Vol:.(1234567890)

Environmental Science and Pollution Research (2024) 31:30126–30136
https://doi.org/10.1007/s11356-024-33250-9

RESEARCH ARTICLE

Determination of per‑ and polyfluoroalkyl compounds 
in paper recycling grades using ultra‑high‑performance liquid 
chromatography–high‑resolution mass spectrometry

Nondumiso Nomonde Mofokeng1,2  · Lawrence Mzukisi Madikizela3 · Ineke Tiggelman2 · Edmond Sanganyado4 · 
Luke Chimuka1

Received: 28 November 2023 / Accepted: 4 April 2024 / Published online: 11 April 2024 
© The Author(s) 2024

Abstract
Globally, per- and polyfluoroalkyl substances (PFAS)–related research on paper products has focused on food packaging with 
less consideration on the presence of PFAS at different stages of the paper recycling chain. This study analysed the prevalence 
of PFAS in paper grades used for the manufacture of recycled paperboard. The presence of PFAS was attributed to the use of 
PFAS-containing additives, consumer usage, exposure to packed goods as well as contamination during mingling, sorting, 
collection, and recovery of paper recycling material. Q Orbitrap mass spectrometry was used to analyse the paper samples 
after accelerated solvent extraction and solid phase extraction. The distribution and possible propagation of 22 PFAS were 
determined in pre-consumer, retail and post-consumer paper products. Post-consumer samples had the highest combined 
average concentration (ΣPFAS) at 213 ng/g, while the ΣPFAS in retail (159 ng/g) and pre-consumer samples (121 ng/g) 
was detected at lower concentrations. This study showed that waste collection and recycling protocols may influence PFAS 
propagation and that measures must be developed to minimise and possibly eliminate exposure opportunities.

Keywords PFAS · Recycled paper · Pollutant prevalence · Ultra-trace analysis · Waste management · Analytical method

Introduction

Over the past 5 years, more than 50 million tons of paper 
products were recycled annually, with almost half of 
these being used to manufacture corrugated boxes (World 

Economic Forum 2022). In the same period, the global paper 
recycling rate was 68% (Van Ewijk et al. 2021), with South 
Africa having an average five-year paper recovery rate of 
67% (Paper Manufacturers Association of South Africa 
2022). The growing emphasis on circular economy and 
thereby paper recycling (Semple et al. 2022) means that it 
is imperative to investigate how potentially toxic substances 
such as per- and polyfluoroalkyl substances (PFAS) propa-
gate across the paper recycling value chain. PFAS may be 
introduced during the initial manufacture of packaging if 
they are applied as moisture and grease repellents (Schultes 
et al. 2019). In addition to the manufacturing stage, PFAS 
exposure may occur during transportation, storage, use, and 
disposal of paper products as well as from the mingling of 
recovered paper with other waste materials during collec-
tion, sorting, and repulping (Reinhart et al. 2023). In addi-
tion, PFAS present in the soil, air, and water (Solan et al. 
2023) may interact with paper destined for recycling. PFAS 
have been shown to be present at waste disposal sites and 
landfills (Helmer et al. 2022) and can thereby be present at 
recycling facilities where recycling includes paper recov-
ered from solid waste disposal sites and landfills. The true 

Responsible Editor: Roland Peter Kallenborn

 * Nondumiso Nomonde Mofokeng 
 nmofokeng@mpact.co.za

1 Molecular Sciences Institute, School of Chemistry, 
University of the Witwatersrand, 1 Jan Smuts Ave, 
Braamfontein, Johannesburg 2000, South Africa

2 Mpact Operations Pty (Ltd), Innovation, Research & 
Development, Devon Valley Road, Stellenbosch 7600, 
South Africa

3 Institute for Nanotechnology and Water Sustainability, 
College of Science, Engineering and Technology, University 
of South Africa, Florida Science Campus, 28 Pioneer Ave, 
Roodepoort, Johannesburg 1709, South Africa

4 Department of Applied Sciences, Northumbria University, 
Newcastle upon Tyne NE1 8ST, UK

http://orcid.org/0000-0002-8565-3267
http://crossmark.crossref.org/dialog/?doi=10.1007/s11356-024-33250-9&domain=pdf


30127Environmental Science and Pollution Research (2024) 31:30126–30136 

contribution of PFAS from paper recycling processes is 
currently not fully understood in developed and developing 
countries (Geueke et al. 2018).

PFAS, often referred to as “forever chemicals”, are classi-
fied as very persistent, bioaccumulative, and toxic (Cousins 
et al. 2020; Chambers et al. 2021; Liu and Sun 2021; Brunn 
et al. 2023). Long-chain PFAS, which typically contain 
fluoroalkyl chains of six or more carbons (Chambers et al. 
2021; Baldwin et al. 2023), possess extremely stable car-
bon–fluorine bonds, making them more resistant to degrada-
tion (Chambers et al. 2021). These longer-chain PFAS have 
increased hydrophobicity which promotes their retention in 
paper’s organic, cellulose lattice (Liu and Sun 2021). Initial 
research into PFAS suggested that PFAS compounds with 
alkyl chain lengths of five carbons or less were significantly 
less bioaccumulative and less toxic (Quinete et al. 2010). 
This led manufacturers to a shift towards shorter-chain PFAS 
which have now also been shown to be very stable (Brendel 
et al. 2018), toxic (Lu et al. 2017; Solan et al. 2023) and per-
sistent in the environment (Vierke et al. 2014; Brendel et al. 
2018). These short-chain PFAS often have a higher mobility 
in aqueous environments owing to their higher solubility 
(Vierke et al. 2014). Since paper manufacturing is associated 
with high water use (Blanco et al. 2013), PFAS may easily 
circulate during the manufacture of recycled paper.

The analysis of PFAS in different paper grades used in 
the manufacture of recycled paper is important to further 
understand the global occurrence of PFAS. Globally, PFAS-
related research on paper products has been focused on food 
packaging (Trier et al. 2011; Rosenmai et al. 2016; Curt-
zwiler et al. 2021; Timshina et al. 2021) with less focus 
on other grades of paper such as newspapers, magazines 
and packaging used for non-food applications (Glüge et al. 
2020). This study aimed to fill this gap in understanding 
the possible presence of PFAS in different paper recycling 
grades used to manufacture recycled paperboard. This inves-
tigation is crucial as it addresses the challenges of paper 
recycling processes by pinpointing the possibility of PFAS 
circulation through the mechanisms employed in solid waste 
management. The findings of the present study are important 
for showcasing a need to develop measures that could assist 
in minimising and eliminating PFAS exposure opportunities.

Materials and methods

Chemicals and buffers

The chemicals and buffers used were LC–MS grade metha-
nol (Anatech, Cape Town, South Africa), water (Merck, 
Johannesburg, South Africa), ammonium formate (Merck, 
Johannesburg, South Africa), HPLC grade toluene (Merck, 
Johannesburg) and analytical grade ammonium hydroxide 

(Merck, Johannesburg, South Africa). Certified reference 
standards made up in methanol were obtained from Accu-
Standard (Stargate, Johannesburg, South Africa), the details 
of which are shown in Table S1. The mixture standard 
contained both short- and long-chain per- and polyfluoro-
carboxylic acids (PFCAs) and sulfonic acids (PFSAs). 
Perfluorohexanesulfonic acid (PFHxS) and perfluorooctane-
sulfonic acid (PFOS) were present as linear and branched 
isomers with both isomers considered in the calibration 
standards and quantification. The calibration standards were 
made up in methanol in two concentration ranges, from 0.2 
to 120 µg/L and from 30 to 450 µg/L.

Sampling

Thirty-nine paper samples were collected from Cape Town, 
South Africa, and consisted of various grades of paper used 
for recycling (Fig. 1; Table S2). The pre-consumer and retail 
samples consisted only of boards, while the post-consumer 
samples consisted of paper grades typically used in the man-
ufacture of recycled boards. These included cartonboards, 
newspapers, corrugated boards (boxes), office paper and 
magazines. The pre-consumer samples were sourced directly 
from paper mills and paper conversion sites, whereas retail 
samples were collected from South African grocery stores. 
Post-consumer samples were collected at recycling facili-
ties, solid waste disposal sites, household waste and informal 
waste pickers.

Sample preparation

Paper samples were prepared in triplicate (1 g each), fol-
lowed by accelerated solvent extraction (ASE) using a 
Dionex 350 ASE system (Anatech, Cape Town, South 
Africa). The extraction method was optimised for 

Fig. 1  Sample overview



30128 Environmental Science and Pollution Research (2024) 31:30126–30136

ethanol:methanol solvent combination (Table S3), with the 
final optimised conditions being a 3:2 ethanol:methanol 
combination at 70 °C oven temperature for three cycles at 
12 min each (MacLennan et al. 2019). After extraction, the 
sample was evaporated to 1 mL under nitrogen at 40 °C 
using a Biotage TurboVap (Anatech, Cape Town, South 
Africa) in preparation for SPE clean-up. The SPE process 
was based on weak ionic exchange (WAX) mechanism. The 
SPE steps were guided by the United States (US) Environ-
mental Protection Agency (EPA) Draft Method 1633, EPA 
Method 533 and Barola et al. (2020) (Wendelken and EPA 
2019; Barola et al. 2020; EPA 2021). For this study, 500 mg 
sorbent bed/6 mL Enviro-Clean WAX SPE cartridges (Star-
gate Scientific, Johannesburg, South Africa) were used. 
The cartridges were mounted on a SPE manifold (Stargate 
Scientific, Johannesburg, South Africa) and operated under 
vacuum using a DryVac 400 vacuum pump (Air & Vacuum 
Technologies, Johannesburg, South Africa). The SPE was 
initiated by conditioning the cartridges with 3 mL of metha-
nol followed with 5 mL of 0.1 M ammonium formate buffer. 
This was followed by loading 500 µL of sample and elu-
tion of analytes using 6 mL of 1% methanolic ammonium 
hydroxide. The eluted compounds were concentrated to 
1 mL under 40 °C nitrogen and filtered into a polypropylene 
vial with 0.22-µm filter (Stargate Scientific, Johannesburg, 
South Africa) before analysis by UHPLC-HRMS.

Instrumentation

High-resolution LC–MS analysis was achieved using a 
Thermo Scientific Vanquish  UHPLC+ Q Exactive Focus 
Orbitrap (Anatech, Cape Town, South Africa). A Hypersil 
Gold aQ 100 mm × 2.1 mm × 1.9 µm column and Hyper-
sil Gold 50 mm × 3 mm × 1.9 µm delay column (Anatech, 
Cape Town, South Africa) were used at 35 °C. The autosa-
mpler temperature was set to 7 °C. The instrument operat-
ing method was adapted from Zhu and Walker (2020), Silva 
et al. (2021) and Curtzwiler et al. (2021) with the final opti-
mised conditions consisting of solvent A as 0.1% formic acid 
in water and 10 mM ammonium formate in methanol as sol-
vent B (Zhu and Walker 2020; Silva et al. 2021; Curtzwiler 
et al. 2021). The initial flowrate was 0.400 mL/min in 30% 
solvent B which increased to 100% solvent B at 13 min (at 
1 mL/min), held until 17 min, before returning to 30% sol-
vent B at 21.1 min (Table S4). The acquisition mode was full 
scan with data-dependent acquisition  (ddMS2) in negative 
mode. The PFAS transitions and retention times are tabled 
in Table S5.

Quality assurance

PFAS are ubiquitous compounds (Evich et al. 2022) and are 
used extensively in analytical chemistry laboratory items 

such as PTFE-lined reagent bottle caps, O-rings, septa lin-
ings and syringe filters. It was therefore important to inves-
tigate latent PFAS contamination in the PFAS analysis 
workflow. The necessary steps were included to measure the 
possible contamination from sample collection (Table S6) 
and the UHPLC-HRMS system (Table S7). Preparation 
blanks were analysed to subtract the analyte concentrations 
found in the blanks from the detected concentrations in 
the samples (Table S8). Additionally, a stringent washing 
and cleaning protocol was established using toluene, 1% 
methanolic ammonium hydroxide and methanol. The target 
compounds absent in the preparation blanks were quanti-
fied using external calibration quantification, whereas those 
found to be present were semi-quantitatively determined by 
subtracting the preparation blank from the detected concen-
tration. PFBA, PFPeA, PFDoA, PFTeDA, PFBS, PFOS, 
PFNS, PFDS and 4:2FTS were identified as system contami-
nants and were semi-quantitatively determined. To evaluate 
the external calibration curves, the coefficient of determina-
tion (R2) was used as an indicator of linearity. The limit of 
detection (LOD) and limit of quantification (LOQ), which 
were used as sensitivity indicators, were measured at signal-
to-noise ratios of 3 and 10, respectively. Relative recovery 
and %RSD were used to evaluate the accuracy and precision 
of the method, respectively. Virgin, unconverted, unprinted 
paper and paperboard samples were used to evaluate the 
method performance by spiking the samples at three differ-
ent concentrations in triplicate. The data was corrected for 
the relative recoveries obtained by considering the unspiked 
paper and paperboard samples. Due to the use of external 
standards and expected variability, the quantified concentra-
tions were reported with their associated uncertainty using 
Eq. (1):

where s2 is the variance of the sample, umatrix is the uncer-
tainty of the sample repeatability due to matrix effects, 
urecovery is the uncertainty of the recovery of the target com-
pound and uprep. blank is the uncertainty related to the prepara-
tion blanks (Rasul et al. 2017; Ellison and Williams 2012). 
The equations related to each term are shown in equations 
(S1) to (S4).

Data analysis

Instrument data analysis was performed using Thermo Sci-
entific Xcalibur™. Further data analysis was performed 
using Microsoft Excel, MetaboAnalyst 5.0 and TIBCO Sta-
tistica 14.0. The statistical analysis aimed to identify pos-
sible correlations between the target analytes. TIBCO Statis-
tica 14.0. was used to determine if the data followed normal 
or non-normal distributions. For normally distributed data, 

(1)U =

√

s2 + u
2
matrix

+ u2
recovery

+ u
2
prep.blanks



30129Environmental Science and Pollution Research (2024) 31:30126–30136 

the Pearson correlation coefficient would be employed, while 
the Spearman rank correlation, a non-parametric correlation, 
would be used for non-normal data that contains outliers 
(Leon 1998). Once established, the Spearman correlation 
was plotted using MetaboAnalyst 5.0. The Spearman rank 
equation is defined as

where the Spearman rank coefficient rs is calculated by 
determining the sum of the squared differences in distance 
(d2) for n observations. A value of rs = 1 indicates a lin-
ear positive relationship, while a value of rs < 0 indicates 
a negative relationship between two variables, where an 
increase in the value of one variable would be associated 
with a decrease in the second variable (Leon 1998). Hier-
archical clustering analysis was performed in conjunction 
with Spearman correlation. Hierarchical clustering allows 
for similarity analysis of one sample to the entire dataset and 
can provide insight into any heterogeneity or homogeneity 
present in different groups (Kumar et al. 2014).

Results and discussion

Method validation

The R2 of the calibration curves ranged from 0.98 for 
PFHpA to 0.99 for PFDS, indicating acceptable overall 
linearity of the target compounds (Table S9). The relative 
recoveries of paper and board were determined by spik-
ing samples at 10, 20 and 100 ng/g; 20, 40 and 200 ng/g; 
and 40, 80 and 400 ng/g, depending on the concentration 
present in the standard mixture. Relative recoveries ranged 
from 55% for PFHxA to 139% for PFOA (except for 6:2 
FTS) (Table S9). For the target PFAS investigated, 19 of 
the 22 fell within the generally accepted range of 70–130% 
(Srivastava et al. 2022). PFHxA (10 ng/g paperboard spike), 
PFOA (10 ng/g paperboard spike) and 6:2 FTS showed poor 
recovery. This may have been due to the lack of isotopically 
labelled internal standards that would have likely corrected 
any matrix effects that would have resulted in changes in 
ionisation. According to Harris et al. (2022) and Rawn et al. 
(2022), the use of isotopically labelled internal standards is 
critical in ensuring absolute quantification and correcting for 
matrix effects (Rawn et al. 2022; Harris et al. 2022). Other 
factors, such as SPE interaction, the influence of the buffer 
solvent system, interaction with other PFAS compounds 
present and salts, ions and organic matter in the paper sam-
ples, may have further influenced the recovery of these tar-
get PFAS (Zabaleta et al. 2016; Kaiser et al. 2020; Harris 
et al. 2022). The %RSD for the relative recoveries ranged 

(2)r
s
= 1 −

6
∑

d
2

n(n2 − 1)

from 1.0 to 9.8%, indicating acceptable precision (Srivastava 
et al. 2022). The method LODs and LOQs were found to 
be generally lower for the compounds present in the lower 
concentration in the calibration standard mix with LODs 
ranging from 1.47 pg/g for PFDA to 10.1 pg/g for PFUnA for 
compounds present as 2 µg/mL in methanol (Table S9). For 
the compounds present in larger concentrations, the LODs 
ranged from 11.2 pg/g for PFPeA to 53.1 pg/g for PFBA. In 
addition to differences in carbon chain lengths and chemi-
cal structures, the stability and possible interactions of the 
different PFAS compounds in methanol may also have con-
tributed to the differences found in the LOQs and LODs. To 
date, there have been limited studies on the quantification of 
paper-based samples using UHPLC Orbitrap HRMS. How-
ever, most studies have focused on the use of LC–MS/MS or 
LC-QTOF-MS (Zabaleta et al. 2016, 2020; Blanco-Zubiagu-
irre et al. 2021; Boisacq et al. 2023; Vera et al. 2024). The 
LODs in this study were thus compared with the analysis 
of PFAS in food matrices and landfill leachate, where the 
instrument of analysis was an HRMS Q Orbitrap. This study 
achieved more sensitive detection limits for common PFAS 
(Rawn et al. 2022; Rehnstam et al. 2023). Rawn et al. (2022) 
reported LOQs ranging from 18 g/g food for L-PFDS to 
12.4 ng/g PFBA food (Rawn et al. 2022). In this study, the 
limits of quantification ranged from 0.0049 ng/g paper for 
PFDA to 0.18 ng/g paper for PFBA, further highlighting the 
sensitivity achieved in this study.

Occurrence of PFAS

The combined sum of average concentrations (ΣPFAS) of 
the 22 analysed PFAS compounds was highest for post-
consumer samples (213 ng/g), followed by retail samples 
(159 ng/g) and pre-consumer samples (121 ng/g), as shown 
in Fig. 2. Overall, PFAS contamination increased from pre-
consumer to post-consumer, with the highest concentration 
associated with post-consumer samples where recovered 
material had likely interacted with the environment and pos-
sibly mingled with other waste materials. The pre-consumer 
samples analysed consisted of samples made with a recycled 
fibre component, whereas the retail and post-consumer sam-
ples were expected to contain virgin, mixed and/or recy-
cled fibre. The occurrence of PFAS in these samples was 
strongly related to PFAS intentionally and/or unintentionally 
used in manufacturing, retention of PFAS from recycling 
and, in retail samples, exposure from transport, distribu-
tion and packed goods. When looking at the categorical box 
and whiskers chart plotted using Statistica ® (Table S10), 
it was further evident that more PFAS were detected in 
post-consumer samples, with the categorical data being 
found to statistically follow normal distributions (Fig. S1 to 
Fig. S22). In terms of the PFAS compounds, 6:2 FTS was 
the most prevalent target analyte with the highest average 



30130 Environmental Science and Pollution Research (2024) 31:30126–30136

concentration of 55.2  ng/g for post-consumer samples, 
34.3 ng/g for retail and 22.1 ng/g for pre-consumer samples. 
This 6-fluoroalkyl chain telomer has become a predominant 
polymer processing alternative to PFOS and PFOA (Lu et al. 
2017) (Schwartz-Narbonne et al. 2023; Solan et al. 2023). 
In a study by Dueñas-Mas et al. (2023) on food packag-
ing in fast-food restaurants in France, 6:2 FTS and PFHxA 
were detected in all 47 samples analysed (Dueñas-Mas 
et al. 2023). It has also been reported in fast-food packag-
ing in the USA (Schaider et al. 2017). This corroborated 
the prevalence of 6:2 FTS in this study. It is important to 
note that matrix enhancement effects may have given results 
that were biased high due to the high 6:2 FTS recovery rate 
obtained. Along with 6:2 FTS, PFBA, PFHxA, PFDoA and 
PFTeDA were also frequently detected in the samples. This 
highlighted the possible circulation of short-chain PFAS. 
According to Palma et al. (2022) and Rehnstam et al. (2023), 
shorter-chain PFAS such as PFPeA, PFHxA and PFBA are 
the main degradation products of both PFOA and PFOS in 
the environment (Palma et al. 2022). PFPeA and PFHxA 
are common breakdown products of stain- and grease-proof 
coatings in food packaging and household products (Liu and 
Liu 2016).

The PFAS range was plotted to compare the ranges 
of the detected PFAS (Fig. 3). The smallest range was 
for PFNS from (0–0.04 ng/g), and the largest was for 
6:2 FTS (0–354.5  ng/g). The majority of the PFAS 
compounds detected were below 50 ng/g, with PFDoA 
(58.3 ± 0.5  ng/g for a recycling facility coffee box), 
PFPeA (70.4 ± 3.1  ng/g for a waste picker corrugated 

box), PFHxA (156.9 ± 9.6 ng/g for a retail chocolate box) 
and 4:2FTS (164.79 ± 7.1 ng/g for the same waste picker 
corrugated box) all being higher than 50 ng/g. In com-
parison, the PFAS concentrations reported in Dueñas-Mas 
et al. (2023) were considerably lower in food packaging 

Fig. 2  Overview of pre-con-
sumer, retail and post-consumer 
samples

Fig. 3  PFAS range



30131Environmental Science and Pollution Research (2024) 31:30126–30136 

with concentrations detected found to be less than 10 ng/g 
(Dueñas-Mas et al. 2023).

PFAS profile of samples

The PFAS profiles of the samples are plotted in Fig. 4 for 
the detected concentrations (Tables S11 and S12). When 
examining the individual PFAS in specific samples, the 
three highest ΣPFAS were found in post-consumer sam-
ples, namely a recycling facility tequila carton (ΣPFAS 
of 647.9 ng/g), a recycling facility newspaper (ΣPFAS of 
400.2 ng/g) and a waste picker corrugated food box (ΣPFAS 
of 548.0 ng/g). The corrugated food box had the highest 
number of different PFAS detected with 21 of the 22 quanti-
fied PFAS detected. An egg carton collected from household 
waste was found to contain 18 of the 22 quantified PFAS 
detected, albeit in smaller combined concentrations (ΣPFAS 
of 127.6 ng/g) than the waste picker corrugated food box. 
The lowest concentration of combined PFAS concentra-
tion samples was found in a newsletter collected at a solid 
waste disposal site (ΣPFAS of 2.6 ng/g), a recycling facil-
ity cereal carton (ΣPFAS = 14.5 ng/g), a colouring book 
cover (ΣPFAS = 17.2 ng/g) and a recycling facility corru-
gated fruit box (ΣPFAS 31.9 ng/g). Among the retail sam-
ples, a chocolate carton had the highest combined PFAS 
concentration (ΣPFAS = 235.1 ng/g) with PFHxA being 
the dominant PFAS. Across the paper recycling chain, the 

average ΣPFAS in the corrugated boxes increased from pre-
consumer (99 ng/g) to retail (102 ng/g) to post-consumer 
(145 ng/g). All samples analysed in this study were found 
to contain PFAS, further demonstrating the prevalence of 
PFAS compounds. This differed Zabaleta et al. (2020) and 
other findings related to targeted quantification (Zafeiraki 
et al. 2014; Zabaleta et al. 2016), where the majority of the 
food packaging material was found to contain PFAS at very 
low concentrations or not detected at all. However, it corre-
lated with Dueñas-Mas et al. (2023) and Sapozhnikova et al. 
(2023). In the study by Sapozhnikova et al. (2023), PFHpA, 
PFDA, 6:2 fluorotelomer phosphate diester and PFHxS 
were the most frequently detected PFAS(Sapozhnikova 
et al. 2023). These comparisons showed that the detection 
of PFAS may be dependent on the region, circulating PFAS, 
exposure pathways, analysis protocols and analytical method 
sensitivity.

The uncategorised data followed non-normal distribu-
tions with outliers (Fig. S23). Spearman rank correlation 
(Eq. (1)) was used as the distance measure for the correla-
tion heat map which was constructed with its associated 
dendrogram using MetaboAnalyst 5.0. In Fig. 5, a correla-
tion of 1 (shown in dark red) represented a directly propor-
tional relationship and − 0.4 indicated the most negative 
correlation, shown in dark blue. The correlation between 
the different PFAS under investigation showed that the 
strongest correlation was between PFPeA and PFTrDA 

Fig. 4  PFAS profile of samples



30132 Environmental Science and Pollution Research (2024) 31:30126–30136

(0.69) and between 8:2 FTS and PFDoS (0.30). This indi-
cated that the presence of PFPeA was accompanied by the 
detection of PFTrDA in the same sample. Furthermore, the 
detection of PFTeDA was associated with the presence of 
PFDA and PFUnA. The PFAS found to likely co-occur to 
some extent were PFNA, PFHpS, PFDS, PFBS, 8:2 FTS 
and PFDoS. Conversely, PFTeDA and PFHpS had a strong 
negative correlation at − 0.261. A hierarchical clustering 
dendrogram as shown in Fig. 6 was based on the principle 
that variables with similar numerical values would also 
be close to each other in space (Kumar et al. 2014). The 
dendrogram indicated distinct clustering in the presence 

of several target PFAS in various papers. For instance, it 
could be seen that PFTeDA, PFDA, PFUnA, PFOA and 
PFDoA clustered together when compared to the remain-
ing target analytes. In addition, further clustering was evi-
dent between PFTeDA and PFDA with PFUnA compared 
to PFOA and PFDoA. The investigation of such clustering 
was beneficial for understanding the detection of numer-
ous types of poly- and perfluorocarboxylic and sulfonic 
acids in different paper samples and environmental media 
(Trier et al. 2011; Zabaleta et al. 2020; Bai and Son 2021; 
Kurwadkar et al. 2022; Bugsel et al. 2022). This further 
suggested that it would be difficult to isolate a single PFAS 

Fig. 5  PFAS compound correlation heat map



30133Environmental Science and Pollution Research (2024) 31:30126–30136 

compound for targeted removal, for instance, without 
determining all possible co-occurrences.

Stockholm‑listed PFAS

In 2009, PFOS and its salts were the first PFAS to be 
listed in the United Nations Stockholm Convention list 
of persistent organic pollutants. The listing of PFOA fol-
lowed in 2019, with PFHxS formally listed most recently 
in 2022 (UNEP 2019a). When looking specifically at the 
Stockholm Convention–listed PFAS, the highest detection 
was at 19.9 ± 2.1 ng/g for PFHxS in a pre-consumer cor-
rugated board. PFHxS was the most prevalent PFAS in the 
Stockholm Convention–listed PFAS, followed by PFOS 
and PFOA (as shown in Fig. 6). Sapozhnikova et al. (2023) 
reported that PFHxS was one of the most frequently detected 
PFAS in their study of globally sourced food packaging 
(Sapozhnikova et al. 2023). PFHxS is used as a surfactant 
in various applications, including firefighting foams, metal 
plating and textiles (Boucher et al. 2019). PFHxS and its 
related compounds have also been associated with paper pro-
duction (UNEP 2019b; Langberg et al. 2021), which could 
explain their detection in this study. In addition, PFHxS has 
been found to form from perfluoroalkyl sulfonamide deriva-
tives during chlorination and chloramination during water 
disinfection (Li et al. 2023) and bioaccumulate in the envi-
ronment (Zhong et al. 2021), which may be another exposure 
pathway in the paper recycling chain. When examining the 
other listed PFAS in this study, PFOS was more prominent 
in the household waste samples with the highest concen-
tration detected in a fast-food container (44.4 ± 1.6 ng/g). 
PFOA, on the other hand, was less prominent in household 
waste and pre-consumer samples but was more prevalent in 
post-consumer solid waste disposal and recycling facility 
samples, in the colouring sheet sample (14.3 ± 0.7 ng/g) and 

magazine sample (7.0 ± 1.4 ng/g), respectively. This shows 
that these longer-chain PFAS of concern may be circulating 
in the environment and consumer-good value chains. Many 
developing countries are guided by the Stockholm Conven-
tion and the ratification thereof. The co-occurrences shown 
in this study are therefore important for the Global South as 
they open avenues for further research that can be used to 
motivate for legislation that is driven towards the restriction 
of all PFAS.

Concluding remarks

The analysis of PFAS using UHPLC-HRMS highlighted 
the difficulty of PFAS analysis given the ubiquitous nature 
of PFAS in the samples as well as in laboratory ware, sol-
vents and instrumentation. Blank samples were largely able 
to account for contamination issues; however, the lack of 
internal standards meant that the matrix effects could not be 
accounted for. When comparing the results obtained, it was 
shown that the combined average concentration of PFAS 
was lowest in the pre-consumer samples and highest in the 
post-consumer samples. This study further showed that the 
co-mingling, sorting and collection protocols may influence 
PFAS propagation, as the highest PFAS concentrations were 
detected at post-consumer sites. When considering paper 
recycling and the circular economy, this study illustrated 
the need to further understand and investigate activities in 
the entire paper recycling chain. The initial manufacturing, 
usage, sorting, collection, disposal, recovery and remanufac-
turing design protocols for recycled paper are key to ensur-
ing minimal PFAS circulation in the paper recycling chain. 
Research on different exposure pathways is still required to 
further unpack PFAS contamination, exposure and propaga-
tion to fully evaluate the safety and impact of PFAS in paper 
recycling.

Supplementary information The online version contains supplemen-
tary material available at https:// doi. org/ 10. 1007/ s11356- 024- 33250-9.

Acknowledgements Anatech Instruments Pty (Ltd) is thanked for the 
opportunity to utilise their Thermo Scientific Vanquish  UHPLC+ Q 
Exactive Focus Orbitrap and for providing excellent training, expertise 
and support.

Author contribution Nondumiso Nomonde Mofokeng, Lawrence 
Mzukisi Madikizela, Ineke Tiggelman, Edmond Sanganyado and Luke 
Chimuka contributed to the study’s conception and design. Material 
preparation, data collection and analysis were performed by Nondu-
miso Nomonde Mofokeng. The first draft of the manuscript was written 
by Nondumiso Nomonde Mofokeng. Lawrence Mzukisi Madikizela, 
Ineke Tiggelman, Edmond Sanganyado and Luke Chimuka reviewed, 
edited and commented on previous versions of the manuscript. Non-
dumiso Nomonde Mofokeng, Lawrence Mzukisi Madikizela, Ineke 
Tiggelman, Edmond Sanganyado and Luke Chimuka read and approved 
the final manuscript.

Fig. 6  Stockholm-listed PFAS radar chart

https://doi.org/10.1007/s11356-024-33250-9


30134 Environmental Science and Pollution Research (2024) 31:30126–30136

Funding Open access funding provided by University of the Witwa-
tersrand. This study was supported financially through the Innovation, 
Research and Development Division of Mpact Operations Pty (Ltd), a 
paper and plastics manufacturing business operating in southern Africa.

Data Availability All data generated in this study is available in the 
article supplementary material.

Declarations 

Ethical approval Not applicable.

Consent to participate Not applicable.

Consent for publication All authors give consent to publish.

Competing interests Nondumiso Nomonde Mofokeng and Ineke 
Tiggelman declare employment at Mpact Operations Pty (Ltd). Law-
rence Mzukisi Madikizela, Edmond Sanganyado and Luke Chimuka 
declare they have no competing interests.

Open Access This article is licensed under a Creative Commons Attri-
bution 4.0 International License, which permits use, sharing, adapta-
tion, distribution and reproduction in any medium or format, as long 
as you give appropriate credit to the original author(s) and the source, 
provide a link to the Creative Commons licence, and indicate if changes 
were made. The images or other third party material in this article are 
included in the article’s Creative Commons licence, unless indicated 
otherwise in a credit line to the material. If material is not included in 
the article’s Creative Commons licence and your intended use is not 
permitted by statutory regulation or exceeds the permitted use, you will 
need to obtain permission directly from the copyright holder. To view a 
copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.

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	Determination of per- and polyfluoroalkyl compounds in paper recycling grades using ultra-high-performance liquid chromatography–high-resolution mass spectrometry
	Abstract
	Introduction
	Materials and methods
	Chemicals and buffers
	Sampling
	Sample preparation
	Instrumentation
	Quality assurance
	Data analysis

	Results and discussion
	Method validation
	Occurrence of PFAS
	PFAS profile of samples
	Stockholm-listed PFAS

	Concluding remarks
	Acknowledgements 
	References