北京某污水处理厂出水中药物和个人护理品的污染现状

通过两次采集北京某大型污水处理厂的水样,采用HPLC-MS技术对水样中的10种PPCPs进行分析.结果显示,进水口水样中PPCPs浓度为7122.92ng/L,其中咖啡因的检出浓度最高(4490.54ng/L),污水处理厂对咖啡因的去除率大于90％(浓度为78.01ng/L).与文献报道值比较发现,该污水处理厂出水水样中PPCPs的浓度与其他国家报道的浓度基本上处于同一数量级,但污水中PPCPs的去除率都普遍低于国际水平.因此,需加强对污水处理厂水样中PPCPs的监测,完善污水处理的工艺.     

太湖以西常州区域水体中典型PPCPs污染特征

为进一步了解环太湖区域药品及个人护理用品（PPCPs）环境污染现状，于2016年9月对太湖以西常州区域水体中典型PPCPs污染水平进行了调查。利用高效液相色谱-串联质谱（HPLC MS/MS）检测分析了24种PPCPs在常州区域水体中的赋存和空间分布特征。结果表明，常州区域水体中24种目标PPCPs均被检出，PPCPs质量浓度总量范围为51.08～325.79 ng/L，20个监测点位中，红凌桥检出PPCPs总量最高，达325.79 ng/L;水体中优势污染物为双酚A和诺氟沙星，双酚A在黄埝桥检出的质量浓度最高，达158.53 ng/L，其次是新河口和红凌桥，质量浓度分别为65.57和57.86 ng/L；诺氟沙星在红凌桥检出的质量浓度最高，达75.12 ng/L。喹诺酮类抗生素、磺胺类抗生素在常州流域内基本呈均匀分布；激素类、大环内酯抗生素、神经镇痛类和心脏病类药物质量浓度与人口密度大致呈正相关。     

水体中磺胺、四环素、喹诺酮类抗生素检测方法

建立了固相萃取-高效液相色谱-串联质谱法(SPE-HPLC-MS/MS)同时检测水体中3类15种抗生素的分析方法。水样用Oasis HLB固相萃取小柱净化富集。通过对比水样在不同pH条件下的回收率,优化了环境水样中抗生素固相萃取过程中的前处理条件。采用甲醇和0.1%甲酸溶液作为流动相,经过梯度洗脱进行分离,在HPLC-MS/MS多反应监测模式下进行定性定量分析。结果表明,环境水体中15种抗生素的检出限和定量下限分别为0.12~1.6 ng/L和0.2~3.0 ng/L,自来水加标回收率为34.9%~102.5%(pH=4)。用该方法对海河流域13个地表水水样进行了初步检测,结果表明,部分抗生素普遍存在于地表水体中。其中,磺胺甲基异NFDA1唑检出频率最高,在13个地表水样品中均有检出。     

高效液相色谱-串联质谱法测定废水中5种喹诺酮类抗生素

建立高浓度有机废水中5种喹诺酮类抗生素的高效液相色谱-串联质谱测定方法。水样经HLB固相萃取小柱富集净化,12 ml甲醇洗脱、浓缩并加入内标溶液后,定容至1 mL待测。以C18柱为分离柱,含0.01%甲酸的甲醇-含0.01%甲酸的水溶液为流动相,目标物质在10 min内分离。在0.25~1 250 ng/mL范围内,目标物质线性关系良好(R20.99)。基质加标试验结果表明,纯水中的回收率为61.40%~91.92%,废水中的回收率为54.92%~101.87%,检出限为0.25~2.5 ng/L,方法定量限为0.36~3.99 ng/L。应用该方法对21家猪场的64份废水样品进行分析,5种喹诺酮类抗生素的检出频率为47%~95%,平均检出浓度为980~5 734 ng/L。该方法快速、准确,适用于高浓度有机废水中喹诺酮类抗生素的同时测定。     

动态固相微萃取-气相色谱质谱法测定水中多种异味有机物

采用动态固相微萃取技术富集水样中2-异丙基-3-甲氧基吡嗪、2-异丁基-3-甲氧基吡嗪、2-MIB、β-环柠檬醛、2,4,6-三氯苯甲醚、GSM、α-紫罗酮和β-紫罗酮等8种异味有机物,并用气相色谱质谱法测定。通过优化试验条件,使方法在2. 00 ng/L～100 ng/L范围内线性良好,方法检出限为1. 0 ng/L～4. 4 ng/L。空白水样3个质量浓度水平的加标回收率为81. 0%～121%,6次测定结果的RSD为1. 7%～8. 9%。将该方法用于一水库实际水样的测定,结果 2-MIB、β-环柠檬醛、α-紫罗酮和β-紫罗酮检出,其余均为未检出。     

高效液相色谱-串联质谱法同时测定地表水中33种药物

采用固相萃取-高效液相色谱-串联质谱法(SPE-HPLC-MS/MS)建立了地表水中25种抗生素类药物和8种非抗生素类药物的分析方法。通过重点优化质谱参数、色谱条件、样品pH、洗脱溶剂组成及用量等确定了最佳分析条件。水样经过滤、固相萃取柱富集净化后，选择Shim-pack XR-ODS为色谱柱，以乙腈和0.2%甲酸-2 mmol/L乙酸铵-水溶液为流动相进行梯度洗脱，采用电喷雾电离源，在多反应监测模式下(MRM)分析测定，内标法定量。33种药物的仪器定量限为0.012～4.68 ng/L,方法检出限为0.011～7.60 ng/L,地表水加标回收率为53.7%～122%,相对标准偏差为1.22%～32.1%(n=6)。方法成功应用于北京市凉水河12个地表水样分析，共检出32种药物，检出质量浓度为未检出～239 ng/L。利托那韦(RTV)作为新型冠状病毒诊疗方案中推荐的药物在凉水河检出率为100%。     

污水处理厂进出水及其受纳水体中典型PPCPs的污染特征

以对乙酰氨基酚为目标物,利用固相萃取(SPE)-高效液相色谱(HPLC)法测定了该药物在泰安市污水处理厂进出水和地表水体中的含量。结果表明,对乙酰氨基酚在污水处理厂进水中均被检出,质量浓度为0.9~238μg/L,表明生活污水为污水处理厂该药物活性成分的来源,出水中质量浓度为ND~8.3μg/L,去除率较高,其中生物降解是主要的降解机制。在泮河中的质量浓度为ND~3.59μg/L,与国内外其他地表水体相比,处于同一个数量级,且污水厂排水口下游水体中目标物浓度高于上游,反映出污水处理厂排放可能是其受纳水体中PPCPs的主要来源之一。     

UPLC-MS/MS法同时测定地表水中多种药物及个人护理品

采用快速液相色谱-三重四级杆串联质谱仪(UPLC-MS/MS)测定地表水中31种药物及个人护理品,通过优化分析条件,使方法在0.01μg/L～10.0μg/L范围内线性良好,方法检出限为0.2 ng/L～1.2 ng/L。地表水样品两个质量浓度水平的加标回收率为64.8%～125%,测定6次结果的RSD≤11%。将该方法用于上海市两条河道中10个水样的测定,结果地西泮、氟康唑、甘宝素、咖啡因、可替宁、氨基比林的测定值为6.56 ng/L～302 ng/L,其余PPCPs未检出。     

杭州贴沙河微囊藻毒素污染特征及健康风险评价

在2014年9月杭州贴沙河出现蓝藻异常增殖期间,利用固相萃取-液质联用法对水体中胞外微囊藻毒素(EMC)和总微囊藻毒素(TMC)进行监测。共检出以MC-LR为主的8种微囊藻毒素(MC)单体,TMC总的质量浓度为63.9 ng/L~1 090 ng/L,其中MC-LR质量浓度为31.6 ng/L~472 ng/L,毒性等效MC-LR浓度为51.8 ng/L~862 ng/L,检出的MC-LR浓度值均低于限值标准。采用USEPA推荐模型对水体中MC污染的健康风险进行评价。各批次水样中MC-LR的非致癌健康风险指数(HI)为0.03~0.39,毒性等效MC-LR的HI介于0.04和0.72之间,均低于基准值,说明贴沙河作为饮用水水源尚无明显的健康风险。     

邕江流域有机氯农药残留问题的初步研究

采用固相萃取和GC-ECD对邕江流域水体中17种痕量有机氯农药的残留状况进行分析测定,检测结果表明,邕江干流均检出硫酸硫丹,但有机氯农药浓度较低,均未超过现有相关标准。城市内河残留的有机氯农药以六六六为主,主要来自于长期的历史残留,而硫酸硫丹除朝阳溪和相思湖丰水期未检测到外,均普遍检出。方法检出限为1~5ng/L,替代物加标回收率为103.5%~112.0%。     

An overview of pharmaceuticals and personal care products contamination along the river Somes watershed, Romania

The mass flows of selected pharmaceuticals and personal care products (PPCPs) were studied in the aqueous compartment of the river Somes in Romania. PPCPs were measured in wastewater treatment effluents and in the receiving river water. The analytical method for the determination of PPCPs in river water was based on solid phase extraction and GC-ITMS. Carbamazepine, pentoxyfylline, ibuprofen, diazepam, galaxolide, tonalide and triclosan were determined in wastewater effluents with individual concentrations ranging from 15 to 774 ng L(-1). Caffeine was measured at concentrations up to 42 560 ng L(-1). Due to the high contamination of WWTP effluents, the receiving river was also polluted. The most abundant PPCPs measured in the Somes were caffeine, galaxolide, carbamazepine and triclosan. They were present at all the 15 sampling sites along the Somes, the concentrations ranging from 10 to 400 ng L(-1). The concentrations in the effluents of the different wastewater treatment plants (WWTPs) varied considerably and the differences are due to different elimination efficiencies of the studied PPCPs during sewage treatment. Only one of 5 WWTPs studied, the WWTP in Cluj-Napoca, was working properly, and therefore technical measures have to be taken for upgrading the WWTPs and reducing the environmental load of micropollutants. This study is the first overview of PPCPs along on Romanian part of river Somes.     

超声波萃取-高效液相色谱-串联质谱同时测沉积物中10种PPCPs化合物

基于EPA1694方法,应用超声波萃取-高效液相色谱-串联质谱技术,建立了沉积物中对乙酰氨基酚、林可霉素、甲氧苄啶、咖啡因、阿奇霉素、磺胺甲唑、泰乐菌素、地尔硫卓、卡马西平及氟西汀等10种药物和个人护理品(PPCPs)的分析检测方法。样品经超声萃取、离心和SAX阴离子交换柱净化,以高效液相色谱-串联质谱仪多反应监测(MRM)模式进行离子定性、定量分析。10种药物加标回收率实验结果表明:添加低浓度样品20 ng/g,回收率为61.1%~128.5%,相对标准偏差(RSD)为1.7%~17.5%(n=5);添加高浓度样品400 ng/g,回收率为66.4%~126.7%,RSD为2.3%~18.0%(n=5),最低检测限为0.12~4.46 ng/g。该方法具有检测限低和回收率高的特点,并经实际样品验证发现,该方法适用于检测沉积物中10种PPCPs化合物。     

Occurrence and fate of pharmaceuticals and personal care products in drinking water in southern China

Occurrence and fate of pharmaceuticals and personal care products (PPCPs) in drinking water was investigated in southern China. Fifteen and twelve PPCPs were detected with concentrations of 0-36 ng L(-1) in source water and of 0-20 ng L(-1) in treated water, respectively. Four PPCPs were detected with concentrations of approximately 1 ng L(-1) in drinking water of distribution network. Conventional water treatment processes removed the types and average concentrations of PPCPs by 30% and above 50%, respectively. Advanced water treatment processes were more efficient in the removal of most PPCPs, with the types and concentrations reduced by 50% and approximately 90%, respectively. Molecular properties of PPCPs had an important influence on their behaviors during water treatment. pK(a) (acidity coefficient) and K(oc) (organic carbon partition coefficient) of PPCPs appeared to have a combined effect on PPCPs removal during coagulation and oxidation. Adsorption and biodegradation were two possible mechanisms responsible for PPCPs removal during sand filtration.     

顶空固相微萃取-气相色谱法测定水中氯苯类化合物

采用顶空固相微萃取（HS －SPME）技术萃取水中6种氯苯类化合物，全面分析对目标物萃取效率的影响因素，并确定萃取试验的最佳条件。用顶空固相微萃取联合气相色谱法（HS －SPME －GC）测定水中6种氯苯类化合物，方法在0.500 ng／L～2.00×10^5 ng／L范围内线性良好，检出限为0.05 ng／L ～2000 ng／L，空白样品加标回收率为69.8％～121％， RSD为4.8％～18.3％。用该方法测定实际水样，平行双样的相对偏差低于20％。     

Using environmental analytical data to estimate levels of community consumption of illicit drugs and abused pharmaceuticals

A solid phase extraction (SPE) method has been developed and applied in conjunction with a previously reported liquid chromatography tandem mass spectrometry (LC-MS-MS) procedure for the determination of illicit drugs and abused pharmaceuticals in treated wastewater and surface water samples at the ng L(-1) level. A full method validation was also performed and determined levels of analytical sensitivity were found to lie in the 1-10 ng L(-1) range using river water as a test sample matrix and a sample size of 500 mL. The developed procedure was successfully applied for the determination of the chosen analytes in wastewater treatment plants in Dublin, Ireland and rapidly expanding commuter towns in the surrounding counties. Cocaine was detected in 70% of the collected samples in the range of 25-489 ng L(-1), its primary metabolite, benzoylecognine (BZE) was also detected in the range of 22-290 ng L(-1). Other substances detected included morphine, Tempazepam and the primary metabolite of methadone.     

SPE-GC-MS/MS法测定水源水中多种有机氯EDCs

采用C 18柱固相萃取(SPE)-三重四级杆气相色谱-质谱法同时测定水中18种含有机氯的环境内分泌干扰物,方法在0.500μg/L^100μg/L范围内线性良好,方法检出限为0.04 ng/L^0.8 ng/L,空白水样的加标回收率为61.3%~108%,6次测定结果的RSD为3.8%~18.0%。将该方法用于饮用水源水监测,18种目标化合物的测定值为未检出~1.5 ng/L,平均加标回收率为71.9%~109%,平行测定结果的RSD<15%。     

固相萃取-超高效液相色谱-串联质谱法同时测定地表水中9种性激素

建立了地表水中9种性激素的固相萃取-超高效液相色谱-串联质谱检测方法。利用HLB固相萃取柱富集水体中痕量性激素,用甲醇洗脱并浓缩,再以1 mmol/L氟化铵-乙腈为流动相,经C_(18)柱分离,采用电喷雾离子源、质谱多反应监测模式,内标法定量,实现了地表水中9种性激素的同时检测。方法检出限为0. 1～1. 8 ng/L,在低、中、高3个加标水平下,性激素的平均回收率为69. 6%～115. 0%,相对标准偏差为3. 2%～17. 7%。该方法灵敏度高,定性准确,操作简单高效,适用于地表水中9种性激素的定性定量分析。     

固相萃取-高效液相色谱法测定水中氯酚类化合物

采用固相萃取-高效液相色谱法测定水中7种氯酚类化合物,Waters OASIS WAX柱萃取效率最高,最佳萃取时间和洗脱时间分别为60和5 min。该法的线性范围为1.0~40 mg/L,检出限为0.015~0.5μg/L,精密度为0.558%~2.22%,回收率为83.2%~105%。该法适用于地表水及饮用水中氯酚类化合物的检测。     

Determination of micropollutants in combined sewer overflows and their removal in a wastewater treatment plant (Seoul,South Korea)

The present study investigated the occurrence of 29 selected micropollutants such as endocrine disrupting compounds (EDCs) and pharmaceuticals and personal care products (PPCPs) in surface waters and wastewaters in Seoul (South Korea) during both dry and wet weather conditions. The study area was selected based on the lack of available information regarding the suspected contamination of rivers/creeks by EDCs and PPCPs in the Seoul region and the presence of a wastewater treatment plant (WWTP), which serves approximately 4.1 million inhabitants and has a design capacity of 1,297?×?10³ m³/day. Many target compounds (83 %) were detected in samples collected from wastewater treatment influent/effluent, creek water, and combined sewer overflow (CSO). The total EDC/PPCP concentrations were as follows: WWTP influent (69,903 ng/L)?>?WWTP effluent (50,175 ng/L) >3 creek samples (16,035–44,446 ng/L) during dry weather, and WWTP influent (53,795 ng/L)?>?WWTP bypass (38,653 ng/L) >5 creek samples (15,260–29,113 ng/L) >2 CSO samples (11,109–11,498 ng/L) during wet weather. EDCs and PPCPs were found to be present at high daily loads (65.1 and 69.8 kg/day during dry and wet weather, respectively) in the WWTP effluent. Compound removal by the WWTP varied significantly by compound: caffeine, diclofenac, ibuprofen, naproxen, and propylparaben (>90 %), and acesulfame, DEET, iohexol, iopromide, and iopamidol (<5 %). These findings and literature information support the hypothesis that the efficiency of removal of EDCs and PPCPs is strongly dependent on both removal mechanism (e.g., biodegradation, adsorption to sludge, and oxidation by chlorine) and compound physicochemical properties (e.g., pK _a and hydrophobicity).