镉胁迫下大豆中镉的分布状况及其籽粒品质

溶液培养中0.5μmol·L-1镉胁迫浓度下,大豆表现出轻微受害症状,籽粒减产25 . 7%,而籽粒中粗脂肪和粗蛋白含量变化不大.镉在大豆中的积累分布状况为根>叶>籽>油,比例为32.100:1.690:1.000:0.003.大豆籽粒含镉4.89mg/kg,超过了国家环境标准规定的最高容许量.而大豆粗脂肪中含镉仅0.015mg/kg,远低于国家食品环境卫生标准.豆粕中含镉6.17mg/kg,表明大豆籽粒中的镉主要存在于粗蛋白和淀粉中.     

基于原代培养背角无齿蚌鳃细胞的镉毒性效应评价

为了探究淡水贝类背角无齿蚌鳃细胞的原代培养途径，并阐释其在评价水体Cd²⁺毒性效应上的潜力，本研究比较了不同酶分解方法（链霉蛋白酶、胰蛋白酶）的鳃细胞存活率差异，并分析了L-15培养基中不同血清浓度（10% FBS、20% FBS）对鳃细胞存活率的影响，细胞置于20℃生化培养箱中培养.进而根据Cd²⁺对鳃细胞的LC₂₅值设定0.0625、0.125、0.25、0.5和1.0 mg·L^-1 5个Cd²⁺理论浓度梯度，对原代培养的鳃细胞进行24 h暴露，分析了细胞活力、总超氧化物歧化酶（SOD）、过氧化氢酶（CAT）和酸性磷酸酶（AcP）的变化特征.结果表明：0.025%链霉蛋白酶在4℃分解16 h的鳃细胞存活率为98.2%±0.2%，显著高于0.25%胰蛋白酶在26℃分解30 min的89.4%±3.5%鳃细胞存活率（p<0.05）；L15培养基加入10% FBS的细胞存活率总体显著高于添加20% FBS的细胞存活率（p<0.05）.在上述较佳的分解和血清浓度组合条件下，细胞培养120 h后，其存活率仍高达90.1%±4.7%.鳃细胞活力随着Cd²⁺浓度的增加而降低，两者之间呈显著的线性负相关（p<0.05）；随着Cd²⁺浓度的增加，SOD和AcP含量总体增加，而CAT含量呈现出"诱导-抑制"的变化趋势.本研究初步建立了较为适宜的背角无齿蚌鳃细胞的原代培养方法，并揭示了其原代培养鳃细胞的细胞活力及SOD、CAT、AcP水平，具有作为评价水环境Cd²⁺毒性/污染的生物指标的潜力.     

植物根系对镉毒害的防御及其代谢

本文采用植物根系生物量、根系内活性氧清除酶活性变化和植物表观中毒症状作指标 ,研究了 Cd毒害对草坪植物的毒性作用、根系应激反应。结果表明 ,当土壤溶液中 Cd浓度达 1.5× 10 - 3mol· dm- 3时 ,植物体内活性氧代谢、生长状况将出现异常 ,甚至出现明显的表观中毒症状。 Cd对植物体内清除酶活性的毒性强度为 CAT>SOD>POD。匍匐翦股颖 (Agrostis stolonifera)根系对 Cd毒害的抵抗作用强于多年生黑麦草 (L olium perernne)。     

吸附剂吸附除镉的研究进展

镉离子主要来源于电镀、电池、合金制造、颜料、采矿与选矿行业排放的工业废水。研究废水中去除镉离子的吸附方法具有重大意义。文章从吸附技术角度出发,对去除镉的离子交换、壳聚糖吸附、利用藻类物质的吸附、利用甘蔗渣吸附、利用电解铝的红泥吸附的技术进行了综述。     

土壤溶液中镉的化学形态及化学平衡研究

据土壤溶液的实际情况建立简便的平衡模式,研究了红壤、黄棕壤、黄潮土三种典型土壤溶液中Cd的化学形态和化学平衡.结果表明,溶液中Cd的主要形态为Cd~(2+)、CdCl~+和CdSO_4~6.黄潮土还有一定量的CdHCO_3~+,其它形态Cd很少,其中游离Cd~(2+)占绝大部分.红壤最高,黄棕壤次之.红壤施石灰后游离Cd~(2+)下降,CdSO_4~6增加;添加氯化物后,溶液pH下降,大量Cd进入溶液中,CdCl~+比例明显升高.溶液中Cd的形态分布与土壤Cd的生物有效性有一定关系.此外,溶解度图证明,供试土壤中不可能有Cd的矿物生成.Cd在固液相间的平衡受吸附解吸反应控制.     

草甸棕壤中镉、铅、油含量对微生物类群和生化活性的影响

本研究以重金属化合物(CdCl_2、PbCl_2)和矿物油作为土壤的污染物,分析土壤中镉、铅、油的含量对土壤微生物类群与生化活性的影响。结果表明,镉、铅、油对水旱田中的细菌抑制作用比较明显,对放线菌、真菌抑制作用较差。小剂量的镉、铅、油对固氮菌有刺激作用,大剂量则有抑制作用。对尿酶和硝化细菌的代谢有明显抑制作用,对其它酶类不明显。 从含重金属的平板培养基上反映出土壤对重金属的掩蔽作用。污染物对微生物的生化活性的临界毒害浓度分别为:镉 5—60ppm;铅 300—500ppm;油 500—5000ppm。     

丹东市区段鸭绿江水体中铅、镉的含量

利用生物指示物（鳙鱼）对丹东地区鸭绿江水体中的铅、镉污染进行监测，采具鳙鱼-碳化酸溶-电热原子光谱法对丹东鸭绿江流域鳙鱼体内的铅、镉的含量进行了相关检测，在相同的实验条件下对该地区的水体中的铅、镉的含量进行对比，并对该地区的铅、镉污染进行了相关的评价，通过一年的监测未见超标。铅、镉含量分别为6．53±0．07（ng/g）、4．60±0．03（ng/g）；回收率分别为98.9％、103.5％；RSD分别为5．3％、4．1％。     

嗜麦芽窄食单胞菌对铜镉的吸附特性与离子交换

研究了投菌量、金属浓度和戊二醛浓度对嗜麦芽窄食单胞菌吸附水体中Cu2+和Cd2+特性的影响,分析了重金属生物吸附、NO3-去除与菌体离子释放的关联,从离子吸附、交换、转化与释放的角度探讨了重金属生物吸附机制.结果表明嗜麦芽窄食单胞菌对Cu2+和Cd2+吸附性能良好,0.2 g·L-1干重菌体处理浓度为0.05 mmol·L-1的Cu(NO3)2和Cd(NO3)2溶液120 min后,Cu2+和Cd2+的吸附率分别达96.3%和83.9%.菌体对Cu(NO3)2和Cd(NO3)2溶液的吸附过程存在Cu2+和Cd2+的表面吸附与胞内运输、NO3-胞内积累、NO3-还原为NO2-等行为,而且Cu2+和Cd2+的胞内运输、NO3-积累和还原需要消耗能量,并会促进Cl-、PO43-、SO42-、Na+、NH4+、K+和Ca2+等离子的释放.红外光谱分析表明菌体酰胺基、羟基与羧基均参与了Cu2+和Cd2+的吸附.X-光电子能谱分析显示吸附后Cu2+和Cd2+的价态不发生变化.     

Phytoremediation potential of charophytes: Bioaccumulation and toxicity studies of cadmium, lead and zinc

The ability for usage of common freshwater charophytes,Chara aculeolata and Nitella opaca in removal of cadmium (Cd),lead (Pb) and zinc (Zn) from wastewater was examined.C.aculeolata and N.opaca were exposed to various concentrations of Cd (0.25 and 0.5 mg/L),Pb (5 and 10 mg/L) and Zn (5 and 10 mg/L) solutions under hydroponic conditions for 6 days.C.aculeolata was more tolerant of Cd and Pb than N.opaca.The relative growth rate of N.opaca was drastically reduced at high concentrations of Cd and Pb although both were tolerant of Zn.Both macroalgae showed a reduction in chloroplast,chlorophyll and carotenoid content after Cd and Pb exposure,while Zn exposure had little effects.The bioaccumulation of both Cd and Pb was higher in N.opaca (1544.3 μg/g at 0.5 mg/L Cd,21657.0 μg/g at 10 mg/L Pb) whereas higher Zn accumulation was observed in C.aculeolata (6703.5 μg/g at 10 mg/L Zn).In addition,high bioconcentration factor values (> 1000) for Cd and Pb were observed in both species.C.aculeolata showed higher percentage of Cd and Pb removal (> 95%) than N.opaca and seemed to be a better choice for Cd and Pb removal from wastewater due to its tolerance to these metals.     

Removal of Cd2+ from water by Friedel’s salt (FS: 3CaO.Al2O3·CaCl2·10H2O): Sorption characteristics and mechanisms

The development of low-cost and efficient new mineral adsorbents has been a hot topic in recent years. In this study, Friedel’s salt (FS:3CaO·A12O3 ·CaCl2 ·10H2O), a hexagonal layered inorganic absorbent, was synthesized to remove Cd2+ from water. The adsorption process was simulated by Langmuir and Freundlich models. The adsorption mechanism was further analyzed with TEM, XRD, FT-IR analysis and monitoring of metal cations released and solution pH variation. The results indicated the adsorbent FS had an outstanding ability for Cd(Ⅱ) adsorption. The maximum adsorption capacity of the FS for Cd(Ⅱ) removal can reach up to 671.14 mg/g. The nearly equal numbers of Cd2+ adsorbed and Ca2+ released demonstrated that ion-exchange (both surface and inner) of the FS for Cd(Ⅱ) played an important role during the adsorption process. Furthermore, the surface of the FS after adsorption was microscopically disintegrated while the inner lamellar structure was almost unchanged. The behavior of Cd(Ⅱ) adsorption by FS was significantly affected by surface reactions. The mechanisms of Cd2+ adsorption by the FS mainly included surface complexation and surface precipitation. In the present study, the adsorption process was fitted better by the Langmuir isotherm model (R2 = 0.9999) than the Freundlich isotherm model (R2 = 0.8122). Finally, due to the high capacity for ion-exchange on the FS surface, FS is a promising layered inorganic adsorbent for the removal of Cd(Ⅱ) from water.