纳米氧化铜颗粒和环丙沙星对好氧颗粒污泥的协同胁迫效应

纳米颗粒和抗生素在污水处理厂中的共同存在可产生综合毒性.选择纳米氧化铜颗粒(CuO NPs)和环丙沙星(CIP)作为纳米颗粒和抗生素的代表性物质,探究了CuO NPs和CIP共存胁迫对好氧颗粒污泥(AGS)系统的运行性能、污泥特性和微生物群落的长期影响.结果表明:CuO NPs单独胁迫使脱氮性能轻微提高,对碳和磷的去除性能轻微下降.CIP单独胁迫显著抑制了碳、氮和磷的去除性能.CuO NPs和CIP共存时对碳、氮和磷去除表现出明显的协同抑制效应.CuO NPs和CIP共存胁迫使细胞膜完整性下降,乳酸脱氢酶(LDH)释放量增多,胞外聚合物(EPS)分泌增强,且溶解性EPS(S-EPS)的官能团发生显著变化.CuO NPs和CIP共存胁迫改变了微生物群落结构,对生物多样性具有显著的协同抑制效应,对微生物具有较强的毒性作用.

纳米氧化铜颗粒的绿色合成及其体外抗PRRSV效果研究

为了开发体外抗猪繁殖与呼吸综合征病毒(PRRSV)的新型药物,试验采用枇杷叶提取物经绿色合成途径制备纳米氧化铜颗粒,采用紫外-可见分光光度计、扫描电子显微镜、透射电子显微镜及X射线能谱分析对纳米氧化铜颗粒进行特征研究;采用MTT法测定其对细胞的毒性;采用3种不同的药物处理方式(暴露前预防、暴露后阻断、直接灭活)评估体外对PRRSV的抗病毒效果。结果表明:纳米氧化铜颗粒在波长265~285 nm处有最大吸收峰;在溶液中纳米氧化铜颗粒呈圆柱体,平均粒径为(7.64±0.88)nm,而呈粉末状态时纳米氧化铜颗粒更倾向于聚集在一起,形成团块,平均粒径为(139.94±22.99)nm;合成的纳米氧化铜颗粒主要含铜原子和氧原子,对细胞的最大安全浓度为0.3125 mg/mL,具有良好的生物安全性;纳米氧化铜颗粒在暴露前预防、暴露后阻断及直接杀灭3种不同药物处理方式下对细胞抵抗PRRSV的最高保护率分别为(46.07±5.53)%、(84.24±3.22)%及(89.78±10.84)%。说明试验成功合成纳米氧化铜颗粒,其对PRRSV的阻断和直接杀灭效果较强,具有良好的抗PRRSV效果。

2种方法测定氧化铜纳米颗粒对新生大鼠脑微血管内皮细胞毒性的比较研究

目的:比较实时细胞分析技术(RTCA)和刃天青法测定氧化铜纳米颗粒(CuO-NPs)对新生大鼠脑微血管内皮细胞(BMECs)的细胞毒性的异同。方法:采用RTCA法确定BMECs细胞毒性实验的最佳细胞接种数量及染毒时间。分别用1.5、0.75、0.38、0.19、0.09 mg/mL的CuO-NPs染毒BMECs,以无细胞的培养液为对照组(0 mg/mL),分别以RTCA法及刃天青法比较其细胞毒性。通过比较2种方法所获得的IC_(50)值判断2种毒性测试方法的相关性。结果:每孔2.5×10~3个细胞为BMECs最佳接种浓度,接种后40h为最佳染毒时间。RTCA检测结果表明1.5、0.75 mg/mL的CuO-NPs染毒BMECs后约2 h开始细胞活性降低,并在染毒4 h内全部死亡。通过刃天青法分别在染毒3、12、24、36、48 h进行测定,得到与RTCA相似的结果,即1.5和0.75 mg/mL组的细胞毒性最大,且CuO-NPs对BMECs的细胞毒性呈剂量依赖性趋势。相关性分析结果显示2种方法所获得IC_(50)值相关系数为0.999,P=0.000,具相关性。配对t检验结果显示,差异无统计学意义(t=1.125,P=0.323)。从计算IC_(50)的R^2值来看,RTCA拟合曲线法R^2值高于刃天青法R^2值。结论:CuO-NPs体外作用于BMECs具有剂量依赖性的细胞毒性,RTCA方法与刃天青法测定BMECs细胞毒性结果具有相关性,RTCA方法所得结果可能更为准确,更适合于CuO-NPs的细胞毒性研究。

纳米氧化铜对人肝癌细胞的毒性作用

目的探讨40 nm氧化铜颗粒对人肝癌HepG2细胞毒性的影响。方法将处于对数生长期的细胞分别暴露于含终浓度分别为0(对照)～200μg/ml纳米氧化铜的无血清培养基中培养24 h。运用CCK-8法和乳酸脱氢酶(LDH)检测分析其对人肝癌细胞的毒性作用。结果不同浓度纳米氧化铜染毒组HepG2细胞的存活率与对照组(0μg/ml)相比均明显降低(P<0.05),且细胞存活率随着纳米氧化铜染毒浓度的上升呈下降趋势;HepG2细胞LDH的活力与对照组(0μg/ml)相比也明显升高(P<0.01),且细胞中LDH活力随着纳米氧化铜染毒浓度升高呈上升趋势。结论 40 nm氧化铜颗粒能够引起HepG2细胞产生毒性效应。

铜及氧化铜纳米颗粒对浮萍、藻类的毒性效应及机理研究进展

由于大量的生产和使用,铜及氧化铜纳米颗粒不可避免地被排放到环境当中。水生植物属于生态系统的初级生产者,纳米颗粒对其造成的损伤及在其体内的积累很可能会通过食物链或食物网进行传递,从而威胁生态系统乃至人类健康。因此,本文就现有研究中铜及氧化铜纳米颗粒对2类重要水生植物(即浮萍、藻类)的毒性效应及致毒机理进行了总结。通过分析发现纳米颗粒的浓度、粒径以及暴露体系的pH值、溶解性有机质、温度和紫外线等环境因素均能影响铜及氧化铜纳米颗粒的毒性效应。据此提出今后相关研究中需更加关注水生植物对铜、氧化铜纳米颗粒及Cu^2+的吸收及积累情况,以及区分纳米颗粒本身及Cu^2+的毒性贡献的重要性,这有助于深入了解铜及氧化铜纳米颗粒对浮萍、藻类的致毒机理。

大豆根中GmPME7基因防御氧化铜纳米颗粒的功能验证

通过构建pCAMBIA3301-GmPME7载体,在大豆毛状根中超表达GmPME7基因,验证了该基因的功能。结果表明:氧化铜纳米颗粒(CuO NPs)处理后,与转入空载体的毛状根相比,转基因毛状根中的果胶甲酯酶(PME)活性逐渐增加,果胶甲酯化程度逐渐降低,2 mg/L CuO NPs处理48 h后的转基因毛状根中PME活性和果胶甲酯化程度分别为对照的1.23倍和0.69倍,说明GmPME7基因的功能可能是通过调控PME活性增加从而降低果胶甲酯化程度,来抵抗CuO NPs的胁迫。

氧化铜纳米粉体的制备新方法

首次以铝箔代替恒电位/电流仪惰性电极作为基体,采用辅助电极电沉积法成功制备了氧化铜纳米颗粒。用X射线衍射仪和透射电子显微镜对所制备的纳米粉体进行了表征,结果表明:氧化铜纳米颗粒为球形,粒径为50nm左右,颗粒大小均匀,形态稳定。并且与氧化还原法和研究电极电沉积法进行了比较。

纳米颗粒对人食管癌EC-9706、EC-109细胞增殖和凋亡的影响

目的研究氧化铜(CuO)、氧化锌(ZnO)、二氧化钛(TiO_2)纳米颗粒在体外对人食管鳞状癌细胞系EC-9706和EC-109增殖的影响及其部分作用机制。方法使用透射电镜(TEM)、动态光散射(DLS)鉴定纳米颗粒物的理化性质,然后将不同浓度的TiO_2、CuO、ZnO(5~80 mg·L^(-1))与体外培养的EC-9706和EC-109细胞孵育,四甲基偶氮唑盐(MTT)法检测细胞生长抑制率,流式细胞术(FCM)法检测细胞周期及凋亡率,Transwell小室法检测细胞侵袭能力,蛋白免疫印迹法检测细胞中Bcl-2和caspase-3蛋白表达情况。结果实验所用的纳米CuO、ZnO、TiO_2颗粒为球形,粒径分别为12、20.6、12 nm。在水中与细胞培养液中聚集成较大颗粒并带负电。随着纳米颗粒浓度的增加,纳米CuO和ZnO颗粒可剂量依赖性抑制食管鳞癌细胞的增殖,G_0/G_1期细胞的比率上调,G_2/M期的比率下降,并促进凋亡率增加,侵袭力下降;纳米颗粒处理48 h后,与对照组相比,活化caspase-3表达量明显升高,Bcl-2表达量明显下降(P<0.05)。纳米TiO_2颗粒对食管鳞癌细胞的增殖、凋亡和侵袭能力无明显的影响。结论与纳米TiO_2相比,一定浓度的CuO和ZnO纳米颗粒可有效抑制食管鳞癌细胞的生长,阻滞细胞周期于G_0/G_1期,并诱导其凋亡,这可能是其抑制食管癌细胞功能的作用机制之一。

氧化铜纳米颗粒对水稻幼苗根系代谢毒性的研究

为阐明氧化铜纳米颗粒(CuO NPs)暴露对植物生长的影响,分别用CuO NPs悬浮液、氧化铜大颗粒(CuO BPs)悬浮液和硫酸铜(CuSO4·5H2O)溶液进行处理,以蒸馏水(d H2O)作为对照,水培水稻幼苗,研究了CuO NPs对水稻幼苗根系相关生理生化行为的影响.结果表明,不同处理对水稻幼苗根系的影响有很大差异,经CuO NPs悬浮液处理后,水稻幼根受损较严重,根系活力明显降低,根内丙二醛(MDA)含量和过氧化氢(H2O2)含量显著升高,超氧化物歧化酶(SOD)和过氧化物酶(POD)活性明显增强.不同处理对水稻幼苗根的影响依次为:CuO NPs>CuSO4·5H2O>CuO BPs>d H2O.说明氧化铜纳米颗粒对水稻根的毒害作用不仅是由于释放离子引起的,纳米颗粒本身也起着重要作用,氧化损伤可能是CuO NPs的主要致毒机制之一.

氧化铜纳米颗粒(CuO NPs)对土壤环境因子与砷生物有效性的影响

氧化铜纳米颗粒(CuO NPs)可以通过农药和肥料施用、意外泄露或污水灌溉进入As污染农田土壤,从而对土壤环境因子和As生物有效性产生影响.本试验选取两种不同类型土壤(安徽宿松黄棕壤和黑龙江海伦黑土)进行人工As污染,添加不同浓度的CuO NPs,探究90 d淹水-落干过程中CuO NPs对As污染农田环境因子和As生物有效态的影响.结果表明,CuO NPs进入土壤后12 h内快速溶解产生Cu^(2+),且在黄棕壤中的溶解速度较黑土迅速.CuO NPs可在短时间内降低土壤pH,提高土壤氧化还原电位(E_(h)),降低土壤电导率(EC),但随着培养时间增加土壤EC逐渐提高.一定时间内CuO NPs在两种类型土壤中可降低51.0%~82.5%土壤浸出液中的As和15.7%~66.5%的As生物有效性,减少淹水时Fe(II)的含量.但在土壤落干时期产生一定的"纳米效应"从而促进了Fe(II)的产生.研究表明,CuO NPs进入As污染农田改变了土壤环境因子,一定时间内降低了土壤As生物有效性.

纳米氧化铜对豚鼠血脑屏障通透性影响观察

目的观察40和200 nm 2种粒径纳米氧化铜颗粒(Cu ONPs)对豚鼠血脑屏障通透性造成的影响。方法制备粒径为40和200 nm的近球型Cu ONPs用于测试。以0.5%HPMC作为分散剂配制Cu ONPs染毒分散悬液。选取250~300 g的豚鼠用于试验。试验设40和200 nm Cu ONPs组、Cu SO4组、0.5%HPMC组和生理盐水组,每组5只动物。以一次性舌下静脉注射方式染毒。Cu ONPs组、Cu SO4组、HPMC组和生理盐水组染毒剂量分别按照1.5、65、4和4 ml/kg·bw进行。分别于染毒后24和48 h从每组取5只动物,先经舌下静脉给动物注射2%伊文氏蓝(EB)生理盐水溶液(4 ml/kg),1 h后实施心脏灌注,切取大脑顶叶皮质及皮质下结构组织,以脑组织中EB渗入量(以吸光度A值计)表示动物血脑屏障的开放程度。结果 40 nm Cu ONP作用24和48 h时皮质和皮质下结构组织A值明显高于相应200 nm Cu ONP组和生理盐水组A值差异有统计学意义(P<0.05)。2种粒径Cu ONPs组作用48 h的A值较各自作用24 h的A值明显增大差异有统计学意义(P<0.05)。同时,200 nm Cu ONPs组48 h皮质A值(0.383±0.017 A/mg)与生理盐水组A值(0.103±0.021 A/mg)之间差异有统计学意义(P<0.05)。除Cu SO4组24和48 h皮质下结构A值分别为0.087±0.026和0.071±0.031 A/mg高于对应生理盐水组,分别为0.041±0.013和0.069±0.022 A/mg外,其余各组的A值与生理盐水组间差异均无统计学意义(P>0.05)。结论 40 nm Cu ONP具有显著的致豚鼠血脑屏障开放效应,且这种效应在作用24~48 h具有增强特点。

纳米CuO离子化水平及其对细胞毒性影响观察

目的试验测评纳米CuO在体外培养条件下离子化水平及其对细胞毒性贡献率。方法粒径为40和200 nm的近球型CuO纳米颗粒(CuO-NPs)用于测试。以超滤离心滤过液中铜元素的含量代表CuO-NPs的离子化水平。ICP-MS方法用于铜元素含量测定。细胞毒性试验设CuO-NPs(40和200 nm粒径)组、CuSO_4组、HPMC组和无处理组。在添加和不添加D-青霉胺(D-PA)情况下给A549细胞染毒,分别于染毒后6和24 h采用刃天青法测算细胞抑制率(IR)并计算离解铜离子对细胞毒性贡献率。结果在CuO-NPs-DMEM/F12体系中,40和200 nm CuO-NPs在孵育6 h时滤过液中铜离子测定浓度分别为(3.6±0.1)和(2.8±0.2)mg/L,在孵育24 h滤过液中铜离子测定浓度分别为(3.9±0.1)和(1.8±0.1)mg/L,上述两个时间点下40 nm CuO-NPs滤过液中铜离子测定浓度均显著高于200 nm CuO-NPs(P<0.05)。细胞毒性试验结果显示,在添加D-青霉胺情况下,40和200 nm CuO-NPs对A549细胞作用6 h的细胞抑制率分别是64.7%和47.2%,作用24 h的细胞抑制率分别是87.5%和70.9%。在不添加D-青霉胺情况下,40和200 nm CuO-NPs对A549细胞作用6 h的细胞抑制率分别是90.3%和69.4%,作用24 h的细胞抑制率分别是95.2%和86.0%。求得40和200 nm CuO-NPs对A549细胞作用6 h的离子化毒性贡献率分别为28.3%和32.0%,作用24 h的离子化毒性贡献率分别为8.1%和17.6%。结论 CuO-NPs在体外培养体系中发生离子化现象,离子化水平与CuO-NPs粒径和时间有关。离子化对CuO-NPs细胞毒性具有一定贡献。

纳米氧化铜对体外培养气血屏障通透性的影响

目的利用体外模型评价纳米氧化铜(CuO-NPs)对气血屏障(ACB)通透性的影响。方法粒径为40、80和100 nm的近球型CuO-NPs用于试验。采用肺毛细血管内皮细胞(PCECs)和A549细胞共培养于细胞插板底膜(A549和PCECs分别生长于底膜内外表面)的方式建立气血屏障通透性测试模型,以跨内皮细胞电阻(TEER)评估模型的屏障特点。利用模型进行三种粒径CuO-NPs通透性影响试验,并计算通透系数(Pe)用以表示气血屏障通透性改变大小。结果建立了气血屏障通透性影响测试模型。所建立模型TEER峰值为(114.8±8.7)Ω/cm^2。通透性影响试验测得40、80和100 nm CuONPs对模型Pe分别是(1.82±0.21)×10^(-3)、(1.26±0.19)×10^(-3)和(1.06±0.16)×10^(-3) cm/min,其中40 nm CuO-NPs Pe值高于模型对照组Pe值[(0.96±0.12)×10^(-3) cm/min]。结论拥有小粒经和大比表面积的40 nm CuO-NPs较80和100 nm CuO-NPs对气血屏障通透性作用明显。

不同粒度CuO及与乙基黄原酸钾复合污染对土壤脲酶和微生物多样性的影响

纳米氧化铜不同于常规的氧化铜,纳米氧化铜的尺寸小,比表面积大,对生态环境存在潜在危害.本次通过向土壤中加入不同比例的纳米氧化铜(N CuO)和微米氧化铜(M Cu0)(0,50,200,800,1600mg/kg干土)观察它们对土壤脲酶活性和細菌群落的影响.同吋,进一步研究了N CuO和M CuO分別与乙基黄原酸钾(PEX)复合污染对土壤微生物的影响.N CuO较M CuO对脲酶活性有更强的抑制作用,只有M CuO浓度为1600mg/kg对脲酶的影响较明显.N CuO对脲酶活性的抑制可能与破坏细菌的細胞膜或刺激细菌产生活性氧,造成細菌細胞的衰退有关,N CuO对细菌群落结构的影响也较大.N CuO与PEX复合污染加剧了N CuO对土壤微生物的毒性,使脲酶的活性大幅度降低,细菌的群落结构也发生了较大的变化.N CuO及其复合污染对土壤微生物的作用机制需进一歩研究.通过比较研究N CuO和M CuO的生态毒性,纳米颗粒的生态毒性更需要引起足够的重视.

Effects of reaction parameters on preparation of Cu nanoparticles via aqueous solution reduction method with NaBH_4

The preparation of Cu nanoparticles by the aqueous solution reduction method was investigated. The effects of different reaction parameters on the preparation of Cu nanoparticles were studied. The optimum conditions for preparing well-dispersed nanoparticles were found as follows: 0.4 mol/L NaBH4 was added into solution containing 0.2 mol/L Cu2+, 1.0% gelatin dispersant in mass fraction, and 1.2 mol/L NH3?H2O at pH 12 and 313 K. In addition, a series of experiments were performed to discover the reaction process. NH3?H2O was found to be able to modulate the reaction process. At pH=10, Cu2+ was transformed to Cu(NH3)42+ as precursor after the addition of NH3?H2O, and then Cu(NH3)42+ was reduced by NaBH4 solution. At pH=12, Cu2+ was transformed to Cu(OH)2 as precursor after the addition of NH3?H2O, and Cu(OH)2 was then reduced by NaBH4 solution.

Preparation and photocatalytic performance of Cu-doped TiO_2 nanoparticles

Cu-doped TiO2 nanoparticles with different doping contents from 0 to 2.0% （mole fraction） were synthesized through sol-gel method. X-ray diffraction （XRD）, X-ray photoelectron spectroscopy （XPS） and field emission scanning electron microscope （FE-SEM） were used to characterize the crystalline structure, chemical valence states and morphology of TiO2 nanoparticles. UV-Vis absorption spectrum was used to measure the optical absorption property of the samples. The photocatalytic performance of the samples was characterized by degrading 20 mg/L methyl orange under UV-Vis irradiation. The results show that the Cu-doped TiO2 nanoparticles exhibit a significant increase in photocatalytic performance over the pure TiO2 nanoparticles, and the TiO2 nanoparticles doped with 1.0% Cu show the best photocatalytic performance. The improvement in photocatalytic performance is attributed to the enhanced light adsorption in UV-Vis range and the decrease of the recombination rate of photoinduced electron-hole oair of the Cu-doped TiO2 nanoparticles.

Octahedral Cu_2O-modified TiO_2 nanotube arrays for efficient photocatalytic reduction of CO_2

A photocatalyst composed of TiO 2 nanotube arrays（TNTs） and octahedral Cu2 O nanoparticles was fabricated,and its performance in the photocatalytic reduction of CO2 under visible and simulated solar irradiation was studied. The average nanotube diameter and length was 100 nm and 5 μm,respectively. The different amount of octahedral Cu2 O modified TNTs were obtained by varying electrochemical deposition time. TNTs modified with an optimized amount of Cu2 O nanoparticles exhibited high efficiency in the photocatalysis,and the predominant hydrocarbon product was methane. The methane yield increased with increasing Cu2 O content of the catalyst up to a certain deposition time,and decreased with further increase in Cu2 O deposition time. Insufficient deposition time（5 min） resulted in a small amount of Cu2 O nanoparticles on the TNTs,leading to the disadvantage of harvesting light. However,excess deposition time（45 min） gave rise to entire TNT surface being most covered with Cu2 O nanoparticles with large sizes,inconvenient for the transport of photo-generated carriers. The highest methane yield under simulated solar and visible light irradiation was observed for the catalysts prepared at a Cu2 O deposition time of 15 and 30 min respectively. The morphology,crystallization,photoresponse and electrochemical properties of the catalyst were characterized to understand the mechanism of its high photocatalytic activity. The TNT structure provided abundant active sites for the adsorption of reactants,and promoted the transport of photogenerated carriers that improved charge separation. Modifying the TNTs with octahedral Cu2 O nanoparticles promoted light absorption,and prevented the hydrocarbon product from oxidation. These factors provided the Cu2O-modified TNT photocatalyst with high efficiency in the reduction of CO2,without requiring co-catalysts or sacrificial agents.

Experimental Investigation of Upgraded Diesel Fuel with Copper Oxide Nanoparticles on Performance and Emissions Characteristics of Diesel Engine

The enhancement of the physicochemical characteristics of fossil fuel has been the subject of extensive research to achieve better efficiency and reduced emissions. Diesel is one of the fossil fuels that are highly consumed in daily life. This paper focuses on the behavior of a refined diesel fuel when copper oxide nanoparticles are added. The resulting blend ofnano-diesel has been analyzed using a four-stroke engine under two loads indicating light vehicles and heavy duty vehicles. The nano-diesel was prepared by the aid of an ultrasonicator and a mechanical homogenizer. A base diesel was taken as a reference to distinguish the effect of the nanoparticles additives. Three different samples with different concentrations are utilized in this study. As a result, the fuel consumption, exhaust temperature, brake power, power losses and engine efficiency have been evaluated and compared to the base diesel in order to demonstrate and access the enhanced performance of the nano-fuel blend. The three concentrations conducted were 100 ppm, 200 ppm and 300 ppm of copper oxide nanoparticles. The results represented that the pure refinery diesel has low exhaust temperatures, high brake power and high efficiency as compared to the commercial diesel supplied from a gas station. In addition, 300 ppm copper oxide nano-diesel showed improvement in engine performances as compared to the other concentrations and pure diesel. In this context, lowest fuel consumption for both passenger cars and heavy duty vehicles was achieved, brake power for passenger cars only was improved and input power showed improvement however, exhaust temperature was the highest as for this fuel.

CuO NPs短期暴露对SBR水处理效果的影响

研究了不同浓度氧化铜纳米颗粒(CuO NPs)对序批式活性污泥工艺(SBR)中化学需氧量、氨氮、总磷、硝态氮和亚硝态氮去除率的影响。实验结果表明,当环境中浓度为1 mg/L和10 mg/L的CuO NPs短期暴露时(1 d),其对活性污泥生存能力和周期内有机物去除、脱氮除磷都没有造成急性影响。经过20 d的短期运行,对SBR系统出水COD、氨氮、总磷、硝态氮和亚硝态氮也没有造成明显的影响。活性污泥呼吸抑制实验结果显示,CuO NPs对活性污泥的呼吸抑制作用与浓度呈正相关性,浓度越高呼吸抑制现象越明显,低浓度CuO NPs对活性污泥活性并没有明显的抑制作用。

Formation of copper oxide nanowires and nanoparticles via electrospinning

Copper oxide nanowires and nanoparticles were fabricated through electrospinning followed by calcinations in different heating conditions.It was found that the solution viscosity and environment humidity had great impact on the morphologies of precursor nanowires,and the parameters of heat treatment,including final temperature and heating rate,significantly affected the product morphologies.