Environmental biotechnology最新文献_第2页

Phytoremediation techniques of wastewater treatment 废水处理中的植物修复技术

Environmental biotechnology

Pub Date : 2015-01-01 DOI: 10.14799/EBMS249

M. Materac, A. Wyrwicka, E. Sobiecka

Heavy Metals in the Environment: Origin, Interaction and RemediationWastewater Engineering: Advanced Wastewater Treatment SystemsAdvances in Bioremediation and Phytoremediation for Sustainable Soil ManagementPhytoremediation: Role of Aquatic Plants in Environmental CleanUpEmerging Eco-friendly Green Technologies for Wastewater TreatmentBioremediation: Applications for Environmental Protection and ManagementHeavy Metals In The EnvironmentMethods for Bioremediation of Water and Wastewater PollutionEnvironmental Risk Assessment of Soil ContaminationRemoval of Refractory Pollutants from Wastewater Treatment PlantsPhysico-Chemical Wastewater Treatment and Resource RecoverySynergistic Application of a Municipal Waste Material and Phytoremediation Technique for Remediating Acid Mine Drainage and Impacted SoilPlant Ecophysiology and Adaptation under Climate Change: Mechanisms and Perspectives IIPhytoremediationRemoval of Refractory Pollutants from Wastewater Treatment PlantsSoil BioremediationCost Effective Technologies for Solid Waste and Wastewater TreatmentHandbook of Engineering Hydrology (Three-Volume Set)An Integration of Phycoremediation Processes in Wastewater TreatmentDevelopment in Wastewater Treatment Research and ProcessesPhytoremediationHandbook of Research on Microbial Tools for Environmental Waste ManagementRecent Advancements in Bioremediation of Metal ContaminantsEmerging and Eco-Friendly Approaches for Waste ManagementThe Role of Phytoremediation in Remediation of Industrial WastePhytoremediation Technology for the Removal of Heavy Metals and Other Contaminants from Soil and WaterPhytoremediationEcological Assessment of Wastewater Treatment TechnologiesSOUVENIR of 4th International Science CongressGreen Materials for Wastewater TreatmentBioremediation and Green TechnologiesWastewater Treatment EngineeringPhytoremediation of Contaminated Soil and WaterContamination of WaterApplication of Microalgae in Wastewater TreatmentNew Trends in Removal of Heavy Metals from Industrial WastewaterWastewater TreatmentAdvanced Treatment Techniques for Industrial WastewaterIntroduction to PhytoremediationPhytoremediation

环境中的重金属:来源、相互作用和修复;废水工程;先进的废水处理系统;生物修复和植物修复在可持续土壤管理中的进展;植物修复;水生植物在环境清洁中的作用;新兴的环保绿色废水处理技术;生物修复;环境保护与管理的应用环境中重金属污染的生物修复水、废水污染的方法土壤污染的环境风险评价废水处理厂难降解污染物的去除废水的理化处理与资源回收城市废弃物与植物修复技术协同应用修复酸性矿井排水和受影响土壤植物生态生理与适应气候变化:机制和前景植物修复废水处理厂难降解污染物的去除土壤生物修复固体废物和废水处理的成本效益技术工程水文学手册(三卷集)废水处理中植物修复过程的整合废水处理研究和过程的发展植物修复环境废物管理微生物工具研究手册植物修复技术在土壤和水体中重金属和其他污染物去除中的应用植物修复技术废水处理技术的生态评价第四届国际科学大会纪念文集废水处理绿色材料生物修复和绿色技术废水处理微藻在废水处理中的应用工业废水中重金属去除的新趋势工业废水高级处理技术植物修复介绍植物修复

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引用次数: 22

Toxicity analysis of coke wastewater treated in a rotating biological contactor and a membrane bioreactor 旋转生物接触器和膜生物反应器处理焦炭废水的毒性分析

Environmental biotechnology

Pub Date : 2015-01-01 DOI: 10.14799/EBMS252

M. Tomaszewski, Karina Pypeć, A. Zgórska, A. Ziembińska-Buczyńska

To investigate the effectiveness of a rotating biological contactor (RBC) and a two-stage membrane bioreactor (MBR) for the treatment of coke wastewater, samples were collected three times (Batches I, II, III) from the “Jadwiga” coke plant in Zabrze, Poland at two-week intervals. The wastewater was then diluted with tap water (1:3 ratio, wastewater: tap water) and then treated at retention times of 4.1 days (RBC) and 7 days (MBR). For phytotoxicity and genotoxicity tests, the wastewater was sampled from various points in the treatment systems and further diluted to produce a range of concentrations. In the phytotoxicity tests (growth inhibition), Lemna minor and Vicia faba were used. A low concentration of wastewater (6.25%) often stimulated growth. © UNIVERSITY OF WARMIA AND MAZURY IN OLSZTYN ABBREVIATIONS CA chromosome aberration EC50 half maximal effective concentration Embr effluent, after wastewater treatment in MBR Erbc effluent, after wastewater treatment in RBC Fmbr flow between two units of MBR reactor INF influent, wastewater after preliminary treatment, diluted four times with tap water before biological treatment MBR two-stage membrane bioreactor

为了研究旋转生物接触器(RBC)和两级膜生物反应器(MBR)处理焦炭废水的有效性，我们从波兰Zabrze的“Jadwiga”焦炭厂每隔两周采集三次样品(第1、2、3批)。用自来水稀释废水(1:3，废水:自来水)，停留时间分别为4.1 d (RBC)和7 d (MBR)。对于植物毒性和遗传毒性测试，从处理系统的不同点取样废水，并进一步稀释以产生一系列浓度。在植物毒性试验(生长抑制)中，采用小叶菜和蚕豆。低浓度的废水(6.25%)经常刺激生长。©瓦姆比亚和马祖里大学IN OLSZTYN缩写CA染色体畸变EC50一半最大有效浓度Embr出水，废水处理后在MBR Erbc出水，废水处理后在RBC Fmbr两个单元之间流入MBR反应器，废水经过初步处理，用自来水稀释四倍后再进行MBR两级膜生物反应器的生物处理

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引用次数: 2

Surface tension technique as a strategy to evaluate the adsorption of biosurfactants used in soil remediation 以表面张力技术评价生物表面活性剂在土壤修复中的吸附作用

Environmental biotechnology

Pub Date : 2015-01-01 DOI: 10.14799/EBMS267

Z. Gusiatin

This study investigated the adsorption of two biosurfactants, non‐ionic saponin and anionic Reco-10 (a mixture of rhamnolipids). The experiments were performed with three different soils (sandy clay loam, clay loam, clay) and at two soil/biosurfactant ratios, m/V=1/10 and 1/40. Using a tensiometer, surface tension in aqueous biosurfactant solutions and their supernatants was measured and the critical micelle concentration © UNIVERSITY OF WARMIA AND MAZURY IN OLSZTYN INTRODUCTION Surfactants are amphiphilic compounds (containing hydrophobic and hydrophilic portions) that reduce the free energy of a system by replacing bulk molecules of higher energy at an interface (Mulligan 2005). Due to their ability to lower surface/interfacial tension, and to increase solubility, detergency power, wetting ability and foaming capacity, surfactants have a wide range of applications in many fields, such as the petroleum or pharmaceutical industries. In addition, surfactants monomers aggregate in micelles at a specific concentration, which not only reduces surface and interfacial tension, but also facilitates the desorption of pollutants and increases their bioavailability in soils or sediments. These properties mean that surfactants can be used in many surfactant-enhanced remediation systems like soil washing (Mao et al. 2015; Mulligan 2009), electrokinetic processes (Saichek and Reddy 2005), phytoremediation (Liu et al. 2013) and bioremediation (Pacwa-Plociniczak et al. 2011). Up to now, different ionic (anionic, cationic) and non-ionic surfactants have been tested for soil remediation. Anionic synthetic surfactants that have been tested include sodium dodecyl sulphate (SDS), bis(2-ethylhexyl) sulfosuccinate sodium (AOT) and linear sodium alkene sulfonates (Spolapon AOS). As a cationic surfactant, cetyltrialkyl ammonium bromide (CTAB) has been used. In contrast to ionic surfactants, nonionic surfactants have lower toxicity and greater capacity to solubilize contaminants, so they are more commonly used in remediation projects than ionic (Zheng et al. 2012). Although ionic surfactants are highly efficient at removing various pollutants 28 ENVIRONMENTAL BIOTECHNOLOGY 11 (2) 2015 such as PCBs, petroleum,NAPLs andBTEX, their toxicity can limit their usefulness (Mao et al. 2015). Currently, biosurfactants appear more attractive than synthetic surfactants for surfactant-based soil remediation. Biosurfactants are natural surface active agents produced by bacteria, fungi and yeast, or extracted from plants (Paria 2008). They have a larger molecular structure and more functional groups than synthetic surfactants, which enables them to remove both hydrophobic organics and heavy metals. The biosurfactants commonly used in soil remediation are anionic rhamnolipids secreted by Pseudomonas aeruginosa (Juwarkar et al. 2007; Muligan 2009) and non-ionic saponin of plant origin (Hong et al. 2002). Biosurfactants differ in their properties and can behave in soil in different ways.

本研究考察了两种生物表面活性剂——非离子皂素和阴离子recoo -10(鼠李糖脂混合物)的吸附作用。试验在3种不同土壤(砂质粘土壤土、粘土壤土、粘土)和2种土壤/生物表面活性剂比(m/V=1/10和1/40)下进行。使用张力计，测量了生物表面活性剂水溶液及其上清液的表面张力和临界胶束浓度©瓦姆瓦大学和马佐里在OLSZTYN介绍表面活性剂是两亲性化合物(包含疏水和亲水部分)，通过取代界面上高能量的大块分子来降低系统的自由能(Mulligan 2005)。由于表面活性剂具有降低表面/界面张力、提高溶解度、清洁能力、润湿能力和发泡能力的能力，因此在石油或制药工业等许多领域有着广泛的应用。此外，表面活性剂单体在特定浓度的胶束中聚集，不仅可以降低表面和界面张力，还可以促进污染物的解吸，提高其在土壤或沉积物中的生物利用度。Mulligan 2009)、电动过程(Saichek and Reddy 2005)、植物修复(Liu et al. 2013)和生物修复(Pacwa-Plociniczak et al. 2011)。迄今为止，已经对不同的离子(阴离子、阳离子)和非离子表面活性剂进行了土壤修复试验。已测试的阴离子合成表面活性剂包括十二烷基硫酸钠(SDS)、双(2-乙基己基)磺基琥珀酸钠(AOT)和线性烯烃磺酸钠(Spolapon AOS)。十六烷基三烷基溴化铵(CTAB)是一种阳离子表面活性剂。与离子表面活性剂相比，非离子表面活性剂毒性更低，对污染物的溶解能力更强，因此在修复项目中比离子表面活性剂更常用(Zheng et al. 2012)。目前，生物表面活性剂比合成表面活性剂在表面活性剂基土壤修复中更具吸引力。生物表面活性剂是由细菌、真菌和酵母产生或从植物中提取的天然表面活性剂(Paria 2008)。它们比合成表面活性剂具有更大的分子结构和更多的官能团，这使它们能够去除疏水有机物和重金属。土壤修复中常用的生物表面活性剂是铜绿假单胞菌分泌的阴离子鼠李糖脂(Juwarkar et al. 2007;Muligan 2009)和植物来源的非离子皂素(Hong et al. 2002)。生物表面活性剂的性质不同，在土壤中表现出不同的特性。虽然生物表面活性剂对环境的影响很小，处理后可以留在土壤中(Wouter et al. 2004)，但它们的吸附会降低表面活性剂修复土壤的效率。它们的吸附程度主要取决于土壤性质，即其有机碳含量和阳离子交换能力，以及表面活性剂的化学性质。阴离子表面活性剂的吸附通常比非离子表面活性剂少，比阳离子表面活性剂少得多(Lee et al. 2004)。由于表面活性剂被吸附到土壤上，可以增加土壤的疏水性，并且以前去除的污染物，特别是有机污染物可以重新吸附在土壤表面(Paria 2008)。在许多修复项目中，生物表面活性剂的浓度是基于临界胶束浓度(CMC)来选择的(Zhang et al. 2011)。如果吸附程度很大，表面活性剂浓度会降到CMC以下，污染物不会被溶解(Chu 2003)。因此，在选择适合土壤修复的生物表面活性剂浓度之前，应先测定土壤-表面活性剂溶液体系中的CMC。为了确定生物表面活性剂的吸附，有一些基于测量选定表面活性剂性质的方法，即表面张力、吸光度或化学需氧量(COD) (Liu et al. 1992)。然而，基于吸光度或COD测量的方法可能会有问题，因为从土壤中释放的化合物会影响提取物的颜色和有机物的浓度。因此，表面活性剂的吸附可能被高估了。Zhou et al.(2013)证实，经过土壤吸附实验后，用紫外光谱法难以准确定量地测定水溶液中皂素的总浓度。因此，使用测量表面张力的方法似乎更合适。虽然各种合成表面活性剂的吸附已经被确定，但对生物表面活性剂在土壤上的吸附，特别是植物生物表面活性剂的吸附却知之甚少。因此，本研究的目的是利用表面张力技术确定两种市售生物表面活性剂(皂素和鼠李糖脂)在其CMC上的吸附。实验在三种不同性质的土壤和两种土壤与生物表面活性剂溶液的比例下进行。材料与方法生物表面活性剂采用两种不同的生物表面活性剂。化学纯皂素(产品号16109)，一种非离子型植物源性生物表面活性剂，购自瑞士RiedeldeHaën。皂苷是一种酸性生物表面活性剂(pH为4.5-5.5)，在20℃(5% H2O)条件下浓度为1.015-1.020g·mL-1。它是从皂荚树的树皮中提取的三萜苷的混合物，其亲水部分由带官能团的糖链组成。Purum皂苷的碳(C)含量为42.3%，氢(H)含量为6.2%，氮(N)含量为0.2%，氧(O)含量为51.3%。recoo -10为RLL (R1, C26H48O9)和RRLL (R2, C32H58O13)两种主要鼠李糖脂的10%混合物，购自美国Jeneil生物表面活性剂有限责任公司。从化学上讲，鼠李糖脂是鼠李糖(6-脱氧甘露糖)和对羟基癸酸的糖苷。鼠李糖脂是从经过灭菌和离心的发酵液中生产出来的。市售产品为深棕色溶液。与皂苷相比，鼠李糖脂的pH值在6 ~ 7之间。两种生物表面活性剂的化学结构如图1所示。从波兰瓦姆尼亚和马祖里省不同地点采集了3种土壤:砂质粘土壤土SCL-B (Baranowo)、粘土壤土CL-W (wangty)和粘土C-W (Wiktorowo)。土壤被风干并磨碎，通过1毫米的筛子。土壤的理化性质如表1所示。为了测定生物表面活性剂在土壤上的吸附，用kr<s:1> ss K100型张力计，采用威廉平板法测定了浓度为1 ~ 10 000mg·L-1的新鲜生物表面活性剂溶液的表面张力。然后，每种给定浓度的生物表面活性剂溶液与土壤(SCL-B, CLW, C-W)在旋转振动筛上以土壤/生物表面活性剂比为1/10和1/40 (m/V)在150 rpm下振荡24小时。上清液8000 rpm离心1h，过滤后再次测定表面张力。绘制表面张力值与表面活性剂浓度的对数关系图。根据实验数据求得的两条回归线的交点即为临界胶束浓度。CMC是表面活性剂的最低水溶液浓度，溶液的表面张力显示出最小的张力(Urum和Pekdemir 2004)。在临界胶束浓度下，生物表面活性剂吸附在土壤上的量采用下式计算(Zheng and Obbard 2002):土壤的物理化学特性。

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引用次数: 4

Selection of optimal spawner‑pairs based on the polymorphism of microsatellite loci in a partially‑tetraploid fish species (Coregonus lavaretus) 基于微卫星位点多态性的部分四倍体鱼最佳产卵对选择

Environmental biotechnology

Pub Date : 2015-01-01 DOI: 10.14799/EBMS255

D. Kaczmarczyk, D. Fopp‐Bayat, A. Wiśniewska

how to adapt this technique to the selection of spawner pairs for restocking populations of partially tetraploid fish species. To test our calculation techniques, we used actual data on the polymorphism of the loci of captured whitefish (Coregonus lavaretus). The data enabled calculations showing which spawner pairs would create the most genetically diverse cohort of offspring if they were bred. The method presented in the paper can be used for breeding fish in aquaculture conditions to help conserve species. Selection of optimal spawner‐pairs based on the polymorphism of microsatellite loci in a partially‐tetraploid fish species (Coregonus lavaretus)

如何将此技术应用于部分四倍体鱼类种群再放养时产卵对的选择。为了验证我们的计算方法，我们使用了捕获白鱼(Coregonus lavaretus)基因座多态性的实际数据。这些数据可以用来计算，如果繁殖的话，哪一对产卵者会产生最具基因多样性的后代。本文提出的方法可以用于养殖条件下的鱼类繁殖，以帮助保护物种。基于微卫星位点多态性的部分四倍体鱼最佳产卵对选择

引用次数: 0

Application of by-products and waste in the synthesis of nanosilver particles 副产物和废料在纳米银粒子合成中的应用

Environmental biotechnology

Pub Date : 2015-01-01 DOI: 10.14799/EBMS257

B. Trepanowska, Michał Łuczyński, S. Kulesza, M. Adamczak

Energy dispersive X-ray spectroscopy showed that elements that typically stabilize nanoparticles were present. The well diffusion method (nutrient agar medium) indicated that AgNP synthesized with raspberry leaf extract exerted strong bacteriostatic and bactericidal activity against Gram-negative bacteria and weaker activity against Gram-positive bacteria. Although further analysis is needed to determine the mechanism of their synthesis, the results of this study show that plant-extract based synthesis can produce nanoparticles with controlled size and morphology. Application of by-products and waste in the synthesis of

能量色散x射线光谱显示，典型的稳定纳米粒子的元素存在。孔扩散法(营养琼脂培养基)表明，覆盆子叶提取物合成的AgNP对革兰氏阴性菌具有较强的抑菌和杀菌活性，对革兰氏阳性菌的抑菌和杀菌活性较弱。虽然需要进一步的分析来确定它们的合成机制，但本研究的结果表明，基于植物提取物的合成可以产生具有控制大小和形态的纳米颗粒。副产物及废弃物在合成中的应用

引用次数: 2

Substrate influence on the structure of methanogenic Archaea communities during anaerobic digestion 厌氧消化过程中底物对产甲烷古菌群落结构的影响

Environmental biotechnology

Pub Date : 2015-01-01 DOI: 10.14799/EBMS264

D. Dąbrowska, K. Bułkowska, S. Ciesielski

This study compares the diversity of methanogenic archaeal communities that developed during biogas production in reactors fed with different substrates. Reactor I was fed with silages of maize and of alfalfa and timothy; and Reactor II was fed with these silages plus pig slurry and glycerol as co‐substrates. The archaeal community structure was studied using polymerase chain reaction–denaturing gradient gel © UNIVERSITY OF WARMIA AND MAZURY IN OLSZTYN IN TRO DUC TION Methane fermentation has recently been a subject of much interest because methane is a renewable energy source and fermentation provides a way to utilize waste. For better methane production, the process parameters can be adjusted for the specific waste product being used as a substrate, and co-substrates can be added. In this way, greater process stability can be achieved, and the quantity and methane content of biogas can be increased (Bułkowska et al. 2012). Although it is known that the Archaea are one of the groups of microorganisms that perform methane fermentation, their community structure and diversity are poorly understood, as is the effect of conditions in the bioreactor on these community characteristics (Ciesielski et al. 2013). For example, the choice of feedstock can affect these characteristics (Ziganshin et al. 2013). The feedstock that is chosen can come from a variety of industries, and its choice can depend on the availability of raw materials. Although in Europe, the materials most commonly used in biogas production are plant-based, some animal-derived organic wastes and other organic wastes are also used, such as pig slurry or glycerol from the biodiesel industry (Hijazi et al. 2016). The effect on biogas production of addition of substrates that are not plant-based has been investigated (Bułkowska et al. 2012). However, little is known about how the diversity of the archaeal community is affected when glycerol and pig slurry are added as co-substrates to plantbased substrates. 42 ENVIRONMENTAL BIOTECHNOLOGY 11 (2) 2015 column was then centrifuged for 1 minute at high speed before the filtrate was poured out and washed twice with A1 solution (A&A Biotechnology). The DNA was then suspended in 50μL of water and stored at -20°C until further analysis. Polymerase chain reaction Genomic DNA was amplified using polymerase chain reaction (PCR). The gene fragment encoding for 16S rRNA was amplified using a pair of primers (GC-0357F-5’ CGCCCGCCGCGCCCCGCGCCCGTCCCGCCGCCCC CGCCCGCCCTACGGGGCGCAGCAG 3’; 0691R-5’ GG ATTACATGATTTCAC 3’) (Watanabe et al. 2004). The amplified fragments measured approximately 500bp. The PCR mix (30μL per reaction) was composed of 3μL of 10×PCR buffer, 2.4μL MgCl2 (25mM), 1.3μL of dNTPs (200μM final concentration), 0.15μL Taq polymerase (2 U·1μL-1·reaction-1), 0.5μL of each primer (20pmol), 18.15μL of dH2O and 1μL of genomic DNA. Reactions were performed in 0.5mL DNA-free PCR tubes using a thermocycler, and the PCR steps were as follows: denaturat

本研究比较了不同基质反应器产气过程中产生的产甲烷古菌群落的多样性。一号反应器用玉米、苜蓿和提摩西青贮饲料饲喂;反应器II用这些青贮饲料加猪浆和甘油作为共底物。利用聚合酶链反应-变性梯度凝胶研究古细菌群落结构©瓦姆尼亚和马祖里大学IN OLSZTYN IN TRO DUC生产甲烷发酵最近成为一个非常感兴趣的主题，因为甲烷是一种可再生能源，发酵提供了一种利用废物的方法。为了更好地生产甲烷，可以根据用作底物的特定废物调整工艺参数，并可以添加辅助底物。这样可以获得更大的工艺稳定性，并可以增加沼气的数量和甲烷含量(Bułkowska et al. 2012)。虽然已知古生菌是进行甲烷发酵的微生物群之一，但人们对其群落结构和多样性知之甚少，生物反应器条件对这些群落特征的影响也是如此(Ciesielski et al. 2013)。例如，原料的选择会影响这些特性(Ziganshin et al. 2013)。所选择的原料可以来自各种行业，其选择可以取决于原材料的可用性。虽然在欧洲，沼气生产中最常用的材料是植物性的，但也使用一些动物来源的有机废物和其他有机废物，例如来自生物柴油行业的猪浆或甘油(Hijazi et al. 2016)。已经研究了添加非植物基基质对沼气生产的影响(Bułkowska等人，2012)。然而，当甘油和猪浆作为共底物添加到植物基底物中时，古细菌群落的多样性是如何受到影响的，人们知之甚少。42 ENVIRONMENTAL BIOTECHNOLOGY 11(2) 2015柱高速离心1分钟后，倒出滤液，用A1溶液(A&A BIOTECHNOLOGY)洗涤2次。将DNA悬浮于50μL水中，-20℃保存，待进一步分析。采用聚合酶链反应(PCR)扩增基因组DNA。编码16S rRNA的基因片段使用一对引物(GC-0357F-5’cgcccgccgcgccccgcgcccccccccccccccccccgccccccctacggggcgcagcag 3’;0691R-5 ' GG ATTACATGATTTCAC 3 ') (Watanabe et al. 2004)。扩增片段的测量值约为500bp。PCR混合物(每反应30μL)由3μL 10×PCR缓冲液、2.4μL MgCl2 (25mM)、1.3μL dNTPs(终浓度200μM)、0.15μL Taq聚合酶(2 μ U·1μL-1·reaction-1)、0.5μL每个引物(20pmol)、18.15μL dH2O和1μL基因组DNA组成。用热循环仪在0.5mL无dna PCR管中进行反应，PCR步骤如下:94℃变性10min, 94℃变性1min，初始循环30个循环，54℃退火1min，每个循环后延长2秒，72℃延长1min。完成后，在72°C下进行额外延长步骤10min，然后将样品冷却至4°C。在1%琼脂糖凝胶上验证PCR产物的长度，用溴化乙啶染色，在紫外光下观察和拍照。变性梯度凝胶电泳(DGGE) PCR产物用GC钳在6%聚丙烯酰胺凝胶(37.5:1丙烯酰胺:双丙烯酰胺)中分离，梯度范围为30 - 60%尿素。采用DCodeTM通用突变检测系统(Bio-Rad Laboratories Inc.， usa)，在1 × tae缓冲液(2M Tris碱基，2M乙酸，0.05M EDTA)中，在60V下电泳12h。用1:10 000 SybrGold (Invitrogen)染色20分钟，然后紫外透照，可见凝胶中溶解的DNA混合物。使用KODAK 1D 3.6图像分析软件记录和分析图像。

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引用次数: 2

Dichlorodiphenyldichloroethylene (DDE) residue limit exceeded in pig tissues after feed-borne exposure to maximum allowed concentration 二氯二苯二氯乙烯(DDE)的最大允许浓度暴露后，猪组织中残留限量超过

Environmental biotechnology

Pub Date : 2015-01-01 DOI: 10.14799/EBMS242

M. Woźny, E. Jakimiuk, P. Brzuzan, M. Florczyk, A. Niewiadowska, K. Obremski, M. Gajęcka, J. Młynarczuk, M. Gajęcki

Monitoring of undesirable substances by the European Union indicates a presence of natural and anthropogenic pollutants in animal feed that may be of concern for the producers, as well as the veterinary services. Although the literature concerning toxicity of DDT (an insecticide widely used in the past) is extensive, less attention has been focused on the biological properties of DDE and its interactions with other contaminants. This study reports on the concentration profile of p,p’-DDE and two other ogranochlorines (p,p’-DDT, p,p’-DDD) in different tissues of immature gilts after 14, 28, and 42 days of oral exposure to p,p’-DDE alone (0.5mg·kg-1feed·day-1) and in mixture with naturally occurring mycotoxin zearalenone, ZEN (0.5+0.1mg·kg-1feed·day-1). The treatment resulted in a time© UNIVERSITY OF WARMIA AND MAZURY IN OLSZTYN INTRODUCTION Dichlorodiphenyltrichloroethane (DDT) is an organochlorine pesticide, used worldwide in the past to control insect vectors of infectious diseases (Rogan and Chen 2005). DDTwas also used as an insecticide to protect crops, including Poland, before it was banned in most countries in the 1970’s for its negative effects on humans, wildlife, and the environment. Despite the ban, this insecticide is still used as a cost-effective method to prevent malaria in some tropical regions (Bettinetti et al. 2011). DDT is a highly persistent pollutant. In the environment, it may last for many years, as it is slowly biodegraded to DDE (dichlorodiphenyltrichloroethylene) and DDD (dichlorodiphenyldichloroethane) in processes generally driven by the action of microorganisms in the soil (ATSDR 2002). Common and intensive use of DDT has resulted in worldwide pollution with this compound. It has been found in organisms living in deserts as well as in the depths of oceans (Turusov et al. 2002). Since the times of DDT extensive use, its residual levels in the environment have greatly declined. 2 ENVIRONMENTAL BIOTECHNOLOGY 11 (1) 2015 However, due to its persistence, the pesticide will be present at low concentrations for decades (Glynn et al. 2009; NTP 2011). Current human exposure to DDT and its metabolites is known to occur mainly through dietary intake, particularly consumption of contaminated fish or meat (ATSDR 2002; NTP 2011). Technical grade DDT is a mixture of different isomers: approximately 85% of the p,p-DDT isomer with o,p’-DDT and o,o’-DDT present in lesser amounts (ATSDR 2002). In mammals, the p,p’-DDT isomer is metabolized mainly to p,p’-DDE and p,p’-DDD by the microsomal cytochrome P450 system (Kitamura et al. 2002). Due to their high lipophilic properties (p,p’-DDD

欧盟对不良物质的监测表明，动物饲料中存在可能引起生产者和兽医服务关注的自然和人为污染物。虽然关于滴滴涕(过去广泛使用的一种杀虫剂)毒性的文献很多，但很少关注滴滴涕的生物学特性及其与其他污染物的相互作用。本研究报告了p,p ' -DDE和另外两种氯(p,p ' -DDT, p,p ' -DDD)在未成熟后备母猪单独(0.5mg·kg-1饲料·d -1)和与天然真菌毒素玉米赤霉烯酮(0.5+0.1mg·kg-1饲料·d -1)混合暴露14、28和42天后在不同组织中的浓度分布。这一处理导致了一段时间©瓦姆尼亚和马祖里大学in OLSZTYN介绍二氯二苯三氯乙烷(DDT)是一种有机氯农药，过去在世界范围内用于控制传染病的昆虫媒介(Rogan和Chen, 2005年)。二十世纪七十年代，ddt被大多数国家禁止使用，因为它对人类、野生动物和环境有负面影响。在此之前，ddt也被用作保护作物的杀虫剂，包括波兰。尽管有禁令，但在一些热带地区，这种杀虫剂仍被用作一种成本效益高的预防疟疾方法(Bettinetti et al. 2011)。滴滴涕是一种持久性很强的污染物。在环境中，它可能持续多年，因为它在通常由土壤中微生物作用驱动的过程中缓慢地生物降解为DDE(二氯二苯三氯乙烯)和DDD(二氯二苯二氯乙烷)(ATSDR 2002)。滴滴涕的普遍和密集使用已导致这种化合物在世界范围内造成污染。人们在生活在沙漠和海洋深处的生物体中发现了它(Turusov等人，2002年)。自DDT被广泛使用以来，其在环境中的残留水平已大大下降。然而，由于其持久性，该农药将以低浓度存在数十年(Glynn et al. 2009;2011年国家结核控制规划)。已知目前人类接触滴滴涕及其代谢物主要是通过饮食摄入，特别是食用受污染的鱼或肉(毒物特别提款权，2002年;2011年国家结核控制规划)。技术级滴滴涕是不同异构体的混合物:大约85%的p,p-滴滴涕异构体含有少量的o,p ' -滴滴涕和o,o ' -滴滴涕(ATSDR, 2002年)。在哺乳动物中，p,p ' -DDT异构体主要通过微粒体细胞色素P450系统代谢为p,p ' -DDE和p,p ' -DDD (Kitamura et al. 2002)。由于它们的高亲脂性(p,p ' -DDD<p,p ' -DDT<p,p ' -DDE)，这些化合物一旦被吸收并按组织脂质含量的比例储存在体内，就很容易分布到体内;它们离开身体的速度很慢。这种生物积累导致高营养水平的化合物浓度增加(ASTDR 2002)。关于滴滴涕及其代谢物的生物学特性的文献非常广泛，对其对动物生殖系统发育和功能的不利影响也引起了相当大的关注。研究表明，这些化合物与核受体结合后具有调节内分泌功能和影响基因表达的能力。例如，p,p ' -滴滴涕是一种结合雌激素受体并诱导雌激素效应的环境雌激素，而p,p ' -DDE已被证明是一种弱雌激素受体激动剂，但是一种强雄激素受体拮抗剂(Kelce等人，1995)。在一项对胎鼠的研究中，暴露于p,p ' -DDE导致出生时肛门生殖器距离缩短，并在出生后保留胸乳头，这表明抗雄激素活性(Kelce etal . 1995)。波兰是欧盟重要的猪肉生产国。除了牛之外，家猪(Sus scrofa)是波兰农场牲畜生产中最受欢迎的品种(CSO 2011)。与不明原因的生殖系统功能障碍相关的健康问题通常被认为是导致动物生产成本增加的重要因素。据信，接触各种内分泌干扰化合物(EDCs)的消化道途径，包括天然的(如真菌毒素)和/或人为来源的(如杀虫剂)，可能是生殖器官疾病发生的原因。此外，后备母猪特别容易受到EDCs激素模拟作用的影响(Jakimiuk et al. 2009)。在立法中，这些动物通常被视为哨兵物种，饲料中不良物质的限制最低(例如PMARD 2012)。对动物饲料材料中不良物质的监测表明，污染物普遍存在，包括滴滴涕及其代谢物(Nag和Raikwar, 2011年)。由于禁止在饲料生产中使用肉骨粉，鱼粉已被引入作为动物蛋白质和脂肪的来源(Weiner et al. 2012)。 25μm电影thic

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引用次数: 0

American funding for biofuel/biorefinery research and development 美国对生物燃料/生物炼制研究和发展的资助

Environmental biotechnology

Pub Date : 2014-01-01 DOI: 10.14799/EBMS243

D. Gallinaro

引用次数: 2

Biomass from field crop production as an energy source and a new activity area for economic operators at the local level 从田间作物生产中获得的生物质作为一种能源和地方经济经营者的新活动领域

Environmental biotechnology

Pub Date : 2014-01-01 DOI: 10.14799/EBMS225

Z. Brodziński, K. Kurowska, Hubert Kryszk

derived from RES is favourable for both reduction of pollutant emissions to the atmosphere and water, and reduction of the volume of waste generated. This paper identifies the potential of biomass production for energy purposes in the region of Warmia and Mazury (Poland), which could be a key action for sustainable development of rural areas and investment activity. Biomass from field crop production as an energy source

从可再生能源中提取的可再生能源有利于减少向大气和水排放的污染物，并减少产生的废物量。本文确定了瓦姆尼亚和马祖里(波兰)地区用于能源目的的生物质生产的潜力，这可能是农村地区可持续发展和投资活动的关键行动。从田间作物生产中获得的生物质作为能源来源

引用次数: 1

Tannic acid as a cost ‑effective substitute for saponin in soil remediation 单宁酸作为皂苷在土壤修复中的成本效益替代品

Environmental biotechnology

Pub Date : 2014-01-01 DOI: 10.14799/EBMS240

Z. Gusiatin, K. Bułkowska, T. Pokój

The efficiency of soil washing with tannic acid (TA) and saponin (SAP) was compared. In the contaminated soil, Cu and Zn were more mobile than Pb. At 3% concentration, both biosurfactants removed similar amounts of Zn (48 and 54%, respectively), SAP removed somewhat more Cu (81%), and TA removed considerably more Pb (63%). SAP removed more Cu due to its

比较了单宁酸(TA)和皂苷(SAP)的洗土效果。在污染土壤中，Cu和Zn的流动性大于Pb。在3%的浓度下，两种生物表面活性剂对Zn的去除率相近(分别为48%和54%)，SAP对Cu的去除率略高(81%)，TA对Pb的去除率相当高(63%)。SAP移除了更多的Cu

引用次数: 16

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