The surface modification of the anionic polyurethane(APU)film was carried out by immersing it in silk fibroin peptide(SFP)solution for 12 h and then treating with low temperature plasma glow discharge.The physical pro...The surface modification of the anionic polyurethane(APU)film was carried out by immersing it in silk fibroin peptide(SFP)solution for 12 h and then treating with low temperature plasma glow discharge.The physical properties and moisture permeability of modified films were examined.The results showed that SFP-modified APU films had better moisture permeability than oleophilic polyurethane,as well as modified APU films kept good flexibility.Modified APU films could overcome rigid and brittle weaks of silk fibroin films.The morphology of SFP on the APU film was corpuscular aggregations.The water-contact angle measurement indicated that the change of hydrophilicity and the element chemical analysis suggested that the SFP-modified film surface was enriched with nitrogen atoms.The biocompatibility of APU films may be improved due to the change of surface components.Cell viability and proliferation of rat embryo dermal fibroblasts seeded on control films,APU films and SFP-modified APU films were evaluated by MTT assay and viable cell counts,respectively.The results indicated that the APU film modified by SFP protein showed the proliferation of fibroblasts on the film,and that the compound interface had good stability in the air.Results also showed that presoaking treatment for APU films was effective to accomplish the goal of surface modification.展开更多
Isothiocyanates(ITCs) extracts were prepared from fresh broccoli.Their antioxidant properties were evaluated by using the in vitro bioassays,including superoxide anion radical( 2 O·-) ,hydroxyl radical(HO·-)...Isothiocyanates(ITCs) extracts were prepared from fresh broccoli.Their antioxidant properties were evaluated by using the in vitro bioassays,including superoxide anion radical( 2 O·-) ,hydroxyl radical(HO·-) and 2,2-diphenyl-1-picrylhydracyl(DPPH·) radical-scavenging methods,lipid peroxidation assay,and reducing power assay.The ITCs extracts exhibited significant dose-dependent antioxidant activities(P<0.01) .Its antioxidant-stability was affected by temperature and storage condition,although it was more stable than vitamin C(Vc) .GC-MS iden-tified sulforaphane in the ITCs extracts.The antioxidant activity of sulforaphane was approximately one tenth to one fifth of that of Vc.Sulforaphane was experimented to be one of dominating contributors to antioxidant capacity of ITCs extracts.However,there was no direct antioxidant activity found for benzyl isothiocyanate(BITC) in vitro. Therefore,it could be concluded that the general group(-N=C=S) was not the essential part for the antioxidant activity of sulforaphane.It is suggested that the ITCs extracts from broccoli can be developed into a promising food additive for healthy food.展开更多
Synthesis and anionic polymerization of the fluorine-substituted phenyl methacrylates are herein reported. A series of monodi-, and multi-substituted fluorophenyl methacrylates H2C=C(CH3)C(O)OC6H4F-4 (M^1a), H2...Synthesis and anionic polymerization of the fluorine-substituted phenyl methacrylates are herein reported. A series of monodi-, and multi-substituted fluorophenyl methacrylates H2C=C(CH3)C(O)OC6H4F-4 (M^1a), H2C=C(CH3)C(O)OC6H4F-3 (M^1b), HEC=C(CH3)C(O)OC6H3F2-2,4 (M^2), H2C=C(CH3)C(O)OC6H2F3-2,3,4 (M^3), H2C=C(CH3)C(O)OC6HF4-2,3,5,6 (M^4), and H2C=C(CH3)C(O)OC6F5 (M^5) were synthesized and characterized. Initially, the polymerization was carded out on the monomer M^1a by using nBuLi, tBuLi, and KH as the respective catalysts; this approach produced the polymers in yields of 12%-50%, but with lower molecular weights. Similar results were obtained by using tBuLi for catalytically polymerizing the other five monomers. By introducing a co-catalyst MeAl(BHT)2, the catalysts Nail, LiH, and tBuOLi each were tested to polymerize M^1a, which gave the polymers in very low yields (3%-7%). Polymer yields of 13%-27% were obtained by each of the catalysts LiAlH4, nBuLi, PhLi, and tBuLi in connection with MeAI(BHT)2, but a better yield (61%) was achieved with KH/MeAl(BHT)2. The KH/MeAl(BHT)2 catalyst system was further employed to polymerize M^1b and M^2, which afforded respective polymer yields of 12%-63% and 10%-53%, depending on the molar ratios of KH:MeAl(BHT)2 as well as on the monomer concentrations. All of the polymers produced were syndiotactically rich in structure, as indicated by either ^1H or ^19F NMR data. The polymerization mechanism by the combined catalyst system is proposed.展开更多
基金Supported by the National Basic Research 973 Programof China(No.2005CB623906)
文摘The surface modification of the anionic polyurethane(APU)film was carried out by immersing it in silk fibroin peptide(SFP)solution for 12 h and then treating with low temperature plasma glow discharge.The physical properties and moisture permeability of modified films were examined.The results showed that SFP-modified APU films had better moisture permeability than oleophilic polyurethane,as well as modified APU films kept good flexibility.Modified APU films could overcome rigid and brittle weaks of silk fibroin films.The morphology of SFP on the APU film was corpuscular aggregations.The water-contact angle measurement indicated that the change of hydrophilicity and the element chemical analysis suggested that the SFP-modified film surface was enriched with nitrogen atoms.The biocompatibility of APU films may be improved due to the change of surface components.Cell viability and proliferation of rat embryo dermal fibroblasts seeded on control films,APU films and SFP-modified APU films were evaluated by MTT assay and viable cell counts,respectively.The results indicated that the APU film modified by SFP protein showed the proliferation of fibroblasts on the film,and that the compound interface had good stability in the air.Results also showed that presoaking treatment for APU films was effective to accomplish the goal of surface modification.
基金Supported by the Natural Science Foundation of Zhejiang Province(Y3090135)
文摘Isothiocyanates(ITCs) extracts were prepared from fresh broccoli.Their antioxidant properties were evaluated by using the in vitro bioassays,including superoxide anion radical( 2 O·-) ,hydroxyl radical(HO·-) and 2,2-diphenyl-1-picrylhydracyl(DPPH·) radical-scavenging methods,lipid peroxidation assay,and reducing power assay.The ITCs extracts exhibited significant dose-dependent antioxidant activities(P<0.01) .Its antioxidant-stability was affected by temperature and storage condition,although it was more stable than vitamin C(Vc) .GC-MS iden-tified sulforaphane in the ITCs extracts.The antioxidant activity of sulforaphane was approximately one tenth to one fifth of that of Vc.Sulforaphane was experimented to be one of dominating contributors to antioxidant capacity of ITCs extracts.However,there was no direct antioxidant activity found for benzyl isothiocyanate(BITC) in vitro. Therefore,it could be concluded that the general group(-N=C=S) was not the essential part for the antioxidant activity of sulforaphane.It is suggested that the ITCs extracts from broccoli can be developed into a promising food additive for healthy food.
基金supported by the National Basic Research Program of China(2012CB821704)the National Natural Science Foundation of China(20972129)the Innovative Research Team Program(IRT1036,J1310024)
文摘Synthesis and anionic polymerization of the fluorine-substituted phenyl methacrylates are herein reported. A series of monodi-, and multi-substituted fluorophenyl methacrylates H2C=C(CH3)C(O)OC6H4F-4 (M^1a), H2C=C(CH3)C(O)OC6H4F-3 (M^1b), HEC=C(CH3)C(O)OC6H3F2-2,4 (M^2), H2C=C(CH3)C(O)OC6H2F3-2,3,4 (M^3), H2C=C(CH3)C(O)OC6HF4-2,3,5,6 (M^4), and H2C=C(CH3)C(O)OC6F5 (M^5) were synthesized and characterized. Initially, the polymerization was carded out on the monomer M^1a by using nBuLi, tBuLi, and KH as the respective catalysts; this approach produced the polymers in yields of 12%-50%, but with lower molecular weights. Similar results were obtained by using tBuLi for catalytically polymerizing the other five monomers. By introducing a co-catalyst MeAl(BHT)2, the catalysts Nail, LiH, and tBuOLi each were tested to polymerize M^1a, which gave the polymers in very low yields (3%-7%). Polymer yields of 13%-27% were obtained by each of the catalysts LiAlH4, nBuLi, PhLi, and tBuLi in connection with MeAI(BHT)2, but a better yield (61%) was achieved with KH/MeAl(BHT)2. The KH/MeAl(BHT)2 catalyst system was further employed to polymerize M^1b and M^2, which afforded respective polymer yields of 12%-63% and 10%-53%, depending on the molar ratios of KH:MeAl(BHT)2 as well as on the monomer concentrations. All of the polymers produced were syndiotactically rich in structure, as indicated by either ^1H or ^19F NMR data. The polymerization mechanism by the combined catalyst system is proposed.
