Analysis of PFAS Extractables in Filtration Products Using Modified EPA 1633

Read about

• Contaminants in PFAS Testing
• Testing Millex^® PES and Nylon Syringe Filters with Methanol Samples Using Modified EPA 1633
• Testing Millipore^® Polypropylene Membrane Filters with Methanol Samples Using Modified EPA 1633
• Filters for Modified EPA 1633
• Recommended Filtration Products
• References

Contaminants in PFAS testing

EPA 1633 tests for 40 PFAS compounds in matrices with higher degrees of particulates - wastewater, surface water, groundwater, soil, biosolids, sediment, landfill leachate, and fish tissue. Particulates in solution must be removed prior to LC-MS/MS as they can be detrimental to sample analysis, column longevity, and overall instrument function. EPA 1633 specifically calls for filtration using a syringe filter format after the extraction and clean-up process for aqueous, solid, and tissue samples.

EPA Method 1633 was used as a guide method to demonstrate that Millex^® polyethersulfone (PES) and nylon syringe filters and Millipore^® hydrophilic polypropylene filter membranes do not impart detectable levels of PFAS contamination and allow for acceptable analyte recovery.

Testing Millex^® PES and Nylon Syringe Filters with Methanol Samples using Modified EPA 1633

Materials and Methods

To investigate PFAS extractables in methanol solvent, PFAS contamination of Millex^® syringe filter devices was tested according to a modified version of EPA 1633 in collaboration with SGS North America (Orlando, FL location).

EPA 1633 requires the detection of a large number of PFAS compounds in high-particulate matrices - either aqueous, solids, or tissues - and thus requires filtration. However, different sample processing and extraction methods are required by the method depending on the percent solids of the samples. Despite this, every sample matrix requires a filtration step after the addition of non-extracted internal standards (NIS) and/or carbon cleanup with a 0.20 µm nylon membrane, which is performed in methanol solvent.

An overview of the method is described in the workflow below, with the LC-MS/MS conditions in Table 1. Briefly, a 5 mL methanol sample was spiked with C-13 labeled extracted (EIS) and non-extracted (NIS) internal standards ranging from 1.25 - 10 ppb, depending on the compound, according to EPA 1633. To determine if sample filtration media contributes to PFAS contamination, the entire sample was passed through the filter. The filtrate was collected and analyzed with LC-MS/MS using a C18 column. Analysis was performed using internal standards. The filters tested included: two lots of Millex^® -GP syringe filters (non-sterile, 33 mm filter with 0.22 µm PES membrane, Product No. SLGP033N), two lots of Millex^® nylon syringe filters (non-sterile, 33 mm filter with 0.20 µm nylon membrane, Product No. SLGN033N), and two lots of Millex^® nylon-HPF syringe filters (non-sterile, 25 mm filter with 0.20 µm nylon membrane and glass fiber prefilter, Product No. SLGNM25).

Workflow for Method Used for Modified EPA 1633

Prepare samples

Mix 5 mL methanol samples with EIS and NIS mixes

Filter

Filter samples using a Millex^® syringe filter or a cut disc filter in a Swinnex^® filter holder.

LC-MS/MS

Analyze by LC-MS/MS.

Table 1. LC and MS/MS conditions used in this study.

Column	C18, 100 x 2.1mm ID, 2.7 µm superficially porous particles
Mobile phase	[A] Acetonitrile [B] 2 mM ammonium acetate in 95:5 water:acetonitrile
Gradient	Time (min)	A%	B%	Flow (mL/min)
	0.20	10%	90%	0.35
	4.00	30%	70%	0.35
	7.00	55%	45%	0.35
	9.00	75%	25%	0.35
	10.00	95%	5%	0.40
	10.30	95%	5%	0.40
	10.40	2%	98%	0.40
	11.80	2%	98%	0.40
	13.00	2%	98%	0.35
Column temp	50.0 °C
Injection volume	6-10 µL autosampler injection
MS/MS conditions	Parameter	Value
	Gas Temp (°C)	250
	Gas Flow (l/min)	10
	Nebulizer (psi)	50
	Sheath Gas Heater	300
	Sheath Gas Flow (L/min)	10
	Capillary (V)	3500
	V Charging	500
	Ionization Mode	Neg ESI
	Collision Cell Gas (PSI)	40
	Collision Cell Gas	UHP N2

Results

There were no detectable PFAS contaminants in any of the Millex^® syringe filters for modified EPA 1633 above the reporting limit (RL) for the 40 compounds in any of the replicates and lots tested in methanol. However, in the category of perfluoroalkyl carboxylic acids (PFCAs), the first replicate device in Lot 1 of Millex^® nylon-HPF syringe filter devices demonstrated hits that were below the RL but above the minimum detection limit (MDL) of the instrument (Table 2). Because of this, one additional replicate device was tested and PFCAs were not detected above RL or MDL in that device. None of the other devices or lots tested for this material demonstrated hits for any PFCAs or other compounds. Regarding membrane material selection, researchers should always investigate whether levels of chemical extractables that may come after exposure to organic solvents are at appropriate levels.

Table 2. Detection of PFAS contaminants after filtration with Millex^® PES and nylon devices using LC-MS/MS according to modified EPA 1633.
^aExtracted internal standard (EIS), five total
^bThree replicate devices per lot tested, no PFAS compound detected in any lot above RL or MDL
^cThree replicate devices tested
^dFourth device tested per lot after hits reported in first replicate device
^eResult appeared in the third replicate device only, all others were ND for all PFAS compounds, including a fourth device
Abbreviations: RL = reporting limit; MDL = minimum detection limit; ND = not detected

Compound	Abbreviation	Standard	RL (ppb)	MDL (ppb)	Millipore® SLGP 0.2 µm PES	Millipore® SLGN 0.2 µm nylon	Millipore® SLGNM 0.2 µm nylon-HPF
					AVE of 2 lotsb	AVE of 2 lotsb	Lot 1c,d	Lot 2c
Perfluoro-n-butanoic acid	PFBA	13C4-PFBAa	0.8	0.4	ND	ND	ND	ND
Perfluoro-n-pentanoic acid	PFPeA	13C5-PFPeAa	0.4	0.1	ND	ND	ND	ND
Perfluoro-n-hexanoic acid	PFHxA	13C5-PFHxAa	0.2	0.05	ND	ND	0.0835e	ND
Perfluoro-n-heptanoic acid	PFHpA	13C4-PFHpAa	0.2	0.05	ND	ND	0.0688e	ND
Perfluoro-n-octanoic acid	PFOA	13C8-PFOAa	0.2	0.05	ND	ND	0.0992e	ND
Perfluoro-n-nonanoic acid	PFNA	13C9-PFNA	0.2	0.061	ND	ND	0.0827e	ND
Perfluoro-n-decanoic acid	PFDA	13C6-PFDA	0.2	0.05	ND	ND	0.115e	ND
Perfluoro-n-undecanoic acid	PFUnDA	13C7-PFUnA	0.2	0.06	ND	ND	0.107e	ND
Perfluoro-n-dodecanoic acid	PFDoDA	13C2-PFDoA	0.2	0.06	ND	ND	0.113e	ND
Perfluoro-n-tridecanoic acid	PFTrDA	13C2-PFTeDA / 13C2-PFDoA	0.2	0.084	ND	ND	0.116e	ND
Perfluoro-n-tetradecanoic acid	PFTeDA	13C2-PFTeDA	0.2	0.05	ND	ND	0.149e	ND
Perfluoro-n-butanesulfonic acid	PFBS	13C3-PFBS	0.2	0.1	ND	ND	ND	ND
Perfluoro-n-pentanesulfonic acid	PFPeS	13C3-PFHxS	0.2	0.11	ND	ND	ND	ND
Perfluoro-n-hexanesulfonic acid	PFHxS	13C3-PFHxS	0.2	0.1	ND	ND	ND	ND
Perfluoro-n-heptanesulfonic acid	PFHpS	13C8-PFOS	0.2	0.1	ND	ND	ND	ND
Perfluoro-n-octanesulfonic acid	PFOS	13C8-PFOS	0.2	0.1	ND	ND	ND	ND
Perfluoro-n-nonanesulfonic acid	PFNS	13C8-PFOS	0.2	0.1	ND	ND	ND	ND
Perfluoro-n-decanesulfonic acid	PFDS	13C8-PFOS	0.2	0.1	ND	ND	ND	ND
Perfluoro-n-dodecanesulfonic acid	PFDoS	13C8-PFOS	0.2	0.11	ND	ND	ND	ND
4:2 Fluorotelomer sulfonic acid	4:2 FTS / 4:2 FTSA	13C2-4:2FTS	0.8	0.4	ND	ND	ND	ND
6:2 Fluorotelomer sulfonic acid	6:2 FTS / 6:2 FTSA	13C2-6:2FTS	0.8	0.4	ND	ND	ND	ND
8:2 Fluorotelomer sulfonic acid	8:2 FTS / 8:2 FTSA	13C2-8:2FTS	0.8	0.41	ND	ND	ND	ND
3-Perfluoropropyl propanoic acid	3:3 FTCA	13C5-PFPeA	1	0.5	ND	ND	ND	ND
2H,2H,3H,3H-Perfluorooctanoic acid	5:3 FTCA	13C5-PFHxA	5	1	ND	ND	ND	ND
n-3-Perfluoroheptyl propanoic acid	FHpPA / 7:3 FTCA	13C5-PFHxA	5	1	ND	ND	ND	ND
Perfluorooctanesulfonamide	PFOSA / FOSA	13C8-PFOSA	0.2	0.1	ND	ND	ND	ND
N-methyl-perfluorooctanesulfonamide	N-MeFOSA	D3-NMeFOSA	0.2	0.1	ND	ND	ND	ND
N-ethyl-perfluorooctanesulfonamide	N-EtFOSA	D5-NEtFOSA	0.2	0.1	ND	ND	ND	ND
N-methyl Perfluorooctanesulfonamidoacetic acid	N-MeFOSAA	D3-NMeFOSAA	0.2	0.1	ND	ND	ND	ND
N-ethyl Perfluorooctanesulfonamidoacetic acid	N-EtFOSAA	D5-NEtFOSAA	0.2	0.13	ND	ND	ND	ND
N-methyl perfluorooctanesulfonamidoethanol	N-MeFOSE	D7-NMeFOSE	2	1	ND	ND	ND	ND
N-ethyl perfluorooctanesulfonoamidoethanol	N-EtFOSE	D9-NEtFOSE	2	1	ND	ND	ND	ND
Hexafluoropropylene oxide dimer acid	GenX / HFPO-DA	13C3-HFPO-DA	0.8	0.2	ND	ND	ND	ND
4,8-Dioxa-3H-perfluorononanoic acid	ADONA / DONA	13C3-HFPO-DA	0.8	0.2	ND	ND	ND	ND
Perfluoro-3-methoxypropanoic acid	PFMPA	13C5-PFPeA	0.4	0.1	ND	ND	ND	ND
Perfluoro-4-methoxybutanoic acid	PFMBA	13C5-PFPeA	0.4	0.11	ND	ND	ND	ND
Nonafluoro-3,6-dioxaheptanoic acid	NFDHA	13C5-PFHxA	0.4	0.12	ND	ND	ND	ND
Chlorohexadecafluoro-3-oxanone-1-sulfonic acid	9Cl-PF3ONS	13C3-HFPO-DA	0.8	0.2	ND	ND	ND	ND
11-Chloroeicosafluoro-3-oxaundecane-1-sulfonic acid	11Cl-PF3OUdS	13C3-HFPO-DA	0.8	0.2	ND	ND	ND	ND
Perfluoro(2-ethoxyethane)sulfonic acid	PFEESA	13C5-PFHxA	0.4	0.1	ND	ND	ND	ND

These results suggest that PES and nylon Millex^® syringe filters are reliable and appropriate to use in the filtration with EPA 1633 for analysis of PFAS compounds. Nylon-HPF Millex^® filtration devices should be considered when samples require pre-filtration, and researchers should always be aware of the required reporting limits for the method.

Chemical extractables (apart from PFAS compounds listed in Table 2) were not tested in this study. To get the best possible data quality, researchers should always investigate the levels of chemical extractables that may come after certain membrane materials are exposed to organic solvents to make sure that they are at acceptable levels.

Recovery

For EPA Method 1633 testing in methanol solvent, the percent recoveries for filtrates from nylon-based syringe filter devices versus PES-based syringe filter devices were at similar levels (Figure 1). This supports what has been reported in literature for methanol helping to dissociate PFAS molecules from filtration media.

Figure 1. The average percent recovery (mean ± standard deviation (STDEV), n=6 replicates over 2 lots) of C-13 labeled standards for PFBS, PFBA, PFOA, PFOS and PFNA after filtration with nylon Millex^® syringe filters (purple, mean±STDEV, n=9 replicates over 3 lots), nylon-HPF Millex^® syringe filters (blue with checked pattern) and PES Millex^® syringe filters (green with horizontal slash marks). The acceptable QC range for recovery of internal standards is demonstrated by the solid black vertical line to the left for each compound.

Testing Millipore^® Polypropylene Membrane Filters with Methanol Samples using Modified EPA 1633

Syringe filter devices are the most recommended and preferred format for filtering samples for LC-MS/MS analysis of PFAS due to ease of use and the range of small volumes that can be processed (10-100 mL). There are instances, however, when syringe filters may not be the best option for filtration; for example, when there are no commercially available syringe filters suitable for a specific application. In these instances, an alternative must be considered. A syringe filter-like device, such as a Swinnex^® holder, is a viable alternative. This pressure-driven device holds any cut disc membrane filter of a specific size (13 mm or 25 mm diameter) and is operated in the same way as a traditional syringe filter, thus converting any membrane material into a syringe filter format.

Polypropylene is a durable material compatible with a broad range of solvents and temperatures and demonstrates low extractables, making it appropriate specifically for PFAS-related sample and mobile phase preparation. A challenge with polypropylene is that it is naturally hydrophobic, which makes it challenging to filter aqueous samples. Most commercially available polypropylene disc filters are hydrophobic, such as Millipore^® polypropylene membrane filters (Product No. PPTG04700 and Product No. PPTH04700). Though appropriate for solvents such as methanol, it can be challenging to filter aqueous samples. In a few cases, polypropylene can be found in a hydrophilic format (Millipore^® hydrophilic polypropylene membrane filters, Product No. PPHG04700 and Product No. PPHH04700). These filters are suited to handle aqueous samples. Thus, realizing the potential for polypropylene material to be used within the context of a variety of PFAS workflows, including mobile phase filtration, we determined the level of PFAS extractables that these filter discs release.

Materials and Methods

Swinnex^® filter holder assembly

Hydrophilic Millipore^® polypropylene (PP) membrane filters of 0.2 µm pore size were tested for PFAS extractable content. Swinnex^® devices (25 mm diameter) were used to convert the disc membrane filters into a Luer-lock based syringe filter device, according to Figure 2. Once assembled, the Swinnex^® device can be connected to a Luer-lock syringe barrel with the material to be filtered. Filtration was then performed as with other syringe filter devices. For every disc replicate, a new and clean Swinnex^® device was used.

Figure 2. Assembling Swinnex^® device with a polypropylene cut disc membrane filter.

Modified 1633

Three lots of the hydrophilic 0.2 µm polypropylene cut disc membrane filters were tested, using n=3 filters per lot. EPA 1633 outlines slightly different strategies of extraction and cleanup for each high-particulate matrix tested. Thus, this study focused on just the filtration step required for all matrices after the addition of non-extracted internal standards (NIS) and/or carbon cleanup performed in a methanol solvent. This was done to focus specifically on whether the cut disc membrane filters tested contained any contamination of the 40 PFAS compounds outlined in the method. This modified method is depicted in the workflow above.

Once each cut disc membrane filter was placed securely into a Swinnex^® device, 5 mL methanol samples spiked with C-13 labeled extracted (EIS) and non-extracted (NIS) internal standards according to the Method were passed through each filter. The filtrate was collected for LC-MS/MS using a C18 column using conditions described in Table 1 and analyzed by internal standards. Since the filtration was performed in methanol, none of the cut disc membrane filters required pre-wetting.

Results

As was found for Millex^® syringe filter devices, there were no detectable PFAS contaminants in any of the hydrophilic polypropylene cut disc membrane filters tested according to modified EPA 1633 above the RL, ranging from 0.2-5 ppb, or the MDL, ranging from 0.05-1 ppb (Table 3). This indicates that these membranes do not have PFAS extractables at these limits and could be used for PFAS applications where filtration is needed for sample preparation. There were no challenges observed with recovery of any of the internal standards for EPA 1633 in methanol, which is unsurprising. Our studies, and previous studies¹ with nylon membranes indicated that exposure to methanol solvent reduced non-specific adsorption of PFAS compounds and internal standards.

Table 3. Detection of PFAS contaminants in methanol samples after filtration with three different lots of hydrophilic 0.2 µm polypropylene disc filters in Swinnex^® devices in methanol solvent using modified EPA 1633.
^aExtracted internal standard (EIS), five total
^bThree replicate devices per lot tested; thus, date is the mean ± standard deviation of n=3 devices. No PFAS compound detected in any device above RL or MDL
Abbreviations: RL = reporting limit; MDL = minimum detection limit; PP = polypropylene; philic = hydrophilic; phobic = hydrophobic; ND = not detected

Compound	Abbreviation(s)	Standard	RL (ppb)	MDL (ppb)	Millipore® PPHG Hydrophilic PP, 0.2 µm
					Lot 1b	Lot 2b	Lot 3b
Perfluoroalkyl Carboxylic Acids
Perfluoro-n-butanoic acid	PFBA	13C4-PFBAa	0.8	0.4	ND	ND	ND
Perfluoro-n-pentanoic acid	PFPeA	13C5-PFPeAa	0.4	0.1	ND	ND	ND
Perfluoro-n-hexanoic acid	PFHxA	13C5-PFHxAa	0.2	0.05	ND	ND	ND
Perfluoro-n-heptanoic acid	PFHpA	13C4-PFHpAa	0.2	0.05	ND	ND	ND
Perfluoro-n-octanoic acid	PFOA	13C8-PFOAa	0.2	0.05	ND	ND	ND
Perfluoro-n-nonanoic acid	PFNA	13C9-PFNA	0.2	0.061	ND	ND	ND
Perfluoro-n-decanoic acid	PFDA	13C6-PFDA	0.2	0.05	ND	ND	ND
Perfluoro-n-undecanoic acid	PFUnDA	13C7-PFUnA	0.2	0.06	ND	ND	ND
Perfluoro-n-dodecanoic acid	PFDoDA	13C2-PFDoA	0.2	0.06	ND	ND	ND
Perfluoro-n-tridecanoic acid	PFTrDA	13C2-PFTeDA / 13C2-PFDoA	0.2	0.084	ND	ND	ND
Perfluoro-n-tetradecanoic acid	PFTeDA	13C2-PFTeDA	0.2	0.05	ND	ND	ND
Perfluoroalkyl Sulfonic Acids
Perfluoro-n-butanesulfonic acid	PFBS	13C3-PFBS	0.2	0.1	ND	ND	ND
Perfluoro-n-pentanesulfonic acid	PFPeS	13C3-PFHxS	0.2	0.11	ND	ND	ND
Perfluoro-n-hexanesulfonic acid	PFHxS	13C3-PFHxS	0.2	0.1	ND	ND	ND
Perfluoro-n-heptanesulfonic acid	PFHpS	13C8-PFOS	0.2	0.1	ND	ND	ND
Perfluoro-n-octanesulfonic acid	PFOS	13C8-PFOS	0.2	0.1	ND	ND	ND
Perfluoro-n-nonanesulfonic acid	PFNS	13C8-PFOS	0.2	0.1	ND	ND	ND
Perfluoro-n-decanesulfonic acid	PFDS	13C8-PFOS	0.2	0.1	ND	ND	ND
Perfluoro-n-dodecanesulfonic acid	PFDoS	13C8-PFOS	0.2	0.11	ND	ND	ND
Fluorotelomer Sulfonic Acids
4:2 Fluorotelomer sulfonic acid	4:2 FTS / 4:2 FTSA	13C2-4:2FTS	0.8	0.4	ND	ND	ND
6:2 Fluorotelomer sulfonic acid	6:2 FTS / 6:2 FTSA	13C2-6:2FTS	0.8	0.4	ND	ND	ND
8:2 Fluorotelomer sulfonic acid	8:2 FTS / 8:2 FTSA	13C2-8:2FTS	0.8	0.41	ND	ND	ND
Fluorotelomer Carboxylic Acids
3-Perfluoropropyl propanoic acid	3:3 FTCA	13C5-PFPeA	1	0.5	ND	ND	ND
2H,2H,3H,3H-Perfluorooctanoic acid	5:3 FTCA	13C5-PFHxA	5	1	ND	ND	ND
n-3-Perfluoroheptyl propanoic acid	FHpPA / 7:3 FTCA	13C5-PFHxA	5	1	ND	ND	ND
Perfluoroctane Sulfonamides
Perfluorooctanesulfonamide	PFOSA / FOSA	13C8-PFOSA	0.2	0.1	ND	ND	ND
N-methyl-perfluorooctanesulfonamide	N-MeFOSA	D3-NMeFOSA	0.2	0.1	ND	ND	ND
N-ethyl-perfluorooctanesulfonamide	N-EtFOSA	D5-NEtFOSA	0.2	0.1	ND	ND	ND
Perfluorooctane Sulfonamidoacetic Acids
N-methyl Perfluorooctanesulfonamidoacetic acid	N-MeFOSAA	D3-NMeFOSAA	0.2	0.1	ND	ND	ND
N-ethyl Perfluorooctanesulfonamidoacetic acid	N-EtFOSAA	D5-NEtFOSAA	0.2	0.13	ND	ND	ND
Perfluorooctane Sulfonamido Ethanols
N-methyl perfluorooctanesulfonamidoethanol	N-MeFOSE	D7-NMeFOSE	2	1	ND	ND	ND
N-ethyl perfluorooctanesulfonoamidoethanol	N-EtFOSE	D9-NEtFOSE	2	1	ND	ND	ND
Per and Polyfluoroether Carboxylic Acids
Hexafluoropropylene oxide dimer acid	GenX / HFPO-DA	13C3-HFPO-DA	0.8	0.2	ND	ND	ND
4,8-Dioxa-3H-perfluorononanoic acid	ADONA / DONA	13C3-HFPO-DA	0.8	0.2	ND	ND	ND
Perfluoro-3-methoxypropanoic acid	PFMPA	13C5-PFPeA	0.4	0.1	ND	ND	ND
Perfluoro-4-methoxybutanoic acid	PFMBA	13C5-PFPeA	0.4	0.11	ND	ND	ND
Nonafluoro-3,6-dioxaheptanoic acid	NFDHA	13C5-PFHxA	0.4	0.12	ND	ND	ND
Per and Polyfluoroether Sulfonic Acids
Chlorohexadecafluoro-3-oxanone-1-sulfonic acid	9Cl-PF3ONS	13C3-HFPO-DA	0.8	0.2	ND	ND	ND
11-Chloroeicosafluoro-3-oxaundecane-1-sulfonic acid	11Cl-PF3OUdS	13C3-HFPO-DA	0.8	0.2	ND	ND	ND
Perfluoro(2-ethoxyethane)sulfonic acid	PFEESA	13C5-PFHxA	0.4	0.1	ND	ND	ND

Recovery

There are nuances in binding and retention of PFAS compounds leading to different recoveries in the filtrate, as observed with polypropylene, nylon, and polyethersulfone membrane materials (Figure 3). Recovery in methanol samples filtered through 0.2 µm hydrophilic polypropylene is similar to that using 0.20 µm nylon and 0.22 µm polyethersulfone. Together, this indicates that polypropylene cut disc membrane filters can be paired with Swinnex^® devices to offer an alternative sample filtration method to syringe filter formats. For PFAS methods where the mobile phase needs to be filtered, polypropylene membrane filters may be used with the appropriate filter holder. Recovery of certain PFAS compounds should be carefully considered as part of this workflow.

Figure 3. The average percent recovery of select C-13 labeled standards in methanol according to EPA 1633 for 0.20 µm nylon syringe filters (purple), 0.22 µm PES syringe filters (blue with checked pattern), and 0.2 µm hydrophilic polypropylene cut disc membrane filters (green with horizontal slash marks). All values are mean ± standard deviation across three lots, for a total of nine discs.

Water versus Methanol Samples

Using syringe filter devices, a trend was observed of increased recovery for nylon devices when filtering methanol versus water, which has also been observed in published studies.¹ However, not all membrane materials may respond in the same way to filtering in water versus methanol. For example, hydrophilic polypropylene demonstrated similar recovery within the acceptable QC range of all internal standards for both methanol and water, and in some cases (for example, shorter chain PFCA and PFSA compounds) even higher recovery in water than methanol, which was not observed with either PES or nylon materials (Figure 4).

Figure 4. The average percent recovery of all C-13 labeled standards for hydrophilic polypropylene cut disc membrane filters in water vs. methanol. For water, values are mean ± standard deviation, n=3 replicates of one lot tested. For methanol, values are mean ± standard deviation, n=3 replicates across three lots, for a total of nine discs.

Filters for Modified EPA 1633

Using a modified EPA 1633 method, this study demonstrated that PES and nylon syringe filters, as well as hydrophilic polypropylene membranes held in a Swinnex^® device, are reliable and appropriate to use in the analyses of PFAS compounds.

• There were no detectable PFAS compounds in any of these filtration devices.
• The percent recoveries for filtrates from all these devices were at similar levels.

Recommended Filtration Products

References

1. So MK, Taniyasu S, Lam PKS, Zheng GJ, Giesy JP, Yamashita N. 2006. Alkaline Digestion and Solid Phase Extraction Method for Perfluorinated Compounds in Mussels and Oysters from South China and Japan. Arch Environ Contam Toxicol. 50(2):240-248. https://doi.org/10.1007/s00244-005-7058-x