PMID- 34227358
OWN - NLM
STAT- PubMed-not-MEDLINE
DCOM- 20210706
LR  - 20230916
IS  - 1872-2059 (Electronic)
IS  - 1000-8713 (Print)
IS  - 1000-8713 (Linking)
VI  - 39
IP  - 1
DP  - 2021 Jan
TI  - [Research progress on analytical methods for the determination of 
      hexachlorobutadiene].
PG  - 46-56
LID - 10.3724/SP.J.1123.2020.05019 [doi]
AB  - Hexachlorobutadiene (HCBD) is one of persistent organic pollutants (POPs) listed 
      in Annex A and Annex C of the Stockholm Convention in 2015 and 2017, 
      respectively. Research on the sources, environmental occurrences, and biological 
      effects of HCBD has a great significance in controlling this newly added POPs. 
      Sensitive and credible methods for the determination of HCBD are preconditions 
      and form the basis for related research work. In recent years, many researchers 
      have included HCBD as one of the analytes in monitoring or methodological 
      studies. Based on the results of these studies, this paper reviews the research 
      progress on analytical methods for the determination of HCBD and focuses on 
      sample pretreatment methods for the analysis of HCBD in various matrices such as 
      air, water, soil, sewage sludge, and biological tissues. The advantages and 
      disadvantages of the methods are also compared to provide reference for further 
      research in this field.For air samples, HCBD was usually collected by passing air 
      through sorbent cartridges. Materials such as Tenax-TA, Carbosieve, Carbopack, 
      Carboxen 1000, or their mixtures were used as the sorbent. HCBD was thermally 
      desorbed and re-concentrated in a trap and finally transferred for instrumental 
      analysis. Limits of detection (LODs) for HCBD in these methods were at the 
      ng/m(3) scale. Compared to sampling using pumps, passive air samplers (PAS) such 
      as polyurethane foam PAS (PUF-PAS) do not require external power supply and are 
      more convenient for sampling POPs in air at a large scale. The LOD of the 
      sorbent-impregnated PUF PAS (SIP-PAS) method was much lower (0.03 pg/m(3)) than 
      that of the PUF-PAS method (20 pg/m(3)). However, the sampling volumes in the 
      SIP-PAS and PUF-PAS methods (-6 m(3)) calculated from the log K(OA) value of HCBD 
      have significant uncertainty, and this must be confirmed in the future.For water 
      samples, HCl or copper sulfate was added to the sample immediately after sampling 
      to prevent any biological activities. HCBD can be extracted from water using 
      methods such as the purge and trap method, liquid-liquid extraction (LLE) method, 
      and solid phase extraction (SPE) method. Among these methods, SPE enabled the 
      simultaneous extraction, purification, and concentration of trace HCBD in a 
      single step. Recoveries of HCBD on Strata-X and Envi-Carb SPE cartridges 
      (63%-64%) were higher than those on Envi-disk, Oasis HLB, and Strata-C18 
      cartridges (31%-46%). Drying is another key step for obtaining high recoveries of 
      HCBD. Disk SPE involving the combination of a high-vacuum pump and a low-humidity 
      atmosphere is an effective way to eliminate the residual water. In addition, a 
      micro SPE method using functionalized polysulfone membranes as sorbents and 
      employing ultrasonic desorption was developed for extracting HCBD from drinking 
      water. The recovery of HCBD reached 102%, with a relative standard deviation 
      (RSD) of 3.5%.For solid samples such as dust, soil, sediment, sewage sludge, fly 
      ash, and biota tissue, multiple pretreatment methods were used in combination, 
      owing to the more complex matrix. Freeze or air drying, grinding, and sieving of 
      samples were commonly carried out before the extraction. Soxhlet extraction is a 
      typical extraction method for HCBD; however, it requires many organic reagents 
      and is time consuming. The accelerated solvent extraction (ASE) method requires a 
      small amount of organic reagent, and the extraction can be performed rapidly. It 
      was recently applied for the extraction of HCBD from solid samples under 10.34 
      MPa and at 100 ℃. Purification could be achieved simultaneously by mixing 
      florisil materials with samples in the ASE pool. Nevertheless, employing the ASE 
      methods widely is difficult because of their high costs. Ultrasonic-assisted 
      extraction (UAE) has the same extraction efficiency for HCBD, with much lower 
      costs compared to ASE, and is therefore adopted by most researchers. The type of 
      extraction solvent, solid-to-liquid ratio, ultrasonic temperature, and power 
      affect the extraction efficiency. Ultrasonic extraction at 30 ℃ and 200 W using 
      30 mL dichloromethane as the extraction solvent resulted in acceptable recoveries 
      (64.0%-69.4%) of HCBD in 2 g fly ash. After extraction, a clean-up step is 
      necessary for the extracts of solid samples. Column chromatography is frequently 
      used for purification. The combined use of several columns or a multilayer column 
      filled with florisil, silica gel, acid silica gel, or alumina can improve the 
      elimination efficiency of interfering substances.Instrumental analysis for HCBD 
      is mainly performed with a gas chromatograph equipped with a mass spectrometer 
      operating in selected ion monitoring mode. DB-5MS, HP-5MS, HP-1, ZB-5MS, and BP-5 
      can be used as the chromatographic columns. Qualification ions and quantification 
      ions include m/z 225, 223, 260, 227, 190, and 188. GC-MS using an electron 
      ionization (EI) source was more sensitive to HCBD than GC-MS using a positive 
      chemical ionization source (PCI) and atmospheric pressure chemical ionization 
      source (APCI). Gas chromatography-tandem mass spectrometry (GC-MS/MS), gas 
      chromatography-high-resolution mass spectrometry (GC-HRMS), and high-resolution 
      gas chromatography-high-resolution mass spectrometry (HRGC-HRMS) have recently 
      been used for the separation and determination of HCBD and various other organic 
      pollutants. Instrumental detection limits for HCBD in GC-MS/MS, GC-HRMS, and 
      HRGC-HRMS were more than ten times lower than that in GC-MS, indicating the 
      remarkable application potential of these high-performance instruments in HCBD 
      analysis.
FAU - Wang, Yaotian
AU  - Wang Y
AD  - Department of Chemistry, College of Sciences, Northeastern University, Shenyang 
      110819, China.
AD  - State Key Laboratory of Environmental Chemistry and Ecotoxicology, Research 
      Center for Eco-Environmental Sciences, Chinese Academy of Sciences, Beijing 
      100085, China.
FAU - Zhang, Haiyan
AU  - Zhang H
AD  - College of Environment, Zhejiang University of Technology, Hangzhou 310014, 
      China.
FAU - Shi, Jianbo
AU  - Shi J
AD  - State Key Laboratory of Environmental Chemistry and Ecotoxicology, Research 
      Center for Eco-Environmental Sciences, Chinese Academy of Sciences, Beijing 
      100085, China.
FAU - Jiang, Guibin
AU  - Jiang G
AD  - State Key Laboratory of Environmental Chemistry and Ecotoxicology, Research 
      Center for Eco-Environmental Sciences, Chinese Academy of Sciences, Beijing 
      100085, China.
LA  - chi
PT  - English Abstract
PT  - Journal Article
PL  - China
TA  - Se Pu
JT  - Se pu = Chinese journal of chromatography
JID - 9424804
SB  - IM
PMC - PMC9274838
OTO - NOTNLM
OT  - hexachlorobutadiene
OT  - instrumental detection
OT  - persistent organic pollutants (POPs)
OT  - review
OT  - sample pretreatment
EDAT- 2021/07/07 06:00
MHDA- 2021/07/07 06:01
PMCR- 2021/01/08
CRDT- 2021/07/06 07:00
PHST- 2021/07/06 07:00 [entrez]
PHST- 2021/07/07 06:00 [pubmed]
PHST- 2021/07/07 06:01 [medline]
PHST- 2021/01/08 00:00 [pmc-release]
AID - 1000-8713-39-1-46 [pii]
AID - 10.3724/SP.J.1123.2020.05019 [doi]
PST - ppublish
SO  - Se Pu. 2021 Jan;39(1):46-56. doi: 10.3724/SP.J.1123.2020.05019.