生物炭影响抗生素在土壤中环境行为的Meta分析

生物炭作为一种减污降碳相协同的土壤改良剂,在抗生素污染控制方面均有较大应用前景.为了系统研究生物炭施用对抗生素在土壤中环境行为的影响,对2011～2021年发表的20篇文献进行Meta分析.结果表明,抗生素在生物炭改良土壤中的吸附、降解行为受生物炭施用量与性质的显著影响.施用质量分数为2%时,对抗生素吸附行为的影响最强,效应值为0.19;施用质量分数为5%时,对其降解作用影响显著,效应值为0.23;生物炭比表面积、极性、稳定性和芳香化程度对分配系数的增加影响非常显著,分别为0.11、0.13、0.09和0.18;而生物炭施用量和性质对抗生素迁移行为影响并不显著.生物炭还可通过调控土壤环境间接影响抗生素环境行为.但抗生素在土壤中多环境行为耦合对生物炭的响应机制仍不明确,生物炭田间施用的长效性与负面效应仍缺乏基础数据支撑.     

长江南京段水源水中抗生素的赋存特征与风险评估

利用固相萃取-液相色谱-串联质谱技术(SPE-HPLC-MS/MS)分析了长江南京段水源水中抗生素的赋存特征.结果表明,16个采样点累计质量浓度范围为13. 37～780. 5 ng·L~(-1),平均值为92. 95 ng·L~(-1),共检出4种磺胺类、3种氟喹诺酮类、1种四环素类、5种大环内酯类和1种氯霉素类抗生素,平均质量浓度为0. 14～49. 91 ng·L~(-1),其中恩诺沙星(ERX)和克拉霉素(CLR)的检出率为100%,克林霉素(CLI)检出质量浓度最高(739. 44 ng·L~(-1)).与国内部分河流、湖泊相比,长江南京段水体中的抗生素浓度处于较低水平.生态风险评估结果表明,点位S2具有最大的联合风险熵值(0. 31),磺胺甲恶唑(SMX)、强力霉素(DOX)和罗红霉素(ROX)的环境风险熵值具有低等风险水平; 9种抗生素对不同年龄段人群的健康风险指数HQ在2. 22×10-6和4. 86×10-3之间,同时CLI和DOX为主要的潜在健康风险因素.     

Simple fabrication of carboxymethyl cellulose and κ-carrageenan composite aerogel with efficient performance in removal of fluoroquinolone antibiotics from water

● A composite aerogel was simply obtained to remove various fluoroquinolones (FQs). ● The structural and textural properties of this composite aerogel are improved. ● Its adsorption capacity was improved at a low content of coexisting Cu²⁺ or Fe³⁺ ion. ● Two substructural analogs of FQs are compared to explore the adsorption mechanisms. ● This aerogel after saturated adsorption can be reused directly for Cu²⁺ adsorption. 3D composite aerogels (CMC-CG) composed of carboxymethyl cellulose and κ-carrageenan were designed and fabricated using the one-pot synthesis technique. The optimized CMC-CG showed a good mechanical property and a high swelling ratio due to its superior textural properties with a proper chemically cross-linked interpenetrating network structure. CMC-CG was utilized for the removal of various fluoroquinolones (FQs) from water and exhibited high adsorption performance because of effective electrostatic attraction and hydrogen bonding interactions. Ciprofloxacin (CIP), a popular FQ, was used as the representative. The optimized CMC-CG had a theoretically maximal CIP uptake of approximately 1.271 mmol/g at the pH of 5.0. The adsorption capacity of CMC-CG was improved in the presence of some cations, Cu²⁺ and Fe³⁺ ions, at a low concentration through the bridging effect but was reduced at a high concentration. The investigation of adsorption mechanisms, based on the adsorption kinetics, isotherms and thermodynamic study, Fourier transform infrared spectrometry and X-ray photoelectron spectroscopy analyses before and after adsorption, and changes in the adsorption performance of CMC-CG toward two molecular probes, further indicated that electrostatic attraction was the dominant interaction rather than hydrogen bonding in this adsorption. CMC-CG after saturated adsorption of CIP could be easily regenerated using a dilute NaCl aqueous solution and reused efficiently. Moreover, the disused aerogel could still be reused as a new adsorbent for effective adsorption of Cu²⁺ ion. Overall, this study suggested the promising applications of this composite aerogel as an eco-friendly, cost-effective, and recyclable adsorbent for the efficient removal of FQs from water.     

在线固相萃取-超高效液相色谱-三重四极杆质谱快速测定地表水中磺胺类抗生素

建立了在线固相萃取-超高效液相色谱-三重四极杆质谱联用技术测定地表水中痕量磺胺类抗生素的方法。样品经滤膜过滤,HLB在线固相萃取小柱富集纯化,以Acquity BEH 130为分析柱,三重四极杆质谱进行检测,外标法定量。通过在线固相萃取,并对色谱和质谱等条件进行优化,该方法检出限为0.2~1.1 ng/L,回收率为80.6%~113%,相对标准偏差<10.6%,浓度范围内线性良好（r＞0.9972）,满足了磺胺类抗生素痕量分析测试的要求,且分析时间仅需17min。该方法灵敏度高、分析速度快,对于保障水环境安全,及时提供污染信息,有效应对环境应急突发事件具有十分重要的意义。     

CuFeO2改性生物炭对四环素的吸附特性

利用共沉淀和水热法于生物炭（BC250、BC350、BC450、BC550和BC650）负载CuFeO₂,得到的复合材料对水中四环素（TC）具有较好的去除效果.CuFeO₂与BC450质量比为2 ：1的CuFeO₂改性生物炭（CuFeO₂/BC450=2 ：1）对TC的吸附性能最强.TC于CuFeO₂/BC450=2 ：1的吸附符合颗粒内扩散模型,表明吸附是界面和孔隙扩散控制的过程.在中性pH、298 K下,CuFeO₂/BC450=2 ：1对TC的Langmuir最大吸附量为82.8 mg ·g^-1,远大于BC450的13.7 mg ·g^-1和CuFeO₂的14.8 mg ·g^-1.热力学结果表明,CuFeO₂/BC450=2 ：1对TC的吸附是自发和吸热过程.随pH增加,CuFeO₂/BC450=2 ：1对TC的吸附去除呈先增加后降低的趋势,中性条件时效果最佳.CuFeO₂/BC450=2 ：1对TC的强吸附得益于CuFeO₂负载对材料孔隙结构的改善、比表面积的增大和表面官能团、电荷属性的改变.研究结果为净化抗生素污染提供了一种高效的磁性吸附剂.     

生产过程中抗生素与抗药基因的排放特征、环境行为及控制

世界卫生组织在2000年的报告中将抗生素抗性列为本世纪人类在健康领域面临的最大挑战之一,有关抗药基因传播机制与控制技术的研究已经成为国际环境科学领域的一个前沿问题.本文以生产量大、使用历史长的几种发酵类和化学合成类生素为对象,以典型城市污水厂为对照系统,全面评估抗生素生产及废水处理过程中抗生素与抗药基因的排放特征;把传统的筛选培养方法与高通量测序技术及生物信息学手段有机结合,深入研究抗生素胁迫下整合子对抗性基因的重组作用及质粒介导的结合转移作用,以揭示抗药基因在抗生素压力驱动下主要的水平转移机制;构建多通道生物膜流动暴露系统进行抗生素最小选择浓度评价;研究针对抗生素生产全过程的抗生素及抗药基因控制多级屏障技术,为抗药基因的污染控制与管理提供全面系统的科学基础.     

Adsorption behavior of sulfamethazine in an activated sludge process treating swine wastewater

Swine wastewater is an important pollution source of antibiotics entering the aquatic environment. In this work,the adsorption behavior of sulfamethazine(SMN),a commonlyused sulfonamide antibiotic,on activated sludge from a sequencing batch reactor treating swine wastewater was investigated. The results show that the adsorption of SMN on activated sludge was an initially rapid process and reached equilibrium after 6 hr. The removal efficiency of SMN from the water phase increased with an increasing concentration of mixed liquor suspended solids,while the adsorbed concentration of SMN decreased. Solution pH influenced both the speciation of SMN and the surface properties of activated sludge,thus significantly impacting the adsorption process. A linear partition model could give a good fit for the equilibrium concentrations of SMN at the test temperatures(i.e.,10,20 and 30°C). The partition coefficient(Kd) was determined to be 100.5 L/kg at 20°C,indicating a quite high adsorption capacity for SMN. Thermodynamic analysis revealed that SMN adsorption on activated sludge was an exothermic process. This study could help to clarify the fate and behavior of sulfonamide antibiotics in the activated sludge process and assess consequent environmental risks arising from sludge disposal as well.     

UV/H2O2氧化降解克拉霉素的反应动力学及影响因素

克拉霉素用量大、检出频率高、生态风险大,已被欧盟列为优先监测污染物.针对传统污水处理厂难以完全去除克拉霉素的问题,主要研究了UV/H_2O_2降解克拉霉素的效果和反应动力学,探讨了pH、天然有机质(NOM)和水中共存阴、阳离子对UV/H_2O_2降解克拉霉素的影响.结果表明:单一UV对克拉霉素的光降解符合准一级反应动力学模型,其反应速率常数为0.0016 min~(-1).UV/H_2O_2对克拉霉素的降解符合准一级反应动力学模型,且克拉霉素的降解速率随H_2O_2浓度的增大而增大,在H_2O_2浓度为40 mmol·L~(-1)时,克拉霉素降解的反应速率常数为0.0284min~(-1).克拉霉素与·OH的二级反应速率常数为(2.36±0.20)×10~(10)L·mol~(-1)·s~(-1).碱性条件有利于克拉霉素的降解;NOM(2~10 mg·L~(-1))会抑制克拉霉素的降解,且随NOM浓度增大而增大;共存阴离子CO_3~(2-)对克拉霉素降解无影响,HCO_3~-、NO_3~-、Cl~-会抑制克拉霉素的降解,抑制程度的大小顺序为NO_3~-HCO_3~-Cl~-;共存阳离子Ca~(2+)、Mg2+、Cu~(2+)、Fe~(3+)会抑制克拉霉素的降解,抑制程度的大小顺序为Fe~(3+)Cu~(2+)Mg2+Ca~(2+).     

人工湿地构型对水产养殖废水含氮污染物和抗生素去除影响

利用水平潜流人工湿地和下行-上行复合垂直流人工湿地净化水产养殖废水,研究水流方式、水力停留时间对水产养殖废水中含氮污染物、抗生素等典型污染物净化效果的影响.结果表明,复合垂直流人工湿地对含氮污染物具有较好的去除效果,对TN、NH_4~+-N的去除率在水力停留时间为3 d时可分别达到58%、80%.采用BIOLOG微平板技术和高通量测序对两个人工湿地入流端基质微生物群落的分析发现,复合垂直流人工湿地因其内部结构有利于水流流向及溶解氧条件使得微生物活性和多样性均较高,Nitrospira属分布较多是氨氮去除效果较好的主要原因.水力停留时间对NO_3~--N、NO_2~--N的去除有较大影响,维持在3~4 d对各类含氮污染物可获得较好的去除效果.采用固相萃取-高效液相色谱串联质谱法对抗生素去除效果进行研究发现,人工湿地构型对抗生素的去除效果差异不大,两种人工湿地对恩诺沙星的去除效果优于磺胺甲唑和氟甲砜霉素,当水力停留时间从1 d延长至3 d可提高磺胺甲唑的去除率至50%以上.     

Dissipation of sulfamethoxazole and trimethoprim antibiotics from manure-amended soils

In this study, the dissipation of two antibiotics, sulfamethoxazole (SMX) and trimethoprim (TRM), in three soils under both aerobic and anaerobic conditions are evaluated. Under aerobic conditions, SMX dissipated rapidly through biodegradation but TRM was more persistent. Within the first 20 days in biologically active soils, >50% of the SMX was lost from the clay loam and loamy sand soils, and >80% loss was noted in the loam soil. Anaerobic dissipation of both compounds was more rapid than aerobic dissipation. The addition of manure to the soil only slightly increased the initial dissipation rate of the two compounds. Little effect was found on glucose mineralisation in soil following the addition of SMX and TRM, even as mixtures at high concentrations.