Determination of 15 phthalate esters in air by gas-phase and particle-phase simultaneous sampling

Based on previous research, the sampling and analysis methods for phthalate esters （PAEs） were improved by increasing the sampling flow of indoor air from 1 to 4 L/min, shortening the sampling duration from 8 to 2 hr. Meanwhile, through the optimization of chromatographic conditions, the concentrations of 9 additional PAE pollutants in indoor air were measured. The optimized chromatographic conditions required a similar amount of time for analysis as before, but gave high responsivity, the capability of simultaneously distinguishing 15 kinds of PAEs, and a high level of discrimination between individual sample peaks, as well as stable peak generation. The recovery rate of all gas-phase and particle-phase samples of the 15 kinds of PAEs ranged from 91.26% to 109.42%, meeting the quantitative analysis requirements for indoor and outdoor air sampling and analysis. For the first time, investigation of the concentration levels as well as characteristics of 15 kinds of PAEs in the indoor air from four different traffic micro-environments （private vehicles, busses, taxis and subways） was carried out, along with validation of the optimized sampling and analytical method. The results show that all the 9 additional PAEs could be detected at relatively high pollution levels in the indoor air from the four traffic micro-environments. As none of the pollution levels of the 15 kinds of PAEs in the indoor air from the 4 traffic micro-environments should be neglected, it is of great significance to increase the types of PAEs able to be detected in indoor air.

Pollution levels and characteristics of phthalate esters in indoor air of offices

The pollution status and characteristics of PAEs（phthalate esters） were investigated in indoor air of offices, and PAEs of both gas-phase and particulate-phase were detected in all the samples. The concentration（sum of the gas phase and the particulate phase） was4748.24 ng/m3, ranging between 3070.09 and 6700.14 ng/m3. Diethyl phthalate, dibutyl phthalate, and di（2-ethylhexyl） phthalate were the most abundant compounds, together accounting for 70% of the ∑ 6PAEs. Dividing the particulate-phase PAEs into four size ranges（〈 2.5, 2.5–5, 5–10, 〉 10 μm）, the result indicated that PAEs in PM2.5were the most abundant,with the proportion of 72.64%. In addition, the PAE concentration in PM2.5correlated significantly with the total particulate-phase PAEs（R2= 0.85）. Thus, the amount of PAEs in PM2.5can be estimated from the total amount of particulate-phase PAEs using this proportion. In a comparison between the offices and a newly decorated study room, it was found that pollution characteristics were similar between these two places. Thus, it is implied that the PAE concentration decreased by 50% 2 yr after decorating.

Pollution characteristics of 15 gas- and particle-phase phthalates in indoor and outdoor air in Hangzhou

Phthalate esters(PAEs),typical pollutants widely used as plasticizers,are ubiquitous in various indoor and outdoor environments.PAEs exist in both gas and particle phases,posing risks to human health.In the present study,we chose four typical kinds of indoor and outdoor environments with the longest average human residence times to assess the human exposure in Hangzhou,including newly decorated residences,ordinary residences,offices and outdoor air.In order to analyze the pollution levels and characteristics of 15 gasand particle-phase PAEs in indoor and outdoor environments,air and particulate samples were collected simultaneously.The total PAEs concentrations in the four types of environments were 25,396,25,466.8,15,388.8 and 3616.2 ng/m^3,respectively.DEHP and DEP were the most abundant,and DMPP was at the lowest level.Distinct variations in the distributions of indoor/outdoor,gas/particle-phase and different molecular weights of PAEs were observed,showing that indoor environments were the main sources of PAEs pollution.While most PAEs tended to exsit in indoor sites and gas-phase,the high-molecular-weight chemicals tended to exist in the particle-phase and were mainly found in PM2.5.PAEs were more likely adsorbed by small particles,especially for the indoor environments.There existed a good correlation between the particle matter concentrations and the PAEs levels.In addition,neither temperature nor humidity had obvious effects on the distributions of the PAEs concentrations.

环境中邻苯二甲酸酯类化合物的分析测定

该文概述了环境中邻苯二甲酸酯类化合物的存在现状,综述了不同环境中邻苯二甲酸酯类化合物的前处理方法及其分析测定技术。色谱技术是对环境中邻苯二甲酸酯类化合物进行定性和定量分析测定的主要方法。而色谱分析前的样品制备,包括预分离和预浓缩技术。大气环境样品中邻苯二甲酸酯类化合物的预处理主要采用的是索氏提取、溶液提取和填充柱分离;水环境样品中采用的前处理技术较多,但大多数都是萃取技术;底质和生物试样目前用的较多是微波萃取、超声波萃取和索氏提取。

空气中邻苯二甲酸酯类分析方法的研究进展

邻苯二甲酸酯是一类重要的环境内分泌干扰物,普遍存在于环境中,可通过呼吸等途径进入人体,影响人体健康。该文对空气中邻苯二甲酸酯的采样方法、前处理方法和分析测试手段等进行了综述,并讨论了相关问题,为今后邻苯二甲酸酯的研究提供参考。

大气样品中酞酸酯的分离与测定研究

建立了以硅胶薄层色谱法预分离，反相高效液相色谱法测定大气颗粒物中酞酸酯的分析方法。该方法分离效果好，操作简单，重复性好，回收率达９０％以上。利用该方法分析济南市大气颗粒物中酞酸二丁酯和二异辛酯的污染浓度分别为４５７和５９５ｎｇ／ｍ￣３。

城区大气和塑料大棚空气中酞酸酯的分析

本文报道了济南市大气飘尘和塑料蔬菜大棚空气中酞酸酯的污染情况,探讨了大气飘尘中酞酸酯随季节变比和昼夜更替的变化情况.

液相色谱法测定环境空气中酞酸酯类

制作了半挥发性有机物中流量采样装置,使用超细玻璃纤维滤膜采样,反相液相色谱法测定环境空气中酞酸酯类,并对样品净化方式、目标化合物在气相和颗粒物上的分布规律及采样器的捕集效率进行了试验。方法在0.50 mg/L^50.0 mg/L之间线性关系良好,当浓缩体积为1.0 mL、采样体积为144 m3时,目标化合物的检出限为0.4×10-3μg/m3~6.0×10-3μg/m3;当采样体积为6 m3时,检出限为0.008μg/m3~0.145μg/m3。

北京市朝阳区采暖期和非采暖期PM_(2.5)中四种邻苯二甲酸酯的污染特征及健康风险

目的了解北京市朝阳区采暖期和非采暖期大气细颗粒物(fine particulate matter,PM_(2.5))中四种邻苯二甲酸酯(phthalate esters,PAEs)污染状况,并对其健康风险进行评估。方法使用大流量采样器结合玻璃纤维滤膜采集北京市朝阳区采暖期和非采暖期PM_(2.5)样品,利用气相色谱—静电场轨道阱高分辨质谱法(GC-Orbitrap-MS)分析其中邻苯二甲酸丁基苄基酯(butylbenzyl phthalate,BBP)、邻苯二甲酸二丁酯(dibutyl phthalate,DBP)、邻苯二甲酸二异丁酯(diisobutyl phthalate,DiBP)、邻苯二甲酸二异壬酯(diisononyl phthalate,DiNP)四种邻苯二甲酸酯的浓度水平。结果四种目标PAEs均有不同程度检出,其中DiBP和DBP的检出率最高,总检出率均为100%;采暖期PM_(2.5)中Σ_(4)PAEs平均浓度为143.07 ng/m^(3),是非采暖期浓度的16.5倍;采暖期PM_(2.5)中单体含量为DiBP>DBP>BBP>DiNP,非采暖期则为DiBP>DBP>DiNP>BBP;非采暖期Σ_(4)PAEs浓度与PM_(2.5)浓度呈正相关(r_(s)=0.419,P<0.05),而采暖期无显著相关性;采暖期和非采暖期目标PAEs经呼吸途径对成人和儿童累积暴露的危害指数(hazard index,HI)均小于1。结论北京市朝阳区采暖期和非采暖期PM_(2.5)中四种目标邻苯二甲酸酯暴露健康风险均在可接受范围。

大气环境中气相和颗粒相上酞酸酯的分析

本文选用聚氨基甲酸酯泡沫塑料(PUFP)吸附块和玻璃纤维摅膜(GF)构成大气全态采样头,捕集大气中气相和颗粒相中酞酸酯化合物,样品经提取分离后用气相色谱(GC)进行测定。以呼和浩特市居民区相草原对照区为采样点,分析夏冬雨季大气中酞酸酯(DNBP和DEHP)。结果表明,冬季大气气相中,DNBP和DEHP平均浓度为0.46和1.89μg/m^3,夏季为2.19和1.82μg/m^3;大气颗粒物相,冬季平均为1.34和1.66μg/m^3,夏季为0.51和0.36μg/m^3。夏季大气气相酞酸酯含量高,冬季大气颗粒相酞酸酯含量高。草原对照区大气颗粒物上DNBP和DEHP的平均浓度为0.17和0.14μg/m^3,夏季为0.23和0.10μg/m^3。DNBP和DEHP在大气全态中的总含量冬季和夏季较为接近。

高校典型室内空气中邻苯二甲酸酯的污染特征

为研究杭州市高校典型室内空气中14种邻苯二甲酸酯(PAEs)的污染特征以及对人体的健康风险,对高校师生主要活动场所(教室、宿舍、活动室和办公室)进行了气态和细颗粒态PAEs的空气采样与分析。结果表明,室内空气中气态PAEs浓度均显著大于细颗粒态,其中教室PAEs的平均浓度最高,气态和细颗粒态PAEs的平均浓度分别为21.0μg/m^3和1.31μg/m^3。相关性分析发现,PAEs浓度水平与温度和相对湿度均存在显著正相关。风险评估表明,高校师生在宿舍和教室中的暴露应予以重视。

冬季天津家庭室内空气颗粒物中邻苯二甲酸酯污染研究

为了解我国家庭住宅室内空气颗粒物中邻苯二甲酸酯的污染程度,采集天津市13户家庭住宅冬季室内空气颗粒物PM10、PM2.5样品,采用GC/MS分析了DMP、DEP、DBP、BBP、DEHP、DOP等6种邻苯二甲酸酯.结果表明,室内空气颗粒物中DMP、DEP、DBP、BBP、DEHP这5种邻苯二甲酸酯在所有家庭均被检出,DOP在部分家庭检出.其中,DBP和DEHP为主要污染物.PM10和PM2.5中的6种物质占ΣPAEs颗粒相的比例规律相同,DBP和DEHP较大,分别为13.92%～91.50%、5.56%～85.08%和20.88%～93.95%、5.53%～75.90%;其次是DMP、DEP和BBP,DOP最小.不同粒径颗粒物上PAEs的分布显示,大多数PAEs易吸附在粒径较小的细粒子PM2.5上;结合调查问卷分析表明,冬季室内空气颗粒物上PAEs污染主要来源于室内,受房间的装修时间、装修特点、生活习惯、吸烟、烹饪、塑料制品使用量、室内清洁度和温度等因素的影响.

室内邻苯二甲酸酯(PAEs)暴露量分析

近期流行病学研究结果表明邻苯二甲酸酯(Phthalic Acid Esters,PAEs)可导致人体呼吸系统、生殖系统和内分泌系统产生疾病。目前,室内PAEs的污染问题还未被足够重视,关于室内PAEs暴露量的研究鲜有报道。本文以文献报道的国内外室内PAEs的浓度为依据,估算了我国室内PAEs的气相和颗粒相浓度,并与发达国家相关数据进行了比较,并在此基础上分析了我国不同人群的PAEs暴露量。分析结果表明:我国室内邻苯二甲酸二甲酯(DMP)、邻苯二甲酸二乙酯(DEP)和邻苯二甲酸二(2-乙基己基)酯(DEHP)的浓度(气相、颗粒相和降尘)明显高于发达国家;儿童PAEs的总暴露量明显高于成人,其中30%家庭的2～3岁儿童的DEHP暴露量超过美国环保局限定剂量。由此可以认为,我国室内PAEs的污染问题以及对人体健康的危害较发达国家严重,应引起人们及相关部门的足够重视。

GC/MS法测定室内空气中邻苯二甲酸酯类物质

针对室内空气中日益严重的邻苯二甲酸酯类污染,建立了固相萃取柱采样,GC/MS测定室内空气中16种邻苯二甲酸酯类物质的测试方法,可用于评价室内空气质量。

气体辅助液/液微萃取-气相色谱-三重四极杆质谱联用法测定生活饮用水中的15种邻苯二甲酸酯

目的建立气体辅助液/液微萃取(AALLME)-气相色谱-三重四极杆质谱(GC-MS)测定水中15种邻苯二甲酸酯(PAEs)的方法。方法采用气体辅助液/液微萃取技术(AALLME)富集,离心分离,使用EI源,选择离子扫描(SIM)模式下外标法定量检测。结果 15种邻苯二甲酸酯的浓度为100.0 ng/L^1 000 ng/L时,线性关系良好,相关系数(r)为0.994 9~0.999 9,方法的检出限为10.9 ng/L^37.4 ng/L,定量限为38.9 ng/L^100.0 ng/L,加标回收率为75.9%~124.6%,相对标准偏差为7.6%~16.5%。方法的富集倍数为759倍~1 246倍。结论本方法简单、快速、可靠,免去了分散剂的使用,提高了富集倍数,减少了复杂基质的干扰,提高了目标化合物的灵敏度,可以用于生活饮用水中的15种邻苯二甲酸酯的测定。

Analysis of the influencing factors of PAEs volatilization from typical plastic products

The primary emphasis of this research was to investigate the foundations of phthalate（PAEs） pollutant source researches and then firstly confirmed the concept of the coefficient of volatile strength, namely phthalate total content in per unit mass and unit surface area of pollutant sources. Through surveying and evaluating the coefficient of volatile strength of PAEs from typical plastic products, this research carried out reasonable classification of PAEs pollutant sources into three categories and then investigated the relationship amongst the coefficient of volatile strength as well as other environmental factors and the concentration level of total PAEs in indoor air measured in environment chambers.Research obtained phthalate concentration results under different temperature, humidity,the coefficient of volatile strength and the closed time through the chamber experiment. In addition, this study further explored the correlation and ratio of influencing factors that affect the concentration level of total PAEs in environment chambers, including environmental factors, the coefficient of volatile strengths of PAEs and contents of total PAEs in plastic products. The research created an improved database system of phthalate the coefficient of volatile strengths of each type of plastic goods, and tentatively revealed that the volatile patterns of PAEs from different typical plastic goods, finally confirmed that the coefficient of volatile strengths of PAEs is a major factor that affects the indoor air total PAEs concentration, which laid a solid foundation for further establishing the volatile equation of PAEs from plastic products.