Microsoft Word - Kodba NB 9-3.doc


Nova Biotechnologica 9-3 (2009)                                                                               249 
 

VALIDATION OF AN IMPROVED EUROPEAN 
STANDARD METHOD FOR THE DETERMINATION 

OF PCBs IN OIL SAMPLES  
 

ZDENKA CENCIČ KODBA1, DARINKA BRODNJAK VONČINA2  
 

1Institute of Public Health Maribor, Environmental Protection Institute, Prvomajska 1, 
2000 Maribor, Slovenia (zdenka.kodba@zzv-mb.si)  

2Faculty of Chemistry and Chemical Engineering, University of Maribor, Smetanova 
17, 2000 Maribor, Slovenia (darinka.brodnjak@uni-mb.si) 

 
Abstract: Two European standard methods (EN 12766 and EN 61619) are currently used for the 
determination of PCBs in specific oil matrix. However, apolar matrix compounds (e.g. hydrocarbons) elute 
from the adsorbent together with the PCBs and are injected into the analytical system where their presence 
contaminates the inlet, detectors and columns; and decreases system performances. Insufficient cleanup 
causes delay of elution of PCBs from GC columns.  
By using new sulfoxide-bonded silica, PCBs are better separated from aliphatic hydrocarbons because the 
specificity of the stationary phase for these compounds is much higher that that used in both standard 
methods. A gas chromatograph AT6890 with two capillary columns of different polarities (HP-5MS and 
DB-1701) coupled to two μECDs is used. Oven temperature program is as followed: 90°C (1 min), 
70°C/min to 180°C, 5°C/min to 230°C (0.1 min), 1.5°C/min to 280°C. Run time is 46 min.  
The procedure was validated through regular analysis of blanks, fortified samples (transformer oil, motor 
used and unused oil) and certified materials (BCR-449 and BCR-420, waste mineral oils, high and low PCB 
levels). Two internal standards were used (PCB 30 and PCB 209). An average recovery ± RSD of 82.8 ± 5.4 
% was achieved for all six PCBs in different matrices. The LOQ per single PCB congener is 0.2 mg kg-1. 
The average recovery ± RSD for the BCR-420 is 92.0 ± 4.6 % and for the BCR-449 is 105 ± 2.5 % for all 
certified PCBs in waste oils.   
 
Key words: PCBs, sulfoxide-bonded silica, validation, oil samples   

 
1. Introduction 

 
The election of standards to quantify PCBs is based on a number of factors among 

which the type of sample, the availability of reference compounds and the aim of the 
determination are included. Two European standard methods (EN 12766 and EN 
61619) are currently used for the determination of PCBs in specific oil matrix. The 
first one is applicable to unused, used and treated petroleum products including 
synthetic lubricating oils and the second one is applicable to unused, reclaimed or used 
insulating liquids where it is specifically emphasized that the presence of mineral oil 
may reduce the sensitivity of the ECD. In addition to the official methods (where a 
combination of acidified silica/anion exchange (SiOH-H2SO4/SA) and silica adsorbent 
is proposed) numerous sample preparation techniques are available for PCB analysis 
in oil samples ranging from extraction with aprotic solvents (e.g. dimethylsulfoxide, 
dimethylformamide) (LARSEN et.al., 1991; LAWN and TOFFEL, 1987), enzyme 
immunoassay (LAMBERT et.al., 1997), HS SPME (CRIADO et.al., 2004), sulphuric 



250                                                                      Kodba, Z.C. and Brodnjak Vončina, D. 
 
acid and alkali treatment (SHIN and KIM, 2006; SHU et.al., 1995), gel permeation 
chromatography (SHERIDAN et.al., 1995), normal-phase (Florisil, alumina) (LULEK, 
1998; NERIN and DOMENO, 1999; STORR-HANSEN et.al., 1992), reversed-phase 
chromatography and many surface modified silica for SPE may be in use (NH2, NH2-
Cl, NH2-SO, SCX-2, SCX-2-NH4, SAX, SAX-SO4, CN, DIOL and PSA) for the 
separation of PCBs from mineral oils (TAKADA  et.al. 2001; NA et.al., 2008; 
NUMATA et.al., 2006; NUMATA et.al., 2007; NUMATA NUMATA et.al., 2008).  

PCBs are not easily separated from oil matrices because their physical and 
chemical characteristics are very similar. The remaining oil during the analytical 
procedure was not an immediate analytical problem, because when the sample fraction 
was analyzed by selective detectors like ECD, the co-extracted compounds are not 
directly detected. Also, lower limits of quantification are required.  That is why a new 
modification of silica was used for sample preparation. Supelclean Sulfoxide SPE 
(PSA-SO) consists of a patent pending sulfoxide-bonded silica where PCBs are 
preferentially retained on the SPE phase whereas sample interferences (e.g. long chain 
hydrocarbons) are eluted in the early fraction. 

The procedure was validated through regular analysis of blanks, fortified samples 
(transformer oil, motor used and unused oil) and certified materials (BCR-449 and 
BCR-420, waste mineral oils, high and low PCB levels). Two internal standards were 
used (PCB 30 and PCB 209). The working range, limit of quantification, repeatability, 
reproducibility and accuracy were determined. 
 

2. Materials and methods 
 

A surrogate standard solution was prepared by dissolving six PCB congeners (PCB 
28, PCB 52, PCB 101, PCB 138, PCB 153 and PCB 180) from Dr. Ehrenstorfer and 
two PCB congeners (PCB 30 and PCB 209) in hexane. Reference materials BCR 
CRM-420 and BCR CRM-449 with a certified concentration of several PCBs were 
purchased from the Institute for Reference Materials and Measurements (Geel, 
Belgium). J.T.Baker supplied acetone and hexane. Individual solutions of internal 
standards were prepared in acetone followed by dilution with hexane. 

Three different matrices of oil samples were taken for analysis. Waste oils were 
classified according to their origin into transformer oil, motor used and unused oil.  
 
2.1 Sample preparation 
 

The following SPE method is based on a modified Supelco procedure. Spiked and 
non-spiked oil samples (0.25 g) were dried with anhydrous sodium sulphate and 
diluted to 10 ml with hexane. Samples were homogenized and placed into the SPE 
station. Supelclean Sulfoxide PP SPE (3g/6ml) from Supelco and SiOH PP SPE 
(500mg/3ml) from Chromabond were used for the sample cleanup. The schematic SPE 
process is shown in Table 1. 

A gas chromatograph AT6890 with two capillary columns of different polarities 
(HP-5MS and DB-1701) coupled to two μECDs was used.  



Nova Biotechnologica 9-3 (2009)                                                                               251 
 

Oven temperature program was 90°C (1 min), 70°C/min to 180°C, 5°C/min to 
230°C (0.1 min), 1.5°C/min to 280°C.  

Four calibration standards were prepared to cover the optimum range with the 
lowest calibration level of 0.2 mg kg-1 per single PCB congener. 
 
Table 1. Sample cleanup preparation by SPE. 
 

I. Supelclean Sulfoxide  SPE (3g/6ml) 
1. Condition and equilibration the SPE with 10 ml of acetone and 20 ml of hexane  
2. Add 0.5 ml of pre-treated sample in hexane  
3. Wash and remove the oil fraction with 0.5 ml and 4.5 ml hexane  
4. Elute the analytes with 13 ml hexane 

Collect and concentrate an eluent to approximately 0.5 ml 
II. SiOH  SPE (500mg/3ml) 

1. Condition and equilibration the SPE with one volume of acetone and one volume 
of hexane  

2. Add 0.5 ml of PCB fraction  
3. Wash and elute the PCB fraction with 2 x 1 ml and one volume of hexane  

Collect and concentrate to 0.2 ml 

 
3. Results and discussion 

 
As shown in the chromatogram (Fig. 1) good peak shape and sufficient separation 

of the critical pairs was obtained (resolution was 0.5 or greater). The working range of 
individual PCB congener was from 0.2 mg kg-1 to 100 mg kg-1. The accuracy was also 
very good. Repeatability was less than 10% for all spiked samples, for all congeners 
over the whole calibration range with some exceptions for the transformer oil.       
 
 

 
Fig. 1. GC-ECD-ECD chromatograms of the BCR standard, waste mineral oil. 
 

An average recovery ± RSD of 82.8 ± 5.4 % was achieved for all six PCBs in 
different matrices (Fig. 2). 

The average recovery ± RSD for the BCR-420 was 92.0 ± 4.6 % and for the BCR-
449 105 ± 2.5 % for all certified PCBs in waste oils (Fig. 3 and Fig. 4). 



252                                                                      Kodba, Z.C. and Brodnjak Vončina, D. 
 

 
Fig. 2. Results of the repeatability and recovery studies on fortified different matrices. 
 

 
Fig. 3. Results of the repeatability and recovery 
studies on the BCR-420. 

Fig. 4. Results of the repeatability and recovery studies 
on the BCR-449. 

 
4. Conclusions 

 
By using new sulfoxide-bonded silica, PCBs are better separated from aliphatic 

hydrocarbons because the specificity of the stationary phase for these compounds is 
much higher than that used in both standard methods. This previously developed 
sulfoxide-bonded silica and ammonium-salt bonded silica stationary phase (PSA-SO) 
together with the additional silica one, offer a simple, fast and efficient sample 
preparation for the extraction of PCBs from waste, transformer and mineral oil 
samples (especially paraffin-based), which can replace that mentioned in both 
European standards without any possible damage to the GC system.  



Nova Biotechnologica 9-3 (2009)                                                                               253 
 

References 
  
CRIADO, M.R., PEREIRO, I.R., TORRIJOS, R.C.: Selective determination of 

polychlorinated biphenyls in waste oils using liquid-liquid partition followed by 
headspace solid-phase microextraction and gas chromatography with atomic 
emission detection. J. Chromatogr. A, 1056, 2004, 263-266. 

CANALS, A., FORTEZA, R., CERDA, V.: The routine determination of PCBs in 
waste automotive engine oils. Chromatographia, 34, 1992, 35-40. 

LAMBERT, N., FAN, T.S., PILETTE, J.: Analysis of PCBs in waste oil by enzyme 
immunoassay. Sci. Total Environ., 196, 1997, 57-61. 

LULEK, J.: Levels of polychlorinated biphenyls in some waste motor and transformer 
oils from Poland. Chemosphere, 37, 1998, 2021-2030. 

LARSEN, B., TILIO, R., KAPILA, S.: A DMSO-based cleanup procedure for 
determination of PCBs in waste oil. Chemosphere, 23, 1991, 8-10. 

LAWN, R.E., TOFFEL, S.A.: Determination of polychlorinated biphenyls in waste oil 
by gas-liquid chromatography. Analyst, 112, 1987, 53-56. 

NERIN, C., DOMENO, C.: Determination of polyaromatic hydrocarbons and some 
related compounds in industrial waste oils by GPC-HPLC-UV. Analyst, 124, 1999, 
67-70. 

NUMATA, M., AOYAGI, Y., TSUDA, Y., YARITA, T., TAKATSU, A.: Separation 
of polychlorinated biphenyls from mineral oil using alkylammonium ion-bonded 
silica stationary phases. Anal. Sci., 22, 2006, 785-788. 

NUMATA, M., AOYAGI, Y., TSUDA, Y., YARITA, T., TAKATSU, A.: Preparation 
of sulfoxide residue bonded silica stationary phase for separation of 
polychlorinated biphenyls from mineral oils. Anal. Chem., 79, 2007, 9211-9217. 

NUMATA, M., KANEKO, T., MI, Q., YE, M., KAWAMATA, S., MATSUO, M., 
YARITA, T.: Preparation of a sulfoxide group and ammonium-salt bonded silica 
stationary phase for separation of polychlorinated biphenyls from mineral oils. J. 
Chromatogr. A, 1210, 2008, 68-75. 

NA, Y., KIM, K., HONG, J., SEO, J.: Determination of polychlorinated biphenyls in 
transformer oil using various adsorbent for solid phase extraction. Chemosphere, 
73, 2008, S7-S12. 

SHIN, S.K., KIM, T.S.: Levels of polychlorinated biphenyls (PCBs) in transformer 
oils from Korea. J. Hazard. Mat., 137, 2006, 1514-1522. 

SHU, Y.Y., DOWDALL, J.E., CHIU, C., LAO, R.C.: Interference of transformer oil 
matrices to the internal standards on PCB quantification. Intern. J. Anal. Chem., 
60, 1995, 185-194. 

STORR-HANSEN, E., CLEEMANN, M., CEDERBERG, T., JANSSON, B.: 
Selective retention of non-ortho substituted coplanar chlorinated biphenyl congener 
on adsorbents for column chromatography. Chemosphere, 24, 1992, 323-333. 

SHERIDAN, B.R., POOLE, G., DAWDALL, E., CHIU, C.: The effect of temperature 
on GPC for the separation of PCBs from transformer oil and subsequent analysis 
by GC-MSD. Int. J. Environ. Anal. Chem., 60, 1995, 195-202. 

TAKADA, M.I., TODA, H., UCHIDA, R.: A new rapid method for quantification of 
PCBs in transformer oil. Chemosphere, 43, 2001, 455-459.