophysiology第五屆國際病理生理學(xué)大會(huì )). 2006628日~71日于北京.

    84. Zhaohui He, Xiaotian Guo, Jie, Meng, Hua Kong, Haiyan Xu?. Preparation of gentamicin-loaded PLA nanopaticles and release investigation in vitro(墻報). 5th International Congress of Pathophysiology第五屆國際病理生理學(xué)大會(huì )). 2006628日~71日于北京.

    85. 孔樺, 孟潔, 郭小天, 楊子彬, 許海燕?. 載藥納米羥基磷灰石材料的體外藥物緩釋研究.中國科協(xié)2005年學(xué)術(shù)年會(huì )第28分會(huì )場(chǎng):人工器官與組織替代. 200581823日于烏魯木齊.