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1. PFAS – Forever Chemicals

   Aras, Deniz; Wasler, Severin; Bieri, Alex; Domenig, Fabio; Moor, Jan (January 2022, Report EUT-P4-22FS-04 / Institute for Biomass and Resource Efficiency)

   Per- and polyfluoroalkyl substances (PFAS) are a group of synthetic fluorinated compounds. Today more than 4’700 PFAS molecules are known. These chemicals have a high resistance and physical stability. They repel water, dirt, and grease. Due to these properties they are used in a wide range of products, from ski-wax and waterproof textiles to fire extinguishers and food packaging. PFAS are the most persistent synthetic chemicals. They do not occur in nature, and they hardly degrade in nature. Therefore they are called “Forever Chemicals”. The number of PFAS detections in the environment and in various organisms worldwide is increasing. The recognition of their bioaccumulative properties, their high mobility and their adverse effects on biological systems has led and is still leading to a regulation of multiple PFAS molecules. The response of the industry was the introduction of other PFAS as substitutes, which are now themselves increasingly detected in the environment. Worrying is that the list of negative health effects from an exposure to PFAS is becoming longer every year. 

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2. Addressing Urgent Questions for PFAS in the 21st Century

   https://doi.org/10.1021/acs.est.1c03386  

   Ng, Carla; Cousins, Ian T.; DeWitt, Jamie C.; Glüge, Juliane; Goldenman, Gretta; Herzke, Dorte; Lohmann, Rainer; Miller, Mark; Patton, Sharyle; Scheringer, Martin; et al (September 2021, Environmental Science & Technology)

   Despite decades of research on per- and polyfluoroalkyl substances (PFAS), fundamental obstacles remain to addressing worldwide contamination by these chemicals and their associated impacts on environmental quality and health. Here, we propose six urgent questions relevant to science, technology, and policy that must be tackled to address the “PFAS problem”: (1) What are the global production volumes of PFAS, and where are PFAS used? (2) Where are the unknown PFAS hotspots in the environment? (3) How can we make measuring PFAS globally accessible? (4) How can we safely manage PFAS-containing waste? (5) How do we understand and describe the health effects of PFAS exposure? (6) Who pays the costs of PFAS contamination? The importance of each question and barriers to progress are briefly described, and several potential paths forward are proposed. Given the diversity of PFAS and their uses, the extreme persistence of most PFAS, the striking ongoing lack of fundamental information, and the inequity of the health and environmental impacts from PFAS contamination, there is a need for scientific and regulatory communities to work together, with cooperation from PFAS-related industries, to fill in critical data gaps and protect human health and the environment. 

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3. An overview of the uses of per- and polyfluoroalkyl substances (PFAS)

   https://doi.org/10.1039/d0em00291g  

   Glüge, Juliane; Scheringer, Martin; Cousins, Ian T.; DeWitt, Jamie C.; Goldenman, Gretta; Herzke, Dorte; Lohmann, Rainer; Ng, Carla A.; Trier, Xenia; Wang, Zhanyun (December 2020, Environmental Science: Processes & Impacts)

   null (Ed.)

   Per- and polyfluoroalkyl substances (PFAS) are of concern because of their high persistence (or that of their degradation products) and their impacts on human and environmental health that are known or can be deduced from some well-studied PFAS. Currently, many different PFAS (on the order of several thousands) are used in a wide range of applications, and there is no comprehensive source of information on the many individual substances and their functions in different applications. Here we provide a broad overview of many use categories where PFAS have been employed and for which function; we also specify which PFAS have been used and discuss the magnitude of the uses. Despite being non-exhaustive, our study clearly demonstrates that PFAS are used in almost all industry branches and many consumer products. In total, more than 200 use categories and subcategories are identified for more than 1400 individual PFAS. In addition to well-known categories such as textile impregnation, fire-fighting foam, and electroplating, the identified use categories also include many categories not described in the scientific literature, including PFAS in ammunition, climbing ropes, guitar strings, artificial turf, and soil remediation. We further discuss several use categories that may be prioritised for finding PFAS-free alternatives. Besides the detailed description of use categories, the present study also provides a list of the identified PFAS per use category, including their exact masses for future analytical studies aiming to identify additional PFAS. 

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4. A prescription for engineering PFAS biodegradation

   https://doi.org/10.1042/BCJ20240283  

   Wackett, Lawrence P; Robinson, Serina L (December 2024, Biochemical Journal)

   Per- and polyfluorinated chemicals (PFAS) are of rising concern due to environmental persistence and emerging evidence of health risks to humans. Environmental persistence is largely attributed to a failure of microbes to degrade PFAS. PFAS recalcitrance has been proposed to result from chemistry, specifically C-F bond strength, or biology, largely negative selection from fluoride toxicity. Given natural evolution has many hurdles, this review advocates for a strategy of laboratory engineering and evolution. Enzymes identified to participate in defluorination reactions have been discovered in all Enzyme Commission classes, providing a palette for metabolic engineering. In vivo PFAS biodegradation will require multiple types of reactions and powerful fluoride mitigation mechanisms to act in concert. The necessary steps are to: (1) engineer bacteria that survive very high, unnatural levels of fluoride, (2) design, evolve, and screen for enzymes that cleave C–F bonds in a broader array of substrates, and (3) create overall physiological conditions that make for positive selective pressure with PFAS substrates. 

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5. Challenges and opportunities for porous media research to address PFAS groundwater contamination

   https://doi.org/10.69631/ipj.v1i2nr35  

   Guo, Bo; Brusseau, Mark L (August 2024, InterPore Journal)

   Per- and polyfluoroalkyl substances (PFAS) have become one of the most important contaminants due to their ubiquitous presence in the environment and potentially profound impacts on human health and the environment even at parts per trillion (ppt) concentration levels.  A growing number of field investigations have revealed that soils act as PFAS reservoirs at many contaminated sites, with significant amounts of PFAS accumulating over several decades. Because PFAS accumulated in soils may migrate downward to contaminate groundwater resources, understanding the fate and transport of PFAS in soils is of paramount importance for characterizing, managing, and mitigating long-term groundwater contamination risks.Many PFAS are surfactants that adsorb at air–water and solid–water interfaces, which leads to complex transport behaviors of PFAS in soils. Concomitantly, PFAS present in porewater can modify surface tension and other interfacial properties, which in turn may impact variably saturated flow and PFAS transport. Furthermore, some PFAS are volatile (i.e., can migrate in the gas phase) and/or can transform under environmental conditions into persistent PFAS. These nonlinear and coupled processes are further complicated by complexities of the soil environment such as thin water films, spatial heterogeneity, and complex geochemical conditions.In this commentary, we present an overview of the current challenges in understanding the fate and transport of PFAS in the environment. Building upon that, we identify a few potential areas where porous media research may play an important role in addressing the problem of PFAS contamination in groundwater. 

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