Investigating the Biodegradability of a Fluorotelomer-Based Acrylate

Oct 8, 2014 - Catch plates were placed under each pot to capture some, although not all, target ... mixed with 100–300 mg of sodium azide (NaN3) to ...
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Investigating the Biodegradability of a Fluorotelomer-Based Acrylate Polymer in a Soil-Plant Microcosm by Indirect and Direct Analysis Keegan Rankin, Holly Lee, Pablo J Tseng, and Scott Andrew Mabury Environ. Sci. Technol., Just Accepted Manuscript • DOI: 10.1021/es502986w • Publication Date (Web): 08 Oct 2014 Downloaded from http://pubs.acs.org on October 11, 2014

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Investigating the Biodegradability of a Fluorotelomer-Based Acrylate Polymer in a Soil-Plant Microcosm by Indirect and Direct Analysis Keegan Rankin, Holly Lee, Pablo J. Tseng and Scott A. Mabury* Department of Chemistry, University of Toronto, 80 St. George St., Toronto, Ontario, Canada, M5S 3H6 *Corresponding author: Phone: (416) 978-1780; Fax: (416) 978-3596; Email: [email protected] Abstract

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Fluorotelomer-based acrylate polymers (FTACPs) are a class of side-chain fluorinated

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polymers used for a variety of commercial applications. The degradation of FTACPs through

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ester hydrolysis and/or cleavage of the polymer backbone could serve as a significant source of

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perfluoroalkyl carboxylates (PFCAs). The biodegradation of FTACPs was evaluated in a soil-

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plant microcosm over 5.5 months in the absence/presence of wastewater treatment plant

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(WWTP) biosolids, using a unique FTACP determined to be a homopolymer of 8:2

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fluorotelomer acrylate (8:2 FTAC). Though structurally different from commercial FTACPs, the

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unique FTACP possesses 8:2 fluorotelomer side chain appendages bound to the polymer

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backbone via ester moieties. Liberation and subsequent biodegradation of the 8:2 fluorotelomer

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appendages was indirectly determined by monitoring for PFCAs of varying chain lengths (C6-

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C9) and known fluorotelomer intermediates by liquid chromatography tandem mass

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spectrometry (LC-MS/MS). A FTACP biodegradation half-life range of 8-111 years was

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inferred from the 8:2 fluorotelomer alcohol (8:2 FTOH) equivalent of the unique FTACP and the

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increase of degradation products. The progress of FTACP biodegradation was also directly

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monitored qualitatively using matrix-assisted laser desorption/ionization time-of-flight (MALDI-

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TOF) mass spectrometry. The combination of indirect and direct analysis indicated that the

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model FTACP biodegraded predominantly to perfluorooctanoate (PFOA) in soils, and at a

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significantly higher rate in the presence of a plant and WWTP biosolids.

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Introduction Fluorotelomer-based polymers (FTPs) are commonly used surface protectants in the

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carpet, textile, upholstery and paper industries.1 The manufacture of FTPs constitutes >80% of

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all fluorotelomer-based raw materials produced worldwide.2 Recent concerns have been raised

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over the role of FTPs as perfluoroalkyl carboxylate (PFCA) precursors.3,4 Residual

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fluorotelomer alcohols (FTOHs) are known to be present in FTP materials,5,6 and have been

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demonstrated to readily biodegrade to PFCAs in aerobic soil and waste water treatment plant

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(WWTP) media.7-12 At levels 7 CF2), which have a demonstrated ability to accumulate in biota.20,21

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Russell et al.3 proposed two potential degradation pathways of FTPs: 1) cleavage of the

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ester or urethane linkage or 2) breakage of the carbon-carbon backbone. Cleavage of the linking

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moiety would release the bound fluorotelomer appendage as FTOHs that then degrade to PFCAs.

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Recent studies demonstrated that pathway 1 could occur via microbial hydrolysis of ester

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linkages of fluorotelomer-based material under aerobic environments, such as polyfluoroalkyl

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phosphate esters (PAPs) and fluorotelomer stearate monoester (FTS).22,23 Alternatively,

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breaking the polymer backbone would yield smaller oligomeric species, which could more

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readily biodegrade because of the lower molecular weight. If the linking ester moieties are

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inaccessible to microbes, then pathway 2 could occur via β-oxidation of the polymer backbone

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as reported for polyacrylic acid.24

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The approach for assessing the biodegradability of FTPs used to date, was to measure

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both intermediates and terminal PFCA products that result from the biotransformation of FTOHs

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rather than analytically probing the polymer directly. This indirect approach was used in the

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three FTP biodegradation studies.3,4,13 However, the presence of intermediates and PFCAs does

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not directly confirm FTP degradation, as the PFCAs themselves may be present in commercial

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products or result from the degradation of other fluorotelomer-based residual materials. As such,

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the detection of target analytes above residual levels was generally used to identify FTP

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degradation,4 a difficult task if there is a large background signal. In two parallel studies, the

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biodegradation half-lives for FTACPs and FTURPs were calculated to be 1200-1700 and 79-241

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years respectively, based on polymer mass.3,13 In a separate study, Washington et al.4 reported a

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biodegradation half-life for FTACPs of 870-1400 years based on polymer mass, but also

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suggested that the half-life could be closer to 10-17 years when normalized to the polymer

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particle surface area. The discrepancy between these half-lives is a reason the biodegradability

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of FTPs remains widely debated.

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The objective of this study was to evaluate the biodegradation of a unique FTACP in a

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soil-plant microcosm over 5 months. The unique FTACP was synthesized in-house using 8:2

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fluorotelomer acrylate (8:2 FTAC) as the primary monomer, and exhaustively purified by

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removing volatile FTACs and/or FTOH residuals prior to incubation. Biodegradation of the

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model FTACP was evaluated under several different soil conditions, including soils amended

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with WWTP biosolids and sown with the alfalfa species, Medicago truncatula. Quantification of

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degradation products by liquid chromatography tandem mass spectrometry (LC-MS/MS) served

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as an indirect means to determine FTACP biodegradation and were used to estimate FTACP

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biodegradation half-lives. We also report herein, the first direct evidence of FTACP

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biodegradation using matrix-assisted laser desorption/ionization time-of-flight (MALDI-TOF)

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mass spectrometry to analyze the polymer itself.

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Experimental Chemicals. A complete list of chemicals used in this study can be found in the Supporting Information (SI).

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Microcosm Materials. Sandy loam soil was collected from an agricultural farmland

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(Northumberland County, ON; 44o05’N, 78o01’W) in 2009 and sieved with a 2 mm stainless

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steel mesh. Soil characterization was performed by SGS AgriFood Laboratories (Guelph, ON)

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and reported as follows: pH 5.5; 1.8% organic matter; cation exchange capacity of 96 µmol/g; 49

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mg/kg of NaHCO3-extractable P; 63% sand, 32% silt and 5% clay. WWTP biosolid material

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(30% solids) was obtained from the North Toronto WWTP (Toronto, ON) in 2009. The alfafa

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plant species Medicago truncatula was grown from seeds donated by the Stinchcombe research

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group (Department of Ecology and Evolutionary Biology, University of Toronto, ON).

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FTACP Polymerization. Multiple approaches were attempted to synthesize a FTACP

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possessing three repeating monomers, but were unsuccessful. A unique FTACP homopolymer

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was synthesized in-house by aqueous dispersion following two commercial patents,14,15 and is

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detailed in the SI. Briefly, 8:2 FTAC and butyl acrylate were added to an aqueous solution of

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dodecyl amine hydrochloride and hexadecylthiol in a round bottom flask equipped with a

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magnetic stirrer and dry ice condenser. The solution was purged with nitrogen for 2.5 hours at

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5oC and then a cold solution of vinylidene chloride and acetone was added. The polymerization

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was initiated with 2,2´-azobis(2-methylpropionamide) dihydrochloride (AIBA) and proceeded

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for 15 hours at 80oC. Upon completion, the aqueous dispersion was filtered and the opaque

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FTACP material was collected.

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Residual Removal. Post-polymerization, a series of wash and heat purging steps were

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used to remove residual FTOH and FTAC impurities. The FTACP material was placed under

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vacuum while periodically washed with a 80:20 methanol:water solution for 14 days. The

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FTACP material was then melted using a 95oC oil bath while continuously purged with carbon-

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filtered air for 20 days. A fraction of the FTACP material was then heated in the same manner

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for 3 days during which any volatile compounds were collected in XAD cartridges. The

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cartridges were extracted with ethyl acetate and analyzed by gas chromatography-mass

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spectrometry (GC-MS). Although this approach differs from the method recently reported by

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Washington et al.,25 our method was also found to exhaustively extract volatile FTOHs and

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FTACs. The purified FTACP was determined to contain 4.71 and 2.63 nmole residual 8:2

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FTOH and 8:2 FTAC per gram of FTACP representing 2.2 x 10-4 and 1.4 x 10-4 wt%,

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respectively. Low PFCA levels, 4.7 x 10-7 wt%, were observed as impurities in the purified

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FTACP, and explain the PFCAs concentrations observed at 0 months.

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FTACP Characterization. The unique FTACP was characterized by differential

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scanning calorimetry (DSC) and MALDI-TOF mass spectrometry. DSC procedures and results

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are presented in the SI. MALDI-TOF characterization was carried out using a Waters

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Micromass MALDI micro MX™ TOF mass spectrometer (Waters Corporation, Milford, MA)

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equipped with a nitrogen laser (λ = 337.1 nm) operated at a frequency of 5 Hz and rastered in a

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pre-set pattern. Mass spectra were acquired in positive ion and reflectron modes using a flight

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tube voltage of 12 kV. A total of 100 mass spectra were acquired per sample, and summed using

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Waters Mass Lynx V4.1 mass spectrometry software.

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FTACP samples were prepared for MALDI-TOF analysis using the two-layer dried

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droplet method.26,27 Dithranol served as the matrix and lithium trifluoroacetate as the

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cationization agent, and were co-dissolved in trichloromethane (CHCl3) at 10 mg/mL and 1

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mg/mL, respectively. FTACP samples were prepared in α,α,α-trifluorotoluene (TFT) at 10

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mg/mL. Deposition of 1µL of the matrix:cationization agent solution onto a stainless steel

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Waters MALDI target plate served as the first layer. A 1µL aliquot of the FTACP solution was

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deposited as the second layer on top of the dried matrix:cationization agent solution.

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Biodegradation Experimental Design. The five experimental variables were prepared

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as follows: (1) Soil Control – soil without biosolids (n = 1 per timepoint); (2) Plant/Biosolids

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Control – biosolids-amended soil sown with plant seeds (n = 3 per timepoint); (3) FTACP/Soil –

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soil without biosolids mixed with 50 mg FTACP (n = 3 per timepoint); (4) FTACP/Plant – soil

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without biosolids sown with plant seeds mixed with 50 mg FTACP (n = 3 per timepoint); (5)

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FTACP/Plant/Biosolids – biosolids-amended soil sown with plant seeds mixed with 50 mg

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FTACP (n = 3 per timepoint).

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Biosolids-amended soils were prepared at a mixing rate of 16 g biosolids/kg of soil (~8.7

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metric dry tons/ha) in an OdjobTM concrete mixer (Scepter Corporation, Toronto, ON). This rate

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is similar to the 5-year maximal application rate of 8 tons/ha permitted in Ontario.28

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Approximately 600 g soil and biosolids were transferred into each pot. Between 5–10 Medicago

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truncatula seeds were planted in each pot for the three conditions, Plant/Biosolids Control,

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FTACP/Plant and FTACP/Plant/Biosolids, followed by inoculation of cultured rhizobia.

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Preparation of the rhizobia culture is described in the SI. Catch plates were placed under each

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pot to capture some, though not all, target analytes that may have leached from the soil during

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watering of the plants. All pots were kept in a greenhouse (Earth Sciences Centre, University of

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Toronto, ON) for 5.5 months under natural sunlight and supplementary illumination (200

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µmol/m2/sec) at a temperature regime of 25/21oC day/night, and watered daily.

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Soils were sampled at 1.5, 3.5 and 5.5 months by sacrificing the entire pot, and then

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immediately mixed with 100–300 mg of sodium azide (NaN3) to halt microbial activity. Initial

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concentrations of target analytes were measured in soil using one pot (n = 1) of all five

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conditions prior to the addition of the model FTACP. Soil was sampled in triplicate (n = 3) from

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each of the three pots in all conditions at each time point, except for the Soil Control in which

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soil was sampled from 1 pot. For Plant/Biosolids Control, FTACP/Plant and

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FTACP/Plant/Biosolids, the plant shoots and roots were harvested, cleaned of soil particles and

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archived together. Catch plates were also archived. All archived microcosm compartments were

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stored at 4oC until analysis.

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Extraction and Analysis. Soil extractions was performed on 2 g soil samples by

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sonication at 60oC for 15-20 minutes in 5 mL of a basic methanol (1% (v/v) ammonium

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hydroxide). Following centrifugation at 6000 rpm, the supernatant was decanted into a new

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polypropylene tube, and the soil extracted a second time. The supernatants were combined and

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blown to dryness. Plant matter was lyophilized and homogenized finely using a mortar pestle,

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and 2 g samples extracted twice in 10 mL basic methanol sonication at 60oC for 15-20 minutes.

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The extracts were cleaned using ENVI Carb cartridges (Supelclean, 1 mL/100 mg) and blown to

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dryness. Catch plates were rinsed with 10 mL basic methanol and blown to dryness. Soil, plant

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and catch plate extracts were reconstituted with 2 mL methanol, passed through 0.2 µm Nylon

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filters, and then analyzed using an Agilent 1100 high pressure liquid chromatography (HPLC)

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coupled to an Applied Biosystems/MDS Sciex API4000 triple quadrupole MS (Concord, ON)

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operated in negative electrospray ionization mode. Chromatographic separation was performed

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using a GeminiNX C18 column (4.6 x 50 mm, 3 µm; Phenomenex, Torrance, CA). Detailed

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instrumental parameters used be found in the SI.

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The unique FTACP was extracted from soils using α,α,α-trifluorotoluene (TFT). For

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each pot, 2 x 5 g soil samples were each extracted with 5 mL of TFT by sonication and vortexing

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for 5 minutes at room temperature. The two extracts per pot were combined and the solids

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removed. The extract was then blown to dryness under nitrogen and re-constituted in 1 mL of

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TFT. MALDI-TOF analysis was carried out using the procedures described above.

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Quality Assurance (QA). Quantitation of the PFCAs, fluorotelomer carboxylates

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(FTCAs) and fluorotelomer unsaturated carboxylates (FTUCAs) was performed using mass-

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labeled internal standards except for those analytes where no corresponding mass-labeled

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standards were available at the time of the experiment. In these few cases, quantification was

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performed using structurally similar internal standards as surrogate standards (Table S1). Spike

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and recoveries from soil, plant and catch plate ranged from 51-132, 73-135 and 32-105%,

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respectively. Additional QA information is provided in the SI.

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Results and Discussion FTACP Characterization. Structural characterization of the unique FTACP was

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performed by MALDI-TOF producing a characteristic pattern indicative of a synthetic polymer

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with repeating signals having a spacing of 518 Da for both major and minor series shown in SI

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Figure S2. The number average molecular weight (Mn, Equation 1), weight average molecular

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weight (Mw, Equation 2) and polydispersity index (PDI, Equation 3) were calculated from the

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major repeating series to be 3007 and 3747 Da, and 1.25, respectively. These values are below

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the ~40000 molecular weight postulated by Russell et al. for commercial FTACPs,3 which could

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result in our unique FTACP being more susceptibility to biodegradation.

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Mn = ΣMiNi ΣNi

(Eq. 1)

Mw = ΣMi2Ni ΣMiNi

(Eq. 2)

PDI = Mw Mn

(Eq. 3)

As the intended FTACP structure was to contain three repeating units and resemble the

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suggested structure of commercial FTACPs (Figure 1A),3 the monomeric species 8:2 FTAC,

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butyl acrylate and vinylidene chloride were all included in the polymerization. However, after

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close inspection of the mass spectrum (Figure S2) and a comparison of the experimental and

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theoretical isotopic pattern for the 1819 m/z signal (Figure S3), it was determined that neither

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butyl acrylate nor vinylidene chloride were incorporated into the FTACP. The peak spacing of

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518 Da corresponds to the mass of 8:2 FTAC and confirms the successful polymerization of a

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FTACP. Our unique FTACP was determined to be solely a homopolymer of 8:2 FTAC

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containing hydrogen and hexadecylthiol end groups (Figure 1B), and have primarily between 2

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to 16 fluorotelomer appendages. Though the two FTACPs shown in Figure 1 have structural

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differences, our unique FTACP (Figure 1B) possesses certain features that make it a suitable

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surrogate to investigate the stability of commercial FTACPs. Firstly, the MALDI-TOF results

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demonstrated that our FTACP contains 8:2 fluorotelomer appendages covalently bound to the

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hydrocarbon backbone through an ester linkage. FTACs are the principle monomer used in the

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preparation of commercial FTACPs,14,15 and have the same bonding of fluorotelomer appendages

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to the polymer backbone. Secondly, the side-by-side configuration of the 8:2 fluorotelomer

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appendages in our FTACP could render the ester moiety more sterically constrained than a

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commercial FTACP, which have additional interspersed non-fluorinated monomers. The

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presence of non-fluorinated monomers could affect the lability of the ester moieties making

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commercial FTACPs more susceptible to microbial hydrolysis. Thus, our unique FTACP likely

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represented a suitable experimental probe for assessing the lability of FTPs having moderate

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molecular weights.

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Indirect Analysis of FTACP Biodegradation. The observed intermediate and product

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trends for FTACP/Soil, FTACP/Plant and FTACP/Plant/Biosolids are consistent with the

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biotransformation of 8:2 FTOH to PFOA previously reported in aerobic soil,10,11 which suggests

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either degradation of the unique FTACP or residual 8:2 FTOH or 8:2 FTAC. From the 50 mg of

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unique FTACP spiked into each pot, the 8:2 FTOH equivalence was calculated to be 8.88 x 104

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nmole using the Mn and Mw values as outlined in the SI. As described earlier, residual 8:2 FTOH

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and 8:2 FTAC in the exhaustively purified FTACP material were estimated to be 4.71 and 2.63

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nmole per gram of FTACP, which equates to as much as 0.236 and 0.132 nmole residual 8:2

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FTOH and 8:2 FTAC per pot (Table 1). For the control pots, Soil Control and Plant/Biosolids

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Control, PFOA was observed to have the highest background level at 5.87 and 36.5 nmole,

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respectively. Therefore, the detection of intermediates and products, as much as 1800 nmole at

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5.5 months, presumably resulted from the biotransformation of the unique FTACP and not from

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the conversion of residuals.

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FTACP biodegradation was inferred from the observed intermediates, 8:2 FTCA and 7:3

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FTCA, 8:2 FTUCA and 7:3 FTUCA, and PFCA (C6-C9) products detected in soil, plant and

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catch plate (Tables S6-S11). The inclusion of the stable intermediate 7:3 FTCA and terminal

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PFCAs C6-C8 expands upon the conceptual model used by Russell et al. in their FTACP

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biodegradation study,3 which solely considered the primary biotransformation of 8:2 FTOH to

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PFOA via 8:2 FTOH  8:2 FTCA  8:2 FTUCA  7:2 secondary FTOH (sFTOH)  PFOA.

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Unfortunately, the analysis of 8:2 FTOH was omitted from our investigation as any volatile

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products released from the soil and/or plants could not be quantified because the pots were

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exposed to the open atmosphere of the greenhouse; thus the overall proportion of products, as

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determined through indirect measurement, from FTACP degradation is likely reported here.

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Incubation of the unique FTACP in all soil conditions resulted in the accumulation of

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perfluorohexanoate (PFHxA), perfluoroheptanoate (PFHpA) and PFOA concurrently with the

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reduction of 8:2 FTCA and 8:2 FTUCA as shown in Figure 2 for FTACP/Plant; similar trends

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are illustrated in SI Figure S5 (FTACP/Soil) and S6 (FTACP/Plant/Biosolids). As expected,

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PFOA was the dominant product constituting 57, 70 and 80% of products in all microcosm

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compartments in FTACP/Soil, FTACP/Plant and FTACP/Plant/Biosolids, respectively (Table

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S13). The formation of the stable intermediate 7:3 FTCA is consistent with transformation

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pathways of 8:2 FTCA and 8:2 FTUCA observed in aerobic microbial degradation.29

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Subsequent dealkylation and defluorination steps of 7:3 FTCA presumably explains the

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production of perfluorohexanoate (PFHxA) and perfluoroheptanoate (PFHpA).30 The

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accumulation of 7:3 FTCA, PFHxA and PFHpA varied depending on the experimental

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conditions, but all were observed to be minor products. The α-oxidation of 8:2 FTOH to PFNA

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has been reported with different mammalian hepatocytes,31-33 but at ≤1% of the total stable

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products; PFNA was only observed within background levels in this study.

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Measured concentration of target analytes in soil varied substantially amongst

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FTACP/Soil, FTACP/Plant and FTACP/Plant/Biosolids (Table 1) and detailed in the SI (Table

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S6 and S9), which suggests an influence between the degree of FTACP biodegradation and

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probable microbial activity. At 5.5 months, the summed analytes level in FTACP/Soil,

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FTACP/Plant and FTAC/Plant/Biosolids were determined to be 2.54 x 102 nmole, 6.94x 102

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nmole and 1.80 x 103 nmole, respectively. Enhanced microbial activity has been demonstrated

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to increase with plant production,34 and is consistent with the increase in analytes for

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FTACP/Plant and FTACP/Plant/Biosolids. PFCAs and PFCA precursors arising from the

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WWTP biosolids themselves were accounted for using a control experiment in biosolid amended

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soil and an alfalfa plant (Plant/Biosolids Control), as described in the SI. The observed

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concentrations in these controls were significantly lower than those reported for

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FTACP/Plant/Biosolids.

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Target analytes were also observed to increase in alfalfa plants throughout incubation.

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Uptake into plants has previously been reported for PFOA and PFOS,35-37 consistent with the

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increase of PFHxA, PFHpA and PFOA levels in the plant as observed in this study (Figure 2B

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and S6B). Plant PFOA levels were observed up to 44.0 ± 12.7 nmole and 49.3 ± 12.9 nmole for

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PFOA at 5.5 months for FTACP/Plant and FTAC/Plant/Biosolids (Table S7). The relative

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percentage of PFCAs that translocated into the plant decreased with increasing PFCA chain

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length (Table S12). Most intermediates in the plants fell below the LOD or were detected at

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levels

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FTACP/Plant ≈ FTACP/Plant/Biosolids).

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The MALDI-TOF results were then re-plotted as a function of relative intensity with

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respect to the most abundant signal; 1301 m/z. In FTACP/Soil pots, the relative signal

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distribution 1.5, 3.5 and 5.5 months did not differ significantly (Figure 4A), whereas, an

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increased contribution from the higher order fluorotelomer units resulted in a change in the

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relative signal distribution from 1.5 to 3.5 and 5.5 months for FTACP/Plant and

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FTACP/Plant/Biosolids pots (Figure 4B and 4C). Additionally, a greater increase in the Mn and

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Mw was calculated from 1.5 to 3.5 and 5.5 months for FTACP/Plant and FTACP/Plant/Biosolid

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pots (Table S17). Thus, an increase in the alteration of FTACPs having a lower molecular

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weight (