Wetting condition of micro/nanostructured surface has received tremendous attention due to the potential applications in commercial,industrial,and military areas.Surfaces with extreme wetting properties,e.g.,superhydr...Wetting condition of micro/nanostructured surface has received tremendous attention due to the potential applications in commercial,industrial,and military areas.Surfaces with extreme wetting properties,e.g.,superhydrophobic or superhydrophilic,are extensively employed due to their superior anti-icing,drag reduction,enhanced boiling heat transfer,self-cleaning,and anti-bacterial properties depending on solid-liquid interfacial interactions.Laser-based techniques have gained popularity in recent years to create micro/nano-structured surface owing to their high flexibility,system precision,and ease for automation.These techniques create laser induced periodic surface structures(LIPSS)or hierarchical structures on substrate material.However,micro/nanostructures alone cannot attain the desired wettability.Subsequent modification of surface chemistry is essentially needed to achieve target extreme wettability.This review paper aims to provide a comprehensive review for both laser texturing techniques and the following chemistry modification methods.Recent research progress and fundamental mechanisms of surface structure generation via different types of lasers and various chemistry modification methods are discussed.The complex combination between the laser texturing and surface chemistry modification methods to decide the final wetting condition is presented.More importantly,surface functionalities of these surfaces with extreme wetting properties are discussed.Lastly,prospects for future research are proposed and discussed.展开更多
To identify, clone ,sequence and highly express the mature peptide gene of ApoA Ⅰ, total RNA was prepared from human fetal liver tissue. cDNA fragment encoding human ApoA Ⅰ was amplified by RT-PCR using specific pri...To identify, clone ,sequence and highly express the mature peptide gene of ApoA Ⅰ, total RNA was prepared from human fetal liver tissue. cDNA fragment encoding human ApoA Ⅰ was amplified by RT-PCR using specific primers, and then was inserted in pGEM-T vector. DNA sequencing indicates that the fragment is 729 base pairs in length and has 100% nucleotide homology with that of reported ApoA Ⅰ cDNA gene previously. The ApoA Ⅰ gene was cloned into pGEX 5X-1.The recombinant protein was expressed in E.coli DH5α, purified by glutathione-Sepharose 4B affinity chromatography and confirmed by SDS-PAGE. It was shown that the recombinant ApoA Ⅰ was expressed in E.coli, and the target protein amounted to 36% of total bacteria proteins. Cholesteryl ester transfer experiment showed that the recombinant ApoA Ⅰ was capable of promoting transfer of CE from HDL to LDL. Western blotting showed that the protein could react specifically with anti-ApoA Ⅰ antibodies.展开更多
基金Project(52105175)supported by the National Natural Science Foundation of ChinaProject(BK20210235)supported by the Natural Science Foundation of Jiangsu Province,ChinaProject(JSSCBS20210121)supported by the Jiangsu Provincial Innovative and Entrepreneurial Doctor Program,China。
文摘Wetting condition of micro/nanostructured surface has received tremendous attention due to the potential applications in commercial,industrial,and military areas.Surfaces with extreme wetting properties,e.g.,superhydrophobic or superhydrophilic,are extensively employed due to their superior anti-icing,drag reduction,enhanced boiling heat transfer,self-cleaning,and anti-bacterial properties depending on solid-liquid interfacial interactions.Laser-based techniques have gained popularity in recent years to create micro/nano-structured surface owing to their high flexibility,system precision,and ease for automation.These techniques create laser induced periodic surface structures(LIPSS)or hierarchical structures on substrate material.However,micro/nanostructures alone cannot attain the desired wettability.Subsequent modification of surface chemistry is essentially needed to achieve target extreme wettability.This review paper aims to provide a comprehensive review for both laser texturing techniques and the following chemistry modification methods.Recent research progress and fundamental mechanisms of surface structure generation via different types of lasers and various chemistry modification methods are discussed.The complex combination between the laser texturing and surface chemistry modification methods to decide the final wetting condition is presented.More importantly,surface functionalities of these surfaces with extreme wetting properties are discussed.Lastly,prospects for future research are proposed and discussed.
文摘To identify, clone ,sequence and highly express the mature peptide gene of ApoA Ⅰ, total RNA was prepared from human fetal liver tissue. cDNA fragment encoding human ApoA Ⅰ was amplified by RT-PCR using specific primers, and then was inserted in pGEM-T vector. DNA sequencing indicates that the fragment is 729 base pairs in length and has 100% nucleotide homology with that of reported ApoA Ⅰ cDNA gene previously. The ApoA Ⅰ gene was cloned into pGEX 5X-1.The recombinant protein was expressed in E.coli DH5α, purified by glutathione-Sepharose 4B affinity chromatography and confirmed by SDS-PAGE. It was shown that the recombinant ApoA Ⅰ was expressed in E.coli, and the target protein amounted to 36% of total bacteria proteins. Cholesteryl ester transfer experiment showed that the recombinant ApoA Ⅰ was capable of promoting transfer of CE from HDL to LDL. Western blotting showed that the protein could react specifically with anti-ApoA Ⅰ antibodies.