系列醚类阳离子型双子表面活性剂的合成与性能

以4-(辛/癸/十二烷氧基)甲基吡啶和1,4-二溴丁烷为原料,制得含有醚键的季铵盐双子表面活性剂：溴化-1,4-二[4-(辛/癸/十二烷氧基)甲基吡啶]丁烷,记作QAE n-4-n(n=8,10,12)。通过¹H NMR、¹³C NMR和MS进行结构表征,并对表面张力、泡沫性能、杀菌性能等进行研究。结果表明：室温下QAE12-4-12的CMC为9.1×10^-2mmol·L^-1,具有良好的表面活性;QAE10-4-10则杀菌效果显著,最小抑菌浓度均小于10mmol·L^-1,最小杀菌浓度在4～20mmol·L^-1之间。该系列醚类季铵盐合成方法简单、表面活性好,杀菌效果明显,具有进一步研究的价值。     

溴化-1,4/1,6-二(α-辛基吡啶)丁烷/己烷的合成及表征

以吡啶和1-溴代正辛烷为原料,制得中间产物α-辛基吡啶,再分别与1,4-二溴丁烷和1,6-二溴己烷反应,得到两种含氮杂环的双子季铵盐表面活性剂,通过定性实验和波谱方法鉴定了其结构,并表征了这两种表面活性剂的表面活性和杀菌活性.结果表明:这两种化合物均有一定的降低水表面张力的能力,以及杀菌活性.     

溴化-1，4／1，6-二（a-辛基吡啶）丁烷／己烷的合成及表征

以吡啶和1-溴代正辛烷为原料，制得中间产物a-辛基吡啶，再分别与l，4-二溴丁烷和1，6-二溴己烷反应，得到两种含氮杂环的双子季铵盐表面活性剂，通过定性实验和波谱方法鉴定了其结构，并表征了这两种表面活性剂的表面活性和杀菌活性．结果表明：这两种化合物均有一定的降低水表面张力的能力，以及杀菌活性．     

表面胶团修饰电极电化学测定双酚A的增敏机理及抗污性能研究

分别以2种阴离子表面活性剂(SDS、SDBS)、3种季铵盐阳离子表面活性剂(CTAB、TTAB、DTAB)和2种季铵盐型双子表面活性剂(12-3-12、12-4-12)修饰碳糊电极。通过原子力显微镜、接触角以及分析物在电极表面的电化学行为探讨了不同表面活性剂在电极表面的吸附情况,推测在浓度大于临界胶束浓度(CMC)时,季铵盐型阳离子表面活性剂CTAB、TTAB、12-3-12和12-4-12在碳糊电极表面形成了圆柱形的表面胶团,而DTAB和SDS可能是饱和单分子层吸附。以BPA为分析物,研究了表面活性剂修饰电极对BPA的电化学增敏机理,结果表明修饰电极对双酚A(BPA)的电化学增敏作用主要是因为表面胶团对BPA的增溶作用,表面活性剂和BPA间的阳离子-π作用是表面胶团增溶BPA的主要原因。     

酯基Gemini双季铵盐表面活性剂的研究进展

Gemini双季铵盐表面活性剂性能优异但生物和化学降解性差,在Gemini双季铵盐表面活性剂结构中引入酯基官能团可以提升产物性能。酯基Gemini双季铵盐表面活性剂含有酯基和双季铵盐基,具有高表面活性、吸附、絮凝、抗盐、湿润、乳化、杀菌防腐和易生物分解等优点,应用前景广阔。本文综述了酯基Gemini双季铵盐表面活性剂的合成路线、性能和石油化工的应用状况,结合发展需求对酯基Gemini双季铵盐表面活性剂的未来发展进行了分析和展望。     

季铵盐型阳离子双子表面活性剂的合成研究进展

阳离子双子表面活性剂具有正电荷性、cmc低、界面活性高、生物降解性好等优点,可作为柔顺剂、抗静电剂、固色剂、保湿剂、杀菌剂和防腐剂等应用于日用化工、皮革造纸、纺织、石油开采及金属防护等领域。本文综述了季铵盐型阳离子双子表面活性剂的分类、合成及应用,结合表面活性剂的发展需求对阳离子双子表面活性剂的发展方向进行了分析和展望。     

聚(4-乙烯基吡啶季铵盐-丙烯酰胺)的抗菌性能与机理研究

季铵盐型阳离子聚合物具有絮凝、缓蚀与杀菌等多种功能,据此,我们通过分子设计,先将丙烯酰胺与4-乙烯基吡啶（4-VP）进行共聚合,然后使用季铵化试剂硫酸二甲酯使共聚物阳离子化,制备了吡啶季铵盐型阳离子聚丙烯酰胺（QPAV）,本文报道QPAV的抗菌性能,并探讨其抗菌机理,结果表明,吡啶季铵盐型阳离子聚丙烯酰胺具有很强的抗菌性能,且其抗菌机理是基于杀菌而不仅仅是抑菌。     

用DCNPNPT测定江水中季铵盐型阳离子表面活性剂

利用三氮烯类试剂与季铵盐型阳离子表面活性剂形成离子缔合物可用于季铵盐型阳离子表面活性剂的测定。如用HDNPAPT[1]、HDAA[2]测定CTMAB、CPB,但其灵敏度有待提高。本文研究了显色剂1 (2,6 二氯 4 硝基苯) 3 (4 硝基苯) 三氮烯(DCNPNPT)[3]与阳离子表面活性剂的显色反应,结果表明,DCNPNPT与CTMAB、CPB反应的表观摩尔吸光系数分别为3 93×104L·mol 1·cm 1,和4 16×104L·mol 1·cm 1,是目前报道的用光度法测定季铵盐型阳离子表面活性剂较灵敏的体系之一。用此法测定了瓯江水中微量阳离子表面活性剂CTMAB、CPB的…     

一种酯类双季铵盐Gemini表面活性剂的合成研究

酯类双季铵盐Gemini表面活性剂含有正电荷性和酯类官能团,具有cmc低、高界面活性、易生物降解的特点。本研究先用三乙胺(TEA)和环氧氯丙烷(EPIC)合成新型季铵盐阳离子表面活性剂失水甘油基三乙基氯化铵(GTA)中间体,最后用GTA和己二酸反应合成得到一种新型酯类双季铵盐Gemini表面活性剂——双季铵盐己二酸酯表面活性剂(BQAA)。超声条件下得出BQAA合成的最佳条件为:超声频率:60KHz,反应体系pH=8,反应温度:50℃,n(GTA)∶n(己二酸)=2. 5∶1. 0,反应时间:6. 5h,BQAA为白色晶体,产率为88. 79%,通过元素分析和IR对产品BQAA进行了表征,对产物BQAA的表面活性、泡沫性能和乳化性能进行了研究,实验结果表明:BQAA的cmc=1. 3×10~(-4)mol·L~(-1),γ_(cmc)=27. 96 mN·m~(-1),泡沫形成稳定性高,起泡能力强,乳化能力好。     

阳离子可聚合表面活性剂的研究进展

可聚合表面活性剂含有可聚合基团,以牢固的共价键键合到聚合物粒子上,成为聚合物的一部分,有效避免了表面活性剂的解吸及其在乳胶膜中的迁移,减少了乳胶膜表面的亲水基团,可以克服传统表面活性剂的许多弊端。阳离子可聚合表面活性剂主要为季铵盐,其容易吸附于一般固体表面,其水溶液一般有优异的杀菌性。本文综述阳离子可聚合表面活性剂,根据不同方式对其进行分类,分别介绍聚合基团不同的阳离子可聚合表面活性剂的合成和应用现状,并对其应用前景作了展望。     

以硅胶为载体通过γ-胺丙基三甲氧基硅烷偶联剂制备季铵盐类水不溶性杀菌剂的方法研究(II)

在利用硅胶表面上的羟基通过g -胺丙基硅烷把季铵盐固载到硅胶载体上制成水不溶性杀菌剂的基础上,考察了原料硅胶对制备产品杀菌性能的影响。在相同操作条件下,使用同一种原料硅胶,随着原料粒度的减小,所制备杀菌剂产品的杀菌率有所增加,但不明显;选用不同种原料硅胶合成的水不溶性季铵盐类杀菌剂的杀菌结果表明,原料比表面积越大,孔体积越小,合成产品的杀菌率越高。红外光谱证明了 -胺丙基三甲氧基硅烷已通过与硅胶表面羟基的反应键合到硅胶表面,叔胺化的硅胶中间体和产物上存在的很强的烷基峰也证明了硅胶上确实固载上了烷基官能团。交叉极化的硅核磁共振谱有效地表征了硅胶上表面羟基的反应情况,为-106处峰的基本消失证明了原料硅胶表面的硅羟基与胺丙基硅烷的键合反应比较完全。使用后的杀菌剂再生结果表明,其再生性能良好,具备重复使用的特点。     

Disinfection of Escherichia Coli Gram Negative Bacteria Using Surface Modified TiO2: Optimization of Ag Metallization and Depiction of Charge Transfer Mechanism

The antibacterial activity of silver deposited TiO₂ (Ag‐TiO₂) against Gram negative Escherichia coli bacteria was investigated by varying the Ag metal content from 0.10 to 0.50% on the surface of TiO₂. Ag depositions by the photoreduction method were found to be stable. Surface silver metallization was confirmed by EDAX and XPS studies. Photoluminescence studies show that the charge carrier recombination is less for 0.1% Ag‐TiO₂ and this catalyst shows superior bactericidal activity under solar light irradiation compared to Sol gel TiO₂ (SG‐TiO₂) due to the surface plasmon effect. The energy levels of deposited Ag are dependent on the Ag content and it varies from ?4.64 eV to ?1.30 eV with respect to the vacuum energy level based on atomic silver to bulk silver deposits. The ability of electron transfer from Ag deposit to O₂ depends on the position of the energy levels. The 0.25% and 0.50% Ag depositions showed detrimental effect on bactericidal activity due to the mismatch of energy levels. The effect of the EROS (External generation of the Reactive Oxygen Species by 0.1% Ag‐TiO₂) and IROS (Interior generation of Reactive Oxygen Species within the bacteria) on the bactericidal inactivation is discussed in detail.     

The synthesis and properties of homologous series of surfactants containing the pyrrolidinium head group with hydroxyethyl moiety

The surface activity, micelle formation, and solubilization ability towards hydrophobic compounds were estimated for the series of new cationic surfactants belonging to the type of 1-alkyl-1-(2-hydroxyethyl)pyrrolidinium bromides. The presence of 2-hydroxyethyl group in these surfactants leads to the twofold increase in their micelle-forming ability as compared to unsubstituted analogs. The critical micelle concentration for the investigated series of pyrrolidinium surfactants is lower at the same hydrophobicity than that for the analogs belonging to the alkylpyridinium, alkylimidazolium, and alkylmorpholinium types. The data acquired for the studied surfactants on their solubilization ability, antimicrobial activity, and hemolytic efficiency indicate their prospective applications to encapsulate hydrophobic biologically active molecules and as the promising bactericidal agents.

     

Micro-Encapsulation and Antifouling Coatings: Development of Poly(lactic acid) Microspheres Containing Bioactive Molecules

Summary: Environmental legislation compels marine paints companies to develop non toxic antifouling coatings respecting ecosystems. In this work, biodegradable polymers are used to conceive delivery systems with a lifetime of many months. For this purpose, chlorhexidine was encapsulated in poly(L-lactide) microspheres and incorporated in antifouling formulations. The characterization (encapsulation yield, surface morphology, particle size) and antibacterial activity (bacteriostatic and bactericidal effects) of microspheres were carried out by using scanning electronic (SEM) and confocal laser scanning microscopies (CLSM). The results indicate a good ability of loaded microspheres to be formulated even though an excellent activity against selected marine bacteria is conserved. This is a promising approach to develop biodegradable antifouling paints based on non toxic molecules and bioactive surfaces.     

Bactericidal mechanism of Ag/Al2O3 against Escherichia coli

The bactericidal process of Ag/Al2O3 to Escherichia coli has been investigated to clarify the bactericidal mechanism. In SEM images, the configuration of E. coli cells contacting with the catalyst surface was quite different from that contacting with AgNO3 solution, which indicated that the Ag+ eluted from the catalyst did not play an important role in the bactericidal process. The bactericidal experiments strongly confirmed the contribution of multiform reactive oxygen species (ROS) (super oxide dismutase (SOD) and catalase as the scavengers for O2*- and H2O2, respectively) to bactericidal effect on the catalyst surface. Furthermore, the surface modification of Ag/Al2O3 by ultraviolet and formaldehyde influenced the bactericidal effect obviously, which not only confirmed the bactericidal mechanism of catalytic oxidation but also provided evidence for the synergistic effect between Ag and Al2O3 on the catalyst surface.     

Surface characterization of electrodeposited silver on activated carbon for bactericidal purposes

The use of an electrochemical reactor operated under different flow conditions to deposit silver from aqueous AgNO(3) solutions and tartaric acid as an organic additive on a commercial activated carbon with ultimate bactericidal applications in water purification processes is presented. The characterization of carbon/silver samples was studied by BET, FTIR, X-ray diffraction, XPS, and SEM techniques. The bactericidal activity of the carbon/silver samples was tested on drinking water samples inoculated with E. coli. A reduction of carbon surface area was detected and was caused by increased amounts of silver deposited on carbon samples. Adherent silver deposits were obtained on the carbon/silver samples. X-ray diffraction studies of carbon with electrodeposited silver showed two different preferential deposition planes, [111] and [220]. The FTIR results confirm the presence of carboxyl, phenolic, quinone, and ether surface groups. The XPS results suggest the formation of Ag(2)O and AgO surface species and confirm the reduction of silver to the metallic form. Antimicrobial activity toward E. coli indicated reductions by up to 7 orders of magnitude in the log CFU/mL in just 10 min contact time and for silver contents of 2.47 wt%.     

Surfaces of fluorinated pyridinium block copolymers with enhanced antibacterial activity

Polystyrene-b-poly(4-vinylpyridine) copolymers were quaternized with 1-bromohexane and 6-perfluorooctyl-1-bromohexane. Surfaces prepared from these polymers were characterized by contact angle measurements, near-edge X-ray absorption fine structure spectroscopy and X-ray photoelectron spectroscopy. The fluorinated pyridinium surfaces showed enhanced antibacterial activity compared to their nonfluorinated counterparts. Even a polymer with a relatively low molecular weight pyridinium block showed high antimicrobial activity. The bactericidal effect was found to be related to the molecular composition and organization in the top 2-3 nm of the surface and increased with increasing hydrophilicity and pyridinium concentration of the surface.     

Sol–gel derived silver-incorporated titania thin films on glass: bactericidal and photocatalytic activity

Titanium dioxide (TiO₂) and silver-containing TiO₂ (Ag-TiO₂) thin films were prepared on silica pre-coated float glass substrates by a sol–gel spin coating method. The bactericidal activity of the films was determined against Staphylococcus epidermidis under natural and ultraviolet (UV) illumination by four complementary methods; (1) the disk diffusion assay, (2) UV-induced bactericidal test, (3) qualitative Ag ion release in bacteria inoculated agar media and (4) surface topographical examination by laserscan profilometry. Photocatalytic activity of the films was measured through the degradation of stearic acid under UV, solar and visible light conditions. The chemical state and distribution of Ag nanoparticles, as well as the structure of the TiO₂ matrix, and hence the bactericidal and photocatalytic activity, is controlled by post-coating calcination treatment (100–650 °C). Additionally, under any given illumination condition the Ag-incorporated films were found to have superior bactericidal and photocataltyic activity performance compared to TiO₂ thin films. It is shown that with optimized thin film processing parameters, both TiO₂ and Ag-TiO₂ thin films calcined at 450 °C were bactericidal and photocatalytically active.     

The effect of covalent surface immobilization on the bactericidal efficacy of a quaternary ammonium compound

This study investigates the effect of surface immobilization on the bactericidal function of a quaternary ammonium compound. Quaternary ammonium silane (QAS) coated planar surfaces did not produce any measurable mortality of Staphylococcus aureus, while 1 µm QAS‐coated microparticles did produce S. aureus mortality. The experiments using QAS‐coated microparticles indicate that the ability of QAS molecules to disrupt the cell wall is not hindered by covalent immobilization of QAS to a surface. These results provide evidence that S. aureus cells on a QAS‐coated planar surface are not exposed to a sufficient number of QAS molecules to produce significant mortality. This result has important implications for the development of self‐decontaminating coatings. Covalent immobilization is used to prevent leaching of the bactericidal compound. However, covalent immobilization may result in a significant tradeoff in bactericidal performance. Published in 2007 by John Wiley & Sons, Ltd.     

Two-level antibacterial coating with both release-killing and contact-killing capabilities

Using a combination of an aqueous layer-by-layer deposition technique, nanoparticle surface modification chemistry, and nanoreactor chemistry, we constructed thin film coatings with two distinct layered functional regions: a reservoir for the loading and release of bactericidal chemicals and a nanoparticle surface cap with immobilized bactericides. This results in dual-functional bactericidal coatings bearing both chemical-releasing bacteria-killing capacity and contact bacteria-killing capacity. These dual-functional coatings showed very high initial bacteria-killing efficiency due to the release of Ag ions and retained significant antibacterial activity after the depletion of embedded Ag because of the immobilized quaternary ammonium salts.