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Urgent research needsfor better understanding
the toxicity of PFASs
Jamie DeWittDepartment of Pharmacology & Toxicology
Brody School of MedicineEast Carolina University
Greenville, [email protected]
Presented for:Northeast Superfund Research Program Meeting
April 5, 2017
Site-specific studies of PFAS serum concentrations and human health effects in the U.S.
Sources: Vieira et al., 2013, Environmental Health Perspectives, 121:318-323.ATSDR Public Health Assessment for PFC Contamination in Lake Elmo and Oakdale, Washington County, Minnesota, 2008.
(Some) Associations reported between serum PFAS concentrations and human health outcomes
• Immune suppression – reduced responses to vaccinations• High cholesterol• Cancer - kidney and testicular• Pregnancy and development complications (ADHD/behavioral)• Autoimmune-related diseases• Thyroid Disease
These findings are diverse.
Are there underlying modes or mechanisms common to these findings?
Do we need mechanism of action to make decisions about these compounds?
PFOA and PFOS
?
?
Activation of the peroxisome proliferator activated receptor alpha (PPARα)
Is PPARα a sufficient and consistent mechanismfor all toxicities? All PFASs?
Activity for mouse and human PPARα in transfected COS-1 cells: PFOA > PFOS (Wolf et al., 2008).
PFOA is dependent on PPARα for developmental toxicity in 129S1 mice (Abbott et al., 2007), PFOS is not (Abbott et al., 2009).
Alteration of in vitro cytokine release is PPARα-dependent for PFOA but not for PFOS (Corsini et al., 2011), but some PFOS in vitro cytokine release is PPARα-dependent (Mollenhauer, 2008).
Antigen-specific antibody production is PPARα-independent in C57BL/6 mice (DeWitt et al, 2016).
PPARα activation is not the only mode/mechanism
• Endocrine disruption, especially modulation of reproductive hormone pathways and thyroid hormones.
• Direct cytotoxicity.
• Oxidative stress and damage, leading to cytotoxicity.
Can mechanism be used as the basis of comparison? For screening? For prioritization? Will it pay off to
spend time and effort identifying a common mechanism? Is one necessary?
PFASs are themselves diverse with diverse uses. Can we use chemistry to understand toxicity?• By class?
• By chain length?
• By functional group?
• By chemical constituent?
• Other factors?
• Do these impact mechanism?
Source of figure: Buck et al., 2011, Integrated Environmental Assessment and Management, 7:513-541.
Some of the non-polymer PFASs
Class Examples
Perfluoroalkylsubstances
PFAAs: Perfluoroalkyl carboxylic acids and perfluoroalkyl carboxylates (PFCAs)Perfluoralkane sulfonic acids and perfluoroalkane sulfonates (PFSAs); PASFs: Perfluoroalkane sulfonyl fluorides; FASAs: Perfluoroalkane sulfonamides; PAFs: Perfluoroalkanoyl fluorides; PFAIs: Perfluoroalkyl iodides; PFALs: Perfluoroalkyl aldehydes
Polyfluoroalkylsubstances
FASEs, FASAAs, MeFASA/E/As, EtFASA/E/As, BuFASA/E/As: Perfluoroalkane sulfonamidosubstances; Fluorotelomer substances: Numerous compounds, including flurotelomeriodides, olefins, alcohols, acrylates, aldehydes, carboxylic acids, and sulfonic acids; Miscellaneous: Polyfluoroalkyl ether carboxylic acids
• Surfactants
• Raw materials for surfactants and surface protection products
• Raw material for PFOA (PAFs) as well as for surfactants and surface protection products
• Surfactant and surface protection products (specific fluorotelomer substances)
• Ski wax and medical applications (semifluorinated n-alkanes and alkenes)
• Intermediate environmental transformation products (various)
Source: Buck et al., 2011, Integrated Environmental Assessment and Management, 7:513-541.
Polymer PFASs – side-chain fluorinated polymers
-CnF2n+1 side chains
Fluorinated acrylate and methacrylate polymers
Fluorinated urethane polymers
Fluorinated oxetane polymers
• Surfactant and surface protection products
• Synthesis of these agents involves incorporation of one or more PFASs as monomers, which creates the potential for degradation of the polymer during or after its useful lifetime (Buck et al., 2011).
Source: Buck et al., 2011, Integrated Environmental Assessment and Management, 7:513-541.
Manufacture of polymer PFASs requires a PFAS as a processing aid. Environmental PFAS release therefore is possible during processing
and during or after their lifetimes.
How should these substances be evaluated toxicologically? As the parent or as the (potential) contaminants/breakdown product(s)?
PFOA and PFOS, the legacy PFAAs (C8s)
Perfluorooctanoic acid (PFOA)
• Cancer, immunotoxicity, and behavioral changes reported in epidemiological studies.
• Reported toxicities in animal models = cancer (liver, pancreatic, and testicular), developmental effects, immunotoxicity, liver, and kidney toxicity.
Perfluorooctane sulfonate (PFOS)
• Reported toxicities in animal models = developmental effects, liver toxicity, and serum lipid alterations, and neurotoxicity.
• Human studies support associations between serum levels and serum lipids and possibly developmental effects, endocrine disruption, and immunotoxicity.
Source of images: ChemSpider.com
Are differences in functional group sufficient to explain
differences in toxicity?
Short(er) chain length PFASs
Perfluorobutane sulfonate(PFBS; C4)
• Estimates of serum half-lives: < 5 hours in rats; ~4 days in monkeys; ~28 days in humans. Faster than PFOA and PFOS.
• Ability to activate mouse PPARα < PFOA and PFOS.
• Ability to activate human PPARα < PFOA and > PFOS.
Perfluorohexane sulfonate(PFHxS; C6)
• Estimates of serum half-lives: ~20-30 days in rats and mice; ~100 days in monkeys; 8.5 years in humans. May be a sex difference in rodents and monkeys. About the same or slower than PFOA and PFOS.
• Ability to activate mouse PPARα < PFOA and > PFOS.
• Ability to activate human PPARα < PFOA and > PFOS.
Source of images: ChemSpider.com. Source of data: C. Lau “Perfluoroalkyl Acids” & Wolf et al., 2008, Toxicol Sciences, 106:162-171.
Are differences in chain length sufficient to explain
differences in toxicity?
“While persistent in the environment, PFCA chemicals with fewer than eight carbons, such as pefluorohexanoic acid (PFHxA), and PFSA chemicals with fewer than six carbons, such as perfluorobutane sulfonic acid (PFBS), are generally less toxic and less bioaccumulative in wildlife and humans.” https://www.epa.gov/assessing-and-managing-chemicals-under-
tsca/and-polyfluoroalkyl-substances-pfass-under-tsca
Polyfluorinated PFASs2,3,3,3-tetrafluoro-2-(heptafluoropropoxy)-propanoate (polyfluorinated)
• Polyfluorinated compound used to replace PFOA in some applications.
• Differences in accumulation and excretion may exist between male and female animals, notably mice and possibly in monkeys.
Perfluorooctanoic acid(PFOA, perfluorinated)
• Multi-system toxicant with health effects reported in myriad species, including humans.
• May induce some toxicities through activation of PPARα; other toxicities induced via other putative mechanisms.
• Classified as a 2B (possibly carcinogenic to humans) carcinogen by the IARC.
Source of images: ChemSpider.com. Source of data: Rae et al., 2015, Toxicol Rep, 2:939-949; Gannon et al., 2016, Toxicol, 340:1-9; Rushing et al., 2008, Toxicol Sciences, epub.
2,3,3,3-tetrafluoro-2-(heptafluoropropoxy)-propanoate
Appear to be sex differences in accumulation and elimination when given orally to experimental animal models:
½ life of about 70 hours in male and female rats (beta phase)½ life of 37 hours in male mice & 24 hours in female mice (beta phase)
[½ life of about 64 hours in male cynomologus monkeys &80 hours in female cynomologus monkeys when given IV]
Source of data: Gannon et al., 2016, Toxicol, 340:1-9.
Are differences in fluorine substitution sufficient to explain
differences in toxicity?
Polymer versus non-polymer PFASs
Fluorotelomer-based polymers (FTPs)
• >80% of all fluorotelomer-based raw materials worldwide.
• May be precursors to PFAAs, especially carboxylate PFAAs such as PFOA.
• In rats, a flurotelomer-based urethane polymeric product induced hepatotoxicity in a 90-day oral study and reduced thyroid weights in F1 offspring in a developmental study.
Perfluorooctanoic acid (PFOA)
• Multi-system toxicant with health effects reported in myriad species, including humans.
• May induce some toxicities through activation of PPARα; other toxicities induced via other putative mechanisms.
• Classified as a 2B (possibly carcinogenic to humans) carcinogen by the IARC.
Source of images: ChemSpider.com. Source of FTP data: Rankin et al., 2011, ES&T, 48:12783-12790; Stadler et al., 2008, Drug & Chemical Toxicol, 31:317-337 .
Are differences in chemical substituent sufficient to explain
differences in toxicity?
Weight-of-evidence is sufficient for PFOA and PFOS, but insufficient for nearly all other PFASs.
What is the best research path forward for these diverse and numerous compounds?
What do independent research scientists need?c
• Use and production data from industry.o Most data on environmental occurrence comes from time-consuming
and labor-intensive surveys of environmental media.
• Standards, analytical methods, and other existing information and knowledge to accelerate research by other stakeholders.o A principle behind the REACH approach in Europe.
• Researchers across disciplines MUST work together.o PFASs present a challenging multidisciplinary problem that requires
cooperation and collaboration of many parties.
• Studies of mechanism and mode.o Adverse outcome pathways to better predict non-tested PFASs.
o But for what compounds?Source Wang et al., 2017, ES&T.
Areas highlighted in blue indicate zip codes where PFASs were detected in
one or more water samples from 2013-2015 that were at or above minimum
reporting levels required by the EPA. From Hu et al., 2016.
The future will likely result in a greater number and diversity of PFASs and fewer resources for regulatory oversight.
Reliance on toxicological data specific to PFOA and PFOS may underestimate site-specific public health risks due to the chemical diversity of these compounds.
We need to find a way to prioritizecompounds, sites, and toxicities and decide on mechanistic approaches.
What does the future hold?
Thank you!
Current PFAS collaborators:• Dr. Mark Strynar and Dr. Andy
Lindstrom at the U.S. EPA
• Dr. Chris Higgins at the Colorado School of Mines
• Dr. Nicole Reisdorph at the University of Colorado Anschutz Medical Campus
• Dr. Sarah Blossom at the Arkansas Children’s Research Institute