The Major Problems with PFAS

Due to their high stability, PFAS have been referred to as “forever chemicals”, because they do not degrade naturally and persist in the environment. They are not degraded naturally because polyfluorinated compounds are not present in nature, so evolutionary pressure for degradation was never present. [1,2]

The continuous production and use of PFAS have inevitably led to their dispersion in the environment, with an estimated 5% of these substances being found in various environmental media. Their widespread presence often exceeds regulatory limits, resulting in significant exposure risk for both wildlife and humans. [2,3,4]

Major sources for intake are drinking water, food, consumer products, and house dust. Prolonged exposure can lead to bioaccumulation in organs and blood serum and PFAS can easily biomagnify along the food chain. [1,5]

Concerns about these substances are growing due to emerging evidence linking PFAS exposure to numerous health issues. These include problems with the immune, endocrine, metabolic, and reproductive systems, as well as an increased risk of cancer, hypertension, higher cholesterol levels, ulcerative colitis, thyroid disease, pregnancy-related hypertension and complications (low birth weight, increased miscarriages, and PFAS transmission to the fetus), liver and kidney damage, and obesity. [3,6]

In addition to the physical health risks, PFAS exposure has serious psychological effects. The invisible nature of these chemicals causes stress, insecurity, disruption of routine, anxiety, a sense of helplessness, and fear. These psychological impacts are often overlooked and insufficiently addressed by institutions. [5]

Exploring Current Solutions to PFAS

Regulations and restrictions on PFAS production and treatment are continually evolving. For example, since the 2000s, short-chain perfluorinated substances made with GenX technology have been introduced to substitute traditional PFAS, but their structure makes them more mobile and consequently more deleterious to the environment. [1,7]

For PFAS degradation, two main approaches have been explored: adapting existing technologies for PFAS destruction or developing new technologies for remediation. Chemicals and physical treatments for PFAS are widely used nowadays, though they require high energy, high costs, and often additional post-processing. The process typically involves separating PFAS from the medium followed by their destruction. Examples of separation technologies are ion exchange resin (IXR), granular activated carbon (GAC), nanofiltration (NF), and reverse osmosis (RO). Although IXR systems are more expensive than GAC, they are favoured because they offer higher adsorption capacities, require less contact time, and occupy a smaller footprint. Additionally, IXR can be regenerated on-site to nearly their original capacity and reused multiple times, unlike GAC, which cannot be feasibly regenerated on-site. With separation technologies, PFAS remains a risk for people and the environment as they do not degrade and so they are often stored until a suitable degradation method is found. Finally, some destructive technologies include electrochemical oxidation, plasma, photocatalysis, sonolysis, supercritical water oxidation, thermal degradation/incineration, pyrolysis/gasification, and advanced oxidation processes (AOPs). [6,8]

On the other hand, biological solutions may represent the best options, due to lower costs and less environmental disruption. Bioremediation successfully treats numerous long-lasting organic contaminants, but for PFAS the biodegradation process is not fully understood. Some intermediate metabolites have been hypothesised, and more studies are needed on microorganisms and enzymes involved in PFAS biodegradation. [1]

Biodegradation strategies include:

• Bacterial degradation, which has been reported in both anaerobic and aerobic conditions. Further studies are needed on enzymatic activities, gene expression, and microorganisms.
• Fungal degradation, which plays a significant role in natural ecosystems for degrading complex compounds, may also be useful for PFAS biodegradation, although research in this area is still limited.
• Phyto-microbial remediation, an in-situ technique that has shown some potential for PFAS removal through plant uptake. However, there is a lack of evidence of internal degradation.
• Phyco-remediation, typically used for wastewater treatment, could also potentially be effective for PFAS. [1,4]

References

1. 5.Zhang Z, Sarkar D, Biswas JK, Datta R. Biodegradation of per- and polyfluoroalkyl substances (PFAS): A review. Bioresour Technol. 2022 Jan 1;344:126223.
2. 9.Wackett LP. Why Is the Biodegradation of Polyfluorinated Compounds So Rare? mSphere. 2021 Oct 13;6(5):10.1128/msphere.00721-21.
3. 1.Scott C, Hu M. Toward the development of a molecular toolkit for the microbial remediation of per-and polyfluoroalkyl substances. Appl Environ Microbiol. 2024 Mar 13;90(4):e00157-24.
4. 3.Marchetto F, Roverso M, Righetti D, Bogialli S, Filippini F, Bergantino E, et al. Bioremediation of Per- and Poly-Fluoroalkyl Substances (PFAS) by Synechocystis sp. PCC 6803: A Chassis for a Synthetic Biology Approach. Life. 2021;11(12).
5. 8.Menegatto M, Lezzi S, Musolino M, Zamperini A. The Psychological Impact of Per- and Poly-Fluoroalkyl Substances (PFAS) Pollution in the Veneto Region, Italy: A Qualitative Study with Parents. Int J Environ Res Public Health [Internet]. 2022;19(22). Available from: https://www.mdpi.com/1660- 4601/19/22/14761
6. 2.Berhanu A, Mutanda I, Taolin J, Qaria MA, Yang B, Zhu D. A review of microbial degradation of per- and polyfluoroalkyl substances (PFAS): Biotransformation routes and enzymes. Sci Total Environ. 2023 Feb 10;859:160010.
7. 7.Giglioli S, Colombo L, Azzellino A. Cluster and multivariate analysis to study the diffuse contamination of emerging per- and polyfluoroalkyl substances (PFAS) in the Veneto Region plain (North-eastern Italy). Chemosphere. 2023 Apr 1;319:137916.
8. 4.Meegoda JN, Bezerra de Souza B, Casarini MM, Kewalramani JA. A Review of PFAS Destruction Technologies. Int J Environ Res Public Health. 2022;19(24).