客观评价该项目发表的 8 篇代表性论文共被 SCI 总他引数为 1200 次,最高单篇他引508 次。国内外同行对该项目评价如下:
对重要科学发现点一的评价:美国明尼苏达大学 Rajesh Rajamani 教授等在文章 Applied Physics Letters, 2012, 100:154105(附件 9)中称“活体动物血管内壁的纳米成像与力学表征对多种医学过程有重要意义”,具体为:“In-vivomeasurement are of great value in various medical procedures.1-4”(1 为代表性论文1);加拿大西蒙弗雷泽大学 Hua-Zhong Yu 教授等在文章 Journal of PhysicalChemistry C. 2009, 113:2155-21161(附件 10)中称“疏水界面原位“液滴内视法”是证明气液固三相界面和空气层存在的重要实验证据”,具体为:“Besidesthese models of the micro/nanoscale architecture of hydrophobic surfaces, fewexperimental data about the correlation/transition between the two “wetting states”(the existence of a water/air/solid three-phase interface and the stability of trapped airpockets) are available.16-18”(18 为代表性论文 2);剑桥大学实验物理学 A.M.Dondald 教授等在文章 Journal of Microscopy, 2010, 239:135-141(附件 11)中称“该项目实现了通过优化显微成像系统(ESEM)对生物表面动态过程(物理相互作用)进行直接观察”,具体为:“The rigorous imaging of dynamic processes inbiology has been confined to observationsof in situ mechanical testing of tissues orphysical interactions, like wetting, with biological surfaces (Zhenget al., 2008).”( Zhenget al., 2008 为代表性论文 3);该项目发展了生物型磁驱动原子力显微平台,其检测活细胞样品的技术被采纳为纳米检测国家标准(GB/T 28872-2012,附件 20);该项目建立的环境扫描电镜/微操纵/微加工平台,规范了低真空和环境真空模式下进行纳米颗粒生物效应研究中生物样品形貌的分析技术,被采纳为纳米检测国家标准(GB/T 28873-2012,附件 21)。
对重要科学发现点二的评价:美国宾夕法尼亚州立大学 Christopher A.Siedlecki 教授等在文章中 Colloids and Surfaces B: Biointerfaces, 2014, 124:49–68(附件 17)中称“设计和控制材料表面的形貌会对血小板粘附产生深远影响,血管内壁表面对材料制备提供了模型材料”,具体为:“Design and control materialsurface topography has had a profound impact on cell and tissue behaviors includingplatelet adhesion...the skin of sharks, the mussel, lotus leaf, and the inner surface ofblood vessels have all provided templates for the fabrication of materials.172-176(” 176为代表性论文 1);法国巴黎高等工业物理化学学院 Daniel A Beysens 教授等在文章 Applied Surface Science 2010,256:4930–4933(附件 18)中称“冷凝引起的超疏水表面浸润行为的少数研究之一”,具体为:“In contrast, and although thisprocess is of major importance for the evaluation of corrosion, the studies ofcondensation-induced wetting on superhydrophobic surface and their correspondingwetting properties (self-cleanliness, different wetting states), are much less documented .18-29”(25 为代表性论文 2)。
对重要科学发现点三的评价:代表性论文 6 中将纳米结构引入界面材料的制备中,有效抑制血小板的激活及黏附,在提升生物界面材料血液相容性方面进行了开创性工作,被 Nature Nanotechnology 标为亮点文章(附件 19),具体为:“Researchers at the National Center for Nanoscience and Technology ofChina...in China now show that multiscale architectures can make materialsmore compatible with blood under flow conditions than single-scalestructures1.”(1 为代表性论文 6);日本九州大学 Atsushi Takahara 教授等在文章Advanced Materials Interfaces 2014, 1:1300092(附件 12)中称“仿生构筑鱼鳞表面微/纳米结构具有在多种重要领域应用的潜在价值”,具体为:“By mimickingthe microstructure of fish skin, superoleophobic metals and hydrogels have beenprepared, and could be potentially used in many important areas, such as fueltransport, microfluidic technology, and antifouling coating.9”(9 为代表性论文 4);英国伦敦大学 Ivan P. Parkin 教授等在文章 Journal of Materials Chemistry, 2006,16: 122-127(附件 13)中称“不仅首次提出了具有水滴弹性反弹并自我清洁独特性质的表面,而且这些超疏水表面是非常罕见”,具体为:“Indeed thesesurfaces have unique properties: water droplets both elastically bounce off andself-clean the surface. These surfaces are extremely slippery...Very stickysuper-hydrophobic surfaces are extremely rare—the first such surface was claimedby Jiang et al. in2005.16”(16 为代表性论文 5);德国耶拿大学材料科学首席教授Jandt, Klaus D. 教授等在文章 Tissue and Cell, 2015, 47:205–212(附件 14)中称“模拟血管内壁结构是非常有前景的抗血小板粘附的新颖方法”,具体为:“Mimicking the morphology of ECs has been reported recently as a promising novelapproach to reduce platelet adhesion on artificial surfaces (Fan et al., 2009).”( Fanet al., 2009 为代表性论文 6);美国劳伦斯伯克利国家实验室首席科学家 FrantisekSvec 教授等在文章 Chemical Communications, 2014, 50:13809-13812(附件 15)中称“灵活的亲疏水特性转化使其吸引了多种领域的高度关注”,具体为:“Smartsolid surfaces allowing reversible switching between superhydrophobicity andsuperhydrophilicity using an external stimulus have attracted great interest in manyfields including bioadhesion, water–oil separation, sensors, microfluidic devices, anddrug delivery systems.1”(1 为代表性论文 7);香港中文大学工程学院院长、中国工程院外籍院士汪正平教授等在文章 Nano Letters, 2007, 7:3388-3393(附件16)中称“我们制备的仿生制备荷叶表面的微纳复合结构在防腐方面的应用非常重要”,具体为:“Superhydrophobicity was first observed on lotus leaves wherehigh-water contact angle and low hysteresis...Such surface properties are also criticalin microelectromechanical systems (MEMS) antistiction, friction reduction, andanticorrosion6 applications.”(6 为代表性论文 8)。
代表性论文专著目录
1.In vivo nanomechanicalimaging of blood -vesseltissues directly in livingmammals using atomicforce microscopy/ AppliedPhysics Letters/ YoudongMao, Quanmei Sun,Xiufeng Wang, Qi Ouyang,Li Han, Lei Jiang, DongHan
2.Wetting behavior atmicro-/nanoscales: directimaging of a microscopicwater/ air/solid three-phaseinterface/Small/ PeipeiChen, Long Chen, DongHan, Jin Zhai, YongmeiZheng, Lei Jiang
3.In situ investigation ondynamic suspending ofmicrodroplet on lotus leafand gradient of wettablemicro- and nanostructurefrom water condensation/Applied Physics Letters/Yongmei Zheng, Dong Han,Jin Zhai, Lei Jiang
4.Bio-inspired hierarchicalmacromolecule-nanoclayhdrogels for robustunderwatersuperoleophobicity/Advanced Materials/ LingLin, Mingjie Liu, Li Chen,Peipei Chen, Jie Ma, DongHan, Lei Jiang
5.Superhydrophobic alignedpolystyrene nanotube filmswith high adhesive force/Advanced Materials/Meihua Jin, Xinjian Feng,Lin Feng, Taolei Sun, JinZhai, Tiejin Li, Lei Jiang
6.Greatlyimprovedbloodcompatibility bymicroscopicmultiscaledesign ofsurfacearchitectures/Small/Honglei Fan, Peipei Chen,Ruomei Qi, Jin Zhai,Jingxia Wang, Long Chen,Li Chen, Quanmei Sun,Yanlin Song, Dong Han, LeiJiang
7.Antiplatelet andthermallyresponsivepoly(N-isopropylacrylamide)surface withnanoscaletopography/ Journal of theAmerican ChemicalSociety/Li Chen, MingjieLiu, Hao Bai, Peipei Chen,Fan Xia, Dong Han, LeiJiang
8.One-stepsolution-immersion processfor the fabrication of stablebionic superhydrophobicsurfaces/AdvancedMaterials/Shutao Wang, LinFeng, Lei Jiang