白腐菌处理染料废水的研究进展

白腐菌是一种可有效处理染料废水的丝状真菌，它可通过其分泌的特殊的降解酶系或其他机制将各种人工合成的染料彻底降解为CO2和H2O，同时，对脱色具有良好的作用。本文就白腐菌的生物学特性及其对染料的降解酶系，机理和白腐菌发酵的主要影响因子，白腐菌处理染料废水的有关研究及应用现状进行了综述。     

开放体系下稻草-白腐菌对染料的吸附脱色与降解

在开放体系下,研究了稻草-白腐菌对孔雀绿和结晶紫的吸附脱色与降解.结果表明,稻草能有效地对孔雀绿和结晶紫进行吸附脱色,其中稻草用量、粒径和pH对稻草吸附染料有一定的影响,在合适条件下稻草对孔雀绿和结晶紫的最大吸附量分别可达到31.89、52.98mg/g;在吸附孔雀绿和结晶紫的稻草中接入白腐菌,发现开放体系下白腐菌能对两种染料进行降解,6d后,孔雀绿和结晶紫的脱色率分别达到93.67%和80.OO%;再生后的稻草基质对孔雀绿和结晶紫也有较好的吸附,最大再生率分别达到74.45%和43.34%.降解过程中白腐菌分泌酶的酶活力与染料及稻草基质降解没有直接的联系.     

木质纤维素水提物促进白腐菌降解孔雀绿研究

对经白腐菌处理的木质纤维素水提物能否促进白腐菌对孔雀绿的降解及其反应机制进行了研究,并探讨了不同木质纤维素组分对白腐菌降解孔雀绿的影响.结果表明,经白腐菌处理不同时间的木质纤维素水提物均能促进白腐菌对孔雀绿的降解,该类物质的加入能缩短白腐菌生长周期及漆酶分泌周期;限氮培养基更有利于白腐菌对孔雀绿的脱色,半纤维素的加入对白腐菌降解孔雀绿的促进作用最为明显.     

白腐菌降解木素酶系及其作用机理

制浆行业目标是脱除木质素,留下纤维素.白腐菌对木素的选择降解性能是造纸工业兴起研究领域如生物制浆,生物漂白及污染处理的理论基础.本文对有关白腐菌降解木素的酶系及作用机制作了概述,目的在于绘出一幅整体的木素降解酶系相互依存的图景,以便人们扩大视野,全面深入研究木素降解过程.     

白腐菌降解木素酶系及其作用机理

制交行业目标是脱除木质素,留下纤维素。白腐菌对木素的选择降解性能是造纸工业兴起研究领域如生物浆浆,生物漂白及污染处理的理论基础。本文对有关白腐菌降解木素的酶系及作用机制作了概述,目的在于绘出一幅整体的木素降解酶系相互依存的图景,以便人们扩大视野,全面深入研究木素降解过程。     

共基质对白腐菌降解喹啉的影响

选用吲哚、苯酚和氨氮作为喹啉降解的共基质.通过白腐菌BP对共基质的降解,研究了白腐菌BP对不同共基质降解体系中喹啉的降解过程及其反应动力学,同时研究了共基质物质对白腐菌BP漆酶活力、生物量增长速率和降解体系pH的影响.结果显示,白腐菌BP对不同共基质降解体系中的喹啉均具有较高的降解率,共基质物质苯酚、吲哚和氨氮对喹啉的降解有一定的抑制作用;共基质降解体系使白腐菌BP漆酶系统启动更加迅速,漆酶活力峰值提前出现;共基质降解体系能促进白腐菌BP的生长,缩短白腐菌BP的生长周期;秸秆滤出液培养基中,pH为6.00～8.00时,白腐菌BP对喹啉均具有较强的降解能力.     

白腐菌应用于堆肥处理含木质素废物的研究

白腐菌对木质素具有较强的降解能力。通过在含大量木质素的模拟垃圾堆肥中采取添加白腐菌菌剂与不添加该菌剂2组实验对比,在相同堆肥处理条件下,接种菌剂的堆肥中木质素总量由274988mg降至15438mg,降解率达4386%,远高于未接种菌剂的堆肥中木质素的降解率,表明白腐菌可有效用于含木质素废弃物的堆肥处理,并有望于加速堆肥腐熟,提高堆肥效率。     

白腐菌S.commune降解微囊藻毒素-LR的研究

为研究真菌对微囊藻毒素的降解作用,以白腐菌S.commune为降解菌,微囊藻毒素-LR(MC-LR)为降解目标进行生物降解,考察了白腐菌预培养方式及降解过程中的培养方式、充氧方式、温度、初始pH以及MC-LR初始浓度对降解效果的影响.结果表明,白腐菌可有效降解MC-LR,经液体预培养白腐菌对MC-LR的降解效果好于固体预培养,白腐菌静置培养过程中每天充入纯氧1min有助于MC-LR的降解,白腐菌降解MC-LR的最佳初始pH为4.5,适宜温度为30～35℃.白腐菌对MC-LR的降解能力随MC-LR初始浓度的增加而降低.在最佳条件下,当MC-LR初始质量浓度为1 mg/L时,其完全降解需要2d;当MC-LR初始质量浓度为15 mg/L时,其完全降解需要7d.高浓度MC-LR(30 mg/L以上)会对白腐菌生长产生抑制作用.MC-LR降解中间产物的具体结构尚不清楚,有待未来深入分析研究.     

白腐菌应用于堆肥处理含木质素废物的研究

白腐菌对木质素具有较强的降解能力。通过在含大量木质素的模拟垃圾堆肥中采取添加白腐菌菌剂与不添加该菌剂2组实验对比，在相同堆肥处理条件下，接种菌剂的堆肥中木质素总量由27498．8mg降至15438mg，降解率达43．86％，远高于未接种菌剂的堆肥中木质素的降解率，表明白腐菌可有效用于含木质素废弃物的堆肥处理，并有望于加速堆肥腐熟，提高堆肥效率。     

白腐菌在固体培养基下对吲哚和吡啶的降解

研究了稻草秆粉介质中白腐菌对吲哚和吡啶的降解.实验结果表明,质量浓度分别为200、80 mg/L左右的吲哚可被白腐菌去除99%以上,质量浓度为74 mg/L吡啶的去除率为61.5%;白腐菌在稻草秆粉培养体系中对吲哚和吡啶的降解,符合零级反应动力学,其中反应速率常数K(高浓度吲哚)＞K(低浓度吲哚)＞K(吡啶);高低浓度吲哚和吡啶3个降解体系的漆酶活力在第6天达到最大;漆酶在吲哚和吡啶降解过程中起着较重要的作用,但酶活的变化与吲哚和吡啶的相对去除率不呈线性相关,稻草秆粉培养基中的介质和培养环境在降解过程中可能也起着重要作用.     

Decolouration of azo dyes by <Emphasis Type="Italic">Phanerochaete chrysosporium</Emphasis> immobilised into alginate beads

Background, aim and scope  

Because of high discharged volumes and effluent composition, wastewater from the textile industry can be considered as the most polluting amongst all industrial sectors, thus greatly requiring appropriate treatment technologies. Although some abiotic methods for the reduction of several dyes exist, these require highly expensive catalysts and reagents. Biotechnological approaches were proven to be potentially effective in the treatment of this pollution source in an eco-efficient manner. The white-rot fungi are, so far, the most efficient microorganisms in degrading synthetic dyes. This white-rot fungi’s property is due to the production of extracellular lignin-modifying enzymes, which are able to degrade a wide range of xenobiotic compounds because of their low substrate specificity. In this paper, we studied the ability of the white-rot fungus Phanerochaete chrysosporium immobilised into Ca-alginate beads to decolourise different recalcitrant azo dyes such as Direct Violet 51 (DV), Reactive Black 5 (RB), Ponceau Xylidine (PX) and Bismark Brown R (BB) in successive batch cultures. To the best of our knowledge, this is the first study on the immobilisation of P. chrysosporium into Ca-alginate beads for its application in dye decolouration.     

真菌和细菌对染料吸附脱色的高效共培养体系研究

在含有真菌G 1培养液中加入染料厂污水排放口的污泥样品 ,从发生快速脱色降解染料的混合培养液中分离出 2株染料脱色细菌L_1和L_2 ,经API鉴定系统鉴定 ,确定菌株L_1为Enterobactersp .,菌株L_2为Peudomonassp .。研究比较了单一和不同组合混合的真菌G_1菌株 (Penicilliumsp .)、细菌L_1菌株 (Enterobactersp .)和L_2菌株 (Pseu domonassp .)对偶氮染料红M - 3BE(C .I .ReactiveRed 2 41)和蒽醌染料艳蓝KN -R(C .1.ReactiveBlue 19)的去除情况 ,发现G - 1真菌和 2种细菌组合的共培养体系对 5 0mg/L红M - 3BE和艳蓝KN -R处理 5h去除率达 10 0 %和 97.9% ,并且是以脱色降解作用为主 ,建立了染料脱色降解菌的最佳组合 ;进一步测定了此最佳共培养体系对另外 13种不同结构染料的脱色降解 ,结果表明 ,除对蒽醌染料R - 478脱色降解较差外 ,对其他染料均可在lh— 3d被完全脱色降解 ,表现出脱色降解染料的广谱性 ;向培养 4d的共培养体系中依次加入 8种染料 ,菌体可对染料连续脱色 ,维持脱色能力达 8d左右     

Phytoremediation of textile effluent and mixture of structurally different dyes by Glandularia pulchella (Sweet) Tronc

Plants of Glandularia pulchella (Sweet) Tronc. performed decolorization of structurally different dyes to varying extent because of induction of different set of enzymes in response to specific dyes. Differential pattern of enzyme induction with respect to time was obtained for lignin peroxidase, veratryl alcohol oxidase, tyrosinase and dichlorophenolindophenol reductase during the decolorization of dye mixture, whose combined action resulted in greater and faster decolorization of dyes. HPLC, FTIR and High Performance Thin Layer Chromatography (HPTLC) analysis confirmed degradation of dyes from textile effluent and mixture. HPTLC demonstrated progressive decolorization of dye mixture along with preferential degradation of the dyes. G. pulchella showed reduction in American Dye Manufacturer's Institute from 405 to 21 and 418 to 22, in case of textile effluent and mixture of dyes respectively. The non-toxic nature of the metabolites of degraded textile dye effluent and mixture of dyes was revealed by phytotoxicity studies.     

Microbial decolorization of synthetic dyes and reactive dyes of industrial effluents by using a novel fungus Aspergillus proliferans

A decolorizing fungal strain was isolated and identified by the morphology and genotypic characterization as Aspergillus proliferans. The effect of A. proliferans on decolorization of synthetic dyes (70 mg ml(-1)) and colored effluent was evaluated in liquid culture medium. A. proliferans expressed their effective decolorization activity in effectual decolorization of synthetic dyes and industrial effluent. Synthetic dyes were decolorized by 76 to 89% within 6 days of treatment and 73.5% of color was removed in industrial effluent within 8 days. The addition of optimum carbon and nitrogen sources were effectively stimulated the decolorization activity. The high concentration of glucose repressed the decolorization activity and supplementation of yeast extract has significantly enhanced the effluent decolorization at p < 0.05. Laccase enzyme was isolated from liquid state fermentation, which showed significant enzyme activity (10,200 Uml(-1)) at p < 0.005. The crude enzyme decolorizes the dyes aniline blue and congo red in 14 hours (40.9 to 70%) and the effluent in 14 hours (88.6%). Moreover, the culture free supernatant without the fungal biomass has also effectively decolorized the effluent and synthetic dyes. The fungi Aspergillus proliferans was used not only for decolorization but also for better bioremediation of industrial effluent.     

Acute toxicity, biochemical and gene expression responses of the earthworm Eisenia fetida exposed to polycyclic musks

Phytoremediation is a novel and promising approach for the treatment of pollutants. This study did explore the potential of Aster amellus Linn. to decolorize a sulfonated azo dye Remazol Red (RR), a mixture of dyes and a textile effluent. Induction in the activities of lignin peroxidase, tyrosinase, veratryl alcohol oxidase and riboflavin reductase was observed during RR decolorization, suggesting their involvement in the metabolism of RR. UV-Visible absorption spectrum, HPLC and FTIR analysis confirmed the degradation of RR. Four metabolites after the degradation of the dye were identified as 2-[(3-diazenylphenyl) sulfonyl] ethanesulfonate, 4-amino-5-hydroxynaphthalene-2,7-disulfonate, naphthalene-2-sulfonate and 3-(1,3,5-triazin-2-ylamino)benzenesulfonate by using GC/MS. Textile effluent and mixture of dyes showed 47% and 62% decrease respectively in American Dye Manufacturers Institute value. BOD of textile effluent and mixture of dyes were reduced by 75% and 48% respectively, COD of industrial effluent and mixture of dyes was reduced by 60% and 75% and TOC was reduced by 54% and 69% respectively after the treatment by A. amellus for 60 h; this indicated that the plant can be used for cleaning textile effluents. Toxicity study revealed the phytotransformation of RR into non-toxic products.     

染料降解菌的脱色特性、降解酶系及基因定位研究进展

本文分析了当前染料废水微生物降解优势菌的降解效果及降解机制等，介绍了三种染料降解酶的催化机理和影响因素，阐明了某些降解菌中的质粒可以控制不同结构染料的脱色。最终指出了提高菌株应用价值的两种途径：一是筛选或构建出具有多功能性的超级菌；二是在不改变染料性质的前提下，向其分子结构中引入特定取代基团，以提高其生物降解性。     

Study of the degradation of dyes by MnP of Phanerochaete chrysosporium produced in a fixed-bed bioreactor

The production of ligninolytic enzymes by the fungus Phanerochaete chrysosporium in a fixed-bed tubular bioreactor, filled with cubes of nylon sponge, operating in semi-solid-state conditions, was studied. Maximum individual manganese-dependent peroxidase (MnP) and lignin peroxidase (LiP) activities of 1293 and 225 U/l were detected.The in vitro decolourisation of two structurally different dyes (Poly R-478, crystal violet) by the extracellular liquid obtained in the above-mentioned bioreactor was monitored in order to determine its degrading capability. The concentration of some compounds (sodium malonate, manganese sulphate) from the reaction mixture was optimised in order to maximise the decolourisation levels. A percentage of Poly R-478 decolourisation of 24% after 15 min of dye incubation was achieved.On the other hand, a methodology for a long treatment of these dyes based on the continuous addition of MnP enzyme and H(2)O(2) was developed. Moreover, this enzymatic treatment was compared with a photochemical decolourisation process. The former allowed to maintain the degradation rate almost constant for a long time, resulting in a decolourisation percentage of 70% and 30% for crystal violet and Poly R-478, respectively, after 2 h of treatment. As for the latter, it was not able to degrade Poly R-478, whereas crystal violet reached a degradation of 40% in 2 h.     

Degradation of azo dyes using low iron concentration of Fenton and Fenton-like system

This study investigated Fenton and Fenton-like reactions at low iron concentration (相似文献   

真菌对染料废水脱色降解的研究进展

染料属生物难降解有机物 ,染料和印染废水已成为当前最重要的水体污染源之一。本文列举了近年发现和研究的染料脱色真菌 ,并综述了真菌脱色降解染料的机理及其在染料废水处理中的应用前景     

Potential of immobilized bitter gourd (Momordica charantia) peroxidases in the decolorization and removal of textile dyes from polluted wastewater and dyeing effluent

Immobilized peroxidases from Momordica charantia were highly effective in decolorizing reactive textile dyes compared to its soluble counterpart. Dye solutions, 50-200 mg/l, were treated with soluble and immobilized bitter gourd peroxidases (specific activity of 99.0 EU per mg protein). The decolorization of dyes with soluble and immobilized enzyme was maximum in the range of pH 3.0-4.0. The effect of different temperatures on the dye decolorization was monitored and it was observed that all the dyes were maximally decolorized at 40 degrees C. In order to examine the operational stability of the immobilized preparation, the enzyme was repeatedly exploited for the decolorization of the dyes from fresh batch of dye solutions. Even after 10 cycles in each case the immobilized preparation retained nearly 50% of the initial enzyme activity. The immobilized enzyme exhibited more than 90% of the original activity while the soluble enzyme lost 33% of the initial activity when stored for 40 d at room temperature. Mixtures of three, four and eight dyes were prepared and treated with soluble and immobilized bitter gourd peroxidase. Each mixture was decolorized by more than 80% when treated with immobilized enzyme. Dyeing effluent collected from local dyers was treated with both types of enzyme preparations. Immobilized enzyme was capable of removing remarkably high concentration of color from the effluent. TOC content of soluble and immobilized enzyme treated individual dyes, mixture of dyes and dyeing effluent was determined and it was observed that higher TOC was removed after treatment with immobilized enzyme.