1.1 本试验方法涵盖室内空气中尼古丁和3-乙烯基吡啶（3-EP）的采样/分析。本试验方法基于通过吸附剂树脂吸附收集尼古丁和3-EP，从吸附剂树脂中提取尼古丁和3-EP，并通过气相色谱（GC）和氮选择性检测进行测定 ( 1. ) . 2. 1.2 活性取样器由连接至取样泵的大孔聚苯乙烯-二乙烯基苯共聚物（例如XAD-4）吸附剂管组成。在本方法中，大孔聚苯乙烯-二乙烯基苯共聚物被称为“吸附树脂”。本试验方法适用于个人或区域取样。 1.3 本试验方法受尼古丁吸附管容量（约300μg）的限制。本试验方法已在24小时样品持续时间内进行了评估；然而，通常为以下目的采集样本: 至少 1小时（有时 只有 1小时） ( 2. ) . 1.4 对于本试验方法，采样率为1.5 L/min时，尼古丁的检测限（LOD）和定量限（LOQ）分别为0.11μg/m 3. 和0.37μg/m 3. 1小时样品持续时间和0.01μg/m 3. 和0.05μg/m 3. 8小时样本持续时间。3-EP在1.5 L/min采样率下的LOD和LOQ分别为0.06μg/m 3. 和0.19μg/m 3. 1小时样品持续时间和0.01μg/m 3. 和0.02μg/m 3. 8小时样本持续时间 ( 2. ) . 通过增加热离子特定检测器的灵敏度，可以降低LOD和LOQ。 1.5 单位- 以国际单位制表示的数值应视为标准值。本标准不包括其他计量单位。 1.6 本标准并非旨在解决与其使用相关的所有安全问题（如有）。本标准的用户有责任在使用前制定适当的安全、健康和环境实践，并确定监管限制的适用性。 具体预防信息见 13.6 . 1.7 本国际标准是根据世界贸易组织技术性贸易壁垒（TBT）委员会发布的《关于制定国际标准、指南和建议的原则的决定》中确立的国际公认标准化原则制定的。 ====意义和用途====== 5.1 为了估计ETS浓度，需要有一种ETS标记物或示踪剂，该标记物或示踪剂对烟草烟雾具有独特性或高度特异性，在空气中具有足够的浓度，可以在实际吸烟率下轻松测量，并且与各种烟草混合物和环境条件下的ETS的其他成分成恒定比例。尼古丁和3-乙烯基吡啶已被用作ETS气相的示踪剂。尼古丁是烟草中的主要生物碱，也是ETS的主要成分。 尼古丁浓度的测定通常用于估计ETS的浓度；然而，由于其不可预测的衰变动力学，尼古丁可能不是一种理想的示踪剂。由于尼古丁很容易吸附到建筑材料和房间家具上，并且从ETS中消耗的速度比大多数其他成分都快，一些人认为尼古丁浓度低估了ETS浓度。虽然在产生烟雾的许多环境中都是这样，但在最近有吸烟史的环境中则相反。随着时间的推移，被吸附的尼古丁缓慢解吸，导致ETS浓度过高。因此，测得的尼古丁浓度仅准确评估空气中的尼古丁，并仅表明吸烟；它们不一定表示其他ETS成分的存在，当然也不表示其他ETS成分的浓度。 另一方面，通过CO和FID响应测量，3-乙烯基吡啶可以准确跟踪ETS的汽相 ( 3. ) . 正是由于这些原因，3-乙烯基吡啶可能是一种更好的ETS示踪剂 ( 1. , 4. , 5. ) . 众所周知，高浓度的ETS对个人来说是令人讨厌和刺激的，人们也对其潜在的健康影响表示担忧。确实需要有可靠的方法来估计ETS水平，以评估其效果。NIOSH此前已将工作场所尼古丁的推荐接触限值（REL）设定为0.5 mg/m 3. . 5.2 研究表明，超过90 % 室内空气中的尼古丁主要以气相形式存在 ( 6. , 7. ) . 所述测试方法定量收集气相尼古丁。对新生成的ETS的早期研究表明，部分但不是全部的颗粒相被截留在树脂上 ( 7. ) . 最近对吸附床捕集颗粒材料的研究表明，室内空气中颗粒的捕集可能几乎是定量的 ( 8. ) . 3-乙烯基吡啶仅存在于气相中。 5.3 尼古丁浓度通常在ND（未检测到）到70μg/m之间 3. 在各种室内环境中，其值通常在此范围的低端 ( 9 ) . 由于经常遇到如此低浓度的尼古丁，因此需要复杂的分析程序和设备来定量室内空气中的尼古丁。还报告了其他测定室内空气中尼古丁的方法 ( 6. , 10 , 11 , 12 ) . 3-乙烯基吡啶浓度通常约为现实环境中尼古丁浓度的三分之一 ( 13 ) .

1.1 This test method covers the sampling/analysis of nicotine and 3-ethenylpyridine (3-EP) in indoor air. This test method is based upon the collection of nicotine and 3-EP by adsorption on a sorbent resin, extraction of nicotine and 3-EP from the sorbent resin, and determination by gas chromatography (GC) with nitrogen selective detection ( 1 ) . 2 1.2 The active samplers consist of an macroreticular polystyrene-divinylbenzene copolymer (for example, XAD-4) sorbent tube attached to a sampling pump. Macroreticular polystyrene-divinylbenzene copolymer is referred to “sorbent resin” throughout this method. This test method is applicable to personal or area sampling. 1.3 This test method is limited in sample duration by the capacity of the sorbent tube for nicotine (about 300 μg). This test method has been evaluated up to 24-h sample duration; however, samples are typically acquired for at least 1 h (sometimes only 1 h) ( 2 ) . 1.4 For this test method, limits of detection (LOD) and quantitation (LOQ) for nicotine at a sampling rate of 1.5 L/min are, respectively, 0.11 μg/m 3 and 0.37 μg/m 3 for 1-h sample duration and 0.01 μg/m 3 and 0.05 μg/m 3 for 8-h sample duration. The LOD and LOQ for 3-EP at a sampling rate of 1.5 L/min are, respectively, 0.06 μg/m 3 and 0.19 μg/m 3 for 1-h sample duration and 0.01 μg/m 3 and 0.02 μg/m 3 for 8-h sample duration ( 2 ) . Both LOD and LOQ can be reduced by increasing the sensitivity of the thermionic specific detector. 1.5 Units— The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard. 1.6 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use. Specific precautionary information is given in 13.6 . 1.7 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee. ====== Significance And Use ====== 5.1 In order to estimate ETS concentrations, there needs to be a marker or tracer for ETS that is unique or highly specific to tobacco smoke, in sufficient concentrations in air to be measured easily at realistic smoking rates, and in constant proportion to the other components of ETS for a variety of tobacco blends and environmental conditions. Nicotine and 3-ethenylpyridine have been used as tracers of the vapor phase of ETS. Nicotine is the major alkaloid of tobacco and a major constituent of ETS. The determination of nicotine concentration has often been used to estimate the concentration of ETS; however, due to its unpredictable decay kinetics, nicotine may not be an ideal tracer. Because nicotine readily adsorbs to building materials and room furnishings and is depleted from ETS at a rate faster than most other components, some have suggested that nicotine concentrations underestimate ETS concentrations. Although this is true in many environments during the generation of smoke, the converse is true in environments with a recent past history of smoking. The adsorbed nicotine slowly desorbs over time, resulting in an overestimation of ETS concentrations. Thus, measured concentrations of nicotine precisely assess only airborne nicotine and indicate only that smoking has taken place; they do not necessarily indicate the presence, and certainly not the concentrations, of other ETS constituents. 3-Ethenylpyridine, on the other hand, has been shown to track exactly the vapor phase of ETS as measured by CO and FID response ( 3 ) . It is for these reasons that 3-ethenylpyridine may be a better tracer of ETS ( 1 , 4 , 5 ) . The ETS at high concentrations is known to be annoying and irritating to individuals, and concerns over potential health effects have also been expressed. There is a definite need to have reliable methods for the estimation of ETS levels in order to evaluate its effect. The NIOSH has previously set a recommended exposure limit (REL) for nicotine in the workplace of 0.5 mg/m 3 . 5.2 Studies show that more than 90 % of nicotine in indoor air is found in the vapor phase ( 6 , 7 ) . The described test method collects vapor-phase nicotine quantitatively. Early studies on freshly generated ETS indicated that some but not all of the particulate phase was trapped on the resin ( 7 ) . A more recent investigation of the trapping of particulate materials by sorbent beds suggests that the trapping of the particles from indoor air may be nearly quantitative ( 8 ) . 3-Ethenylpyridine is found exclusively in the vapor phase. 5.3 Nicotine concentrations typically range from ND (not detected) to 70 μg/m 3 in various indoor environments with values usually at the lower end of this range ( 9 ) . Because such low concentrations of nicotine are often encountered, sophisticated analytical procedures and equipment are required for quantifying nicotine in indoor air. Other methods for the determination of nicotine in indoor air have also been reported ( 6 , 10 , 11 , 12 ) . 3-Ethenylpyridine concentrations typically are about one third the concentrations of nicotine in real-world environments ( 13 ) .