Optimized Methods for Sensitive and Robust PFAS Analysis of Wastewater
App Note / Case Study
Last Updated: July 1, 2024
(+ more)
Published: March 14, 2024
Credit: iStock
Monitoring per- and polyfluoroalkyl substances (PFAS) in the environment is paramount to control the health and ecological impacts of these substances.
The Environmental Protection Agency (EPA) imposes quality criteria that must be met in routine monitoring to detect even the most minute PFAS concentrations.
These application notes present optimized liquid chromatography-mass spectrometry (LC-MS) workflows to meet and exceed the limits of quantitation required for the monitoring of PFAS in complex environmental matrices such as wastewater samples.
Download these application notes to learn more about:
- Quality assurance and quality control criteria specified by EPA 1633 and ASTM D8421-22
- Standardized methods to help with PFAS detection and quantification
- Comprehensive solutions for PFAS analysis to save time and effort
User Benefits
Application
News
◆ Reproducible results can be achieved with the Shimadzu LCMS 8060NX for the analysis of wastewater according to EPA
Method 1633.
◆ Achieve quantification 10x lower than the EPA’s Limit of Quantitation (LOQ).
◆ The excellent sensitivity achieved enables laboratories to reoptimize their sample preparation approach (i.e. reduce sample
volume) while ensuring performance as required in EPA 1633
LCMS -8060NX High Performance Liquid Chromatograph Mass Spectrometer
EPA Method 1633: Method Detection Limits of Perand Polyfluoroalkyl Substances (PFAS) in Aqueous
Matrices using the Triple Quad LCMS-8060NX
Megan Davis, Om Shrestha, Kathleen Lou, Ruth Marfil-Vega, Landon Wiest, Evelyn Wang
Shimadzu Scientific Instruments, Inc.
■ Introduction
This application note demonstrates that the LCMS8060NX meets and exceeds the method detection limits,
required by the Environmental Protection Agency (EPA) in
Method 1633 for aqueous matrices.1 All 40 Per- and
Polyfluoroalkyl Substances (PFAS) compounds were
successfully quantified at concentrations 10x lower than
the Limit of Quantitation (LOQ). This improved sensitivity
allows laboratories to minimize operational cost by
decreasing the volume of sample that needs to be
collected, shipped, and extracted.
■ Method Overview
This application details the analysis of 40 native target
PFAS compounds extracted from aqueous matrix along
with 23 extracted internal standards (EIS), and 7 nonextracted internal standards (NIS). Stock standards were
purchased from Wellington Laboratories as a series of
native and mass-labelled PFAS mixtures in methanol
(PFAC-MXF, PFAC-MXG, PFAC-MXH, PFAC-MXI, PFACMXJ, MPFAC-HIFES, and MPFAC-HIF-IS). Three spiking standards was made
containing the native targets, EIS, and NIS compounds by
diluting the stock solutions in methanol. The calibration
curve was made by preparing methanol with 4% water,
1% ammonium hydroxide, and 0.625% acetic acid. The
stock standards were then diluted to make a curve that
ranged from 0.025 to 10.0 μg/L for PFBA, 1.0 to 20.0 μg/L
for EIS, and 1.0 to 4.0 μg/L for NIS. All standards were
prepared for analysis in 200 μL silanized glass inserts in
1.5 mL amber silanized glass vials a with PE/Silicone blue
screw caps.
Type Name Type Name
Target PFBA Target NMeFOSE
Target PFMPA Target NMeFOSA
Target 3:3 FTCA Target NEtFOSE
Target PFPeA Target NEtFOSA
Target PFMBA EIS 13C4-PFBA
Target 4-2 FTS EIS 13C5-PFPeA
Target NFDHA EIS 13C2-4:2 FTS
Target PFHxA EIS 13C5-PFHxA
Target PFBS EIS 13C3-PFBS
Target HFPO-DA EIS 13C3-HFPO-DA
Target 5:3 FTCA EIS 13C4-PFHpA
Target PFEESA EIS 13C2-6:2FTS
Target PFHpA EIS 13C8-PFOA
Target PFPeS EIS 13C3-PFHxS
Target ADONA EIS 13C9-PFNA
Target 6-2 FTS EIS 13C2-8:2FTS
Target PFOA EIS D3-NMeFOSAA
Target PFHxS EIS 13C6-PFDA
Target 7:3 FTCA EIS D5-NEtFOSAA
Target PFNA EIS 13C8-PFOS
Target PFHpS EIS 13C7-PFUnA
Target 8-2 FTS EIS 13C2-PFDoA
Target NMeFOSAA EIS 13C8-PFOSA
Target PFDA EIS 13C2-PFTeDA
Target NEtFOSAA EIS D7-NMeFOSE
Target PFOS EIS D3-NMeFOSA
Target PFUnA EIS D9-NEtFOSE
Target 9Cl-PF3ONS EIS D5-NEtFOSA
Target PFNS NIS 13C3-PFBA
Target PFDOA NIS 13C2-PFHxA
Target PFOSA NIS 13C4-PFOA
Target PFDS NIS 18O2-PFHxS
Target PFTrDA NIS 13C5-PFNA
Target 11Cl-PF3OUdS NIS 13C2-PFDA
Target PFTeDA NIS 13C4-PFOS
Target PFDOS
Table 1: EPA Draft Method 1633 compound list
■ Sample Preparation and Extraction
500 mL of reagent water was spiked with 50 μL of EIS
(800 μg/L 13C4-PFBA) and 200 μL of native compounds (2
μg/L PFBA). Method Blanks (MB) were also prepared and
only spiked with EIS. Samples were extracted by solidphase extraction (SPE) using Biotage EVOLUTE® EXPRESS
WAX 150-mg/6-mL cartridges. Silanized glass wool was
added to each cartridge before extraction, and each was
pre-conditioned with 1% methanolic ammonium
hydroxide and 0.3 M formic acid. Samples were loaded
onto the WAX cartridges at a rate of 5 mL/min. The
cartridges were then rinsed with LCMS grade water and
0.1 M formic acid/methanol and were left to dry for 15
seconds by vacuum. Elution was then carried out by
rinsing the sample bottles with 1% methanolic
ammonium hydroxide and eluted onto the WAX cartridge.
Acetic acid and carbon were added to each extracted
sample, then shaken by hand for a maximum of five
minutes and centrifuged for ten minutes. The extracted
samples were then filtered using a NYLON Choice 25,
0.22 μm filter into a new collection tube containing 50 μL
of NIS (400μg/L 13C3-PFBA) spiking solution. A portion
was transferred to a 1 mL silanized amber glass vial and
vortexed for LCMS analysis.
Parameter Value
LCMS Shimadzu LCMS-8060NX
Analytical Column Shim-pack Scepter C18-120, 3.0 μm,
2.0 x 50mm
Delay Column Shim-pack Scepter C18-120, 3.0 μm,
2.0 x 100mm
Injection Volume 10 μL
Pretreatment Mode Co-Injection
Column Oven Temp. 40°C
Mobile Phase
A: 2 mM Ammonium Acetate in LCMS Grade
Water
B: Acetonitrile
Flow Rate 0.4 mL/min
Run Time 14 minutes
Table 2: LCMS analysis method parameters
Figure 1: Installation/placement of a delay column for PFAS Analysis.
■ Instrument and Operational Conditions
The LCMS analysis was performed by using a Shimadzu
triple quadrupole mass spectrometer LCMS-8060NX,
coupled with a Shimadzu Nexera -40 Series UHPLC. To
minimize PFAS background contamination, a delay column
was installed between the mixer and high-pressure valve
shown in Figure 1. The LCMS parameters are included in
Table 2. Samples run for calculating MDLs, according to
EPA Method 1633, occurred over a minimum of three
days. Day 1 analyses included, a calibration curve,
instrument blank, a calibration verification (CV), three
method blanks, and three spiked water samples were
analyzed. Day 2 consisted of analyzing the instrument
blank, CV, three method blanks, and three spiked water
samples. This was repeated on Day 3 with the instrument
blank, CV, two method blanks, and two spiked water
samples. Before each LC-MS/MS batch, every vial was
vortexed to resuspend PFAS compounds that may have
adsorbed to the walls of their respective vials. This helps to
improve relative standard error (RSE), as PFAS compounds
are known to adsorb to the walls of sample vials.
Table 3: Retention time, calibration range, and resulted RSE for each target PFAS and EIS compound.
Type Name Ret.
Time
CS1
(μg/L)
CS9
(μg/L)
RF RSE
(curve) Type Name Ret.
Time
CS1
(μg/L)
CS9
(μg/L)
RF RSE
(curve)
Target PFBA 2.43 0.03 10.00 10.00 Target PFTrDA 9.10 0.01 2.50 7.00
Target PFMPA 2.73 0.01 5.00 9.00 Target 11Cl-PF3OUdS 9.23 0.03 10.00 10.00
Target 3:3 FTCA 2.82 0.03 12.50 11.00 Target PFTeDA 9.40 0.01 2.50 15.00
Target PFPeA 3.27 0.01 5.00 10.00 Target PFDOS 9.59 0.01 2.50 10.00
Target PFMBA 3.57 0.01 5.00 10.00 Target NMeFOSE 9.42 0.06 25.00 9.00
Target 4-2 FTS 3.87 0.03 10.00 10.00 Target NMeFOSA 9.50 0.01 2.50 19.00
Target NFDHA 4.09 0.01 5.00 10.00 Target NEtFOSE 9.60 0.06 25.00 9.00
Target PFHxA 4.19 0.01 2.50 17.00 Target NEtFOSA 9.67 0.01 2.50 10.00
Target PFBS 4.33 0.01 2.50 9.00 EIS 13C4-PFBA 2.43 8.00 8.00 1.00
Target HFPO-DA 4.57 0.03 10.00 17.00 EIS 13C5-PFPeA 3.27 4.00 4.00 4.00
Target 5:3 FTCA 4.56 0.16 62.50 9.00 EIS 13C2-4:2 FTS 3.87 4.00 4.00 4.00
Target PFEESA 4.84 0.01 5.00 3.00 EIS 13C5-PFHxA 4.19 2.00 2.00 1.00
Target PFHpA 5.13 0.01 2.50 9.00 EIS 13C3-PFBS 4.33 2.00 2.00 3.00
Target PFPeS 5.39 0.01 2.50 9.00 EIS 13C3-HFPO-DA 4.56 8.00 8.00 11.00
Target ADONA 5.45 0.03 10.00 9.00 EIS 13C4-PFHpA 5.13 2.00 2.00 3.00
Target 6-2 FTS 5.59 0.03 10.00 11.00 EIS 13C2-6:2FTS 5.60 4.00 4.00 5.00
Target PFOA 5.97 0.01 2.50 14.00 EIS 13C8-PFOA 5.97 2.00 2.00 1.00
Target PFHxS 6.32 0.01 2.50 11.00 EIS 13C3-PFHxS 6.33 2.00 2.00 1.00
Target 7:3 FTCA 6.23 0.16 62.50 11.00 EIS 13C9-PFNA 6.78 1.00 1.00 1.00
Target PFNA 6.78 0.01 2.50 10.00 EIS 13C2-8:2FTS 7.16 4.00 4.00 2.00
Target PFHpS 7.21 0.01 2.50 10.00 EIS D3-NMeFOSAA 7.47 2.00 2.00 1.00
Target 8-2 FTS 7.16 0.03 10.00 11.00 EIS 13C6-PFDA 7.57 1.00 1.00 1.00
Target NMeFOSAA 7.48 0.01 2.50 8.00 EIS D5-NEtFOSAA 7.78 4.00 4.00 2.00
Target PFDA 7.57 0.01 2.50 12.00 EIS 13C8-PFOS 8.03 2.00 2.00 2.00
Target NEtFOSAA 7.81 0.01 2.50 15.00 EIS 13C7-PFUnA 8.30 1.00 1.00 2.00
Target PFOS 8.03 0.01 2.50 9.00 EIS 13C2-PFDoA 8.77 1.00 1.00 3.00
Target PFUnA 8.30 0.01 2.50 13.00 EIS 13C8-PFOSA 8.72 2.00 2.00 3.00
Target 9Cl-PF3ONS 8.51 0.03 10.00 8.00 EIS 13C2-PFTeDA 9.39 1.00 1.00 4.00
Target PFNS 8.64 0.01 2.50 11.00 EIS D7-NMeFOSE 9.41 20.00 20.00 4.00
Target PFDOA 8.76 0.01 2.50 18.00 EIS D3-NMeFOSA 9.50 2.00 2.00 6.00
Target PFOSA 8.73 0.01 2.50 16.00 EIS D9-NEtFOSE 9.59 20.00 20.00 3.00
Target PFDS 9.00 0.01 2.50 9.00 EIS D5-NEtFOSA 9.67 2.00 2.00 2.00
■ Calibration Curve Results
Relative standard error (RSE) of all native target PFAS and
EIS compounds ranged between 1% and 19% and were
below the maximum level of 20% required in the EPA
method. Table 3 shows the concentration range from CS1
to CS9 for each compound along with its retention time
and RSE. The calibration curve for NMeFOSA can be seen
in Figure 2. Each curve contained a minimum of 7
calibration standards within the linear quantitative range.
Conc.Ratio
0.0 0.2 0.4 0.6 0.8 1.0 1.2
Area Ratio
0.0
0.2
0.4
0.6
0.8
1.0
NMeFOSA
RSE: 18.935798
Figure 2. Calibration curve for NMeFOSA
■ Method Detection Limit Calculations and
Results
The method detection limits for spiked samples (MDLs)
were computed by taking the standard deviation of each
compound’s concentration and multiplying it by the
appropriate t-value (Equation 1). The method detection
limit for the method blanks (MDLb) was computed if the
compound was found to have a numerical result. If all
seven samples did not give a numerical result, then it does
not apply. If any of the method blanks gave a numerical
result the MDLb is set to the highest recorded method
blank. The MDLb was calculated using Equation 2. If the
average concentration found was negative, then it was
changed to zero) after multiplying the t-value and
standard deviation of each compound.
Equation 1: 𝑀𝐷𝐿s = 𝑡(𝑛−1,1−∝≡0.99)𝑆𝑠
Equation 2: 𝑀𝐷𝐿b = 𝑋ത + 𝑡(𝑛−1,1−∝≡0.99)𝑆𝑠
The greater value between the MDLs and MDLb for each
compound becomes the initial MDL result.2 Out of the 40
compounds, 39 had higher MDLs values than their
corresponding MDLb. PFHpA was the only compound for
which the concentration quantified in the Method Blank
(MB) was used to compute the max MDL value. This
demonstrates that despite the high sensitivity achieved
with this method, presence of PFAS in the MB was
minimal and had negligible impact in the final MDLs.
These results are all shown in Table 4 along with the
values obtained by the EPA.
0
0.2
0.4
0.6
0.8
1
PFBA
PFPeA
PFHxA
PFHpA
PFOA
PFNA
PFDA
PFUnA
PFDOA
PFTeDA PFTrDA
PFBS
PFPeS
PFHxS
PFHpS
PFOS
PFNS
PFDS
PFDOS
MDL Range
EPA reported:
0 - 1 ng/L
Shimadzu:
0 - 0.4 ng/L
EPA Reported Shimadzu
Figure 3: MDLs reported in EPA 1633 and obtained with Shimadzu’s LCMS-8060NX of perfluoroalkyl carboxylic acids and sulfonic acids.
Overall, the MDLs ranged from 0.10 ng/L for PFEESA to
1.48 ng/L for 5:3 FTCA and were up to 13.4x better than
those reported in EPA Method 1633. Figures 3 and 4
compare the MDLs reported in EPA Method 1633
compared with those from Shimadzu’s LCMS-8060NX,
based on the class of PFAS. For perfluoralkyl carboxylic
and sulfonic acids (Figure 3), the highest MDL obtained
with Shimadzu’s LCMS-8060NX was 0.34 ng/L (PFOA),
1.6x better than MDL reported in the method. The results
from the other classes of PFAS included in EPA 1633 are
shown in Figure 4. MDLs reported in EPA Method 1633
ranged from 0.32 ng/L (PFOSA) and 9.59 ng/L (5:3 FTCA);
those obtained with Shimadzu’s LCMS-8060NX were
between 0.1 ng/L (PFEESA) and 1.48 (5:3 FTCA). In
addition to the improved sensitivity, which was up to
13.4x less as compared to results from the published EPA
method, results presented less disparity in the
concentrations determined from all PFAS classes targeted
in the method. These results confirm concentrations of
PFAS can be determined with 99% confidence at ppt
levels and distinguishable from the method blank results.
0
2
4
6
8
10
HFPO-DA
ADONA
PFMPA
PFMBA
NFDHA
9Cl-PF3ONS
11Cl-PF3OUdS
PFEESA
4-2 FTS
6-2 FTS
PFOSA 8-2 FTS
NMeFOSA
NEtFOSA
NMeFOSAA
NEtFOSAA
NMeFOSE
NEtFOSE
3:3 FTCA
5:3 FTCA
MDL Range 7:3 FTCA
EPA reported:
0 - 10 ng/L
Shimadzu:
0 - 2 ng/L
EPA Reported Shimadzu
Figure 4: MDLs reported in EPA 1633 and obtained with Shimadzu’s LCMS-8060NX of Per- and Polyfluoroether carboxylicacids, Ether sulfonic
acids, Fluorotelomer sulfonic acids, Perfluorooctane sulfonamides, Perfluorooctane sulfonamidoacetic acids, Perfluorooctane sulfonamide
ethanols, Fluorotelomer carboxylic acids.
Table 4:Comparison of Method Detection Limits values obtained by this study and EPA Draft Method 1633
■ References
(1) Method 1633* Analysis of Per- and Polyfluoroalkyl Substances (PFAS) in Aqueous, Solid, Biosolids, and Tissue
Samples by LC-MS/MS
(2) Appendix B to Part 136, Title 40 -- Definition and Procedure for the Determination of the Method Detection
Limit—Revision 2
■ Conclusions
• The Shimadzu LCMS-8060NX can detect 10x lower
than EPA’s LOQ in a neat standard matrix and
extracted aqueous matrix.
• Low MDL values were determined using the Shimadzu
LCMS-8060NX, confirming sufficient sensitivity and
reproducibility to meet and exceed (up to 13.4x better)
all EPA 1633 requirements.
• Passing calibration curve linearity was obtained using
this analysis method and consumables that were tested
to ensure they did not interact with or contain any
detectable PFAS constituents.
Users must test every new lot number of consumables
used n this analysis to ensure absence of detectable
PFAS.
©Shimadzu Scientific Instruments, 2024
First Edition: March 2024
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LCMS-8040 LCMS-8050 LCMS-8060NX LCMS-2020 Q-TOF LCMS-9030/9050
For Research Use Only. Not for use in diagnostic procedures. The content of this publication shall not be reproduced, altered or
sold for any commercial purpose without the written approval of Shimadzu.The information contained herein is provided to
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This publication is based upon the information available to Shimadzu on or before the date of publication, and subject to
change without notice.
LCMS-8045 LCMS-2050
Reference: SSI-LCMS-154
No. SSI-LCMS-150
This application news summarizes the performance of the
Shimadzu LCMS-8060NX Liquid Chromatography Mass Spectrometer (LC/MS/MS) (Fig. 1) for all analytes listed in ASTM
D8421. Results meet or exceed the requirements outlined in
the method.
The reporting range and the target analytes are listed in Table 1. The reporting limit (RL) for the test method is defined
as an integer value that is equal to the concentration of the
lowest calibration standard.
Fig. 1 Shimadzu LCMS-8060NX
Introduction and Background
ASTM International published ASTM D84211
for the analysis
of 44 per- and polyfluorinated alkyl substances and 24 labeled isotopes in non-potable water samples. This method
extracts the substances in a 1+1 ratio of sample and
methanol, filters and then measures the targeted compounds using external standard calibration liquid chromatography-tandem mass spectrometry (LC/MS/MS). The
minimum reporting limit is 10 ng/L with an analytical range
of 10 - 400 ng/L for most compounds. The method requires
standard solutions be prepared by the laboratory from neat
compounds.
To save a laboratory’s time and effort from preparing stock
standards individually, we optimized the method using commercially available native and labeled calibration standard
mixes. Additionally, we optimized chromatography, achieving better peak shape for early-eluting compounds, such as
PFBA and PFPrA.
Table 1 Analyte List with D8421 Reporting Range
Analyte Name Acronym CAS Number Range
(ng/L)
Perfluorotetradecanoic acid PFTreA 376-06-7 10-400
Perfluorotridecanoic acid PFTriA 72629-94-8 10-400
Perfluorododecanoic acid PFDoA 307-55-1 10-400
Perfluoroundecanoic acid PFUnA 2058-94-8 10-400
Perfluorodecanoic acid PFDA 335-76-2 10-400
Perfluorononanoic acid PFNA 375-95-1 10-400
Perfluorooctanoic acid PFOA 335-67-1 10-400
Perfluoroheptanoic acid PFHpA 375-85-9 10-400
Perfluorohexanoic acid PFHxA 307-24-4 10-400
Perfluoropentanoic acid PFPeA 2706-90-3 50-1000
Perfluorobutanoic acid PFBA 375-22-4 50-1000
Perfluorodecanesulfonic acid PFDS 335-77-3 10-400
User Benefits
◆ The LCMS-8060NX easily meets and exceeds method performance criteria of ASTM D8421 for 44 PFAS and 24 surrogates.
◆ Optimized chromatography and MS conditions for excellent peak shape for improved precision and accuracy.
◆ ASTM D8421 is a simple extraction procedure validated by ASTM for the analysis of PFAS in wastewater samples.
Liquid Chromatography Mass Spectrometry
ASTM D8421-22 Standard Test Method for
Determination of Per- and Polyfluoroalkyl Substances
(PFAS) in Aqueous Matrices by Co-solvation Followed
by Analysis Using the Shimadzu LCMS-8060NX
Nami Iwasa1
, Landon Wiest2
, William Lipps2
1 Shimadzu Corporation, 2 Shimadzu Scientific Instruments, Inc.
Perfluorononanes`ulfonic acid PFNS 68259-12-1 10-400
Perfluorooctanesulfonic acid PFOS 1763-23-1 10-400
Perfluoroheptanesulfonic acid PFHpS 375-92-8 10-400
Perfluorohexanesulfonic acid PFHxS 355-46-4 10-400
Perfluoropentanesulfonic acid PFPeS 2706-91-4 10-400
Perfluorobutanesulfonic acid PFBS 375-73-5 10-400
Perfluorooctanesulfonamide PFOSA 754-91-6 10-400
8:2 Fluorotelomer sulfonic acid 8:2 FTS 39108-34-4 10-400
6:2 Fluorotelomer sulfonic acid 6:2 FTS 27619-97-2 10-400
4:2 Fluorotelomer sulfonic acid 4:2 FTS 757124-72-4 10-400
N-Ethylperfluorooctanesulfonamidoacetic acid NEtFOSAA 2991-50-6 10-400
N-Methylperfluorooctanesulfonamidoacetic acid NMeFOSAA 2355-31-9 10-400
Perfluorododecanesulfonic acid PFDoS 79780-39-5 10-400
N-Methylperfluorooctanesulfonamide NMeFOSA 31506-32-8 10-400
N-Ethylperfluorooctanesulfonamide NEtFOSA 4151-50-2 10-400
N-Methylperfluorooctanesulfonamidoethanol NMeFOSE 24448-09-7 10-400
N-Ethylperfluorooctanesulfonamidoethanol NEtFOSE 1691-99-2 10-400
Hexafluoropropylene oxide dimer acid HFPO-DA 13252-13-6 10-400
4,8-dioxa-3H-perfluorononanoic acid ADONA 919005-14-4 10-400
9-chlorohexadecafluoro-3-oxanonane-1-sulfonic acid 9Cl-PF3ONS 756426-58-1 10-400
11-chloroeicosafluoro-3-oxaundecane-1-sulfonic acid 11Cl-PF3OUdS 763051-92-9 10-400
Pentafluorpropanoic acid PFPrA 422-64-0 50-1000
Perfluoro-3,6-dioxaheptanoic acid NFDHA 151772-58-6 10-400
Perfluoro(2-ethoxyethane) sulfonic acid PFEESA 113507-82-7 10-400
Perfluoro-3-methoxypropanoic acid PFMPA 377-73-1 10-400
Perfluoro-4-methoxybutanoic acid PFMBA 863090-89-5 10-400
2H,2H,3H,3H-Perfluorohexanoic Acid 3:3 FTCA 356-02-05 10-400
2H,2H,3H,3H-Perfluorooctanoic Acid 5:3 FTCA 914637-49-3 10-400
2H,2H,3H,3H-Perfluorodecanoic acid 7:3 FTCA 812-70-4 10-400
2H-perfluoro-2-octenoic acid FHUEA 70887-88-6 10-400
2H-perfluoro-2-decenoic acid FOUEA 70887-84-2 10-400
Lithium Bis(trifluoromethane)sulfonimide * HQ-115 90076-65-6 10-400
Surrogates
Perfluoro-n-[13C4] butanoic acid MPFBA NA 10-400
Perfluor0-n-[13C5] pentanoic acid M5PFPeA NA 10-400
Perfluoro-n-[1,2,3,4,6-13C5] hexanoic acid M5PFHxA NA 10-400
Perfluoro-n-[1,2,3,4-13C4] heptanoic acid M4PFHpA NA 10-400
Perfluoro-n-[13C8] octanoic acid M8PFOA NA 10-400
Perfluoro-n-[13C9] nonanoic acid M9PFNA NA 10-400
Perfluoro-n-[1,2,3,4,5,6-13C6] decanoic acid M6PFDA NA 10-400
Perfluoro-n-[1,2,3,4,5,6,7-13C7] undecanoic acid M7PFUnA NA 10-400
Perfluoro-n-[1,2-13C2] dodecanoic acid MPFDoA NA 10-400
Perfluoro-n-[1,2-13C2] tetradecanoic acid M2PFTreA NA 10-400
Perfluoro-1-[13C8] octanesulfonamide M8FOSA NA 10-400
N-methyl-d3-perfluoro-1-octanesulfonamidoacetic acid D3-N-MeFOSAA NA 10-400
N-ethyl-d5-perfluoro-1-octanesulfonamidoacetic acid D5-N-EtFOSAA NA 10-400
N-methyl-d3-perfluoro-1-octanesulfanamide d-N-MeFOSA NA 10-400
N-ethyl-d5-perfluoro-1-octanesulfanamide d-N-EtFOSA NA 10-400
2-(N-methyl-d3-perfluoro-1-octanesulfonamido) ethan-d4-ol d7-N-MeFOSE NA 10-400
2-(N-ethyl-d5-perfluoro-1-octanesulfonamido) ethan-d4-ol D9-N-EtFOSE NA 10-400
2,3,3,3-Tetrafluoro-2-(1,1,2,2,3,3,3-heptafluoropropoxy-13C3-propanoic acid MHFPO-DA NA 10-400
1H,1H,2H,2H-perfluoro-1-[1,2-13C2] hexane sulfonate M4:2FTS NA 10-400
1H,1H,2H,2H-perfluoro-1-[1,2-13C2]-octane sulfonate M6:2FTS NA 10-400
1H,1H,2H,2H-perfluoro-1-[1,2-13C2]-decane sulfonate M8:2FTS NA 10-400
Perfluoro-1-[13C8] octanesulfonate M8PFOS NA 10-400
Perfluoro-1-[2,3,4-13C3] butanesulfonate MPFBS NA 10-400
Perfluoro-1-[1,2,3-13C3] hexanesulfonate M3PFHxS NA 10-400
Compounds in red are not in the Method 1633 standards and need to be added separately
The individual standard solution was prepared in 50:50 (vol:
vol) methanol/water with 0.1% acetic acid to obtain final
concentrations shown in Table 2.
Materials and Methods
Stock standard solutions containing native analytes and
labeled isotopes (surrogates) were diluted from
commercially available mixed stock standards
(Wellington Method 1633 standard mixes) to be within
the calibration range per analyte as shown in Table 1.
Table 2 Concentrations of each Calibration Standard (CS) in ng/L
These standards were not filtered. Calibration is performed
using a 6 to 10-point curve, depending on the analyte. To
obtain the calibration levels from the commercial stock
solutions, 15 individual calibration standards were prepared
and analyzed. Only the calibration points within the methodspecified range were used.
The stock solutions were prepared and stored in PFAS-free
polypropylene (PP) containers. Prior to the analysis,
the solutions were shaken thoroughly, then transferred to
a 2 mL PP LC vial and analyzed within 24 hours. If samples or
standards are allowed to sit in the LC vials, some PFAS
compounds may settle, rise, precipitate, or adsorb on
the surface. To ensure a homogenous solution and
optimum results, the solutions were vortexed prior to
injection.
2.1 Sample Preparatio n
The surrogate spiking mix is added to 5 mL of sample
contained in a 15 mL polypropylene vial. Add 5 mL of
methanol and mix by vortex for ~2 minutes. After mixing,
add acetic acid and adjust the pH ~4. Transfer an aliquot to a
LC vial and cap with a Shimadzu GLC PP vial with septum
confirmed to not contain PFAS. Analyze per the conditions
shown in Table 3. Concentrations obtained from the curve
are multiplied by two to obtain the final concentration in the
samples.
Compounds CS1 CS2 CS3 CS4 CS5 CS6 CS7 CS8 CS9 CS10 CS11 CS12 CS13 CS14 CS15
Analyte
All analytes unless
otherwise noted 1 2.5 5 10 25 40 60 80 100 150 200 250 375 500 800
PFPeA 2 5 10 20 50 80 120 160 200 300 400 500 750 1000 1600
PFBA, 4:2-FTS, 6:2-
FTS, 8:2-FTS 4 10 20 40 100 160 240 320 400 600 800 1000 1500 2000 3200
PFPrA, 5:3 FTCA, 7:3
FTCA 5 12.5 25 50 125 200 300 400 500 750 1000 1250 1875 2500 4000
NMeFOSE, NEtFOSE 10 25 50 100 250 400 600 800 1000 1500 2000 2500 3750 5000 8000
Surrogate
13C9-PFNA, 13C6-
PFDA, 13C7-PFUnA,
13C2-PFDoA, 13C2-
PFTreA
0.25 0.625 1.25 2.5 6.25 10 15 20 25 37.5 50 62.5 93.75 125 200
13C5-PFHxA, 13C4-
PFHpA, 13C8-PFOA,
13C8-PFOSA, D3-
NMeFOSA, D5-
NEtFOSA, 13C8-
PFOS, 13C3-PFBS,
13C3-PFHxS
0.5 1.25 2.5 5 12.5 20 30 40 50 75 100 125 187.5 250 400
13C5-PFPeA, 13C2-
4:2FTS,13C2-6:2FTS,
13C2-8:2FTS, D3-
NMeFOSAA, D5-
NEtFOSAA
1 2.5 5 10 25 40 60 80 100 150 200 250 375 500 800
13C4-PFBA, 13C3-
HFPO-DA 2 5 10 20 50 80 120 160 200 300 400 500 750 1000 1600
D7-NMeFOSE,
D9-NEtFOSE
5 12.5 25 50 125 200 300 400 500 750 1000 1250 1875 2500 4000
2.2 Analytical Conditions
Table 3 Instrument Configuration and Analytical Conditions
for ASTM D8421 PFAS using the Shimadzu LCMS-8060NX.
Mobile Phase
A: 2 mmol/L Ammonium Acetate in H2O/
Acetonitrile = 95/5
B: Acetonitrile
Delay Column
Shim-pack ScepterTM C18-120
2.1 mm x 100 mm, 3 µm
(P/N: 227-31014-05)
Analytical
Column
Shim-packTM GIST-HP C18
3.0 mm x 100 mm, 3 um
(P/N: 227-30040-04)
Gradient (%B)
10% (0 min) 22% (2.3-3.0 min)
45% (6.0 min) 80% (13.0 min) 95%
(14.0-16 min ) 10% (16.01-20.0 min )
Interface IonFocus ESI
Column Oven
Temp.
40 oC
Flow rate 0.6 mL/min
Injection volume
Multiple draw
injection
program
Co-injection 25 µL Sample 25 µL 0.1%
Acetic acid in H2O
Interface Temp. 170
Probe position +3 mm
Neblizer gas
flow 3 L/min
Heating gas flow 15 L/min
Interface Voltage -0.5 kV (same value for all compounds
DL Temp. 200
Heatblock Temp. 300
Drying gas flow 5 L/min
Focus bias -2 kV (same value for all compounds
Results and Discussion
A single laboratory validation of this method for specificity,
linearity, recovery, and precision in nine wastewater
matrices according to ASTM D82722 was previously
described.3
For this application news, a study was made to
improve peak shape, particularly of early-eluting
compounds, such as PFPrA and PFBA. This included
evaluation of injection technique, columns, and flow rate.
Co-injection of 25 µL sample with 25 µL 0.1% acetic acid in
reagent water significantly improved the peak shapes of
PFPrA, PFBA, and PFMPA (Fig. 2). A large diameter column
with a long column length and large particle size, combined
with a high flow rate, allowed greater axial diffusion,
improving peak shape (Fig. 3).
Finally, to better separate impurities from the mobile phase, a
new delay column was chosen, and the gradient program
was modified (Fig. 4). Upon optimization of chromatography
and mass spectrometer conditions, calibration mixtures
(Table 2) were prepared and used for subsequent analysis.
Compound parameters, including quantitation ion,
confirmation ion and collision energies, were optimized
using LabSolutionsTM software. At least two MRM transitions, if available, were used.
Fig. 2 Optimization of injection technique to improve peak shape
Fig. 3 Example chromatograms for final column and flow rate
with co-injection applied
These compounds were chosen to illustrate because of
their likelihood for regulation in wastewater.
Additionally, calibration curves and midpoint
chromatograms of PFPrA and NEtFOSE are shown in
Figures 7 and 8. These compounds were chosen
because they are the earliest and latest eluting
compounds respectively.
Linearity Study
Calibration curves for each analyte were found by Shimadzu
Lab Solutions Insight data processing software to have a %
RSD of less than 30%, as required by ASTM D8421.
Calibration data, MRM transitions for the quantitation and
confirmation ions (when available), and retention times are
shown in Table 4. Calibration curves along with a midpoint
standard chromatogram of PFOA and PFOS are shown in
Figures 5 and 6.
Table 4 Summary of calibration data.
Compound Quantitation Ion Confirmation Ion Retention Time (min) r
2
PFTreA 712.95>668.95 712.95>169.00 11.756 0.9962
PFTriA 662.95>618.95 662.95>169.00 11.026 0.9978
PFDoA 612.95>568.95 612.95>319.00 10.286 0.9987
PFUnA 562.95>518.95 562.95>269.00 9.543 0.9991
PFDA 512.95>468.95 512.95>219.00 8.813 0.9967
PFNA 462.95>418.95 462.95>219.00 8.11 0.9921
PFOA 412.95>369.00 412.95>169.00 7.451 0.9929
PFHpA 362.95>319.00 362.95>169.00 6.807 0.9989
PFHxA 312.95>269.00 312.95>119.00 6.028 0.9976
PFPeA 263.00>219.00 263.00>69.00 4.728 0.9996
PFBA 213.00>169.00 ---- 3.026 0.9985
PFDS 598.90>79.95 598.90>98.95 10.785 0.9971
PFNS 548.95>79.95 548.95>98.95 10.033 0.9975
PFOS 498.95>79.95 498.95>98.95 9.275 0.9951
PFHpS 448.95>79.95 448.95>98.95 8.522 0.9951
PFHxS 398.95>79.95 398.95>98.95 7.783 0.9917
PFPeS 348.95>79.95 348.95>98.95 7.059 0.9917
PFBS 298.95>79.95 298.95>98.95 6.17 0.9990
PFOSA 497.95>77.95 497.95>477.95 11.075 0.9979
8:2FTS 526.95>506.95 526.95>80.90 8.426 0.9976
6:2FTS 426.95>406.95 426.95>80.90 7.148 0.9960
4:2FTS 326.95>306.95 326.95>80.90 5.678 0.9970
Fig. 4 Final gradient with chromatogram of
PFPrA, the earliest eluting peak
NEtFOSAA 584.00>418.95 584.00>526.00 9.01 0.9950
NMeFOSAA 569.95>418.95 569.95>482.95 8.703 0.9929
PFDoS 698.90>79.95 698.90>98.95 12.228 0.9959
NMeFOSA 511.95>219.00 511.95>169.00 13.556 0.9956
NEtFOSA 526.00>219.00 526.00>169.00 14.149 0.9988
NMeFOSE 616.00>59.00 ---- 13.246 0.9996
NEtFOSE 630.00>59.00 ---- 13.853 0.9998
HFPO-DA 285.00>169.00 285.00>185.00 6.365 0.9971
ADONA 376.95>251.00 376.95>85.00 7.064 0.9980
9Cl-PF3ONS 530.90>350.95 532.90>352.95 9.809 0.9994
11Cl-PF3OUdS 630.90>450.95 632.90>452.95 11.308 0.9994
PFPrA 163.00>119.00 ---- 1.589 0.9996
NFDHA 294.95>201.00 294.95>85.00 5.937 0.9953
PFEESA 314.95>135.00 314.95>82.95 6.628 0.9978
PFMPA 228.95>85.00 ---- 3.656 0.9981
PFMBA 278.95>85.00 ---- 5.279 0.9979
3:3 FTCA 241.00>177.00 241.00>117.00 3.804 0.9717
5:3 FTCA 341.00>237.00 341.00>217.00 6.375 0.9945
7:3 FTCA 441.00>317.00 441.00>337.00 7.752 0.9964
FHUEA 357.00>293.00 ---- 6.472 0.9962
FOUEA 456.95>393.00 ---- 7.704 0.9973
HQ-115 279.90>146.95 279.90>210.90 7.259 0.9988
13C4-PFBA_Surr 217.00>172.00 ---- 3.023 0.9982
13C5-PFPeA_Surr 268.00>223.00 ---- 4.726 0.9976
13C5-PFHxA_Surr 318.00>273.00 318.00>120.00 6.026 0.9972
13C4-PFHpA_Surr 367.00>322.00 ---- 6.806 0.9994
13C8-PFOA_Surr 421.00>376.00 ---- 7.45 0.9959
13C9-PFNA_Surr 472.00>427.00 ---- 8.108 0.9947
13C6-PFDA_Surr 519.00>474.00 ---- 8.81 0.9989
13C7-PFUnA_Surr 570.00>525.00 ---- 9.541 0.9979
13C2-PFDoA_Surr 614.95>569.95 ---- 10.285 0.9968
13C2-PFTreA_Surr 714.95>669.95 ---- 11.755 0.9952
13C8-PFOSA_Surr 505.95>77.95 ---- 11.077 0.9983
D3-NMeFOSAA_Surr 573.00>418.95 ---- 8.697 0.9933
D5-NEtFOSAA_Surr 589.00>418.95 ---- 9 0.9976
D3-NMeFOSA_Surr 515.00>219.00 515.00>168.90 13.548 0.9993
D5-NEtFOSA_Surr 531.00>219.00 531.00>168.90 14.131 0.9983
D7-NMeFOSE_Surr 623.05>59.00 ---- 13.206 0.9957
D9-NEtFOSE_Surr 639.10>59.00 ---- 13.807 0.9994
13C3-HFPO-DA_Surr 287.00>169.00 284.90>185.00 6.363 0.9921
13C2-4:2FTS_Surr 329.00>308.95 329.00>80.90 5.678 0.9943
13C2-6:2FTS_Surr 428.95>408.95 428.95>80.90 7.147 0.9903
13C2-8:2FTS_Surr 528.95>508.95 528.95>80.90 8.425 0.9956
13C8-PFOS_Surr 506.95>79.95 506.95>98.95 9.274 0.9966
13C3-PFBS_Surr 301.95>79.95 301.95>98.95 6.17 0.9953
13C3-PFHxS_Surr 401.95>79.95 401.95>98.95 7.782 0.9921
Fig. 5 Calibration curve and midpoint chromatogram for PFOA
Fig. 6 Calibration curve and midpoint chromatogram for PFOS
Fig. 7 Calibration curve and midpoint chromatogram for PFPrA
Fig. 8 Calibration curve and midpoint chromatogram for NEtFOSE
These data are well within the 70 -130 % recovery and ≤ 30
%RSD limits of the method.
Recovery and Repeatability Stu dy
Recovery and repeatability (Table 5) were evaluated in
reagent water and wastewater, each spiked four times
at the concentration indicated. Recovery was calculated
after subtracting the native PFAS found in the unspiked sample
matrices.
Table 5 Recovery and Repeatability in Reagent Water and Wastewater
Compound
Spike
Concentration
(ppt)
Reagent
Water %
Recovery
Reagent Water
%RSD (n=4)
Wastewater
% Recovery
Wastewater
%RSD (n=4)
PFTreA 160 110 3.76 119 2.71
PFTriA 160 109 2.08 79.9 4.82
PFDoA 160 104 4.33 107 4.6
PFUnA 160 113 5.53 105 2.49
PFDA 160 113 2.67 102 4.5
PFNA 160 113 6.71 107 2.34
PFOA 160 111 7.52 112 5.7
PFHpA 160 116 4.13 108 4.46
PFHxA 160 114 6.83 115 3.41
PFPeA 320 106 4.37 108 2.47
PFBA 640 107 0.55 108 2.06
PFDS 160 112 8.89 112 3.73
PFNS 160 113 3.72 116 5.58
PFOS 160 110 3.83 122 4.02
PFHpS 160 115 6.09 102 6.91
PFHxS 160 113 5.93 113 13.15
PFPeS 160 124 4.94 119 9.49
PFBS 160 109 4.59 114 5.12
PFOSA 160 101 2.44 100 4.59
8:2FTS 640 113 6.24 103 4.97
6:2FTS 640 119 3.2 107 3.3
4:2FTS 640 121 0.7 100 2.47
NEtFOSAA 160 113 7.5 89.4 10.15
NMeFOSAA 160 111 13.35 88.0 7.42
PFDoS 160 106 5.23 108 9.31
NMeFOSA 160 102 3.68 91.5 5.59
NEtFOSA 160 100 0.73 90.5 3.33
NMeFOSE 1600 97.2 0.34 93.6 0.94
NEtFOSE 1600 96.8 0.9 93.5 1.39
HFPO-DA 160 109 2.35 112 9.66
ADONA 160 110 1.01 104 4.22
9Cl-PF3ONS 160 111 2.01 111 1.92
11Cl-PF3OUdS 160 112 3.59 111 2.78
PFPrA 800 108 1.8 105 0.77
NFDHA 160 107 9.13 110 4.16
PFEESA 160 112 4.71 115 4.45
PFMPA 160 106 2.37 102 5.83
PFMBA 160 113 7.07 115 2.55
3:3 FTCA 160 87.1 20.57 94.8 14.52
5:3 FTCA 800 95.7 6.91 90.4 4.22
7:3 FTCA 800 92.5 2.56 88.8 2.73
FHUEA 160 99.1 3.91 95.3 2.16
FOUEA 160 102 4.2 97.2 3.5
HQ-115 160 112 2.56 111 0.78
Surrogates
13C4-PFBA_Surr 320 102 1.7 96.4 2.88
13C5-PFPeA_Surr 160 108 6.03 96.4 3.36
13C5-PFHxA_Surr 80 110 3.7 101 5.35
13C4-PFHpA_Surr 80 104 6.43 105 5.99
13C8-PFOA_Surr 80 107 11.32 100 10.19
13C9-PFNA_Surr 40 98.2 13.76 92.2 17.29
13C6-PFDA_Surr 40 106 5.74 96.5 8.59
13C7-PFUnA_Surr 40 98.6 6.01 90.8 6.68
13C2-PFDoA_Surr 40 96.1 4.31 94.9 5.43
13C2-PFTreA_Surr 40 98.9 10.44 119 9.46
13C8-PFOSA_Surr 80 92.2 2.22 91.4 6.54
D3-NMeFOSAA_Surr 160 98.4 3.95 90.6 6.56
D5-NEtFOSAA_Surr 160 95.0 3.55 81.3 3.26
D3-NMeFOSA_Surr 80 89.3 12.1 82.6 8.57
D5-NEtFOSA_Surr 80 90.5 8.83 84.2 8.94
D7-NMeFOSE_Surr 800 88.8 0.49 85.4 1.68
D9-NEtFOSE_Surr 800 89.6 0.97 85.9 1.49
13C3-HFPO-DA_Surr 320 103 3.19 101 8.25
13C2-4:2FTS_Surr 160 116 3.15 96.2 6.88
13C2-6:2FTS_Surr 160 119 2.25 97.3 5.65
13C2-8:2FTS_Surr 160 104 0.73 97.4 7.53
13C8-PFOS_Surr 80 103 9.45 105 9.61
13C3-PFBS_Surr 80 121 5.06 94.0 6.33
13C3-PFHxS_Surr 80 116 9.99 108 6.65
Conclusion
This application news demonstrates the analysis of 44 PFAS
and 24 surrogate compounds in non-potable water by
ASTM D8421 using the Shimadzu LCMS-8060NX Liquid
Chromatography Mass Spectrometer (LC/MS/MS).
Chromatographic conditions were optimized to achieve
excellent peak shape, even for the earliest eluting
compounds, such as PFPrA and PFBA.
The highly sensitive Shimadzu LCMS-8060NX easily
exceeds method performance criteria of the ASTM
method and provides testing laboratories with highly
accurate and reliable, repeatable results for PFAS in
wastewater samples.
References
1. ASTM Test Method D8241 Determination of Per- and Polyfluoroalkyl Substances (PFAS) in Aqueous Matrices by Cosolvation followed by Liquid Chromatography Tandem Mass Spectrometry (LC/MS/MS)
2. ASTM Standard D8272-19 -Standard Guide for Development and Optimization of D19 Chemical Analysis Methods
Intended for EPA Compliance Reporting / ASTM International / West Conshohocken / PA / 2020 / 10.1520/D8272-19/
https://www.astm.org/
3. Lipps, W., ASTM D8421-22 Standard Test Method for Determination of Per- and Polyfluoroalkyl Substances (PFAS) in
Aqueous Matrices by Co-solvation followed by Liquid Chromatography Tandem Mass Spectrometry (LC/MS/MS),
Shimadzu Whitepaper, August 2023.
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