ALS METHOD CODE
LIMIT OF REPORTING (LOR)
Water (including landfill leachate) 0.02 mg/L
Soil & Sediment 1 mg/kg
AFFF Products 50 mg/kg
Water/AFFF Product 60mL HDPE plastic bottle (Unpreserved), grey label
Soil/Sediment 200mL HDPE plastic specimen jar (Unpreserved), grey label
Note – for soils/sediments, the same specimen jar can be used for both PFAS and TOF analysis
QLD Waste Disposal (ERA 60)
Sampling and Holding Time
Interest in TOF analysis is primarily associated with accounting for the total mass of Per- and Polyfluoroalkyl Substances (PFAS) in a sample. PFAS represents a group of thousands of man-made organofluorine compounds (e.g. PFOS & PFOA) which have been shown to be globally distributed, environmentally persistent and bioaccumulative. Due to their unique water and oil resistant properties and thermal stability, PFAS have been used in a wide range of commercial applications, including food packaging, cleaners, floor polishes, photographic film, cosmetics, insecticides, Teflon® production, and in surface treatments, such as protection of paper, clothing and carpets. Large-scale releases have been associated with their use in fire-fighting foams (i.e AFFF), where the fluorinated surfactants are key ingredients that provide low surface tension, enabling film formation on top of fuels, starving the fire of oxygen.
Conventional PFAS analysis by LCMSMS typically quantifies a relatively small set of key analytes (~30 compounds) and therefore may greatly underestimate the extent of PFAS in the environment. The PFAS National Environmental Management Plan (NEMP) states that it is “important that environmental assessments qualitatively consider the likely total mass and distribution of all PFAS present” using techniques such as the Total Oxidisable Precursor (TOP) and TOF assays, as a multiple lines of evidence approach to inform risk assessments. ALS currently holds NATA accreditation for the TOP assay (refer to Enviromails™ 110 & 117), and the addition of TOF rounds out ALS ’ analytical capabilities for comprehensive PFAS accounting.
A key limitation of the Total Oxidisable Precursor (TOP) assay is that it relies on the analytical scope provided by conventional LCMSMS analysis and therefore fails to account for oxidation products with carbon chain lengths <C4 and >C14. The oxidation process also forms perfluoroalkyl carboxylic acid products from fluorotelomer “precursors” with chain lengths shorter than the parent fluorotelomer. The fluorinated portions of the carbon chain lost during this process are therefore also unaccounted for.
While TOF analysis is not subject to these limitations, it provides no information of chain length and is not selective for PFAS, rather providing an estimate of the total fluorine from organic forms in a sample. TOF analysis can therefore be used to verify the degree to which the TOP assay accounts for potential precursors. Note, TOF analysis is not as sensitive a technique as conventional LCMSMS
and so has higher limits of reporting (LOR). It may therefore not be suitable for low level screening, but more appropriate as a screening tool for higher impact zones and circumstances where information on the approximate carbon chain length is not required. Ultimately, a combination of TOP, TOF and standard LCMSMS analysis may be appropriate to provide a well-rounded understanding of the PFAS content of a sample. Scenarios are provided below which demonstrate how the combination of tests may be useful.
Scenario B: Standard PFAS < TOP ≈ TOF. Evidence of precursors, largely accounted for by TOP.
Scenario C: Standard PFAS < TOP < TOF. Evidence of precursors but not fully accounted for by TOP.
ALS Enviromail™ #117. PFAS Testing in Brisbane and TOP Assay Challenges and Developments, 2017.
ALS Enviromail™ #126. Total Organic Fluorine (TOF) for Compliance with QLD Waste Disposal Guideline ERA 60.
HEPA (2018). PFAS National Environmental Management Plan 2018. Heads of EPA Australia and New Zealand.