微生物合成的糖脂类生物表面活性剂

介绍了糖脂类生物表面活性剂的种类、理化特性、微生物合成的方法及应用和发展趋势。相对于化学合成的表面活性剂,微生物糖脂具有可生物降解、在高温或极端pH环境下仍然有效和无毒或低毒等优点,有些微生物糖脂还表现出高效的抗菌、防霉和抗病毒特性。但目前通过微生物合成糖脂的生产成本仍比化学合成的高,因此降低其生产成本是当前研究开发的热点和主要发展方向。     

脂肽类生物表面活性剂研究进展

脂肽是由微生物代谢产生的一类具有很强表面活性的生物表面活性剂,在医药、环境保护、化妆品和微生物采油等方面有良好的应用潜力。该文对脂肽的生产、分离、鉴定及应用进展进行了综述。引用文献45篇。     

Recovery of biosurfactants by ultrafiltration

Ultrafiltration was used in a one-step method to purify and concentrate biosurfactants—surfactin and rhamnolipids—from culture supernatant fluids. The ability of surfactant molecules to form micelles at concentrations above the critical micelle concentration allows these aggregates to be retained by relatively high molecular weight cut-off membranes. Lower molecular weight impurities such as salts, free amino acids, peptides and small proteins are easily removed. Various molecular weight cut-off membranes were examined for the retention of surfactin and rhamnolipids (mol. wts 1036 and 802 respectively). Amicon XM 50 was the superior membrane for retention of surfactin and a 160-fold purification was rapidly achieved. The YM 10 membrane was the most appropriate for rhamnolipid recovery. Ultrafiltration can play an important role in biosurfactant purification as large volumes of media can be processed rapidly at extremely low cost.     

Surfactin生物表面活性剂及其驱油研究进展

表面活性素（surfactin）是一类由革兰氏阳性的枯草芽孢杆菌产生的脂肽（lipopeptide）型生物表面活性剂,因其具有优于化学合成表面活性剂的若干优点,如低毒性、高生物降解性、更好的环境相容性,且在极端环境下稳定性好,在提高石油采收率方面有较好的应用潜力,但是目前只有少数的生物表面活性剂可以大规模生产实现工业化应用。本文介绍了surfactin生物表面活性剂的化学结构和生物合成机制,并对其发酵生产过程的影响因素进行分析,为提高其生产经济性探索不同的策略,例如使用更便宜的原材料、优化培养基组分、优化反应器等,系统论述了surfactin生物表面活性剂的驱油机理和其与化学合成表面活性剂的复配研究,同时针对其应用时的不足之处提出研究新思路。     

生物表面活性剂在油田中的应用

生物表面活性剂和化学表面活性剂一样 ,有亲水基团和疏水基团 ,它是由微生物生长在水不溶的物质中并以它为食物源产生的。在油田中 ,生物表面活性剂是微生物提高采收率的重要机理 ,具有水溶性好、反应产物均一、无毒、安全、驱油效果好等特点。生物表面活性剂有 4种类型 :糖脂类、磷脂类、脂蛋白或缩氨酸脂和聚合物类。大多数生物表面活性剂是糖脂 ,是碳水化合物连接在长链脂肪酸上。目前 ,室内研究主要是研究各种反应条件对微生物产生生物表面活性剂和生物表面活性剂对原油的影响。矿场实验有地面发酵和地下发酵两种形式。从生物表面活性剂的特点、筛选产生生物表面活性剂的菌种、生物表面活性剂的类型、室内研究、矿场实验和今后的发展方向等 6个方面综述了油田中的生物表面活性剂的应用     

Foaming properties of surfactin,a lipopeptide biosurfactant fromBacillus subtilis

Foaming properties of surfactin were investigated and compared to those of sodium dodecyl sulfate (SDS) and bovine serum albumin (BSA). Foams were formed by a bubbling technique. Evolution of the foam volume and the liquid in the foam was monitored with optical and conductimetric methods to characterize foam formation and stability. Excellent foaming properties of surfactin were shown by its higher ability to form and stabilize the foam at a concentration as low as 0.05 mg/mL, in comparison with SDS and BSA. Surfactin produced a foam with intermediate maximum density and stabilized the liquid in foam, as well as BSA.     

Chemical Structure,Property and Potential Applications of Biosurfactants Produced by Bacillus subtilis in Petroleum Recovery and Spill Mitigation

Lipopeptides produced by microorganisms are one of the five major classes of biosurfactants known and they have received much attention from scientific and industrial communities due to their powerful interfacial and biological activities as well as environmentally friendly characteristics. Microbially produced lipopeptides are a series of chemical structural analogues of different families and, among them, 26 families covering about 90 lipopeptide compounds have been reported in the last two decades. This paper reviews the chemical structural characteristics and molecular behaviors of surfactin, one of the representative lipopeptides of the 26 families. In particular, two novel surfactin molecules isolated from cell-free cultures of Bacillus subtilis HSO121 are presented. Surfactins exhibit strong self-assembly ability to form sphere-like micelles and larger aggregates at very low concentrations. The amphipathic and surface properties of surfactins are related to the existence of the minor polar and major hydrophobic domains in the three 3-D conformations. In addition, the application potential of surfactin in bioremediation of oil spills and oil contaminants, and microbial enhanced oil recovery are discussed.     

Biosurfactants for microbubble preparation and application

Biosurfactants can be classified by their chemical composition and their origin. This review briefly describes various classes of biosurfactants based on their origin and introduces a few of the most widely used biosurfactants. The current status and future trends in biosurfactant production are discussed, with an emphasis on those derived from plants. Following a brief introduction of the properties of microbubbles, recent progress in the application of microbubble technology to molecular imaging, wastewater treatment, and aerobic fermentation are presented. Several studies on the preparation, characterization and applications of biosurfactant-based microbubbles are reviewed.     

假单胞菌O-2-2产鼠李糖脂的结构表征及理化性质

利用液相色谱/质谱联用仪分析了铜绿假单胞菌O-2-2以正十八烷为碳源所产鼠李糖脂生物表面活性剂的组成。共检出21种鼠李糖脂的同系物,都由1~2分子的鼠李糖和1~2个含β-羟基的碳链长度为8~12的饱和或不饱和脂肪酸构成;主要组分为α-L-吡喃鼠李糖苷-β-羟基癸酰-β-羟基癸酸和2-O-α-L-吡喃鼠李糖苷-α-L-吡喃鼠李糖苷-β-羟基癸酰-β-羟基癸酸。该糖脂类生物表面活性剂可将水的表面张力降至28·6mN/m,临界胶束浓度为1·3×10-4mol/L,在120℃加热4h或者在ρ(NaCl)=100g/L或ρ(CaCl2)=20g/L的盐溶液中仍能保持表面活性。     

Characterization and emulsification properties of rhamnolipid and sophorolipid biosurfactants and their applications

Due to their non-toxic nature, biodegradability and production from renewable resources, research has shown an increasing interest in the use of biosurfactants in a wide variety of applications. This paper reviews the characterization of rhamnolipid and sophorolipid biosurfactants based on their hydrophilicity/hydrophobicity and their ability to form microemulsions with a range of oils without additives. The use of the biosurfactants in applications such as detergency and vegetable oil extraction for biodiesel application is also discussed. Rhamnolipid was found to be a hydrophilic surfactant while sophorolipid was found to be very hydrophobic. Therefore, rhamnolipid and sophorolipid biosurfactants in mixtures showed robust performance in these applications.     

脂肪酶催化合成生物表面活性剂

脂肪酸单甘油酯、脂肪酸糖酯、聚甘油脂肪酸酯和长链脂肪酸蜡酯是重要的生物表面活性剂。传统化学法以碱为催化剂在高温下进行,不仅能耗高且产品纯度低。脂肪酶作为一种天然生物催化剂,可以温和条件下催化合成上述生物表面活性剂,能耗低且产品纯度高。综述对脂肪酶催化合成生物表面活笥剂工艺路线、反应体系及操作参数。     

鼠李糖脂生物表面活性剂及其纯化方法研究进展

鼠李糖脂生物表面活性剂是由微生物在一定的培养条件下分泌的次级代谢产物,具有良好的环境相容性,生产成本是制约其工业化应用的主要因素。综述了鼠李糖脂的常用纯化方法,并对其研究方向进行了展望。     

一种脂肽类生物表面活性剂的产生及特性研究

从油田采出水中分离到一株芽孢杆菌(Bacillus lichenifonnis)。菌种发酵液具有高表面活性,经分离提取获得浅黄色固体产物,其临界胶束浓度(cmc值)为30.0mg／L,该产物经聚丙烯酰胺凝胶电泳、红外光谱(IR)、色谱-质谱联用(GC-MS)和纸层析(PC)分析表明：其疏水基半分子为β-甲基十四碳脂肪酸及β-羟基十八碳脂肪酸;亲水基半分子含Asp、Glu、Ile、Val、Lys等氨基酸,为一种由脂肪酸和肽组成的脂肽类生物表面活性剂。特性分析表明：该表面活性剂可耐高温和高浓度盐,pH适应范围较广,对原油具有较强的乳化、增溶、脱附和降黏作用。     

生物表面活性剂对城市污泥中铜和锌的去除研究

采用振荡淋洗的方法研究了生物表面活性剂鼠李糖脂浓度、p H、淋洗时间对城市污泥中Cu和Zn去除效果的影响。结果表明:随着鼠李糖脂浓度的增加,Cu和Zn的去除率增加,效果明显优于去离子水的去除,而鼠李糖脂对污泥中Cu的去除明显优于对Zn的去除,且鼠李糖脂在较高p H值下对Cu和Zn的去除效果较好;随着振荡时间的增加,Cu和Zn的去除率随之增加,最高去除率可高达63.9%、5.1%。本研究可为城市污泥的再利用所需要解决的问题提供参考方案。     

Precipitation and Recovery of Cellulase using Biosurfactant

Rhamnolipid and saponin were used as biosurfactant to form cellulase-biosurfactant complex systems. Acetone, ethanol, and methanol were tested recovery solvents, and among the three tested recovery solvents, acetone was the optimum one. Using acetone as recovery solvent and with the addition of 0.1 mM NaCl, the highest protein and activity recovery were yielded. The optimum conditions during the process for cellulase-rhamnolipid complex systems and cellulase-saponin complex systems were discovered. Two cellulase-biosurfactant complex systems were better than the cellulase-AOT complex system. Experimental results showed that biosurfactants have great potential in protein precipitation.     

Biosurfactants: Multifunctional Biomolecules of the 21st Century

In the era of global industrialisation, the exploration of natural resources has served as a source of experimentation for science and advanced technologies, giving rise to the manufacturing of products with high aggregate value in the world market, such as biosurfactants. Biosurfactants are amphiphilic microbial molecules with hydrophilic and hydrophobic moieties that partition at liquid/liquid, liquid/gas or liquid/solid interfaces. Such characteristics allow these biomolecules to play a key role in emulsification, foam formation, detergency and dispersal, which are desirable qualities in different industries. Biosurfactant production is considered one of the key technologies for development in the 21st century. Besides exerting a strong positive impact on the main global problems, biosurfactant production has considerable importance to the implantation of sustainable industrial processes, such as the use of renewable resources and “green” products. Biodegradability and low toxicity have led to the intensification of scientific studies on a wide range of industrial applications for biosurfactants in the field of bioremediation as well as the petroleum, food processing, health, chemical, agricultural and cosmetic industries. In this paper, we offer an extensive review regarding knowledge accumulated over the years and advances achieved in the incorporation of biomolecules in different industries.     

Bioremediation of Polycyclic Aromatic Hydrocarbon Contaminated Soil by a Microbial Consortium through Supplementation of Biosurfactant Produced by Pseudomonas aeruginosa Strain

Lipopeptide biosurfactant produced by Pseudomonas aeruginosa Lbp 3 strain isolated from petroleum contaminated soil was investigated for its potential to enhance bioavailability, and hence, the biodegradation of polycyclic aromatic hydrocarbons (PAHs) in contaminated soil microcosms. Experiments were conducted on a soil spiked with equal parts of the PAHs Phenanthrene, Fluoranthene, and Pyrene to a final concentration of 1200 mg of total PAHs per kg of dry soil. To evaluate biodegradation enhancement efficiency, 50 g spiked soil samples were supplemented with 50 mgL^?1, 100 mgL^?1, 300 mgL^?1, and 1000 mgL^?1of lipopeptide dissolved in 30 mL of MSM, and incubated for 40 days at 30°C in darkness. Statistically significant (P < 0.05) biodegradation rates were observed in all the amended microcosms in comparison to the unamended controls. Maximal biodegradations (> 96% of Phenanthrene and Fluoranthene and > 93% of Pyrene) were observed in the soil microcosms supplemented with 1000 mgL^?1and 50 mgL^?1 lipopeptide. The effect of substrate interactivity of the PAHs on the biodegradation kinetics was also tested in comparison with sole substrate microcosms. Competitive inhibition of the biodegradation of low molecular weight PAHs was observed as a result of substrate interactivity in the multisubstrate system.     

Synthesis of brushite particles in reverse microemulsions of the biosurfactant surfactin

In this study the "green chemistry" use of the biosurfactant surfactin for the synthesis of calcium phosphate using the reverse microemulsion technique was demonstrated. Calcium phosphates are bioactive materials that are a major constituent of human teeth and bone tissue. A reverse microemulsion technique with surfactin was used to produce nanocrystalline brushite particles. Structural diversity (analyzed by SEM and TEM) resulted from different water to surfactin ratios (W/S; 250, 500, 1000 and 40,000). The particle sizes were found to be in the 16-200 nm range. Morphological variety was observed in the as-synthesized microemulsions, which consisted of nanospheres (~16 nm in diameter) and needle-like (8-14 nm in diameter and 80-100 nm in length) noncalcinated particles. However, the calcinated products included nanospheres (50-200 nm in diameter), oval (~300 nm in diameter) and nanorod (200-400 nm in length) particles. FTIR and XRD analysis confirmed the formation of brushite nanoparticles in the as-synthesized products, while calcium pyrophosphate was produced after calcination. These results indicate that the reverse microemulsion technique using surfactin is a green process suitable for the synthesis of nanoparticles.     

生物表面活性剂对疏水性有机物的增溶特性

在提高疏水性有机污染物的生物可利用性方面,生物表面活性剂的增溶效果是关键.通过实验测试了单一鼠李糖脂生物表面活性剂、复配表面活性剂(鼠李糖脂-非离子表面活性剂)对疏水性有机污染物增溶性能的影响,在此基础上,进一步考察了无机盐对复配表面活性剂增溶效果的影响.结果表明:鼠李糖脂质量浓度在临界胶束质量浓度之上时,长链烷烃和多...     

假单胞菌AB93066产鼠李糖脂发酵条件的优化

通过单因素实验和正交实验对铜绿假单胞杆菌AB93066产鼠李糖脂(RL)的摇瓶发酵培养基配方和产生规律进行了研究。结果表明,最佳培养基配方为:ρ(酵母膏)=0.2 g/L,ρ(豆油)=120 g/L,ρ(NaNO3)=6.5 g/L,ρ(KH2PO4)=1.0 g/L,ρ(Na2HPO4.12H2O)=1.0 g/L,ρ(MgSO4.7H2O)=0.1 g/L,ρ(FeSO4.7H2O)=0.2 g/L,pH=6.0。RL的收获期在发酵后156~168 h最佳。发酵生产RL的扩大实验表明,在最优发酵条件下RL的产量可达56 g/L以上,提取后的RL可将去离子水的表面张力降至29.01 mN/m。用高效液相色谱/质谱联用仪进一步分析了所提取的RL的组成,它分别为二鼠李糖脂(R1)和单鼠李糖脂(R2)两种同系物。R1和R2的表观临界胶束浓度(CMC)分别为0.03 mmol/L和0.04 mmol/L。