电子垃圾拆解对台州氯代/溴代二噁英浓度和组成的影响

电子垃圾拆解会导致有毒有害污染物向大气的排放,造成环境污染的产生。为了解电子垃圾拆解及废旧金属再生活动对拆解地及邻近地区空气质量的影响,对台州峰江金属再生园区附近及对照区路桥市区大气中(气态和颗粒态)氯代二噁英(PCDD/Fs)、溴代二噁英(PBDD/Fs)的含量、同系物组成及气/固分配规律进行了研究,通过相关性分析探讨了PCDD/Fs和PBDD/Fs的可能来源。结果显示,金属再生园区冬季采样期间17种2,3,7,8-PCDD/Fs和8种2,3,7,8-PBDD/Fs的平均浓度分别为212.2 pg·m-3和17.6 pg·m-3,夏季采样期间的平均浓度分别为84.5 pg·m-3和5.4 pg·m-3,均显著高于对照点。夏季采样期间对照点处于再生园区的下风向,其二噁英浓度高于冬季,说明其受到了金属再生园区的明显影响。基于相关性分析的结果,塑料焚烧是金属再生活动中氯代和溴代二噁英的主要来源。初步的暴露风险评价表明,金属再生园区附近居民每日摄入的二噁英含量远远超过世界卫生组织规定的人体每日耐受量(1~4 pg W-TEQ·kg-1·d-1)。上述研究结果为规范电子垃圾拆解活动提供了基础数据。     

苏南城市群河流表层沉积物中二噁英和共平面多氯联苯的浓度水平、来源和生态风险

对25个苏南城市群河流表层沉积物中二噁英及17个样品中共平面多氯联苯的监测表明,PCDD/Fs和dl-PCBs中位值分别为6.61 ng WHO1998TEQ·kg-1和1.43 ng WHO1998TEQ·kg-1,均处于我国和亚洲河流表层沉积物的中等水平.PCDD/Fs和dl-PCBs含量水平与经济发展水平和工业规模呈现正相关.开发区新建企业是PCDD/Fs的新排放源之一.统计分析表明,南通PCDD/Fs的排放以燃煤和农药五氯酚的使用为主,无锡来源于农业活动和少量工业污染源,苏州则受到目前工业排放源的影响,3个城市的PCBs主要来源于历史上PCBs工业品的使用.96%的采样点总毒性当量浓度(TEQ)超过加拿大沉积物质量指导值(ISQGs),88%的采样点超过美国EPA ISQGs,表明苏南城市群表层沉积物PCDD/Fs和dl-PCBs具有一定生态风险.     

典型电子垃圾拆解区二噁英污染特征、相分配及暴露风险

选取南方某典型电子垃圾拆解区不同作业区为研究对象,重点研究了拆解地大气中二噁英的污染特征、气相-颗粒相分配及呼吸暴露风险。通过对5个采样点（包括1个背景点）的研究发现,电子垃圾拆解作业区颗粒相ΣPCDD/Fs的质量浓度为：20.64-56.14 pg·m^-3,毒性当量为：I-TEQ 0.293-1.490 pg·m^-3;气相ΣPCDD/Fs的质量浓度为：3.861-19.29 pg·m^-3,毒性当量为：I-TEQ 0.384-2.150 pg·m^-3。背景点大气中二噁英浓度相对较低,颗粒相和气相样品中质量浓度值分别为：3.734 pg·m^-3和2.637 pg·m^-3,毒性当量仅为I-TEQ 0.176-0.267 pg·m^-3;要明显低于电子垃圾拆解区。基于污染物气相-颗粒相分配系数与蒸汽压的关系对二噁英的气-固分配行为研究显示,除了拆解混合作业区有较好的分配系数（-0.64）外,其它监测点位二噁英的气-固平衡状态较弱（-0.27--0.03）,更多的是以低分子量的单体化合物赋存于气相样品中。对拆解区二噁英呼吸暴露风险研究结果表明,儿童呼吸暴露风险要高于成年人;同时无论是儿童还是成年人,其二噁英的呼吸暴露量均要高于国内外城市报道的二噁英人体呼吸暴露量,说明本次监测的电子垃圾拆解区存在的潜在健康风险不容忽视。     

四川省卧龙地区土壤中二噁英类化合物和多氯萘的海拔梯度分布及对牦牛的毒性风险评价

初步研究了四川省卧龙地区5个不同海拔高度的表层土壤和2个牦牛样品中二噁英/呋喃(PCDD/Fs)、共平面多氯联苯(co-PCBs)和多氯萘(PCNs)的分布特征、来源、毒性当量以及生态风险状况.土壤样品中总2,3,7,8-PCDD/Fs的含量范围为2.48-4.30 pg·g-1dw,平均3.50 pg·g-1dw,最高含量在海拔3927 m的塘房.co-PCBs的总含量平均为9.14 pg·g-1dw,最高值在海拔4487 m的垭口.总2,3,7,8-PC-DD/Fs和总co-PCBs含量随海拔高度的变化表现出正相关关系.不同海拔高度土壤中的PCDD/Fs和co-PCBs异构体的分布相似,表明具有相同的来源.总PCNs与海拔梯度呈负相关关系,最高含量出现在海拔3345 m的贝母坪,平均21.4 pg·g-1dw,主要以3.氯为主.土壤中PcDD/Fs毒性当量浓度范围为0.29-0.43pg TEQ·g-1dw.牦牛肉和牦牛组织中PcDD,/Fs总浓度分别为27.5和23.6 pg·g-1脂肪,毒性当量浓度为4.04和4.07 pg TEQ·g-1脂肪.结果表明,牦牛中的PCDD/Fg,co-PcBs和PCNs不大可能对卧龙地区人群导致严重的负面效应.     

高分辨气相色谱-质谱法同时测定土壤及沉积物中二英、溴代二英、多氯联苯和多溴联苯醚

采用同位素内标稀释-高分辨气相色谱-高分辨质谱法同时测定土壤及沉积物样品中PCDD/Fs、PBDD/Fs、DL-PCBs和PBDEs 4种二英类持久性有机物的含量.利用凝胶渗透色谱、多层酸碱硅胶净化柱、活性炭分散硅胶净化柱针对不同二英类污染物的不同吸附特性,运用不同极性的溶剂淋洗,实现二英组分(PCDD/Fs、PBDD/Fs)和其他两个组分(DL-PCBs、PBDEs)的分离,排除了同系物间及其他物质的干扰.所建方法的精密度变化范围在1.4%—13.6%之间,净化内标回收率范围在61%—104%之间,PCDD/Fs和PBDD/Fs的检出限分别在0.048—0.153 pg·g-1和0.044—0.395 pg·g-1之间,DL-PCBs和PBDEs的检出限分别在0.028—0.105 pg·g-1和0.034—10.2 pg·g-1之间,目标物检测结果大部分在质控样品标准范围之内,本文所建立的方法可以用于土壤及沉积物中PCDD/Fs、PBDD/Fs、DL-PCBs和PBDEs的同时净化分离.     

利用蚀刻废液生产碱式氯化铜过程中二英类污染物的去除

针对蚀刻废液及其回收后生产的碱式氯化铜产品中二英(PCDD/Fs)和二英类多氯联苯(dl-PCBs)进行了分析研究,并比较了采用去除工艺前后两类污染物含量水平的变化特征.利用高分辨气相色谱/高分辨质谱对样品中PCDD/Fs和dl-PCBs进行分析,结果表明,氯化铜废液中PCDD/Fs和dl-PCBs的平均总浓度分别为264、139 pg·mL-1,而铜氨液中浓度分别为0.09、0.50 pg·mL-1;碱式氯化铜产品中浓度分别为106 pg·g-1(2.79 pg WHO-TEQ2005·g-1)和27.8 pg·g-1(0.69 pg WHO-TEQ2005·g-1);而经过吸附和过滤等去除工艺后,产品中PCDD/Fs和dl-PCBs的TEQ浓度水平分别降低至0.10—0.25 pg WHO-TEQ2005·g-1和0.05—0.72 pg WHO-TEQ2005·g-1,满足欧盟对于矿物源性饲料添加剂中PCDD/Fs和dl-PCBs的限量标准要求.研究表明该工艺能够有效去除利用蚀刻废液生产碱式氯化铜过程中的二英类污染物.     

南四湖沉积物中二噁英类化合物的分布

用1 3C同位素内标法 ,高分辨率气相色谱 高分辨率质谱对南四湖表层沉积物中 1 7种含 2 3 7 8 氯代二苯并二英 /呋喃 (PCDD/Fs)及 1 2种共平面多氯联苯 (Co PCBs)的含量、同系物异构体的分布特征、沉积通量、毒性当量及来源进行了初步分析 ,并与山东近海 (日照、烟台、青岛 )的测定结果进行比较 .总Co PCBs含量分别为 5 4 4pg·g- 1 dw (南阳湖 )和 41 4pg·g- 1 dw (微山湖 ) .总PCDD/Fs含量分别为 1 0 6 7pg·g- 1 dw (南阳湖 )和1 47 0pg·g- 1 dw (微山湖 ) .两湖含 2 3 7 8 PCDD/Fs异构体对总毒性当量浓度的贡献基本相同 ,即以四—五氯代异构体为主 .PCDD/Fs含量次序为青岛 >日照 >南四湖 >烟台 .南四湖、日照、烟台近海沉积物中的PCDD/Fs对总TEQ (PCDD/F TEQ PCB TEQ)的贡献为68 8%— 93 0 % .南四湖与山东近海沉积物中PCDDs/PCDFs比值和OCDD %∑百分比表明 ,山东省PCDD/Fs的来源较为一致 ,相对恒定 .除河口处外 ,大气沉降应是南四湖及山东近海PCDD/Fs的主要来源 .     

南四湖沉积物中二(口恶)英类化合物的分布

用13C同位素内标法,高分辨率气相色谱-高分辨率质谱对南四湖表层沉积物中17种含2,3,7,8-氯代二苯并二NB12E英/呋喃(PCDD/Fs)及12种共平面多氯联苯(Co-PCBs)的含量、同系物异构体的分布特征、沉积通量、毒性当量及来源进行了初步分析,并与山东近海(日照、烟台、青岛)的测定结果进行比较.总Co-PCBs含量分别为54.4pg·g-1dw(南阳湖)和41.4pg·g-1dw(微山湖).总PCDD/Fs含量分别为106.7pg·g-1 dw(南阳湖)和147.0pg·g-1 dw(微山湖).两湖含2,3,7,8-PCDD/Fs异构体对总毒性当量浓度的贡献基本相同,即以四-五氯代异构体为主.PCDD/Fs含量次序为青岛＞日照＞南四湖＞烟台.南四湖、日照、烟台近海沉积物中的PCDD/Fs对总TEQ(PCDD/F-TEQ+PCB-TEQ)的贡献为68.8%-93.0%.南四湖与山东近海沉积物中PCDDs/PCDFs比值和OCDD%∑百分比表明,山东省PCDD/Fs的来源较为一致,相对恒定.除河口处外,大气沉降应是南四湖及山东近海PCDD/Fs的主要来源.     

北京市一次重污染天气下大气颗粒物中PCDD/Fs、PCNs、PCBs粒径分布特征及呼吸暴露风险评估

本研究于2017年5月4日至7日,采集了北京城区一次重污染天气下4种不同粒径段(10μm、5—10μm、2.5—5μm、2.5μm)大气颗粒物样本,并采集了晴朗天气样本作为对照.首先,测定了各粒径段颗粒物中17种2,3,7,8-PCDD/Fs、三氯代至八氯代PCNs及12种dl-PCBs单体的含量,进而对这些化合物的粒径分布特征及呼吸暴露风险进行了分析和评估.结果表明,在本次重污染天气下,北京城区大气颗粒物中PCDD/Fs、PCNs、dl-PCBs浓度依次为8.03、6.68、1.18 pg·m~(-3),明显高于晴朗天气.PCDD/Fs、PCNs、dl-PCBs主要富集于粒径2.5μm的细颗粒物中,含量分别达到86.5%、47.9%、39.8%.PCNs、dl-PCBs大致呈现出随颗粒物粒径减小,其高氯代同系物相对富集量增加的趋势.通过呼吸暴露风险评估发现,本次重污染天气下大气颗粒物中PCDD/Fs、PCNs、dl-PCBs致癌风险分别为1.1×10~(-5)、1.4×10~(-7)、2.2×10~(-7),总致癌风险是晴朗天气下的33倍.PCDD/Fs对总致癌风险贡献率为96.7%,是需优先控制的持久性有机污染物.     

北京市冬季大气细颗粒物中二■英的污染特征

为了解北京市大气细颗粒物(PM_(2.5))中二■英(PCDD/Fs)的污染特征,利用中流量大气颗粒物采样器,在北京市3个功能区5个采样点(两个市区点、两个工业区点和一个背景点),同步连续采集了大气细颗粒物PM_(2.5)样品.参照US EPA 1613B标准方法,应用高分辨率气相色谱/高分辨率质谱(HRGC/HRMS),分析了PM_(2.5)中17种PCDD/Fs的浓度水平和区域分布特征,并对PCDD/Fs的污染来源做了初步探讨.结果表明,5个采样点PM_(2.5)的日均质量浓度范围102—146μg·m~(-3),平均日均值119μg·m~(-3),超出国家二级标准(75μg·m~(-3))59%,污染较重.在空间分布上,PM_(2.5)的日均浓度表现为工业区大于背景点大于市区的特征.所有采样点17种PCDD/Fs的总浓度范围∑PCDD/Fs是1.60—4.09 pg·m~(-3),平均值3.23 pg·m~(-3),PCDD/Fs总毒性当量∑TEQ范围是140.54—275.69 fg I-TEQ·m~(-3),平均值233.18 fg I-TEQ·m~(-3).与国内外其他城市相比,北京市大气PM_(2.5)中PCDD/Fs污染处于相当或略高水平.OCDD、OCDF和1,2,3,4,7,8-HpCDF是PCDD/Fs的主要组成成分,分别占总浓度∑PCDD/Fs的10%、19%和24%.对于总毒性当量∑TEQ贡献最大的是2,3,4,7,8-PeCDF,占总毒性当量的48.3%,∑PCDDs/∑PCDFs比值范围为0.19—0.23,平均值0.22,属于典型的"热源"特征.在浓度变化上, PCDDs呈现为随氯取代个数的增加而增加,除OCDF外, PCDFs的各单体浓度也随着取代氯原子个数的增加而增大.在区域分布上,PCDD/Fs浓度表现为工业区高于市区,市区大于背景点,充分体现了局地源的特点.采样期间工业热过程(化石燃料燃烧、电弧炉、烧结和冶炼等)、机动车排放和固体垃圾焚烧是北京冬季大气PM_(2.5)中PCDD/Fs和PM_(2.5)污染水平的主要影响因素.     

Pollution characteristics and potential health risk of polychlorinated dibenzo-p-dioxins and dibenzofurans (PCDD/Fs) in soil/sediment from Baiyin City, North West, China

In order to better understand the environmental behaviors of persistent organic pollutants, the characteristics of polychlorinated dibenzo-p-dioxins and dibenzofurans (PCDD/Fs) were investigated in twenty-three soil/sediment samples from Baiying City, Northwest China, in 2008. The possible sources and potential health risk of PCDD/Fs were also discussed. The concentrations of PCDD/Fs in nineteen soil samples varied between 20.13 and 496.26 pg/g dry weight (dw.), with an average value of 125.59 pg/g dw. The highest International Toxic Equivalent (I-TEQ) of PCDD/Fs (8.34 pg/g dw.) in soil was found at sample S1 collected from proximity to a copper metallurgy plant. The concentrations of PCDD/Fs in four sediment samples ranged from 37.69 to 491.49 pg/g dw., with an average value of 169.95 pg/g dw. The highest I-TEQ of PCDD/Fs (8.56 pg/g dw.) in sediment was found at sample S12 collected from the East big ditch with waste water discharged into the Yellow River. The results indicated that PCDD/Fs contamination of soil/sediment is originated from three sources: chlorine-containing chemicals, non-ferrous metal industrial PCDD/Fs emission and coal burning. The health risk exposure to PCDD/Fs through soil, dust ingestion and dermal absorption ranged from 0.0006 to 0.0134 pg/kg/day Word Health Organization’s toxic equivalent in 1998 (WHO₁₉₉₈-TEQ) with mean values 0.0032 pg WHO₁₉₉₈-TEQ for adults and varied between 0.0012 and 0.0256 pg/kg/day WHO₁₉₉₈-TEQ with mean values 0.006 pg/kg/day WHO₁₉₉₈-TEQ for children, respectively. These results indicated that health risk of PCDD/Fs for children should be paid more attention.     

PCDD/Fs emission, risk characterization, and reduction in China’s secondary copper production industry

Secondary copper production is one of the key polychlorinated dibenzo-p-dioxins and dibenzofurans (PCDD/Fs) emission sources in China, but research and data on this issue are rare. In 2004, when the Stockholm Convention entered into force in China, PCDD/Fs emissions from secondary copper production contributed to 32.2% of the total release. In this paper, PCDD/Fs emission dynamics from secondary copper industry were discussed and cumulative risks were characterized. From 2004 to 2009, industrial policies played an indirect role in PCDD/Fs reduction, but its effects are still limited. The Yangtze River Delta, Pearl River Delta and central regions were among the top three of dioxin emissions from secondary copper production in China. Shanghai, Shandong, Zhejiang, and Jiangxi had comparatively higher accumulated risk and were recommended as the priority regions for promoting PCDD/Fs emission control in China. From 2009 to 2015, the PCDD/Fs emission dynamics in the secondary copper industry were presented through simulation. PCDD/Fs emission equations were established, resulting in the recommendation of control technology conversion rate at 30% for small scale smelters and 51%–57% for large and medium-sized enterprises in 2015. In conclusion, both indirect policy and direct control technology retrofitting should be integrated for more effective PCDD/Fs emission reduction in secondary copper industry.     

珠江河口沉积物中拟除虫菊酯类农药污染及毒性评价

拟除虫菊酯农药是一种广谱、高效、低毒、低残留的亲脂性杀虫剂,它会随农田排水、降雨淋洗进入水体,最终进入沉积环境,故沉积物是其最终归宿之一。本研究针对珠江河口沉积物中菊酯类农药的污染状况进行调查,研究它们的含量、组成比例、污染来源及其潜在毒性,为珠江渔业水生生态环境管理及掌握环境中有机污染情况提供依据,对保护渔业环境安全有十分重要的意义。2012年5月采集珠江河口表层沉积物,采用气相色谱法-电子捕获法（GC-ECD）对表层沉积物中联苯菊酯、甲氰菊酯、高效氯氟氰菊酯、氯菊酯、氯氰菊酯、氰戊菊酯、溴氰菊酯进行残留检测,并利用其对钩虾的生物毒性来评价沉积物的潜在毒性。结果显示,表层沉积物（以干质量计）中7种菊酯类农药质量分数介于ND~6.59μg·kg-1（ND表示未检出）,平均值为0.75μg·kg-1,其总质量分数与有机碳质量分数呈现一定的正相关性;组成比例表明,氯菊酯最多,占总量的57.63%,它的检出率为61.90%,甲氰菊酯其次,约占总量的16.39%,检出率为28.57%,氯菊酯占主要组成部分,可能与其在珠江三角洲居民生活中被大量使用及其降解速率有关;珠江桥采样点高浓度的菊酯类农药的检出（6.59μg·kg-1）,可能与其靠近人口密集和经济发达的广州有关;与国内外其他地区相比,珠江河口沉积物中菊酯农药处于较低水平;采用毒性单元TU（选用钩虾Hyallela Azteca的LC50）进行毒性评估,∑TU值范围为0~0.09,远远低于1,表明珠江河口拟除虫菊酯不存在生态风险。     

Distribution,seasonal variation and inhalation risks of polychlorinated dibenzo-<Emphasis Type="Italic">p</Emphasis>-dioxins and dibenzofurans,polychlorinated biphenyls and polybrominated diphenyl ethers in the atmosphere of Beijing,China

Spatial distribution, seasonal variation and potential inhalation risks of polychlorinated dibenzo-p-dioxins and dibenzofurans (PCDD/Fs), polychlorinated biphenyls (PCBs) and polybrominated diphenyl ethers (PBDEs) were investigated in the atmosphere of Beijing, using passive air samplers equipped with polyurethane foam disks. Concentrations of ΣPCDD/Fs, ΣPCBs and ΣPBDEs ranged from 8.4 to 179 fg WHO₂₀₀₅-TEQ/m³, 38.6–139 and 1.5–176 pg/m³, respectively. PCDFs showed higher air concentrations than those of PCDDs, indicating the influence of industrial activities and other combustion processes. The non-Aroclor congener, PCB-11, was detected in air (12.3–99.4 pg/m³) and dominated the PCB congener profiles (61.7–71.5% to ∑PCBs). The congener patterns of PBDEs showed signatures from both penta-BDE and octa-BDE products. Levels of PCDD/Fs, PCBs and PBDEs at the industrial and residential sites were higher than those at rural site, indicating human activities in urban area as potential sources. Higher air concentrations of PCDD/Fs, PCBs and PBDEs were observed in summer, which could be associated with atmospheric deposition process, re-volatilization from soil surface and volatilization from use of technical products, respectively. Results of inhalation exposure and cancer risk showed that atmospheric PCDD/Fs, dioxin-like PCBs and PBDEs did not cause high risks to the local residents of Beijing. This study provides further aid in evaluating emission sources, influencing factors and potential inhalation risks of the persistent organic pollutants to human health in mega-cities of China.     

Legacies and health risks of heavy metals,polybrominated diphenyl ethers,and polychlorinated dibenzo-dioxins/furans at e-waste recycling sites in South China

● Heavy metals and organic toxins may persist in legacy sites for a long time. ● Contaminants pose potential harms to the nearby community (HI > 1). ● PCDD/Fs had the risk of endocrine disruption and reproductive risk. ● Further intervention is needed to reduce pollution and related risks. Informal electronic-waste (e-waste) recycling sites pose substantial health risks to surrounding environments and populations, yet they are not properly regulated. In this study, the soil levels of copper, lead, cadmium, eight polybrominated diphenyl ethers (PBDEs), and 18 polychlorinated dibenzo-dioxins/furans (PCDD/Fs) were measured at two e-waste recycling sites in South China between 2014 and 2019. Both sites have been abandoned for natural restoration. Our results indicate that the mean Cd and PCDD/F levels at Site A in 2019 were higher than those recommended by current safety guidelines. Meanwhile, the highest exposure among children was 1.36 × 10⁻² mg/(kg·d) for Cu, followed by 5.05 × 10⁻³ mg/(kg·d) for Pb, 9.71 ng/(kg·d) for PBDEs, and 6.82 ng TEQ/(kg·d) for PCDD/Fs. Children were at elevated risk for health problem posed by Pb and Cu exposure at both sites (hazard quotient > 1) and by PCDD/Fs at Site A. Further risk assessment was conducted on the target organs and endpoints of heavy metals and PCDD/Fs. The hazard index (HI) for the target organ mixed-risk of heavy metals was high (HI = 1.27), as was that of PCDD/Fs (HI = 1.66), which can disrupt endocrine function and pose a risk of reproductive toxicity in children. Owing to incomplete cleaning, contaminants persist in soils over long periods and may harm nearby environments and communities. Our study demonstrates that heavy metal, PBDE, and PCDD/F contamination have not yet been remediated, and intervention is needed to reduce pollution and associated risks in areas affected by e-waste.     

北京市农业区不同使用类型土壤中二噁英类分析

2005年6—7月采集了北京市农业区不同使用类型土壤样品24个,分别为蔬菜地8个、粮地8个、果园地8个,采用高分辨气质联机对17种二噁英类进行了分析.结果表明:所有样品中二噁英浓度范围为,0.26—5.74(平均值为1.51)pgI-TEQ.g-1;蔬菜地浓度范围为,0.26—5.62(平均值1.75)pgI-TEQ.g-1;粮地浓度范围为,0.45—5.74(平均值2.02)pgI-TEQ.g-1;果园地浓度范围为,0.34—2.02(平均值0.73)pgI-TEQ.g-1;三种类型中粮食地浓度最高,其次为蔬菜地,果园地浓度最低.与国外农业区土壤中的二噁英浓度相比而言,北京市相对较低.所有样品中,样品8和16浓度异常高,但是8.3%(2:24)的高浓度样品数并不代表对人体有害.由于样品24处于垃圾焚烧炉旁边,也对此进行了详细的分析.样品中二噁英类物质形态分布出现了极大的离散性,这表明农田土壤中二噁英可能是多种因素综合作用的结果,例如:除草剂的使用、秸秆等固体废弃物的焚烧、汽车尾气排放等.     

福建省稻米中的砷水平及其健康风险研究

为更好了解区域水平上水稻(OryzasativaL.)砷所引起的健康风险,在福建省9个地区采集了206份水稻样品并对其总砷和无机砷含量进行了分析,然后在此基础上建立风险评价模型并对其健康风险进行了评价。结果表明,福建省水稻精米中总砷平均含量为(0.105±0.091)mg·kg-1,无机砷平均含量为(0.045±0.019)mg·kg-1。全省所有样品中无机砷含量符合中国国家标准规定的限量标准(MCL)0.15mg·kg-1。通过膳食调查的数据和水稻无机砷含量对每天通过稻米消费无机砷摄入量进行了计算,全省平均每天无机砷摄入量为13.50μg,并且9个地区每天无机砷摄入量均超过了美国国家研究委员会所规定的最大限量标准10μg·d-1。根据无机砷摄入量和癌症斜率因子所构建的癌症风险模型结果表明,福建省稻米无机砷所引起的癌症风险为每100000有37.5人,虽然低于中国的平均水平(每100000有61人),但是超过了美国国家环境保护局所规定的可以接受的癌症风险的上限(每100000人有10人)。因此,需要进一步通过流行病学方面的调查来确定福建省稻米无机砷摄入和健康风险之间的关系。     

兰州地区人群对多环芳烃的暴露及健康风险评价

采用多介质-多途径暴露模型,评价兰州地区居民暴露于多环芳烃的健康风险,分析风险来源、暴露介质及暴露途径,并结合蒙特卡罗方法分析研究过程中的不确定性。结果表明,兰州地区居民中男性和女性对环境中多环芳烃的终身日平均暴露量分别为4.55×10-4和5.07×10-4mg.kg-1.d-1。暴露途径中食物摄取是最主要途径,食物中贡献较大的为谷物。相应的男性和女性的健康风险度分别为4.12×10-5.a-1和4.80×10-5.a-1,兰州地区多环芳烃类污染物居民人体健康风险度远远高于可接受健康风险度的标准。兰州地区女性对多环芳烃的暴露量高于男性,女性健康风险平均值亦远远高于EPA标准值,兰州地区女性乳腺癌发病率较高可能与长时间低剂量多环芳烃暴露有一定的关系。兰州地区多环芳烃人群暴露与天津和北京相比存在一定的差异。