Exposure Investigation Report - Perfluorochemical Serum Sampling Decatur, AL

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ATSDR Exposure Investigations (EIs)

Exposure Investigation Report - Perfluorochemical Serum Sampling Decatur, AL

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Health Consultation
Exposure Investigation Report
Perfluorochemical Serum Sampling
In the vicinity of Decatur, Alabama
Morgan, Lawrence, and Limestone Counties

APRIL 1, 2013

U.S. DEPARTMENT OF HEALTH AND HUMAN SERVICES
Agency for Toxic Substances and Disease Registry
Division of Community Health Investigations
Atlanta, Georgia 30333

Health Consultation: A Note of Explanation

An ATSDR health consultation is a verbal or written response from ATSDR to a specific
request for information about health risks related to a specific site, a chemical release, or
the presence of hazardous material. In order to prevent or mitigate exposures, a
consultation may lead to specific actions, such as restricting use of or replacing water
supplies; intensifying environmental sampling; restricting site access; or removing the
contaminated material.
In addition, consultations may recommend additional public health actions, such as
conducting health surveillance activities to evaluate exposure or trends in adverse health
outcomes; conducting biological indicators of exposure studies to assess exposure; and
providing health education for health care providers and community members. This
concludes the health consultation process for this site, unless additional information is
obtained by ATSDR which, in the Agency’s opinion, indicates a need to revise or append
the conclusions previously issued.

You May Contact ATSDR TOLL FREE at
1-888-42ATSDR
or
Visit our Home Page at: http://www.atsdr.cdc.gov

HEALTH CONSULTATION

Exposure Investigation Report
Perfluorochemical Serum Sampling
In the vicinity of Decatur, Alabama
Morgan, Lawrence, and Limestone Counties

Prepared by:
Agency for Toxic Substances and Disease Registry
Division of Community Health Investigations
Science Support Branch

Table of Contents
ABBREVIATIONS and ACRONYMS .................................................................................................... 3
EXECUTIVE SUMMARY ...................................................................................................................... 5
PURPOSE OF EXPOSURE INVESTIGATION ..................................................................................... 9
LIMITATIONS......................................................................................................................................... 9
BACKGROUND ...................................................................................................................................... 9
A. Soil sampling.................................................................................................................................. 11
B. Water sampling............................................................................................................................... 12
C. Potentially exposed population ...................................................................................................... 13
METHODS ............................................................................................................................................. 14
RESULTS ............................................................................................................................................... 15
A. Demographic and Survey Characteristics ...................................................................................... 15
B . Serum Perfluorochemical Concentrations: Detection, Distribution and Measures of Central
Tendency ............................................................................................................................................. 15
C. Serum Perfluorochemical Concentrations by Age, Gender, Length of Residence, Vegetable
Consumption, Meat Consumption, Water Source, and Proximity to Biosolid Application Fields .... 16
DISCUSSION ......................................................................................................................................... 19
A. Serum Perfluorochemical Concentrations and Health Effects ....................................................... 19
B. Serum Perfluorochemical Concentrations ...................................................................................... 20
C. Serum Perfluorochemical Concentrations: Age and Gender ......................................................... 22
D. Serum Perfluorochemical Concentrations and Environmental Variables ...................................... 23
CONCLUSIONS .................................................................................................................................... 25
RECOMMENDATIONS ........................................................................................................................ 27
REFERENCES ....................................................................................................................................... 28
AUTHORS ............................................................................................................................................. 35
APPENDIX A: Figures.......................................................................................................................... 37
APPENDIX B: Tables ........................................................................................................................... 51
APPENDIX C: Exposure Investigation Protocol .................................................................................. 55
APPENDIX D: Review of PFC Studies and Health Effects ................................................................. 76
APPENDIX E: Investigation Summary and Health Information Sheet ................................................ 85

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ABBREVIATIONS and ACRONYMS
ALP

Alkaline phosphatase

ALT

Alanine aminotransferase

AST

Aspartate aminotransferase

ATSDR

Agency for Toxic Substances and Disease Registry

CDC

Centers for Disease Control and Prevention

EI

Exposure Investigation

EPA

Environmental Protection Agency

Et-PFOSA-AcOH

2-(N-ethyl-Perfluorooctane sulfonamide) acetic acid

FDA

Food and Drug Administration

GGT

Gamma-glutamyl transferase

Me-PFOSA-AcOH

2-(N-methyl-Perfluorooctane sulfonamide) acetic acid

MRL

Minimal Risk Level

NCEH

National Center for Environmental Health at CDC

ng/mL

Nanograms per milliliter (same as micrograms per liter or ppb)

NHANES

National Health and Nutrition Examination Survey

PFAC

Perfluoroalkyl carboxylate

PFAS

Perfluoroalkyl sulfonate

PFC

Perfluorochemical

PFCA

Perfluorocarboxylic acid

PFDeA

Perfluorodecanoic acid

PFHxS

Perfluorohexane sulfonic acid

PFNA

Perfluorononanoic acid

PFOA

Perfluorooctanoic acid
3

PFOS

Perfluorooctane sulfonic acid

PFOSA

Perfluorooctane sulfonamide

PFSA

Perfluorosulfonic acid

PHA

Provisional Health Advisory

POSF

Perfluorooctanesulfonyl fluoride

PPAR-α

Peroxisome proliferator activated receptor-alpha

ppb

Parts per billion

PWS

Public Water System

SMR

Standardized mortality ratio

TC

Total cholesterol

TSH

Thyroid stimulating hormone

ug/kg

Micrograms per kilogram (same as milligrams per kilogram or ppb)

μg/L

Micrograms per liter (same as milligrams per kilogram or ppb)

USDA

United States Department of Agriculture

WM/EL

West Morgan / East Lawrence

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EXECUTIVE SUMMARY
Background
In May 2007, a perfluorochemical (PFC) manufacturer in Decatur, Alabama, notified the EPA that it
had unknowingly discharged large amounts of perfluorocarboxylic acids (PFCA) into the Decatur
Utilities’ Dry Creek Wastewater Treatment Plant. PFCA is a class of PFCs that includes
perfluorooctanoic acid (PFOA) and other PFCs. PFCs are a class of organofluorine compounds that
are used in a variety of industrial and consumer products, including fire-fighting foams; personal care
and cleaning products; and oil, stain, grease, and water repellent coatings on carpet, textiles, leather,
“non-stick” cookware and paper such as wrappers used on fast food items. As a result, the general
United States (U.S.) population’s exposure to PFCs is common. One PFC, perfluorooctane sulfonic
acid or PFOS, is no longer manufactured in the U.S.
From 1996 to 2008 treated sewage sludge (biosolids) from Decatur Utilities was used as a soil
amendment on about 5,000 acres of privately owned agricultural fields in Lawrence, Morgan and
Limestone Counties, Alabama. In September 2007 EPA screened biosolids and soil for PFCs in a
small number of these agricultural fields. PFCs were elevated compared to background levels. In
February and March of 2009, EPA followed up with additional sample collection of the surface water,
ground water, drinking water, and soils in the area around the treated fields to determine the
concentrations of PFCs and PFC precursors. EPA found PFC chemicals in the Decatur Utilities’
biosolids, in soils, surface water, ground water, and drinking water.
In January 2009, EPA established a drinking water Provisional Health Advisory level (USEPA 2009)
for two of the PFC compounds with the most available toxicological information, perfluorooctanoic
acid (PFOA) and perfluorooctane sulfonate (PFOS). The Provisional Health Advisory level was
established at 0.4 parts per billion (ppb) for PFOA and 0.2 ppb for PFOS. In February 2009 EPA
tested six private drinking water wells located in close proximity to the fields tested for PFCs; two
private drinking water wells had PFOA concentrations above the EPA Provisional Health Advisory
levels. They were immediately provided an alternate drinking water source and then connected to the
public water supply system. At EPA’s request, a group of local industries completed a comprehensive
private drinking water well survey and sampling events in the areas surrounding land application sites.
From August 2009 through August 2010, the local industries tested 12 private drinking water wells.
One had elevated levels of PFOS above EPA’s Provisional Health Advisory value. This residence was
immediately provided an alternate drinking water source and connected to the local public water
supply system.
In addition, EPA sampled five local public drinking water systems. PFCs were detected in one system.
PFOA and PFOS were detected in the West Morgan/East Lawrence (WM/EL) water supply but at
concentrations below EPA’s Provisional Health Advisory levels. This system draws its water from the
Tennessee River approximately 13 miles downstream from an industrial center where several PFC
manufacturers and users are located. A study funded by one of the local industries (Hanson 2002)
detected PFOA and PFOS in samples collected in 2000 from the Tennessee River. A study for analysis
for PFOA in surface water and sediment from several points along the Tennessee River funded by one
of the local industries found levels from not detected to 86.7 ppb in surface water and from not
detected to 574 ppb in sediment (Weston 2008). A 2012 quarterly status report produced for one of the
local industries in Decatur, AL identified levels of PFOA in monitoring wells bordering the industrial
center along the Tennessee River and Bakers Creek to have shallow groundwater levels above 3000
5

ppb in some locations (Weston 2012). The agricultural fields that received the Decatur Utilities’
biosolids are not suspected to be the source of PFCs in the West Morgan/East Lawrence public water
supply system.
In 2009 EPA contacted ATSDR and requested an exposure investigation.
Population Tested
A total of 155 people volunteered to have PFC concentrations measured in their blood. This
investigation targeted residents who live and work in a predominantly rural community in the Decatur
area who may have higher non-occupational exposure to PFCs than the average person in the United
States. These included people who live on or near soils that received applications of biosolids from
Decatur Utilities or were drinking water containing PFCs. Two participants did not live in the Decatur
area and their results were excluded from the final analysis and reporting.
Conclusions
Because this investigation was designed to select individuals with the greatest likelihood of PFC
exposure, these results cannot be generalized nor inferred to represent others living in the area or to
other locations / populations. The results of this investigation are applicable only to the individuals
tested. In addition, results of this EI cannot be used to predict the future occurrence of disease nor be
associated with current or past health problems. Blood serum PFC concentrations do not provide
information about the source (i.e., water; soil; food; personal care and cleaning products; oil, stain,
grease, and water repellent coatings on carpet, textiles, and leather; ”non-stick” cookware; paper
products such as the wrappers used on fast food items), timing, frequency, or magnitude of exposure.
Blood Serum PFC Concentrations
• Each participant’s blood was analyzed for eight PFCs. The results were compared to values found
in the 2005-2006 National Health and Nutrition Examination Survey (NHANES).
• NHANES is a program of studies designed to assess the health and nutritional status of adults and
children in the United States and examines a nationally representative sample of about 5,000
persons each year. It includes demographic, socioeconomic, dietary, and health-related questions,
an examination component that consists of medical, dental, and physiological measurements and
laboratory tests to include over 200 environmental chemicals.
•

Five PFCs measured (PFNA, PFDeA, Me-PFOSA-AcOH, Et-PFOSA-AcOH and PFOSA) were
lower than or similar to the U.S. general population as defined by the NHANES 95th percentile
for PFCs.

•

Geometric mean levels for three PFCs (PFOA, PFOS and PFHxS) were elevated (about two to
four times) in participants compared to the U.S. general population, but were similar to or lower
than levels found in other U.S. communities exposed to PFCs via drinking water or other
environmental pathways.

•

Of the three elevated serum PFCs, concentrations increased with age and were higher in males
than females.

•

Serum levels of all eight PFCs measured in this investigation were much lower than levels found
in occupational studies of PFC manufacturing workers.
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Finding PFCs in blood does not imply that the levels of PFCs cause an adverse health effect. The
epidemiologic literature on the human health effects of PFCs is limited and the link between PFCs in
blood and health effects is not conclusive. Three recent studies (C8 Science Panel 2011-2012,
Grandjean 2012, Halldorsson 2012) have identified a possible link with health effects in humans with
serum PFC levels similar to or below levels found in this investigation.
Blood Serum PFC Concentrations and Environmental Survey
Analysis of serum PFC levels in EI participants who regularly used the WM/EL public water system as
their primary drinking water source found that they had higher serum levels of PFOA, PFOS and
PFHxs when comparing the geometric mean of participants to the geometric mean found in a national
survey (NHANES).
In addition, EI participants who regularly used the WM/EL public water system as their primary
drinking water source had significantly higher geometric mean serum levels of PFOA and PFHxS
compared to the NHANES geometric mean than participants who were otherwise similar but reported
using an alternative water source that did not have a detectable level of PFCs. Serum PFOS among
those who regularly used the WM/EL public water system was also found to be higher than those
participants using an alternative water source compared to NHANES but was not significantly higher.
Alternative water sources include bottled water, private wells and other public water systems in the
region that did not have a documented detectable level of PFCs. This analysis suggests an association
between the detectable levels of PFCs in the drinking water from the WM/EL public water system and
elevated serum PFC levels among participants who used it as their primary drinking water source.
With the exception of the drinking water source, no association or link between serum PFC
concentrations and potential PFC sources in the environment was found in this investigation. The
limited sample size of this investigation was not sufficient to determine if a significant link between
blood serum levels of PFCs and individual exposures to PFCs through biosolids or consumption of
local cattle, fish, and vegetables existed.

Recommendations
•

Continue efforts to reduce the level of PFCs present in the Tennessee River which is used as
source water for the WM/EL public water supply system.

•

Continue monitoring for PFCs in the WM/EL public water supply and other potentially
impacted public water supplies downstream of Decatur, Alabama. The WM/EL public water
system has already taken steps to improve water treatment which is expected to reduce PFC
levels in finished drinking water. If PFOA and/or PFOS concentrations in the finished drinking
water of the WM/EL public water system increase and remain above the EPA’s Provisional
Health Advisory levels, we recommend that the public water system evaluate modifications to
their treatment processes to reduce contaminant levels.

•

Conduct routine periodic monitoring of other local area public water supplies for potential
contamination with PFCs. Although these water supplies are considered to be at a lower risk for
PFC contamination because of their location and have no detectable PFCs to date, it is good
public health practice to conduct routine periodic monitoring.
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•

Owners of private drinking water wells located on or near biosolids application fields not
previously tested should consider conducting periodic monitoring for PFCs. If levels are
consistently above EPA’s Provisional Health Advisory levels, residents should use alternate
drinking water sources. Some private drinking water wells in the area were sampled quarterly
for a year and those that exceeded EPA’s provisional health advisory levels for PFOA/PFOS
were placed on public water. All other sampled wells did not exceed the provisional health
advisory levels.

•

The community’s exposure to PFCs is expected to decline because of the actions taken to
remove or decrease PFCs in the environment. Follow-up serum PFC testing in this community
should be considered to verify that serum PFC concentrations are declining and to identify
whether additional public health actions may be needed.

•

Continue providing the community with any new science about health effects of PFC exposure
as new information is documented.

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PURPOSE OF EXPOSURE INVESTIGATION
In August 2009, the EPA Region 4 Water Protection Division contacted the ATSDR Exposure
Investigation Team and requested an exposure investigation to determine if the population using the
WM/EL public water system as their primary drinking water source and the population residing near
biosolids application fields in the Decatur, AL area were exposed to PFCs.
The purpose of this EI was to determine if unusual community exposures to PFCs was occurring by
collecting blood serum samples from people with a high potential for PFC exposure. An EI is not a
research study. Participant selection was specifically focused on those participants with the greatest
potential for exposure rather than selecting participants in a systematic manner to generate or
contribute to generalizable knowledge as is the case in a research study (CDC 2010a). Participants
were recruited for the EI based on the following exposure factors:




Living on or near agricultural fields that received biosolids applications as a soil amendment
from Decatur Utilities, or
Drinking water from private wells located in or near fields that received biosolids from Decatur
Utilities, or
Drinking water from the West Morgan / East Lawrence (WM/EL) public water system which
has detectable PFOA and / or PFOS concentrations below U.S. Environmental Protection
Agency (EPA) Provisional Heath Advisory levels.

LIMITATIONS
The results of this investigation are only applicable to the individuals tested. The results cannot be
generalized to other populations because this investigation attempts to specifically target people with
potential for higher exposure. In addition, results of this EI cannot be used to predict the future
occurrence of disease nor be associated with current or past health problems. Serum PFC
concentrations will not necessarily provide information about the source of exposure (i.e. water, soil,
food etc.) but along with other exposure pathway information may help determine if there is an
association or link with potential PFC sources.

BACKGROUND
In May 2007, a PFC manufacturer in Decatur, Alabama, notified the EPA that it had unknowingly
discharged large amounts of perfluorocarboxylic acids (PFCA) over a period of years into the Decatur
Utilities’ Dry Creek Wastewater Treatment Plant. Decatur Utilities receives wastewater from domestic
and industrial sources, including fluorochemical manufacturing and use facilities. From 1996 to 2008,
treated sewage sludge (biosolids) from Decatur Utilities were used as a soil amendment on about 5,000
acres of privately owned agricultural fields in Lawrence, Morgan and Limestone Counties, Alabama.
EPA regulations under the Clean Water Act (CWA) allow biosolid land application for soil
amendment and fertilizer. PFCs are a class of man-made chemicals that are not regulated under the
CWA by EPA. Testing of biosolids for these chemicals is not required.
In September 2007, EPA tested biosolids and soil for PFCs in a small number of agricultural fields that
received biosolids from Decatur Utilities. The results revealed elevated PFCs compared to background
9

levels. In February and March 2009, EPA collected samples from the surface water, ground water,
drinking water, and soils in the area around the treated fields for PFCs and PFC precursor analyses.
EPA found PFCs in the Decatur Utilities’ biosolids, in soils from the agricultural fields treated with the
biosolids, and in surface water, ground water, and drinking water (EPA 2011a).
In January 2009, EPA established a drinking water Provisional Health Advisory level (EPA 2009) for
two of the PFC compounds with the most available toxicological information: perfluorooctanoic acid
(PFOA) and perfluorooctane sulfonate (PFOS). The Provisional Health Advisory levels are 0.4 parts
per billion (ppb) for PFOA and 0.2 ppb for PFOS. Provisional Health Advisory values are developed
to provide information in response to an urgent or rapidly developing situation. They reflect
reasonable, health-based hazard concentrations above which action should be taken to reduce exposure
to unregulated contaminants in drinking water. They are updated as additional information becomes
available and can be evaluated.
In February 2009 EPA tested six private drinking water wells near agricultural fields for PFCs and
identified two with PFOA above the EPA Provisional Health Advisory level. These residences were
immediately provided an alternate drinking water source and connected to the local public water
supply system.
At EPA’s request, Decatur Utilities and a group of local industries completed a comprehensive private
drinking water well survey and sampling events in the areas surrounding the land application sites.
From August 2009 through August 2010, the local industries sampled 12 private drinking water wells.
One of the 12 had PFOS levels above EPA’s Provisional Health Advisory value. This residence was
immediately provided an alternate drinking water source and connected to the local public water
supply system.
EPA sampled five local public drinking water systems; PFCs (PFOA and PFOS) were detected in one,
the WM/EL public water supply. Testing for PFCs in WM/EL public water supply began in 2006. Both
PFOA and PFOS in the finished water levels were below the EPA’s Provisional Health Advisory
levels. Additional treatment methods were recently implemented at this public water supply system to
treat a portion of the raw water for disinfection byproducts that will also help further reduce PFCs in
the finished water.
The WM/EL public water supply system draws its water from the Tennessee River several miles
downstream from an industrial center where several PFC manufacturers and users are located. A study
(Hanson 2002) funded by one of the local industries detected PFOA and PFOS in samples collected in
2000 from the Tennessee River. It also noted measurable levels of PFOS present upstream of the
Decatur PFC manufacturing facilities, although below the 2009 EPA Provisional Health Advisory
level. The presence of PFOS in samples collected upstream of the manufacturing facilities suggests the
possibility of another unidentified source of PFOS. None of the upstream samples detected PFOA. A
study for analysis for PFOA in surface water and sediment from several points along the Tennessee
River funded by one of the local industries found levels from not detected to 86.7 ppb in surface water
and from not detected to 574 ppb in sediment (Weston 2008). A 2012 quarterly status report produced
for one of the local industries in Decatur, AL identified levels of PFOA in monitoring wells bordering
the industrial center along the Tennessee River and Bakers Creek to have shallow groundwater levels
above 3000 ppb in some locations (Weston 2012). The agricultural fields that received the Decatur
Utilities’ biosolids are not suspected to be the source of PFCs in this public water supply system.
10

In August 2009, the EPA Region 4 Water Protection Division contacted the ATSDR Exposure
Investigation Team and requested an exposure investigation to determine if the population using the
WM/EL public water system as their primary drinking water source and the population residing near
biosolids application fields in the Decatur, AL area were exposed to PFCs.
In October 2009, EPA released residential direct ingestion soil screening guidance values for PFOA
and PFOS that are protective of children’s health (which are also protective of adult health). These soil
screening values are 16,000 ppb [micrograms per kilogram (ug/kg)] for PFOA and 6,000 ppb for
PFOS. ATSDR has not developed direct ingestion soil screening values for PFOA or PFOS.
More information on the EPA field studies in Decatur and the EPA-developed guidance values for
PFCs may be obtained from the following website: http://www.epa.gov/region4/water/PFCindex.html
PFCs are a class of organofluorine compounds where hydrogen atoms on the carbon chain have been
replaced by fluorine and also contain at least one different atom or functional group. The compounds
are both hydrophobic and oleophobic.
- A hydrophobic molecule is repelled by water. Hydrophobic is a chemical property of a compound
which literally means something with a fear of water. Hydrophobic molecules often cluster together
when dropped in water, just as oil does.
- An oleophobic molecule is repelled by oil. Oleophobic is a chemical property of a compound which
literally means something with a fear of fat (or oil). Oleophobic molecules often cluster together when
dropped in oil, just as water does.

PFCs and PFC precursors are used in a variety of industrial and consumer applications and products.
These include fire-fighting foams; personal care and cleaning products; oil, stain, grease, and water
repellent coatings on carpet, textiles, leather, ”non-stick” cookware; and paper such as the wrappers
used on fast food items. As a result, the general United State (U.S.) population’s exposure to PFCs is
very common. PFOS is no longer manufactured in the U.S.
A. Soil sampling
In 2007, EPA conducted limited sampling of sewage sludge and biosolids from the Decatur Utilities
facility and soil from four agricultural sites that received biosolids. The results indicated relatively high
levels of PFOA and PFOS compared to other industrial and non-industrial sites (U.S. EPA 2011a). The
four soil sampling sites showed PFOS ranging from 276 to 1,409 ppb and PFOA ranging from 541 to
2,531 ppb. Nearby fields that did not have application of contaminated biosolids were also tested.
None of the targeted PFCs were detected above the method’s lower detection limit of 100 ppb,
suggesting no or very minimal background levels.
In March 2009, EPA collected 30 soil samples in or near the fields with the highest applications of
biosolids. Four background samples were collected from fields that did not receive biosolids. Most
background samples fell below the analytical limit of quantitation (LOQ) of 0.018 ppb and a few
samples that detected PFCs fell just slightly above the LOQ. Soil test results of treated fields indicated
that the majority of the Decatur soils in the land application area have concentrations of numerous
PFCs above the background levels. Concentrations of PFOA ranged from below the LOQ up to 317
11

ppb, with most concentrations in the 100 to 200 ppb range. Concentrations of PFOS ranged from
below the LOQ up to 408 ppb, with most concentrations around 100 to 200 ppb. Levels of the tencarbon carboxylic acid (C10) were as high as 986 ppb; levels of 12-carbon carboxylic acid (C12) were
as high as 526 ppb.
Soil sampling and analysis techniques changed between the 2007 and 2009, making it difficult to
compare results. Decatur Utilities voluntarily discontinued biosolids application in the later part of
2008. None of the soil samples collected by EPA in 2007 or 2009 exceeded EPA’s residential direct
ingestion soil screening guidance values.
B. Water sampling
In November 2008, EPA tested water samples from the Moulton, Decatur and WM/EL public water
systems for PFCs. There were no detectable concentrations of PFCs in the Moulton and Decatur
systems. The levels of PFCs detected in the WM/EL system were below EPA’s Provisional Health
Advisory levels for PFOA (0.4 ppb) and PFOS (0.2 ppb). In September 2009, EPA retested these three
systems and expanded sampling to include the public water systems of the Limestone County and
Swann Creek communities. No PFCs were detected in four of the five systems and the repeat samples
of the WM/EL system were below EPA’s Provisional Health Advisory levels. Repeat sampling of the
WM/EL system in 2011 found similar results. Because these values have remained below EPA’s
Provisional Health Advisory levels, EPA does not recommend removing residents from these public
water systems.
In February 2009 EPA sampled a number of private water wells (potable and non-potable), ponds, and
streams located near the fields that received biosolids from Decatur Utilities.
Sampling results from twelve non-potable private water wells for PFOA ranged from below the LOQ
(0.01 ppb) up to 6.41 ppb and for PFOS ranged from below the LOQ up to 0.15 ppb. These wells were
used for agricultural purposes.
The surface water samples for PFOA results from 32 ponds and one stream ranged from below the
LOQ up to 11.0 ppb; PFOS concentrations ranged from below the LOQ up to 0.08 ppb. EPA has not
yet established PFOA or PFOS provisional health advisory values for water that is used for purposes
other than human consumption.
The analytical results for two of the six private drinking water wells sampled had levels above EPA’s
Provisional Health Advisory levels. Water from drinking water wells at two residences had PFOA
levels of 0.6 ppb and 2.2 ppb respectively. These residents were immediately provided an alternate
water source and then connected to the public water supply system. The remaining private drinking
water wells sampled had PFOA and / or PFOS values below EPA’s Provisional Health Advisory
levels.
From August 2009 through August 2010, at the request of EPA, Decatur Utilities and a group of local
industries sampled 12 private drinking water wells. One of these 12 private drinking water wells had
a PFOS level of 0.365 ppb which was above EPA’s Provisional Health Advisory value. This residence
was immediately provided an alternative source of drinking water and connected to the local public
water supply system. Water concentrations of PFOA and PFOS from the remaining 11 residences
remained below EPA’s Provisional Health Advisory values for the duration of the sampling period.
12

C. Potentially exposed population
The potentially exposed population in the Decatur area includes residents who live and work in a
predominantly rural community. In addition to the PFC related industries located in the general area,
approximately 179 fields on approximately 35 farms received PFC contaminated biosolids from
Decatur Utilities. People that live near or work in these fields are potentially exposed to PFCs by way
of direct contact with contaminated soils, inhaling contaminated airborne dust, drinking contaminated
water, and eating contaminated food. Possible dietary PFC sources in addition to drinking water
include commercial and home grown vegetables, beef and milk from locally raised cattle that may
graze on pastures that received PFC- contaminated biosolids, or may drink water containing PFCs, and
fish from contaminated local rivers, ponds and lakes. Prior to this EI, there has not been human
exposure monitoring for PFCs in the Decatur area population to determine if human exposure above
background levels was occurring.
The USDA and FDA, in collaboration with EPA, collected and analyzed blood, tissue and milk
samples from local cattle grazed on farms where Decatur Utilities biosolids were land applied. This
sampling was conducted to help determine whether local foods, such as meat and dairy products, may
be contaminated with PFCs. The USDA and FDA provided the following information to EPA
regarding the analytic results from these tests (located on the EPA Region 4 Water Protection Division
website at http://www.epa.gov/region4/water/PFCindex.html. This language is quoted from email
communications sent by USDA and FDA to EPA. USDA and FDA have not provided EPA Region 4
or ATSDR with written reference materials supporting these statements):
“In May 2009, the U.S. Department of Agriculture (USDA) sampled blood and tissue from selected
cows/steers from farms where Decatur Utilities biosolids were land applied in the past. Samples from
seven animals associated with "high" application fields and two animals from "minimally" applied
fields were collected. The final analytical results from these tests indicate the values are below
USDA's minimum proficiency level (MPL) of 20 ppb for both PFOS and PFOA. Therefore, these
samples are reported as not detectable for PFOS and PFOA. Based on USDA estimates for human
health concerns using the MPL as an upper limit value and current Decatur area exposure patterns, this
testing supports USDA's finding that there is no reason to believe there are human health concerns with
consuming the meat processed from cattle grazed on lands receiving these biosolids.”
“Also in May 2009, FDA sampled and analyzed two milk samples for PFOA and PFOS. One sample
was collected from a single cow and the other sample collected from a bulk milk tank from a dairy
farm located in the Decatur area that received limited application of Decatur Utilities biosolids. FDA
testing found no PFOA or PFOS in the milk sample from the single cow. A very low level (0.16 ppb)
of PFOS was detected in the bulk tank milk sample. FDA has also tested additional samples including
raw (n=10) and retail (n=49) milk samples collected throughout the U.S. for 10 perfluorinated
compounds, including PFOA and PFOS, to obtain additional information on background levels for
PFCs in milk. FDA testing found no PFCs in any of the additional raw or retail milk samples.”
155 participants initially enrolled in the EI but two were later found to reside outside the investigation
area. One excluded participant grew up in the region and came to the EI with other local residents but
only later revealed that they had not lived in the area for many years. The second excluded participant
provided an address that was not initially recognized as being outside the investigation area but was
later identified as such. Both participants received their individual blood test results. For the remainder
of this report, all information is based on a total of 153 participants.
13

Nine of the 153 EI participants had been drinking water from three private water wells that exceed
EPA’s Provisional Health Advisories for PFOA and PFOS. Once sampling results from February 2009
indicated elevated PFOA and / or PFOS levels in these three drinking water wells, the residents were
immediately provided an alternative source of drinking water and then connected to the public water
system.
Many community members receive their drinking water from the WM/EL public water supply system.
While the concentrations of PFOA and PFOS in this water system are below EPA’s Provisional Health
Advisory levels, they are present. Because of the long half-life of PFCs in the human body, sustained
low level exposure may lead to increases in the blood serum concentrations of PFCs. No detectable
levels of PFOA or PFOS were identified in the Decatur or Moulton public water supply.

METHODS
This exposure investigation targeted a specific population in the Decatur, Alabama area.
Property Criteria:
 Has lived on current property for at least one year
 One or more of the following:
o Lives on or near property with sludge application
o Is exposed to drinking water contaminated with PFCs from private wells or low level
exposure from a public water system (as defined by EPA sampling)
Personal Criteria:
 Is 12 years of age and older
 Does not have a bleeding disorder or anemia
 Does not have current or past occupational (industrial) exposure to PFCs
The age criteria (12 years of age and older) was used because the reference values to be used for
comparison in this investigation are only available for children 12 and older (CDC 2010b).
Approximately 519 eligible households were sent letters inviting them to participate in the EI and
provided a toll-free number to call for an appointment at a central location. A total of 153 people
residing in the area of interest (85 households) participated during the week of April 12-15, 2010.
At the blood collection center, each adult participant was required to provide written informed consent.
Children from 12 to 17 years of age were also required to provide written assent with the written
consent of their guardian. Each participant was asked to complete a short survey to gather information
on risk factors for exposure to PFCs. A phlebotomist collected a 4-ml blood sample in a tube by
venipuncture. ATSDR staff was available to answer participant questions.
Blood samples were analyzed for eight perfluorochemicals. Table 1B in Appendix B lists the eight
PFCs measured by abbreviation, complete chemical name, and LOQ. Test results were reported as
nanograms of the PFC analyte per milliliter of blood (ng/mL).
Statistical analysis was performed using SAS (Release 9.2, SAS Institute, Cary, NC) and SPSS.
14

For additional details on sample handling and shipment, lab processing and analysis, confidentiality
protection and statistical analysis see Appendix C: Exposure Investigation Protocol for details on
methods used in the exposure investigation.
RESULTS
A. Demographic and Survey Characteristics
The participant population consisted of 145 adults and 8 children. There were 63 males and 90
females. The mean age of the participants was 52 years old. The mean length of residence was 25.5
years. Table 2B, Appendix B provides the frequency distribution of demographic and environmental
variables collected in this investigation.
B . Serum Perfluorochemical Concentrations: Detection, Distribution and Measures of Central
Tendency
Detection
Serum samples were analyzed for eight PFCs and PFC precursors: PFOA, PFOS, PFHxS, PFNA,
PFDeA, Me-PFOSA-AcOH, Et-PFOSA-AcOH, and PFOSA (see Table 1B, Appendix B for list of
PFC chemical acronyms). PFOA, PFOS, PFHxS and PFNA were detected in 100% of the 153 serum
samples. Other PFCs (PFDeA, Me-PFOSA-AcOH, and Et-PFOSA-AcOH) were not found in every
sample. The percent detections for these PFCs are as shown in Table 1, below. PFOSA was not
detected in any sample.
Table 1: Percent of Blood Serum Samples Containing PFC1 or PFC Precursor
(n=153)
PFCs and PFC precursors
MeEtPFOA
PFOS PFHxS PFNA PFDeA PFOSA PFOSA PFOSA
-AcOH -AcOH
% Detected
100%
100%
100%
100%
65%
63%
1%
0%
in EI2
% Detected
99.9%
99.8%
99.2% 99.5%
70%
70.3%
3.3%
0.52%
in NHANES3
1
PFC = Perfluorochemical. See abbreviations and acronyms section (page 3) for individual PFC
definitions.
2
EI = Exposure Investigation
3
NHANES = 2007-2008 National Health and Nutrition Examination Survey
The percent detected of each PFC/PFC precursor in this EI is consistent with the findings of a
representative sample of the U.S. population from 2007-2008 National Health and Nutrition
Examination Survey (NHANES) data (Kato 2011). Detectable amounts of Et-PFOSA-AcOH and
PFOSA were all below the NHANES 95th percentile and found in so few participants that it indicates
this population was not significantly exposed to these PFC precursors. With the presence of a large
number of values for PFDeA and Me-PFOSA-AcOH below the limit of detection, using these values
for conducting additional statistical analysis for evidence of exposure compared to the U.S. population
would not provide a valid analysis. The geometric mean for PFDeA (0.4 ng/mL) and Me-PFOSA15

AcOH (0.4 ng/mL) were below the NHANES geometric mean (PFDeA – 3.55 ng/mL, Me-PFOSAAcOH – 4.7 ng/mL). Only 1 sample for PFDeA and 4 samples for Me-PFOSA-AcOH exceeded the
NHANES 95th percentile (PFDeA – 1.5 ng/mL, Me-PFOSA-AcOH – 1.8 ng/mL) indicating that
participants did not have unusual exposures compared to the U.S. population. Therefore, the
remainder of the report is focused on the analysis of PFOA, PFOS, PFHxS and PFNA, all of which had
multiple samples that exceeded the NHANES 95th percentile.
Distribution
Figures 1 - 4 (Appendix A) display the distribution of the four PFCs selected for further analysis,
PFOA, PFOS, PFHxS, and PFNA. Each distribution is highly skewed. To complete the analysis, each
of the PFC measures was log10 transformed. Figures 5 - 8 (Appendix A) show that the log-transformed
PFC distributions are normally distributed. The Shapiro-Wilks statistic is a test of the null hypothesis
that the adjusted data are normally distributed. All p-values were greater than 0.05 indicating evidence
for the null hypothesis for the adjusted data, and therefore log transformation of the data is appropriate.
Log-transformed PFC variables were used for calculation of geometric mean concentrations and as
dependent variables in all linear regression analyses.
Measures of Central Tendency
Table 3B (Appendix B) provides comparisons of all eight PFCs measured in this investigation to the
2005-2006 NHANES data (CDC 2010b). NHANES is a population-based survey designed to collect
information on the health and nutrition of the U.S. household population. This survey is periodically
updated to measure chemical concentrations in the general U.S. population.
Table 3B (Appendix B) displays the measures of central tendency for each PFC measured in this
investigation. PFOA had a geometric mean of 16.3 ng/mL (ppb), a range of 2.2 – 144 ng/mL. The
geometric mean for PFOS was 39.8 ng/mL with a range of 5.4 – 472 ng/mL. The geometric mean for
PFHxS was 6.4 with a range of 0.6 – 59.1 ng/mL. The geometric mean for PFNA was 1.7 ng/mL with
a range of 0.3 – 5.5 ng/mL. This was less than twice the NHANES geometric mean for PFNA (1.09
ng/mL). The 95th percentile for PFNA (3.6 ng/mL) in this investigation was the same as NHANES
95th percentile (3.6 ng/mL) indicating that PFNA in this investigation was similar to the NHANES
reference value. The remaining four PFCs and their measures of central tendency are listed in Table 3B
(Appendix B) for information purposes only. They are not included in any additional analysis because
they did not show any evidence to suggest the presence of unusual exposures compared to the U.S.
population as noted previously. Additional analysis and discussion will focus on the three PFCs PFOA, PFOS, PFHxS - that were detected in all samples and were more than twice the NHANES
geometric mean.
Statistically significant correlations were detected between the log-tranformed serum concentrations of
PFOA and PFOS (Pearson correlation coefficient r = 0.76, p<0.0001), between PFOA and PFHxS (r =
0.86, p<0.0001), and between PFOS and PFHxS (r =0.85, p<0.0001) (Table 4B – Appendix B).
C. Serum Perfluorochemical Concentrations by Age, Gender, Length of Residence, Vegetable
Consumption, Meat Consumption, Water Source, and Proximity to Biosolid Application Fields
Survey Variables other than Age and Gender
Linear regression models of survey variables were done using backward elimination. The first model
16

contained all predictor variables. Subsequent models systematically removed variables that were not
significant or did not improve the model. All survey variables, with the exception of age and gender,
were not significantly associated with serum PFC concentrations. These variables include length of
residence, consumption of locally grown vegetables, consumption of locally raised cattle meat,
proximity to biosolids application fields, and soil exposure near the home. This includes drinking
water source when defined as regulated (all public water sources) versus unregulated (private well,
community well or spring) versus bottled water. When serum PFC concentrations were evaluated
looking at individual public water systems a significant association between use of public drinking
water from the WM/EL public water system was found for PFOA and PFHxS as discussed below.
Age
Linear regression analysis detected a small but significant relationship between serum PFC
concentrations and age (Table 5B – Appendix B). Scatter plots of the log-transformed PFCs – PFOA,
PFOS and PFHxS - and age are presented in Figures 9-11 of Appendix A. The r-squared and p-values
are as follows:
 PFOA and age, the R2 = 0.182 (p < 0.0001),
 PFOS and age, R2 = 0.313 (p < 0.0001), and
 PFHxS and age, R2 = 0.262 (p < 0.0001).
These plots show a log linear association between age and PFC measurements in which age was the
variable most associated with increasing PFC concentration. Generally, serum PFC concentrations
increased with the increased age of the participant.
Gender
Linear regression analysis detected a small but significant relationship between serum PFC
concentrations and gender. Geometric mean serum PFC concentrations were significantly higher in
males than females. The r-square and p-values are as follows (Table 5B – Appendix B):
 PFOA and gender, R2 = 0.039 (p = 0.014),
 PFOS and gender, R2 = 0.056 (p = 0.003), and
 PFHxS and gender, R2 = 0.067 (p = 0.001).
Age and Gender
Although statistically significant, gender has very low R2 values for each PFC. However with
multivariate linear regression using both age and gender the addition of gender improves the model
(Table 5B – Appendix B) as compared to regression analysis with age alone and helps explain the
source of the dependent variable’s variability.
West Morgan/East Lawrence Public Water Supply vs. other sources of primary drinking water
The initial evaluation, which included all three water systems in the public drinking water category,
showed little correlation of PFCs with water source. However, further examination of the results of the
121 participants who reported using the WM/EL public water system as their primary drinking water
source compared to those with a primary drinking water source that did not have a known detectable
level of PFCs (Moulton and Decatur public water systems, private wells without PFCs present and
bottled water) was conducted. This comparison did show a difference between the WM/EL public
17

water system and other sources of primary drinking water. Results are shown in Table 2.
Of the 153 participants, 100 (65.4%) had a serum PFOA greater than the NHANES 95th percentile of
11.3 ng/mL. One additional participant had a serum PFOA of 11.3 ng/ml. 66 participants (43.1%) had
a serum PFOS greater than the NHANES 95th percentile (47.5 ng/mL), and 55 (35.9%) had a serum
PFHxS above the NHANES 95th percentile (8.3 ng/mL). One additional participant had a serum
PFHxS of 8.3 ng/ml.
One participant did not provide data for all required survey variables leaving 152 participants for
further analysis. Accounting for the statistically significant variables of age and sex, the odds ratio of
having a serum PFOA level greater than the NHANES 95th percentile for participants using the
WM/EL water system as their primary drinking water source versus participants who used a primary
water source that did not have a detectable level of PFCs was 9.01. This finding was statistically
significant with a 95% confidence interval of 2.63-30.85 (See Table 3).
The odds ratio of having a serum PFHxS greater than the NHANES 95th percentile for PFHxS versus
the participants who used a primary water source that did not have a detectable level of PFCs was
13.08. This finding was statistically significant with a 95% confidence interval of 2.43-70.31 (See
Table 3).
The odds ratio of having a serum PFOS greater than the NHANES 95th percentile for PFOS versus the
participants who used a primary water source that did not have a detectable level of PFCs was 2.17.
Although this suggested an association between elevated serum PFOS and use of the WM/EL water
system as their primary drinking water source this finding was not statistically significant with a 95%
confidence interval of 0.61-7.70 (See Table 3).
Table 2: Comparison of serum perfluorochemicals (PFCs) between primary drinking water sources: West Morgan / East
Lawrence (WM/EL) public water system (PWS) vs. primary drinking water source without detectable levels of PFCs vs.
private drinking water wells with detectable levels of PFCs
(n=153)
Serum PFOA (ng/mL)
Serum PFOS (ng/mL)
Serum PFHxS (ng/mL)
WM/EL
Water
Private
WM/EL
Water
Private
WM/EL
Water
Private
PWS
Source
drinking
PWS
Source
drinking
PWS
Source
drinking
with
without
well with
with
without
well with
with
without
well with
detectable detectable detectable detectable detectable detectable detectable detectable detectable
level of
level of
level of
level of
level of
level of
level of
level of
level of
PFCs
PFCs
PFCs
PFCs
PFCs
PFCs
PFCs
PFCs
PFCs
(n=121)
(n=23)
(n=9)
(n=121)
(n=23)
(n=9)
(n=121)
(n=23)
(n=9)
Mean
Median
Range
GeoMean1
NHANES2
GeoMean1
NHANES2
95%4(CI4)

23.93
18.1
2.2-78.8
17.59

11.88
7.40
2.8-50.4
9.01

44.06
30.8
7.6-144
28.51

54.86
39.3
5.6-248
39.98

44.28
31.5
5.4-201
30.86

111.48
60.8
38.6-472
75.12

9.23
7.4
0.6-32.3
6.68

5.36
4.80
1.2-24.8
4.08

3.92 (3.48-4.42)

17.1 (16.0-18.2)

1.67 (1.42-1.98)

11.3 (8.80-14.6)

47.5 (42.7-56.8)

8.3 (5.80-11.9)

1

2

3

4

GeoMean = Geometric mean
95th Percentile

15.89
8.30
6.1-59.1
11.63

NHANES = 2005-06 National Health and Nutrition Examination Survey
CI = Confidence Interval

18

Levels of PFOA, PFOS and PFHxS were also higher for those participants who used private drinking
wells with detectable levels of PFCs. Similar to what was found with participants using the WM/EL
water system the odds of having a serum PFC greater than the NHANES 95th percentile were elevated
for all three chemicals but only PFOA and PFHxS were significantly elevated. Results are summarized
in Table 3.
Table 3: Summary of Odds Ratio (OR) and 95% Wald Confidence Limits (95% CL) of serum
perfluorochemicals (PFCs) for participants using West Morgan / East Lawrence (WM/EL) public water system
(PWS) and private drinking water wells with detectable levels of PFCs greater than NHANES 95th percentile as
compared to participants using drinking water source without detectable levels of PFCs
Serum PFOA
Serum PFOS
Serum PFHxS
OR
95% CL
OR
95% CL
OR
95% CL
WM/EL PWS
9.01
2.63-30.85
2.17
0.61-7.70
13.08
2.43-70.31
Private Wells
13.24
1.77-99.13
6.42
0.93- 44.50
23.61
2.55-218.87

DISCUSSION
PFCs are man-made chemicals introduced after World War II for use as a lubricant and stain/water
repellent and are now ubiquitous in the environment. All potential routes of exposure in the general
population are not clear but have included contaminated drinking water and consumption of
contaminated food such as fish caught from a water source with known PFC contamination. PFCs are
present in numerous modern products including personal care and cleaning products, oil, stain, grease,
and water repellent coatings on carpet, textiles, leather as well as fast food or packaged food containers
such as french fry boxes, pizza boxes, hamburger wrappers, and microwave popcorn bags.
PFCs have been shown to have health effects on animals at serum concentrations that are higher than
observed in human exposure studies. Human health effects associated with PFCs have not been clearly
established though studies have shown a potential relationship between elevated PFC levels and a
number of health end points. Animal studies of the straight-chain perfluoroalkyl sulfonate (PFAS) and
perfluoroalkyl carboxylate (PFAC) have shown that these compounds are well absorbed orally, but
poorly eliminated; they are not metabolized, and they undergo extensive uptake from enterohepatic
circulation. Studies of PFOS and PFOA have shown that these compounds are distributed mainly to the
serum, kidney, and liver, with liver concentrations being several times higher than serum
concentrations; the distribution is mainly extracellular. Both compounds have a high affinity for
binding to albumin, β-lipoproteins, and liver fatty acid binding protein. Studies have reported PFOS,
PFOA, and other PFCs in umbilical cord blood indicating these chemicals cross the placenta. For
further information of potential health effects see Appendix D: Review of PFC Studies and Health
Effects.
A. Serum Perfluorochemical Concentrations and Health Effects
In animals, adverse health effects have been demonstrated with PFOA/PFOS exposure at doses that are
higher than have been observed in the general human population (Kennedy 2004, Lau 2007, U.S. EPA
2005, Luebker 2005). In addition, extrapolation from animals to humans is uncertain because of
pronounced differences in elimination rates, substantial variability across species and other issues
(ATSDR, 2009).

19

The epidemiologic literature on the human health effects of PFCs is limited. Most studies have a crosssectional design, thus making causal inferences problematic.
A recent study found that PFC exposures in children at levels similar to the NHANES geometric mean
were associated with lower antibody responses to childhood immunizations and an increased risk of
antibody concentrations below the level needed to provide long-term protection (Grandjean 2012).
Another recent study found that the effects of low-dose developmental exposures to PFOA are
consistent with experimental results suggesting obesogenic effects in female offspring at 20 years of
age in a population in Denmark (Halldorsson 2012).
Reports by the C8 Science panel have noted a probable link between exposure to PFOA and several
health effects to include pregnancy-induced hypertension, testicular cancer and kidney cancer, thyroid
disease and ulcerative colitis. Participants had a PFOA level that was on average 37% higher than the
average PFOA level in the participants in this EI. This report also noted that there was not a probable
link between exposure to PFOA and birth defects, miscarriage or stillbirth, and preterm birth or low
birth weight. They also did not find a link between other forms of cancer that were evaluated in the
study, Type II diabetes, stroke, asthma or chronic obstructive airways disease (COPD),
neurodevelopmental disorders in children (such as attention deficit disorders and learning disabilities),
common infections or autoimmune disorders other than ulcerative colitis (to include rheumatoid
arthritis, lupus, Type I diabetes, Crohn’s disease or multiple sclerosis). Results from this large study
will continue to be shared over the next few years and should add to our knowledge about health and
PFCs (C8 Science Panel 2011-2012a,b,c, Holtcamp 2012).
A brief review of additional occupational and community populations exposed to PFCs and health
effects is summarized in Appendix D.
The summary provides a review of studies for PFCs and clinical laboratory measurements such as lipid
concentrations, liver function tests, thyroid function, kidney function and sex hormones. In addition,
studies that examined the relationship between PFCs and diseases such as diabetes, cardiovascular
disease, and cancer are discussed. Most of the discussion focuses on PFOA and, when data is available,
on PFOS and PFHxS.
PFC exposure and associations with chronic diseases and clinical laboratory measurements are limited
and inconclusive. These limitations prohibit definitive conclusions. Although the number of studies
related to PFC exposure and health effects is increasing, additional research on humans is needed to
better understand the role of PFC exposure in association with diseases or clinical laboratory
measurements. Currently, no clinical values are established by any U.S. Governmental agency for
interpreting serum PFC levels in terms of determining public or individual health risk.
In summary, the association of PFC exposure and any disease or laboratory measurements remains
inconsistent and inconclusive.
B. Serum Perfluorochemical Concentrations
PFCs have been found in the environment, in wildlife and in the blood of the general population
(Calafat 2006a, 2007, Kannan 2004, Taniyasu 2003). The range of PFC concentrations varies with
populations and not all PFCs are examined consistently in every study. The most commonly measured
20

PFCs are PFOA and PFOS. The results of this investigation provide information on the distribution of
eight PFCs.
PFOA, PFOS, and PFHxS were shown to be highly correlated with each other in this investigation,
which is consistent with the published literature (Calafat et al., 2007b, MDH 2009). This may be due to
PFOS, PFHxS and to a lesser extent PFOA being a manufactured byproduct of perfluorooctanesulfonyl
fluoride (POSF), Me-PFOSA-AcOH, Et-PFOSA-AcOH and PFOSA. POSF is a synthetic
perfluorinated compound with a sulfonyl fluoride functional group but was not analyzed in this EI
because no national comparison data is available in NHANES. It is used to make PFOS and PFOSbased compounds.
Serum PFC concentrations for three PFCs (PFOA, PFOS, PFHxS) in this investigation are elevated
compared to the U.S. general population (CDC 2010b). As observed in Table 3B, Appendix B, PFOA,
PFOS and PFHxS, had geometric means that were two to four times the geometric mean of the U.S
general population from NHANES data. Briefly, the geometric means for this investigation were as
follows: PFOA 16.3 ng/mL (U.S. population: 3.9 ng/mL), the geometric mean for PFOS was 39.8
ng/mL (U.S. population: 17.1 ng/mL), and the geometric mean for PFHxs was 6.4 ng/mL (U.S.
population: 1.67 ng/mL). Only PFOA was also above the 95th percentile of NHANES for the U.S.
population (See Table 2).
The geometric mean for the remaining five PFCs (PFNA, PFDeA, Me-PFOSA-AcOH, Et-PFOSAAcOH and PFOSA) are similar to or lower than the geometric mean for the U.S. general population
(NHANES). For the remainder of this discussion PFOA, PFOS and PFHxs will be the focus of
analysis because they were moderately elevated. The other five PFCs will not be discussed further.
Comparisons with other PFC published reports are useful to place these findings in context and
provide a meaningful interpretation. Serum levels of PFCs, especially PFOS, appear to be higher in the
U.S. compared to other countries. In Columbia, Brazil, Poland, Belgium, Malaysia, Korea and Japan,
PFC levels are two- to threefold lower than the United States; in Italy and India serum levels are about
eight to sixteen fold lower. (Kannan 2004). Peru is about thirty fold lower (Calafat 2006b). However,
the sample sizes were small in both of these referenced studies and neither should be used to
conclusively describe worldwide trends.
In a 2008 study, Red Cross Blood Donors from six different regions across the U.S. were analyzed for
PFCs. Concentrations were similar to those of NHANES. Serum PFC concentrations in our
investigation are elevated compared to the 600 Red Cross Blood Donor samples (PFOA geometric
mean 3.4 ng/mL, PFOS geometric mean 14.5 ng/mL, and PFHxS geometric mean 1.5 ng/mL) (Olsen
2008).
The NHANES serum PFC concentrations demonstrate that PFCs are widespread in the population.
These compounds are ubiquitous in the environment and it is unlikely that drinking water alone is the
primary source of exposure in the general population. Although, the three serum PFC concentrations in
this investigation are elevated compared to the U.S. population, this is not unexpected because
NHANES represents the general U.S. population. The community in this investigation has a known
history of environmental PFC contamination.
In communities where there is a documented history of environmental PFC contamination, serum PFC
concentrations were similar or lower than levels found in this investigation. For instance, the serum
21

PFC concentrations observed in this investigation are similar to a community in Minnesota exposed to
PFC contamination in the drinking water. Mean PFC contamination in six municipal wells in the
Minnesota community ranged from 0.07 to 0.7 μg/L for PFOA, not detected to 1.04 μg/L for PFOS
and not detected to 0.09 μg/L for PFHxS. There were efforts in this community to use water from the
municipal wells that showed the least amount of contamination so the true concentration levels that the
population was exposed to are not known. The serum PFC geometric means in the Minnesota
community were as follows: PFOA (15.4 ng/mL), PFOS (35.9 ng/mL) and PFHxS (8.4 ng/mL) (MDH
2009).
However, other communities had higher drinking water PFC exposures and higher serum levels. In an
Ohio community exposed to PFOA-contaminated drinking water (average water level = 3.55 ng/mL,
Emmet 2006a), there was a median serum PFOA level of 354 ng/ml in the 371 participants (Emmet
2006b). This was much higher than was found in this EI (PFOA median 18.1 ng/mL). In a larger study
of 69,030 people in the same area of the Ohio/West Virginia border, exposed to PFOA contaminated
drinking water, (as well as food and possibly other sources), the median serum PFOA was 28.2 ng/mL
(Steenland 2009a). A German study of 355 exposed subjects who drank PFC-contaminated water
found a geometric mean serum PFOA of 25 ng/mL (Hölzer 2008). This community had a higher
geometric mean compared to participants in the Decatur, AL EI (17.59 ng/mL).
Finally, serum PFC concentrations in this investigation are much lower compared to occupational
exposures. For example, in 2000 a group of 3M employees in Decatur, Alabama voluntarily had PFC
measurements taken for medical surveillance. The geometric mean for serum PFOA in this group was
1,130 ng/mL and for serum PFOS the geometric mean was 440 ng/mL (Olsen 2003). Another study
reported that Dupont workers had a arithmetic mean of 428 ng/mL for serum PFOA with a median of
189 ng/mL (Sakr 2007).
A comparison of mean serum concentrations of PFOA and PFOS studies in relation to the mean serum
concentration in this Decatur, AL EI is displayed in Figures 12 and 13 (Appendix A). The studies used
for comparison include some where the effected population had drinking water exposure to PFCs as
well as two PFC occupational studies. Worker exposure routes are generally different from participants
in this EI. Occupational serum PFC concentrations are elevated compared to the general population.
In our investigation, serum PFC concentrations for PFOA, PFOS and PFHxS are moderately higher
than the U.S. population but similar to or lower than U.S. communities believed to be exposed
primarily through drinking water. Mean serum concentrations for five PFCs (PFNA, PFDeA, MePFOSA-AcOH, Et-PFOSA-AcOH, and PFOSA) observed in this investigation were lower than or
similar to the mean for the U.S. population (NHANES). PFC concentrations observed in this
investigation were much lower than levels found in occupational studies of PFC manufacturing
workers.
C. Serum Perfluorochemical Concentrations: Age and Gender
Age
We found that serum PFC concentrations had a small but significant association with increasing age
for all three PFCs – PFOA, PFOS and PFHxS. This has been previously reported by others with PFOA
contamination in drinking water (Emmett 2006a, Steenland 2009a, Minnesota 2010, Calafat 2007b). In
contrast, Kannan (2004) did not find a statistical association with PFOA and age in 473 serum samples
22

from industrialized countries. One study using pooled 2001-02 NHANES data found that most serum
PFC levels in the general population are higher in children ages 3-11 years years of age compared to
adults, especially for PFHxS (Kato 2009). More recent data on children under 12 years of age are not
available.
PFOA is not metabolized in the body and knowledge of its tissue distribution in humans is limited.
The half-life for each PFC varies in humans and is based on small samples sizes (n = 5-26) (Olsen
2007a, Harada 2005a). Based on these small studies, half-lives are estimated at 2-4 years (PFOA), 2-5
years (PFOS), and 7 years (PFHxS). In light of the limited understanding of the half-lives of these
chemicals, human pharmacokinetics, and inconsistency in published reports, the relationship of serum
PFOA concentration and age is unclear.
Gender
In agreement with previous reports, we found that men had higher serum PFC concentrations than
women, including couples residing at the same address. A Red Cross Donor study of 140 donors
found that men had higher serum PFOA levels than women. This study was a measure of population
background levels in a population with no known exposure (Olsen 2007). The Minnesota investigation
also found that men had significantly higher serum PFC concentrations than women. Other
investigators have reported similar results (Calafat 2007a, 2007b, Fromme 2007, Harada 2004,
Midasch 2006, Yueng 2006, Hölzer 2008). However, one study did not show a gender difference.
Kannan (2004) examined 473 serum PFOA samples from many industrialized countries and found no
significant differences in gender even though PFOA was detected in most samples.
The reason for a gender difference in PFC concentrations is unclear. Perhaps this observation may
represent gender differences in occupation, diet, lifestyle, loss during menstruation and lactation and/or
use of PFC containing products. Additional research is ongoing in a number of laboratories to try to
verify and better understand this observation.
D. Serum Perfluorochemical Concentrations and Environmental Variables
In this investigation, length of residence, soil exposure, proximity to fields which received biosolids
applications from Decatur Utilities, locally raised cattle meat consumption, and local vegetable
consumption did not show an association with serum PFC concentrations. In addition a review of
drinking water sources when looking at regulated water sources (all public water systems) as compared
to unregulated water sources (private well water) did not show a clear association with serum PFC
concentrations.
However, analysis of serum PFC levels in EI participants who regularly used the WM/EL public water
system as their primary drinking water source found that they had higher geometric mean serum levels
of PFOA, PFOS and PFHxs when compared to the geometric mean found in a national survey
(NHANES). In addition serum PFC levels in EI participants who regularly used the WM/EL public
water system as their primary drinking water source had significantly higher serum levels of PFOA
and PFHxS compared to NHANES than participants who were otherwise similar but reported using an
alternative water source that did not have a detectable level of PFCs. Serum PFOS among those who
regularly used the WM/EL public water system was also found to be higher than those participants
using an alternative water source compared to NHANES but was not significantly higher. Alternative
water sources include bottled water, private wells and other public water systems in the region that did
23

not have a documented detectable level of PFCs. This analysis suggests an association between the
detectable levels of PFCs in the drinking water from the WM/EL public water system and elevated
serum PFC levels among participants who used it as their primary drinking water source.
EI participants who used private drinking water wells that were found to have elevated levels of PFCs
as their primary drinking water source were also found to have elevated serum PFC levels that were
significantly higher than the general U.S. population as shown in Table 2.
In a population primarily exposed to PFCs from their drinking water supply, Emmet (2006a) found a
PFOA median serum/drinking water ratio of 105. Applying that same ratio to the participants in this EI
who used the WM/EL public water system as their primary drinking water source (median serum
PFOA of 18.1 ng/mL) results in the following estimate of PFOA level in the drinking water: 18.1/105
= 0.172 ng/ml (172 ng/L). The level of PFOA in finished water from the WM/EL public water system
in 2010 was found to be 0.070 ng/ml (70 ng/L). However there have been ongoing efforts by the
WM/El public water system to reduce PFOA in finished water over the past several years. Past
samples of finished water from 2006 (the first year that PFOA was evaluated) have been as high as
0.155 ng/ml (155 ng/L). This value is much closer to the expected value of 172 ng/L estimated by the
ratio proposed by Emmet and provides further indication that the presence of PFOA in WM/EL public
water system drinking water was a contributor to elevated serum PFOA levels in the EI participants
using this water source as their primary drinking water.
Limited published data is available on factors associated with serum concentrations of PFCs.
Although this investigation did not find a statistical association with environmental variables and PFC
serum concentrations other than drinking water source, others have reported positive correlations. In a
German population, increased serum PFOA concentrations were associated with eating locally grown
vegetables, drinking large quantities of PFC contaminated public water and residing in an area with
environmental contamination compared to a reference population (Hölzer 2008). A later publication
on the same population suggested an association between serum PFCs and fish consumption from PFC
contaminated water sources (Hölzer 2011). Emmett (2006a) reported a correlation between consuming
locally grown vegetables and wild game and serum PFC levels in an area with contaminated drinking
water. A study (Yoo et al., 2011) compared PFC concentrations in vegetation growing in fields treated
with and without biosolids in the Decatur, AL area. Results showed measurable concentrations of PFC
in the treated fields. There are additional studies looking at vegetative uptake of PFCs that are ongoing.
Trudel (2008) used environmental and product-related data, to include contaminated foods and
drinking water, in Europe and North America to model estimates of chronic exposure to PFOA and
PFOS. They conclude that ingestion of contaminated dietary sources, like drinking water, is the
greatest source of exposure in the general population. For those living near an identified source of
contamination, drinking water has been identified as associated with exposure (Emmett 2006a, Holzer
2008, Steenland 2009a). A study in Ohio found that activated carbon filtration in the drinking water
system reduced serum PFOA concentrations in the population (Bartell 2010). In addition to
implementing an activated carbon filtration system, Emmet (2006a) found that substitution with
bottled water resulted in lower levels of serum PFOA concentrations in a population exposed to PFOA
contaminated public water.
Participants who are outliers in this EI may provide additional insight into potential sources of
exposure from drinking water. For example, the highest serum PFOS concentration was 248 ng/mL
(NHANES 95th percentile: 47.5 ng/mL) and for PFHxS was 59 ng/mL (NHANES 95th percentile: 8.3
24

ng/mL) and both were detected in one individual. This person was over 80 years of age and had been
drinking private well water the majority of their life (they changed to public water the week that blood
was collected for this investigation). The water sampled from this well had PFOS levels above EPA’s
Provisional Health Advisory. Another participant who had the highest serum PFOA concentration
(144 ng/mL - NHANES 95th percentile: 11.3 ng/mL) was middle aged (age 40 – 50 years). This
person had been using the same private well water as their primary source of drinking water. Their
drinking water well had PFOA levels above EPA’s Provisional Health Advisory, so the residence was
connected to the public water system and the person no longer uses the well as a drinking water source.
In contrast, two participants from a residence connected to the WM/EL public water system reported
using bottled water almost exclusively for their drinking water source (they did use WM/EL public
water for cooking) and neither had any elevation in PFCs above the NHANES 95th percentile. They
lived next door to two other participants who were connected to and used the WM/EL public water
system as their primary drinking water source. The latter two participants had serum PFOA, PFOS and
PFHxS values above the NHANES 95th percentile. An elderly male EI participant (the group that
tended to have the highest levels of serum PFC’s) used a private well with no PFC contamination as
his primary drinking water source had serum PFOA, PFOS and PFHxS results below the NHANES
95th percentile.
Serum PFOA, PFOS and PFHxS levels were higher in participants who used the WM/EL public water
system as their primary drinking water source compared to those who used an alternative primary
drinking water source with non-detectable levels of these chemicals. The WM/EL group had twice the
amount of serum PFOA present on average than the alternative group and the geometric mean was
well above the NHANES 95th percentile. The alternative water supply group had an average PFOA
slightly above the NHANES 95th percentile but within its upper 95th confidence interval. The primary
limitation of this comparison was the relatively small number of participants, particularly in the
alternative drinking water source group (n=23). Although the geometric mean for the alternative group
was significantly less than the WM/EL group some members of the alternative group did have levels of
PFCs that were elevated well above the NHANES 95th percentile suggesting other factors could have a
role in the presence of elevated serum PFCs in this population.
Steps have already been taken to improve finished water produced by the WM/EL public water system
which has had a history of detectable levels of PFCs (2006 PFOA level – 155 ng/L, 2010 PFOA level –
70 ng/L). These levels have remained below the current EPA Provisional Health Advisory level. The
water intake for the WM/EL public water system is located downstream from the local PFC producing
industries. Other tested public water systems in Morgan, Limestone and Lawrence counties have not
demonstrated evidence of detectable levels of PFCs. Water intake for these public water systems is less
likely to be impacted by local PFC producing industries because the water intake is located upstream
from these industries or uses surface water reservoirs.
CONCLUSIONS
Because this investigation was designed to select individuals with the greatest likelihood of PFC
exposure, results cannot be generalized nor inferred to represent others living in the area or other
locations. The results of this investigation are applicable only to the individuals tested. In addition,
results of this EI cannot be used to predict the future occurrence of health effects or associations with
current or past health problems. Blood serum PFC concentrations do not provide information about the
source of exposure (i.e., water; soil; food; personal care and cleaning products; oil, stain, grease, and
25

water repellent coatings on carpet, textiles, and leather; ”non-stick” cookware; paper products such as
the wrappers used on fast food items).
Blood Serum PFC Concentrations
• Eight PFCs were measured in the blood of each participant.
– Five PFCs measured (PFNA, PFDeA, Me-PFOSA-AcOH, Et-PFOSA-AcOH and PFOSA)
were lower than or similar to the U.S. general population as defined by the 2005-06 NHANES
95th percentile for PFCs.
– Geometric mean levels for three PFCs (PFOA, PFOS and PFHxS) were elevated (about two to
four times) in participants compared to the U.S. general population, but were similar to or
lower than levels found in other U.S. communities exposed to PFCs via drinking water or other
environmental pathways.
– Of the three elevated serum PFCs, concentrations increased with age and were higher in males
than females.
– Serum levels of all eight PFCs measured in this investigation were much lower than levels
found in occupational studies of PFC manufacturing workers.
• Finding PFCs in blood does not imply that the levels of PFCs cause an adverse health effect. The
epidemiologic literature on the human health effects of PFCs is limited and the link between PFCs
in blood and health effects is not conclusive. See the discussion section for more information on
recent human studies.
Blood Serum PFC Concentrations and Environmental Survey
With the exception of drinking water source, this EI found no association or link between serum PFC
concentrations and potential PFC sources in the environment. The limited sample size may not have
been sufficient to determine a significant association between blood serum PFCs and exposures
through biosolids or consumption of local cattle, fish, and vegetables, all of which have been found to
be significant in other studies.
Although a link to fish and blood serum concentrations of PFCs was not found in this EI PFCs,
including both PFOA and PFOS, were detected in fish tissue samples taken from catfish and largemouth bass in the Tennessee River near Decatur. The PFOA analytical results averaged 0.74 ppb and
the PFOS analytical results averaged 806.06 ppb. Based on the PFOS results, the Alabama Department
of Public Health issued a 'no consumption' fish advisory in August 2012 for all species of fish in the
Baker's Creek embayment of Wheeler Reservoir. Future testing will determine if this advisory needs to
be expanded. The entire advisory can be found at www.adph.org.
Serum PFC levels in EI participants who regularly used the WM/EL public water system as their
primary drinking water source had significantly higher levels of PFOA and PFHxS compared to a
national survey (NHANES) than participants who were otherwise similar but reported using an
alternative primary water source with no detectable PFCs. Levels of PFOS were also higher, but not
significantly higher. Alternative water sources include bottled water, private wells and other public
water systems in the region that did not have a documented detectable level of PFCs. Results suggest
an association between PFCs in the WM/EL public water system and elevated serum PFC levels
among participants who used it as their primary drinking water source.
26

While serum PFC levels are not as high among participants using an alternative primary water source
with no detectable PFCs, they did have serum PFC levels that were at the high end of the range of
PFCs found in the general population with NHANES. This group of participants could be exposed part
of the time to drinking water from the WM/EL public water system. However, it is possible that other
exposure pathways are contributing to the level of serum PFCs that are present in addition to drinking
water with detectable levels of PFCs and that they were not identified by this EI.
RECOMMENDATIONS
•

Continue efforts to reduce the level of PFCs present in the Tennessee River which is used as
source water for the WM/EL public water supply system.

•

Continue monitoring for PFCs in the WM/EL public water supply and other potentially
impacted public water supplies downstream of Decatur, Alabama. The WM/EL public water
system has already taken steps to improve water treatment which is expected to reduce PFC
levels in finished drinking water. If PFOA and/or PFOS concentrations in the finished drinking
water of the WM/EL public water system increase and remain above the EPA’s Provisional
Health Advisory levels, we recommend that the public water system evaluate modifications to
their treatment processes to reduce contaminant levels.

•

Conduct routine periodic monitoring of other local area public water supplies for potential
contamination with PFCs. Although these water supplies are considered to be at a lower risk
for PFC contamination because of their location and have no detectable PFCs to date, it is good
public health practice to conduct routine periodic monitoring.

•

Owners of private drinking water wells located on or near biosolids application fields not
previously tested should consider conducting periodic monitoring for PFCs. If levels are
consistently above EPA’s Provisional Health Advisory levels, residents should use alternate
drinking water sources. Some private drinking water wells in the area were sampled quarterly
for a year and those that exceeded EPA’s provisional health advisory levels for PFOA/PFOS
were placed on public water. All other sampled wells did not exceed the provisional health
advisory levels.

•

The community’s exposure to PFCs is expected to decline because of the actions taken to
remove or decrease PFCs in the environment. Follow-up serum PFC testing in this community
should be considered to verify that serum PFC concentrations are declining and to identify
whether additional public health actions may be needed.

•

Continue providing the community with any new science about health effects of PFC exposure
as new information is documented.

27

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Steenland K, Jin C, MacNeil J, Lally C, Ducatman A, Vieira V, et al. 2009a. Predictors of PFOA levels
in a community surrounding a chemical plant. Environ Health Perspect 117: 1083–1088.
Steenland K, Tinker S, Frisbee S, Ducatman A, Vaccarino A. 2009b. Association of perfluorooctanic
acid (PFOA) and perfluoroctanesulfonate (PFOS) with serum lipids among adults living near a
chemical plant. Am J Epidemiol 170: 1268–1278
32

Steenland K, Fletcher T, and Savitz, D. 2010. Epidemiologic evidence on the health effects of
perfluorooctanoic acid (PFOA). Environmental Health Perspectives. 118 (8):1100-1108.
Taniyasu S, Kannan K, Horil Y, Hanari N, Yamashita N. 2003. A survey of perfluorooctane sulfonate
and related perfluorinated organic compunds in water, fish, birds, and humans from Japan. Environ Sci
Technol 37:2634-2639.
Trudel D, Horowitz L, Wormuth M, et al. 2008. Estimating consumer exposure to PFOS and PFOA.
Risk Anal 28(2):251-269.
U.S. EPA (Environmental Protection Agency). 2005. Draft Risk Assessment of the Potential for
Human Health Effects Associated with Exposure to Perflourooctanoic Acids and Salts. Available:
http://www.epa.gov/opptintr/pfoa/pubs/pfoarisk.pdf [accessed September 2010].
U.S. EPA (Environmental Protection Agency). 2009. Provisional Health Advisories for
Perfluorooctanoic Acid (PFOA) and Perfluorooctane Sulfonate (PFOS) Available:
http://www.epa.gov/region4/water/documents/d_pha_phoa_pfos_final_010809.pdf [accessed July
2011]
U.S. EPA (Environmental Protection Agency). 2011a Perflourochemical Contamination of Biosolids
Near Decatur, Alabama. Available: http://www.epa.gov/region4/water/PFCindex.html [accessed
November 2011]
U.S. EPA (Environmental Protection Agency). 2011b Release of Perflourochemicals (PFCs) from the
Dalton Utilities Loopers Bend Wastewater Treatment Plant (Dalton Utilities) in Dalton, Georgia.
Available: http://www.epa.gov/region4/water/PFCdaltonindex.html [accessed July 2011]
Washington, J. W.; Henderson, W. M.; Ellington, J. J.; Jenkins, T. M.; Evans, J. J. Analysis of
perfluorinated carboxylic acids in soils II: Optimization of chromatography and extraction. J.
Chromatogr. A 2008, 1181 (1-2), 21–32.
Washington, J. W.; Yoo, H.; Ellington, J. J.; Jenkins, T. M.; Libelo, E. L. Concentrations, distribution
and persistence of perfluoroalkylates in sludge-applied soils near Decatur, Alabama, USA. Environ.
Sci. Technol. 2010, 44 (22), 8390–8396.
Weston Solutions, Inc. Perfluorooctanoic Acid (PFOA) Site Related Environmental Assessment
Program, 3M Decatur, Alabama Site, Quarterly Status Report, Raw Data Volumes for July 25, 2007 to
August 2008, Volume 1. Prepared for 3M Company by Weston Solutions, Inc.
http://www.regulations.gov/#!documentDetail;D=EPA-HQ-OPPT-2004-0112-0124 [accessed January
2013]
Weston Solutions, Inc. Perfluorooctanoic Acid (PFOA) Site Related Environmental Assessment
Program, 3M Decatur, Alabama Site - Quarterly Status Report, April 1, 2012 to June 30, 2012.
Prepared for 3M Company by Weston Solutions, Inc.
http://www.regulations.gov/#!documentDetail;D=EPA-HQ-OPPT-2004-0112-0147 [accessed January
2013].
Yeung LWY, So MK, Jiang GB, Taniyasu S, Yamashita N, Song MY, et al. 2006.
33

Perfluorooctanesulfonate and related fluorochemicals in human blood samples from
China. Environ Sci Technol 40: 715–720.
Yoo, Hoon, John W. Washington, Thomas M. Jenkins, and J. Jackson Ellington, 2011. Quantitative
Determination of Perfluorochemicals and Fluorotelomer Alcohols in Plants from Biosolid-Amended
Fields using LC/MS/MS and GC/MS, Environ. Sci. Technol., Publication Date (Web): January 19,
2011.
Yoo, H.; Washington, J. W.; Ellington, J. J.; Jenkins, T. M.; Neill, M. P. Concentrations, distribution
and persistence of fluorotelomer alcohols in sludge-applied soils near Decatur, Alabama, USA.
Environ. Sci. Technol. 2010, 44 (22), 8397–8402.

34

AUTHORS
Prepared by:
Bruce C. Tierney, M.D.
Captain, U.S. Public Health Service
Medical Officer, Exposure Investigation Team
Science Support Branch
Division of Community Health Investigations
Agency for Toxic Substances and Disease Registry
Statistical analysis by:
Michael Lewin, M.S.
Senior Statistician
Division of Toxicology and Human Health Studies
Agency for Toxic Substances and Disease Registry
Field and logistical assistance by:
Jane Zhu, B.S.
Environmental Health Scientist
Division of Community Health Investigations (proposed)
Agency for Toxic Substances and Disease Registry
Ed Poolos
Alabama Department of Environmental Management
Decatur, Alabama
Connie Roberts
Environmental Protection Agency, Region 4
Atlanta, Georgia
Reviewed by:
Susan Metcalf, M.D., M.P.H.
Team Leader, Exposure Investigation Team
Science Support Branch
Division of Community Health Investigations
Agency for Toxic Substances and Disease Registry
Susan Moore, M.S.
Branch Chief
Science Support Branch
Division of Community Health Investigations
Agency for Toxic Substances and Disease Registry

35

Lynn Wilder, Ph.D., CIH
Associate Director of Science
Division of Community Health Investigations
Agency for Toxic Substances and Disease Registry
Tina Forrester, Ph.D.
Acting Division Director
Division of Community Health Investigations
Agency for Toxic Substances and Disease Registry
Clement Welsh, Ph.D.
Acting Deputy Director
Division of Toxicology and Human Health Studies
Agency for Toxic Substances and Disease Registry
Ken Orloff, Ph.D., DABT
Toxocologist, Exposure Investigation Team
Science Support Branch
Division of Community Health Investigations
Agency for Toxic Substances and Disease Registry
Acknowledgments:
Ketna Mistry, M.D. - ATSDR, Division of Community Health Investigations, Exposure Investigation
Team for contributions to protocol development and implementation.
Diane Jackson, B.S., P.E. - ATSDR, Division of Community Health Investigations for data entry.
Antonia Calafat, Ph.D. and staff - Centers for Disease Control and Prevention, National Center for
Environmental Health for PFC laboratory analysis.
U.S. Environmental Protection Agency (EPA), Region 4; Office of Research and Development; and
EPA, Office of Pollution Prevention and Toxics for providing background information of the area and
review of the report.

36

APPENDIX A: Figures

37

Figure 1: Serum Perfluorooctanoic Acid (PFOA) distribution

38

Figure 2: Serum Perfluorooctane Sulfonic Acid (PFOS) distribution

39

Figure 3: Serum Perfluorohexane Sulfonic Acid (PFHxS) Distribution

40

Figure 4: Serum Perfluorononanoic Acid (PFNA) Distribution

41

Figure 5: Log 10 Serum Perfluorooctanoic Acid (PFOA)

42

Figure 6: Log 10 Serum Perfluorooctane Sulfonic Acid (PFOS)

43

Figure 7: Log 10 Serum Perfluorohexane Sulfonic Acid (PFHxS)

44

Figure 8: Log 10 Serum Perfluorononanoic Acid (PFNA)

45

Figure 9: Linear Regression and 95% Confidence Limits of Log 10 Serum
Perfluorooctanoic Acid (PFOA) vs. Age

46

Figure 10: Linear Regression and 95% Confidence Limits of Log 10 of Serum
Perfluorooctane Sulfonic Acid (PFOS) vs. Age

47

Figure 11: Linear Regression and 95% Confidence Limits of Log 10 of Serum
Perfluorohexane Sulfonic Acid (PFHxS) Serum vs. Age

48

Figure 12 : Study Comparison of
Perfluorooctanoic Acid (PFOA) Mean Serum
Concentrations (ng/mL)
3M Workers
Dupont Workers
Little Hocking, OH
Ohio River Valley
Minnesota Pilot Study
Decatur, AL PFC Testing
Red Cross Blood Donors
U.S. Population
0

200

400

600

800

1000

1200

PFOA Mean Serum Concentration (ng/mL)
References: 3M Workers - Olsen 2003; Dupont - Sakr 2007; Little Hocking, OH - Emmet 2006a,b; Ohio River Valley - Steenland
2009; Minnesota Pilot Study - MDH 2009; Red Cross Blood Donors - Olsen 2008; U.S. Population - CDC/NHANES 2010

49

Figure 13: Study Comparison of Mean
Perfluorooctane Sulfonic Acid (PFOS) Serum
Concentrations (ng/mL)
3M Workers
Minnesota Pilot Study
Decatur, AL PFC Testing
Red Cross Blood Donors
US Population
0

100

200

300

400

500

PFOS Mean Serum Concentration (ng/mL)

References: 3M Workers - Olsen 2003; Minnesota Pilot Study - MDH 2009; Red Cross Blood Donors - Olsen 2008; U.S.
Population - CDC/NHANES 2010

50

APPENDIX B: Tables

51

Table 1B: List of Perfluorochemicals (PFCs) measured listed by
abbreviation, chemical name and limit of quantitation (LOQ).
Abbreviation
Chemical Name
PFOA
PFOS
PFHxS
PFNA
PFDeA
Me-PFOSA-AcOH
Et-PFOSA-AcOH
PFOSA

LOQ
(ng/mL)

Perfluorooctanoic acid
Perfluorooctane sulfonic acid
Perfluorohexane sulfonic acid
Perfluorononanoic acid
Perfluorodecanoic acid
2-(N-methyl-Perfluorooctane sulfonamido) acetic acid
2-(N-ethyl-Perfluorooctane sulfonamido) acetic acid
Perfluorooctane sulfonamide

0.1
0.2
0.1
0.1
0.2
0.2
0.2
0.1

Table 2B: Description of survey data collected for participants.
(n=153)
Survey Variable
Count
Percent
Age
0-29 years

23

15.0

30-59 years

67

43.8

60+ years

62

40.5

Not reported

1

0.7

6 months-1 year

4

2.6

2-5 years

20

13.1

6-10 years

23

15.0

11-20 years

24

15.7

21-30 years

22

14.4

31-40 years

20

13.1

>40 years

39

25.5

Unknown

1

0.7

Never

16

10.5

Daily

30

19.6

Weekly

68

44.4

Monthly

18

11.8

Yearly

13

8.5

Seasonal

5

3.3

Unknown

3

2.0

Length of residence

Frequency of working on soil on home property

52

Table 2B (cont.): Description of survey data collected for participants (n=153)
Wear gloves while working in soil on home property
Never Do This

47

30.7

Seldom Do This

41

26.8

Sometimes Do This

41

26.8

Always Do This

5

3.3

Unknown

19

12.4

Never

11

7.2

Daily

58

37.9

Weekly

55

35.9

Monthly

21

13.7

Other

2

1.3

Unknown

6

3.9

Never

78

51.0

Daily

3

2.0

Weekly

25

16.3

Monthly

11

7.2

Yearly

5

3.3

Don’t Know

29

19.0

Unknown

2

1.3

Never

67

43.8

1-3 meals/month

37

24.2

4-6 meals/month

15

9.8

7-9 meals/month

9

5.9

10 or more meals/month

2

1.3

Unknown frequency/month

23

15.0

Regulated (public water source)

128

83.7

Unregulated (private well, community well, spring)

14

9.1

Bottled

11

7.2

Frequency of consuming locally grown fruits & vegetables

Frequency of consuming domestically raised cattle

Consume fish caught from local rivers, ponds, and lakes

Major source of current drinking water

53

Table 3B: Blood serum geometric mean and range for eight perfluorochemicals measured
compared to NHANES geometric mean (ng/mL) and 95th percentile
NHANES
EI#
NHANES
Limit of
EI
Geometric Mean
th
PFC
Geometric
95
Detection
Range
(CI##)
Mean
Percentile
(2005-06)**
PFOA
16.3
2.2 - 144
3.92 (3.48 – 4.42)
11.3
0.1
PFOS
39.8
5.4 - 472
17.1 (16.0 – 18.2)
47.5
0.2
PFHxS
6.4
0.6 - 59.1
1.67 (1.42 – 1.98)
8.3
0.1
PFNA
1.7
0.3 - 5.5
1.09 (0.91 – 1.29)
3.6
0.1
Et-PFOSA-Acoh
*
0.2 - 0.2
*
0.3
0.2
Me- PFOSA-Acoh
0.4
0.2 - 4.8
0.47 (0.43 - 0.52)
1.8
0.2
PFDeA
0.4
0.2 - 2.5
0.36 (0.30 - 0.42)
1.5
0.2
PFOSA
*
0.1 - 0.1
*
0.3
0.1
*Not calculated: proportion of results below limit of detection was too high to provide a valid result.
**NHANES, the National Health and Nutrition Examination Survey, is a population-based survey
designed to collect information on the health and nutrition of the U.S. household population.
#
EI refers to this “exposure investigation” conducted in the Decatur, Alabama area
Note: The limit of detection for this investigation was the same as NHANES.
##
CI = 95% Confidence Interval

Table 4B : Pearson correlation coefficients (Log10) between PFOA, PFOS, PFHxS and
PFNA (n=153)
PFOA
1
PFOA
0.76
PFOS
0.85
PFHxS
0.58
PFNA
p<0.0001 for all correlations

PFOS

PFHxS

PFNA

1
0.81
0.66

1
0.58

1

Table 5B: Linear regression results of log-transformed Perfluorochemical (PFC) concentrations
and survey variables*
Variable
log PFOA
log PFOS
log PFHxS
2
2
2
R
β
P value
R
β
P value R
β
P value
Age

0.182

0.009

<0.0001

0.313

0.011

Sex

0.039

-0.153

0.014

0.056

-0.175

0.003

0.009

<0.0001

0.011

<0.0001

-0.137

0.016

-0.158

0.001

Age &
Sex**

Age
Sex

0.214

0.358

<0.0001 0.262
0.067
0.318

0.010

<0.0001

-0.199

0.001

0.010

<0.0001

-0.183

0.001

* Multiple linear regression was initially done with all survey variables for each PFC. Only age and
sex were found to be significant. Both age and sex were significant for each PFC.
** Males=0, Females=1

54

APPENDIX C: Exposure Investigation Protocol

55

Exposure Investigation Protocol

Perfluoroalkyl Serum Sampling
Near Decatur, Alabama
Morgan, Lawrence and Limestone Counties

November 6, 2009

Prepared by

Agency for Toxic Substances and Disease Registry
Atlanta, Georgia

56

Exposure Investigation
An exposure investigation (EI) is not a study. It is a biased attempt to determine if exposure is
occurring among a potentially highly exposed group of individuals. This investigation has received an
IRB exemption because it is not considered research. Its primary intent is public health practice.

Background
Introduction
In 2007, a Perfluoroalkyl (PFC) manufacturer in Decatur, Alabama notified the Environmental
Protection Agency (EPA) that it had unknowingly discharged PFCs into the Decatur Utilities
wastewater treatment plant. Sewage sludge from the Decatur wastewater treatment plant was applied to
agricultural fields. This action led EPA to initiate an investigation to determine if the biosolids from
the treatment plant were contaminated and if land application had resulted in a potential discharge of
PFCs to the environment.
The Decatur Utilities plant receives wastewater from domestic and industrial sources, including
fluorochemical manufacturing and use facilities in the area. Municipal sewage sludge from this facility
was land applied to approximately 5000 acres of privately owned agricultural fields for approximately
12 years. To date, EPA has identified four direct sources of PFCs to the Decatur Utilities Plant: the 3M
Company, Daikin America, Inc., Toray Fluorofibers America, Inc., and the Morgan County Landfill
leachate.
PFCs are used in a variety of industrial and consumer applications and products, including fire-fighting
foams; personal care and cleaning products; and oil, stain, grease, and water repellent coatings on
carpet, textiles, leather, and paper (ATSDR 2009). Perfluorooctyl sulfonate (PFOS) is no longer
manufactured in the United States.
PFCs are not currently regulated by EPA and the testing of biosolids for these chemicals is typically
not required. EPA has not established an action level for PFOA or PFOS in soil or sewage sludge.
ATSDR has not established a minimal risk level (MRL) for PFCs due to the paucity of human data in
the scientific literature.
EPA recently developed drinking water provisional health advisory levels for two of the PFCs,
perfluorooctanoic acid (PFOA), and PFOS. The provisional health advisory level for PFOA is 0.4 parts
per billion (ppb) [micrograms per liter (ug/L)] and the provisional advisory level for PFOS is 0.2 ppb.
Soil sampling
In 2007, EPA conducted limited sampling of soil and sludge samples from two biosolid agricultural
application sites and from the Decatur Utilities facility. In 2008, the results indicated relatively high
levels of PFOA and PFOS compared to other industrial and non-industrial sites. The two soil sampling
sites showed PFOS ranging from 589 to1296 ppb [micrograms per kilogram (ug/kg)] and PFOA
ranging from 55 to 2531 ppb in the nine soil samples. The Decatur Utilities ceased land application of
biosolids after learning of these PFC levels in its biosolids.
57

In March 2009, EPA collected 30 soil samples in or near the fields with the highest applications of
biosolids. The results indicate that the majority of the Decatur soils in the land application area have
concentrations of numerous PFCs above the background levels. Concentrations of PFOA range from
non-detect up to 312 ppb with most concentrations in the 100 to 200 ppb range. Concentrations of
PFOS range from non-detect up to 325 ppb with most concentrations around 100 to 200 ppb.
Concentrations of ten carbon PFCs (C10) are as high as 986 ppb and concentrations of 12 carbon PFCs
(C12) are as high as 526 ppb.
Water sampling
In November 2008, water samples were collected for PFCs analysis. There were non-quantifiable
levels of PFCs in two of the three public water systems (Moulton and Decatur). Levels of PFCs
detected in the East Lawrence/West Morgan system were at levels below EPA’s provisional health
advisory levels of 0.4 ppb for PFOA and 0.2 ppb for PFOS in drinking water. Based on its current
understanding, EPA believes these levels are not of concern and residents may rely upon public water
systems.
In February 2009, 51 water samples were collected from ground water wells, ponds, and a stream in or
near the fields that received the highest applications of biosolids. The final report indicated the
following results:
• Two of six private drinking water wells sampled had PFOA levels above EPA’s provisional health
advisory level and none had levels above the PFOS provisional health advisory levels. These two
wells had PFOA levels of 2.2 ppb and 0.6 ppb respectively. Both of these residences with elevated
PFOA levels were quickly provided with bottled water and connected to the public water supply
system by Decatur Utilities and a group of local industries in the area.
• The final ground water sampling results from the 13 other water wells for PFOA ranged from no
detectable levels to 6.41 ppb and for PFOS ranged from no detectable levels to 0.15 ppb. These
wells serve as a water supply for livestock, gardens, and lawns.
• The final surface water sampling results from 32 ponds and one stream for PFOA ranged from no
detectable levels to 11.0 ppb and for PFOS ranged from no detectable levels to 0.08 ppb.
All soil and water sampling data collected can be obtained from the following website:
http://www.epa.gov/region4/water/PFCindex.html.

Perfluoroalkyls and health effects
PFCs have been found in the environment, in wildlife and in the blood of the general population
(Calafat 2006a, 2007, Kannan 2004, Taniyasu 2003).
In one population with environmental exposure to PFOA contaminated drinking water, no definite
association between PFC exposure and adverse health effects was observed (Emmett 2006b). Some
human studies report associations with lower birth weight (Apelberg 2007, Fei 2007), higher
cholesterol (Sakr 2007a, 2007b), and changes in liver function (Olsen 2007), however the effects are
relatively small.

58

In occupational studies, no definite association has been established between PFOA/PFOS and adverse
health effects (Leonard 2007, Grice 2007, Olsen 2004a, Alexander 2003, Gilliland and Mandel 1993).
In animals, adverse health effects have been demonstrated with PFOA/PFOS exposure (Kennedy
2004, Lau 2004) but at doses that are orders of magnitude higher than has been observed in the general
human population (Butenhoff 2004, Luebker 2005). In addition, extrapolation from animals to humans
is highly uncertain because of pronounced differences in elimination rates, substantial variability
across species and other issues (ATSDR, 2009).
Exposed population
The exposed population in the Decatur area includes residents who live and work in a predominantly
rural community. There are approximately 179 fields on approximately 35 farms that received
contaminated biosolids. People that work in these fields are exposed to contamination by way of direct
contact, air and dust inhalation, and in some cases, drinking water and food consumption (home grown
vegetables, beef from locally raised cows that may consume PFC contaminated water, and fish from
ponds contaminated with PFCs).
Two families have been drinking water from private water wells that exceeds EPA’s Provisional
Health Advisory. Many community members receive their drinking water from the East
Lawrence/West Morgan public water supply system. While the concentrations of PFOA and PFOS are
below EPA’s PHAs, this system has detectable current levels of PFOA in the 0.025 ppb range and
PFOS also at the 0.025 ppb range.
In a German population, increased PFOA concentrations were associated with eating locally grown
vegetables, drinking large quantities of public water and residing in an exposed versus non-exposed
area (Holzer 2007). Emmett (2006a) reported a correlation between consumption of locally grown
vegetables and wild game and human blood levels in an area contaminated with PFC.

Project Overview
A. Purpose
The purpose of this Exposure Investigation (EI) is to determine if unusual exposure to PFCs is
occurring by collecting serum samples from people with a high potential of exposure. An exposure
investigation is not a study. It is a biased attempt to determine if exposure is occurring among a
potentially highly exposed group of individuals. If unusual exposure is documented in an EI, then
additional public health activities may be initiated. Participants will be recruited based on two
exposure factors:



Living on or near soil with elevated levels of PFCs or
Drinking water contaminated with elevated PFCs from private wells or from chronic exposure
to low level PFCs from the East Lawrence/West Morgan public water supply system

ATSDR will utilize EPA soil and water sampling data to focus recruitment efforts of residents with
soil and water exposures. ATSDR will protect the privacy of all individual information provided by
EPA. Participants will be asked about local vegetable and meat consumption to address other exposure
59

pathways. ATSDR will test up to 200 volunteers.
The results of the EI will help individual participants better understand the magnitude of their sitespecific environmental exposures to PFCs. In addition, the results of the EI will assist EPA in deciding
the appropriate course of action at this site. Because these contaminants are not currently regulated by
EPA, the course of follow-up (or remedial) action is not clearly defined by existing regulations. A
detection of unusually high exposures in this investigation would support and provide further impetus
for further site investigation. Unusually high exposures would also clearly signal the need for
communication to residents on ways to reduce their exposure, and minimize risk to their health.
If the EI indicates that exposures are no higher that what is considered to be normal or usual exposures
to PFCs, community residents could be reassured that their risk of exposure is no greater than that of
the general population. This information would also be useful to EPA’s decision-making process and
would provide information about the merit of conducting further site characterization and remedial
action, if needed.
The results of this investigation will be applicable only to the individuals tested and cannot be
generalized to other populations. In addition, results of this exposure investigation cannot be used to
predict the future occurrence of disease nor be associated with current health problems.
B. Investigators and collaborators
The ATSDR will be the lead agency for this investigation. The EPA and Alabama Department of
Environmental Management (ADEM) will be collaborators in this investigation.
ATSDR will:









Contact and recruit eligible participants
Provide and pay for all collection supplies and equipment
Make arrangements and pay for the use of blood collection centers
Make a arrangements and pay for phlebotomists at the blood collection centers
Arrange and fund laboratory analyses of the biological samples
Coordinate blood sampling and sample shipment
Provide participants with an interpretation of their individual results
Write a report that summarizes the findings of the investigation

EPA/ADEM will:
 Assist ATSDR in recruiting participants
 Provide assistance with logistical organization
 Provide field assistance, if needed

Methods
A. Eligibility criteria
This exposure investigation targets a specific population in the Decatur area. A maximum of 200
60

residents will be offered blood testing. Participants must meet all eligibility requirements to participate
in this investigation. A full-time resident who meets the all the following criteria is eligible to
participate in this investigation:
 Is 12 years of age and older
 Lives on or near property with elevated levels of PFCs in soil and/or is exposed to drinking
water contaminated with PFCs from private wells or low level exposure from a public water
system (as defined by EPA sampling)
 Has lived on current property for at least one year
 Does not have a bleeding disorder or is anemic
 Does not have current or past occupational (industrial) exposure to PFCs
Participants who have soil or sludge exposure will be recruited first because data regarding soil
exposure in humans to PFCs is not available. After all available soil exposure participants have agreed
to participate in the investigation, participants with drinking water exposure will be recruited next until
a maximum of 200 participants has been reached. Residents with known private well exposure to PFCs
will be given priority to participate in the investigation compared to residents drinking from a public
water supply with PFC concentrations below the PHA. The age criteria (12 years of age and older) is
used because the reference values to be used for comparison in this investigation are only available for
children 12 and older (Calafat et al. 2007).
B. Recruiting participants
On December 1, 2009, staff from ATSDR/EPA and other government agencies will hold a public
meeting with the residents to inform them of the investigation and participation criteria. Community
members will be informed that families that live on or near property with elevated levels of PFCs or
have current or past exposure to PFC from drinking water will be sent a letter. The letter will provide
information about the investigation and a
1-800 number for participants to call and make an appointment for a blood draw.
During the week of April 12-15, 2010, ATSDR will meet with eligible participants at the designated
blood collection center. ATSDR staff will further explain the investigation, answer questions, and
obtain written informed consent/assent prior to blood collection.
C. Sample collection, informed consent, and survey
Participants in the investigation will be instructed to make an appointment at a blood collection center
to have a blood sample drawn. At the blood collection center, each adult participant will be required to
sign an informed consent form. Children ages 12 to 17 will also be required to sign an assent form
with the consent of their guardian. Copies of these forms are attached. (Attachment A).
Each participant will be asked to complete a short survey (Attachment B). Each participant will be
asked a few questions to gather information on risk factors for exposure to PFCs through food
pathways, contact with contaminated soil, or local well water use. The total time it will take
participants to read through consent/assent forms, respond to a brief survey, and provide a blood
specimen is estimated to be approximately 15 minutes.
A nurse/technician will collect a 5-ml blood sample in a tube by venipuncture. Blood samples will be
61

collected 4 days/week, Monday through Thursday, for one week. For one night, Tuesday, the blood
collection location will be open from 6-8 pm, to accommodate people who are not available during the
day.
D. Sample handling and shipping
Each tube will be labeled with a preprinted bar-coded label associated with the participant. A
collection log will also be maintained. Then each sample tube will be placed upright in a rack. This
will allow the blood to clot for a minimum of 30 minutes, preferably as much as 2 hours to create
maximum serum yield.
After the contents in the tube have clotted, each will be placed inside storage boxes provided by the
laboratory. Each box will be placed inside a plastic Saf-T-Pak™ biohazard bags along with an
absorbent pad and sealed. This plastic bag will be placed inside a larger Tyvek® bag and sealed. The
bagged specimen boxes will be placed inside a Styrofoam shipping container. Dry ice will be added to
the shipper. The blood samples will be shipped overnight on dry ice to the National Center for
Environmental Health (NCEH) Laboratory in Atlanta, Georgia. ATSDR staff will maintain and
manage proper chain of custody for all blood samples.
E. Lab processing and analysis
Blood samples will be analyzed for twelve perfluoroalkyls. Test results will be reported as nanograms
of the PFC analyte per liter of blood (ng/mL). All laboratory analysis will be conducted with
established procedures for quality assurance and control. Details of the laboratory processing, analysis
methods, quality assurance and quality control measures are available at
http://www.cdc.gov/nchs/data/nhanes/nhanes_05_06/pfc_d_met.pdf .
Table 1 provides the list of the 12 PFCs to be measured in this investigation. Table 2 provides the
limits of detection for each PFC to be measured in this investigation.

Table 1: List of PFCs to measured in this investigation - abbreviation
and associated chemical name.
Abbreviation
PFOSA
Me-PFOSA-AcOH

PFHpA

Chemical Name
Perfluorooctane sulfonamide
2-(N-methyl-Perfluorooctane sulfonamido)
acetic acid
2-(N-ethyl-Perfluorooctane sulfonamido)
acetic acid
Perfluorobutane sulfonic acid
Perfluorohexane sulfonic acid
Perfluorooctane sulfonic acid
Perfluoroheptanoic acid

PFOA
PFNA

Perfluorooctanoic acid
Perfluorononanoic acid

Et-PFOSA-AcOH
PFBuS
PFHxS
PFOS

62

PFDeA
PFUA
PFDoA

Perfluorodecanoic acid
Perfluoroundecanoic acid
Perfluorododecanoic acid

Table 2: Limit of Detection (LOD) for each PFC to be
measured in serum.
Analyte

LOD (ng/mL)

PFOSA
Me-PFOSA-AcOH
Et-PFOSA-AcOH
PFBuS
PFHxS
PFOS
PFHpA
PFOA
PFNA
PFDeA
PFUA
PFDoA

0.1
0.1
0.1
0.1
0.1
0.2
0.4
0.1
0.1
0.2
0.2
0.2

F. Confidentiality
Confidentiality will be protected to the fullest extent possible by law. Any reports produced from this
information will give only group information and not identify specific individuals. Confidential
information will be kept in locked cabinets at ATSDR or on a password-protected computer. Only if a
participant consents, the test results may be released only to other federal, state and local public health
and environmental agencies. These agencies must also protect this confidential information.
G. Data management, analysis and interpretation
Serum PFC results will be electronically transmitted from NCEH to ATSDR in spreadsheet format. No
personal identifiers will be included in the spreadsheet. Data quality assurance and quality control will
be performed by the NCEH laboratory.
National values for twelve PFC analytes are available from the National Health and Nutrition
Examination Survey NHANES 2003-2004 (Calafat et al. 2007) and are considered to be national
measures of exposure for the general US population. The 95th percentile for each PFC serum
concentration will be used as a comparison value.
H. Reporting of results
Individual test results with a written explanation of their meaning will be provided to the participants
63

six months after blood is collected. ATSDR will author the letters. Following dissemination of
individual results, an ATSDR physician will be available to discuss individual questions by phone.
Recommendations for follow-up actions will be made, if warranted.
Individual test results will not be made available to the public, and confidentiality will be protected
according to Federal and State laws. At the conclusion of the investigation, ATSDR will prepare a
report summarizing the findings of the investigation, but will not reveal personal identifiers.
I. Limitations of exposure investigation
PFC serum concentrations cannot be used to predict the future occurrence of disease nor be attributed
to current health problems. Serum PFC concentrations will not necessarily provide information about
the source of exposure (i.e. water, soil, food etc.). The results of this investigation will be applicable
only to the individuals tested and can not be generalized to other populations.
J. Risks and benefits to participants
Risks
A risk to participants of this investigation is the possibility of bruising from collecting a blood sample.
Benefits
The potential benefit to the participant is that they will learn the amount of PFCs that are present in
their serum. They will also be provided an interpretation of this result by a health care professional
who can advise on preventative actions to reduce current or future exposure to PFCs.
As more studies are conducted, a better of understanding of PFC serum concentrations and associated
health effects may be demonstrated in the future. If PFC associated health effects are demonstrated in
the future, the PFC measurements in this investigation may inform and guide future health care issues
in the participant.

64

References
Alexander BH, Olsen GW, Burris JW, Mandel JH, Mandel JS 2003. Mortality of employees of a
perfluorooctanesulphonyl fluoride manufacturing facility. Occup Environ Med 60:722-729.
Agency for Toxic Substance and Disease Registry (ATSDR). Toxicological Profile for Perfluoroalkyls
(Draft for Public Comment) October 30, 2009. Agency for Toxic Substances and Disease Registry.
Atlanta, GA: U.S. Department of Health and Human Services, Public Health Services.
Apelberg BJ, Witter FR, Herbstman JB, Calafat Am, Haiden RU, Needham LL et al. 2007. Cord serum
concentrations of perfluorooctane sulfonate (PFOS) and perfluorooctanoate (PFOA) in relation to
weight and size at birth. Envirn Health Perspect 115:1670-1676.
Butenhoff JL, Kennedy GL, Frame SR, O’Connor JC, York RG 2004. The reproductive toxicology of
ammonium perfluorooctanoate (APFO) in the rat. Toxicology. 196:95-116.
Calafat AM, Wong LY, Zsuzsanna K, Reidy JA, Needham LL. 2007. Polyfluoroalkyl
chemicals in the U.S. population: Data from the National Health and Nutrition
Examination Survey (NHANES) 2003-2004 and Comparisons with NHANES 19992000. Environmental Health Perspectives. 115 (11): 1596-1602.
Calafat AM, Kuklenyiz Z, Caudill SP, Reidy JA, Needham LL. 2006a.
Perfluorochemicals in pooled serum samples from United States residents in 2001 and
2002. Environ Sci Technol 40:2128-2134.
Emmett EA, Zhang H, Shofer FS, Freeman D, Rodway NV, Desai C, et al. 2006b.
Community exposure to perfluorooctanoate: Relationships between serum levels and
certain health parameters. J Occup Environ Med 48:771-779.
Fei C, McLaughlin JK, Tarone RE, Olsen J. 2007. Perfluorinated chemicals and fetal
growth: a study within the Danish National Birth Cohort, Environmental Health
Perspectives. 115:1677-1682.
Gilland FD and Mandel JS. 1993. Mortality among employees of a perfluorooctanoic
acid production plant. J Occup Med 35(9):950-954.
Grice MM, Alexander BH, Hoffbeck R, Kampa DM. 2007. Self reported medical
conditions in perfluoroooctanesulfonyl fluoride manufacturing workers. J Occup Environ
Med 49:722-729.
Holzer J, Midasch O, Rauchfuss K, Kraft M, Reupert R, Angerer J, et al. 2008. Biomonitoring of
perfluorinated compounds in children and adults exposed to perfluorooctanoate-contaminated drinking
water. Environ Health Perspect. 116:651-657.

65

Kannan K, Corsolini S, Falandysz J, Fillmann G, Kumar KS, Loganathan BG et al. 2004.
Perfluorooctanesulfonate and related fluorochemicals in human blood from several countries. Envrion.
Sci Technol 38:4489-4495.
Kennedy GL, Buttenhoff JL, Olsen GW, O’Connor JC, Seacat AM, Perkins RG et al 2004. The
toxicology of perfluorooctanoate. Crit Rev Toxicol 34:351-384.
Lau C. Buttenhoff JL, Rogers JM. 2004. The developmental toxicity of perfluoroalkyl acids and their
derivatives. Toxicol Appl Pharmacol 198:231-241.
Leonard RC, Kreckman KH, Sakr CJ, Symons JM. 2007. Retrospective cohort mortality study of
workers in a polymer production plant including a reference population of regional workers. Ann
Epidemiol 18:15-20.
Luebker DJ, York RG, Hansen KJ, Moore JA, Butenhoff JL. 2005. Neonatal mortality from in utero
exposure to perfluorooctanesulfonate (PFOS) in Sprague-Dawly rats: Dose-response, biochemical and
pharmacokinetic parameters. Toxicology. 215:149-169.
Olsen GW, Burlew MM, Marshall JC, Burris JM, Mandel JH. 2004a. Analysis of episodes of care in a
perfluorooctanesulfonyl fluoride production facicility. J Occup Environ Med. 46:837-846.
Olsen GW, Mair DC, Reagen WK. 2007. Preliminary evidence of a decline in
perfluorooctanesulfonate (PFOS) and perfluorooctanoate (PFOA) concentrations in American Red
Cross blood donors. Chemosphere 68:105-11.
Sakr CJ, Kreckmann KH, Green JW, Gillies PJ, Reynolds JL, Leonard JC. 2007a. Cross-sectional
study of lipids and liver enzymes related to a serum biomarker of exposure as part of a general health
survey in a cohort of occupationally exposed workers. J Occup Environ Med 49:1086-1096.
Sakr CJ, Leonard RC, Kreckmann KH, Slade Md, Cullen MR. 2007b. Longitudinal study of serum
lipids and liver enzymes in workers with occupational exposure to ammonium perfluorooctanoate. J
Occup Environ Med 49:872-879.
Taniyasu S, Kannan K, Horil Y, Hanari N, Yamashita N. 2003. A survey of perfluorooctane sulfonate
and related perfluorinated organic compunds in water, fish, birds, and humans from Japan. Environ Sci
Technol 37:2634-2639.

.

66

Attachment A: Consent Forms

67

U.S. Department of Health and Human Services
Agency for Toxic Substances and Disease Registry

PFC Exposure Investigation
Adult Consent Form

Place ID # sticker
HERE
For office use
only

Who are we and why is this blood test being offered to me?
We are from the Agency for Toxic Substances and Disease Registry (ATSDR), a federal public health
agency based in Atlanta. We are inviting you to have a blood test for a family of chemicals called
Perfluoroalkyls (PFC). We are offering this test to find out how much of these chemicals is getting into
your body.
The Environmental Protection Agency has found these chemicals in soil fields treated with sewage
sludge from the local wastewater treatment plant. People that work or live near these fields may come
into contact with these chemicals. Some private drinking water wells have been contaminated with this
chemical. Recent tests in one public water system have found these PFC chemicals at levels below
current guidelines. PFCs can be found in consumer products like non-stick cookware, paper coatings,
stain-resistant carpets, nail polishes and fire-fighting foam. The effect on human health from PFC
chemicals in not known; more research is needed.
What is involved in this blood testing?
In this test, a 5 ml sample of blood (about 1 teaspoon) will be collected from a vein in your arm. The blood
sample will be tested for 12 different types of PFC chemicals. If you are anemic (low blood) or have a
bleeding disorder then we will not be able to sample your blood.
Your blood sample will be sent to a lab for testing. We will mail you the test results 6 months after
testing, but some delays might occur. In some cases, we may ask you to repeat the test for chemicals in
your blood. You may share these results with your doctor - it is your choice.
What are the benefits from being involved in this testing effort?
By being part of this testing effort, you will find out how much of the PFC chemicals is present in your
blood. If the tests show high levels of PFC, you will get tips on how to avoid current and future
exposure to PFC chemicals. We will give you written information about PFC chemicals.
Scientists do not know how PFC levels in the blood can affect a person’s health; more research is
needed. We will not be able to tell you if the PFC levels in your blood will make you sick now or later
in life. We will not be able to tell you from where or how the PFC chemicals entered your body. No
68

medical diagnosis, treatment, or additional testing will be offered from this testing effort.
This testing is free for you.

What are the risks of being tested?
There may be some bruising in the bend in your elbow where the blood sample is collected.
What about my privacy?
We will protect your privacy as much as the law allows. We will give you an identification (ID)
number. This number, not your name, will go on the blood sample. We will not use your name in any
report we write. We will keep a record of your name, address, and ID number so that we can send you
the test result. We keep all records with your name on them in a locked file cabinet or in a passwordprotected computer file.
Who do I contact if I have questions?
If you have any questions about this testing, you can ask us now. If you have questions later, you can
call Dr. Ketna Mistry of ATSDR toll-free at 1-866-448-0242.
Voluntary Consent
I agree to be tested. I have been given a chance to ask questions and feel that all questions have been
answered. I know that being in this testing is my choice. I know that after choosing to be in this
testing, I may leave it at any time.
SIGNATURE
I have read this form or it has been read to me. I have had a chance to ask questions about this testing
and my questions have been answered. I agree to be a part of this testing.
________________________________________________
Participant - Printed Name
________________________________________________
Participant - Signature

______________
Date

May we share these test results with other Federal and State health and environmental agencies? YES
or NO (Circle One)
Address:

____________________________________________
____________________________________________
____________________________________________

Phone - Home #:

__________________ Phone - Cell #:

______________
69

U.S. Department of Health and Human Services
Agency for Toxic Substances and Disease Registry

PFC Exposure Investigation
Assent Form for Children
(12-17 Years)

Place ID # sticker
HERE
For office use
only

Who are we and why are we doing this blood testing?
We are from the Agency for Toxic Substances and Disease Registry (ATSDR), a federal public health
agency, based in Atlanta. We are inviting you to have your blood tested for a family of chemicals
called Perfluoroalkyls (PFC). You will find out how much of the PFC chemicals is in your blood.
These chemicals have been found in soil fields treated with sewage sludge from the local wastewater
treatment plant. People that work or live near these fields may come into contact with these chemicals.
These chemicals have also been found in some private wells and low amounts in one water system.
Scientists don’t know how these chemicals can affect a person’s health.
What is involved in this blood testing?
In this test, a 5 ml sample of blood (about 1 teaspoon) will be taken from a vein in your arm. If you are
anemic (low blood) or have a bleeding disorder then we will not be able to take your blood.
What are the benefits from being involved in this testing effort?
By being part of this testing effort, you will find out how much PFC chemicals is in your blood. We
will give you written information about PFC chemicals.
We will not be able to tell you if the PFC levels in your blood will make you sick now or later in life.
We will not be able to tell you from where or how the PFC chemicals got into your body.
This testing is free for you.
What are the risks of being tested?
There may be some bruising in the bend in your elbow where the blood sample is collected.
Assent
Your parents/guardian said it is all right for you to have this test. You don’t have to get tested if you
don’t want to.

70

What if I have questions?
If you have questions, you can ask us now. You can talk with your parents if you want. If you have
questions later, ask your parent. They can call us for answers.
SIGNATURE
I have talked with someone about this test. I asked questions, if I wanted to. I agree to be part of this
testing.
__________________________________________
Signature of Minor

______________________
Date

__________________________________________
Printed Name of Minor
____________________________________________________
Signature of Parent/Guardian
________________________________________________
Printed Name or Parent/Guardian
May we share these test results with other Federal and State health and environmental agencies? YES
or NO (Circle One)

Address:

____________________________________________
____________________________________________
____________________________________________

Phone - Home #:

_________________ Phone - Cell #:

__________________

71

Attachment B: Survey

72

Place ID # sticker

Agency for Toxic Substances and Disease Registry

HERE

PFC Survey

For office use
only

Name:_________________________________________________________
Age: _________(years)

Gender:

Male or

Female

1. Do you work in the soil around your home or in the fields (e.g. gardening, digging,
farming, building, repairing)?
Yes No Don’t Know
If "No" or “Don’t Know”, skip to question # 4.
2. How frequently do you work in the soil?
Daily

Weekly

Monthly

Yearly

3. How often do you use gloves and protective clothing when you work in the soil
(e.g. working, playing outdoors, gardening, yard work)? Circle One
Never

Seldom

Sometimes

4. Do you eat locally grown fruits and vegetables? Yes

No

Always

Don’t Know

If “No” or “Don’t Know”, skip to question # 7.
5. When you eat those fruits and vegetables, how often do you eat them?
Daily

Weekly

Monthly

6. What fruits and vegetables do you eat and where do you get them?
Type of Fruit/Vegetable
__________________________
___________________________
___________________________

Place Bought
___________________________
___________________________
___________________________

7. Do you currently eat locally raised cattle meat? Yes

No Don’t Know

If “No” or “Don’t Know”, go to # 11.
8. How often do you eat locally raised cattle? Circle One
Daily

Weekly

Monthly

Yearly
73

9. Where do you buy or get your local cattle meat? Please list below.
___________________________
___________________________
___________________________
___________________________
___________________________
___________________________
10. Do you eat the fish caught from local ponds, lakes or rivers?
Yes
No

Don’t Know

If “No or “Don’t Know”, skip to question # 13.
11. Please name the kind of fish you eat and where you catch it. Please list below.
Type of Fish
___________________________
___________________________
___________________________

Place Caught
___________________________
___________________________
___________________________

12. In the last 30 days, how many fish meals have you eaten from the fish caught
in any of the water bodies listed above?
1-3

4-6

7-9

More than 10

13. What is the main source of drinking water in your home? Circle One.
Public - City or county
Name of water supplier:
_____________________

Cistern

Private Well

Community Well

Spring

Bottled

14. If you have a private well, has it been tested for PFCs? Yes No

Pond

Don’t Know

Don’t Know

If “No” or “Don’t Know”, skip to question # 16.

15. If yes, do you know the date it was tested, who did the testing, and the results
of the PFC testing?

Date

Company/Government

PFC Results

74

16. How many years have you lived at your current address? ______________

17. If you live on land that had PFCs applied to it, do you work (tilling, plowing,
digging, farming) the land?
(Circle One)
Yes

No

Don’t Know

Not Applicable

18. Please list your job title and where you have worked for the past 20
years?

Company Name

Job Title

Year Started

Year Ended

*** THANK YOU ***

75

APPENDIX D: Review of PFC Studies and Health Effects

76

Brief Review of PFC Studies and Health Effects
Clinical Laboratory Measurements: Lipids, Liver Function, Thyroid Function, Kidney Function and
Sex Hormones
Lipids
In animal studies, PFOA has been associated with decreasing serum lipids (Lau 2007).
Animal studies suggest that PFOA/PFOS are peroxisome proliferator activated receptor-alpha (PPARα) agonists that subsequently activate peroxisome proliferation (Lau 2007, Kennedy 2004, Kudo
2003). Peroxisome proliferator-activated receptors are nuclear receptor proteins that regulate gene
expression for metabolism of carbohydrates and lipids. However, PPAR-α is expressed at only 10% in
humans compared to rats, therefore humans are thought to be less responsive to PPAR-α agonists
(Klaunig 2003). It is not clear if this animal-based evidence can be extrapolated to humans. Also, the
elimination rate for PFOA/ PFOS in humans (2-5 years) is much longer than in rats (days) (ATSDR,
2009). Thus, associations between lipids and PFCs are etiologically plausible if a non-PPAR-α
mechanistic pathway is initiated in humans.
Human studies have reported different associations between PFOA and lipid levels compared to
animals. Several reports have evaluated lipid profiles in workers and communities exposed to
PFOA/PFOS, and the results are not consistent. For the remainder of the discussion, only total
cholesterol will be discussed because it remains consistently examined in studies. Most studies do not
address the dose-response curve and the strength of association varies considerably among studies.
Four occupational studies observed a statistically significant association between cholesterol and
serum PFOA values (Costa 2009, Olsen 2003, Sakr 2007a, 2007b). Sakr (2007a, 2007b) studied a
large cohort of DuPont workers (n = 454 for a longitudinal study and 1,025 for a cross-sectional study)
and reported that PFOA was positively associated with total cholesterol (TC). However, in the Sakr
(2007a) study, the subjects studied represented only 16% of all employees who ever worked in the
PFOA area. A small study of Italian workers (n = 53), reported a positive association between TC and
PFOA (Costa 2009). Findings from worker studies with the 3M Company at three locations (Cottage
Grove, Minnesota; Decatur, Alabama; Antwerp, Belgium) are not consistent. In a 3M study (Olsen and
Zobel 2007), investigators did not find evidence of an association between serum PFOA and TC
among 506 employees who did not take cholesterol-lowering medications. However, in a previous
study of the same workers at two 3M locations, investigators found a positive association between
serum PFOS and PFOA and TC in a cross-sectional analysis (n = 421) and PFOA in a longitudinal
analysis (n = 174) (Olsen 2003). In the 2003 study, investigators did not adjust for use of cholesterollowering medications.
Two community studies have been conducted on PFCs with clinical laboratory measurements (Emmett
2006a, Steenland 2009b). Emmett (2006a) studied serum PFOA concentrations in 371 residents living
near a Dupont plant. Subjects were exposed to PFOA in their drinking water. This investigation did
not find an association between serum PFOA and TC and also did not exclude individuals on
cholesterol-lowering medications. Steenland (2009b) reported on 46,294 people living in six water
districts near a Dupont plant where the water system contained PFOA. Mean serum PFOA and PFOS
levels were 80 ng/mL and 22 ng/mL, respectively. Investigators found a positive association between
serum PFOA and PFOS levels and TC. The most important predictors for increased total cholesterol
were age, gender and body mass index, not serum PFOA/PFOS levels. In addition, approximately
77

71% of subjects had a body mass index of greater than 24 kg/m2. Both studies were cross-sectional by
design and therefore causality cannot be inferred.
Finally, investigators studied the relationship between serum PFC concentrations and lipid outcomes in
a publicly available data set that represents the U.S. general population (NHANES) for participants
12–80 years of age (N=2094) (Nelson 2010). They detected an association between serum PFOA,
PFOS and PFNA levels and total cholesterol. A negative association with serum PFHxS and total
cholesterol was detected. They did not find consistent associations between PFCs and BMI or insulin
resistance. This study does not demonstrate a causal association between PFC exposure and serum
cholesterol levels because of its cross-sectional design.
In summary, some limited evidence of cholesterol increases associated with higher PFOA levels has
been reported. The strength of association for PFOA and TC varied by study and therefore
interpretation remains difficult. Also, most of these studies have been cross-sectional in nature and
causality cannot be determined. The mechanism of action for this observation in humans is not
understood.
Liver Function
Reports on the effects of liver function in animals are limited. At elevated exposures, increased weight
in the rat liver has been reported (Kennedy 1987, Kinney 1989, Lau 2007). Serum liver enzymes in
rats were unremarkable except for alkaline phosphatase which was elevated in rats with medium to
high exposure (Kennedy 1987). Using predominately a cross-sectional design, a number of human
studies have examined this endpoint.
Some occupational studies did not report any association between serum PFOA levels and liver
enzymes (Grice 2007, Olsen 2003, Olsen 2004). Olsen and Zobel (2007) in assessment of 506
employees at three fluorochemical production plants (Cottage Grove, Minnesota; Decatur, Alabama;
Antwerp, Belgium) found no statistically significant associations between PFOA and hepatic enzymes
for the three facilities, although some modest positive associations were observed between PFOA and
hepatic enzymes, alanine aminotransferase (ALT) and gamma-glutamyl transferase ( GGT), at one of
the three facilities. The relationship between PFOA and bilirubin was consistently negative. Sakr
(2007) examined the relationship between PFOA and liver enzymes in a longitudinal study of 454
workers and a cross-sectional analysis of 1,025 PFOA exposed workers (Sakr 2007). In the
longitudinal study, PFOA was negatively associated with total bilirubin and positively with serum
aspartate aminotransferase (AST) activity, but not ALT or GGT. Limitations of this analysis include
lack of information about lipid-lowering medications and alcohol intake, and exposure and outcome
were not always measured simultaneously. In the same group of workers, investigators conducted a
cross-sectional study of 1,025 active workers (76% males) at the same plant with PFOA exposure
(Sakr et al. 2007b). The serum PFOA levels ranged from 5 to 9,550 ng/mL. There was a modest but
statistically significant positive association between PFOA and GGT activity. No associations were
found for bilirubin, ALT and AST activities. Finally, Costa (2009) reported on 30 years of medical
surveillance for 56 workers in a PFOA plant. A cross sectional analysis did not detect any associations
between PFOA and liver enzymes. However, in the longitudinal analysis ALT, GGT and alkaline
phosphatase (ALP) were associated with increasing serum PFOA concentrations, with p values ≤ 0.05.
In the one community investigation by Emmett (2006b) with 371 residents (PFOA median serum level
=354 ng/mL), no correlation was found with liver enzymes and PFOA concentrations. Within the
78

general population, Lin (2010) examined the relationship between four serum PFC concentrations and
liver enzymes in a publicly available data set that represents the U.S. general population for
participants 12–80 years of age (N=2216). In this cross-sectional analysis, ALT and GGT were
positively associated with serum PFOA concentrations in subjects who were obese and had insulin
resistance and/or metabolic syndrome. Also, the effect of exposure was small, ranging from 1 to 3
ng/ml. A more recent study by Gallo (2012) showed a positive association in adults between PFOA
and PFOS concentrations and serum ALT level, a marker of hepatocellular damage. There was less
consistent evidence of an association of PFOA and GGT or bilirubin. The relationship with bilirubin
appears to rise at low levels of PFOA and to fall again at higher levels.
These studies provide limited and inconsistent evidence of the association between PFOA and liver
enzymes. The changes liver enzymes appear to be small. The magnitude of the effect appears to be
inconsistent. The clinical or public health relevance is not clear because causality cannot be inferred
from the limited data.
Thyroid Function
Animal data demonstrate that rats and monkeys have reduced thyroxine (T4) and triiodothyronine (T3)
levels when exposed to very high concentrations of PFCs (Butenhoff 2002, Lau 2007). Consequently,
a number of studies have examined this endpoint, usually with a cross-sectional design. Generally, the
occupational studies do not demonstrate evidence of a reduction in thyroid hormone at high exposure
levels. Olsen (2003) did not find an association between PFOA and thyroid hormones in a longitudinal
analysis of 174 3M workers with three consecutive examinations. Similar results were reported in another
cross-sectional study of PFOA workers (Sakr 2007). Researchers in this study reported that serum TSH, T4, and
T3 uptake was within normal limits.

Another recent study (Olsen and Zobel 2007), with 506 workers in three locations with a median
serum PFOA level of 1,100 ng/mL, also did not find an association between thyroid measurements,
thyroid stimulating hormone (TSH) and T4, and serum PFOA levels. A negative association was
observed for free T4 and a positive association for T3; however, all assays were within normal limits.
In a community that was exposed to PFOA in the drinking water (Emmett 2006b), investigators found
no significant association between TSH and serum PFOA levels with median PFOA levels of 197
ng/mL. A small study, (N=31) in New York State found no association between thyroid hormone and
serum PFOA levels (PFOA geometric mean = 1.33 ng/mL) (Bloom 2010).
Finally, investigators studied the relationship between serum PFC concentrations and self-reported
thyroid disease in a publicly available data set that represents the U.S. general population (N=3974)
(Melzer 2010). They detected a statistical association between higher serum PFOA and PFOS levels
and self-reported thyroid disease. The study had only self-reported diagnosis, no thyroid hormone data,
no exposure data at the time of diagnosis, and no information about the type of thyroid disease.
Because of these significant study limitations, interpretation is very difficult. This study does not
demonstrate a causal association between PFC exposure and thyroid disease because of its crosssectional design and significant study limitations.
In general, there is very weak and inconclusive evidence between an association with thyroid function
and PFC exposure.
Kidney Function
79

In animals, PFOA has been demonstrated to concentrate in the kidney (Lau 2007, Kennedy 2004). To
date, kidney toxicity has not been reported in animals.
In an Italian worker study (Costa 2009), no significant associations in kidney function parameters,
blood urea nitrogen or creatinine, have been reported in association with serum PFC concentrations.
Similarly, Emmett (2006b) also did not find a significant association between clinical laboratory
measurements for kidney function and serum PFC concentrations in a community study. Shankar
(2011) found that serum levels of PFCs, including PFOA and PFOS, were positively associated with
chronic kidney disease.
As a whole, there is only a very sparse data set addressing kidney function and serum PFC
concentrations and no association has been found to date.
Sex Hormones
In animals, increases in estradiol and decreases in testosterone were observed in rodents with PFOA
exposure (Lau 2007). Only three human studies have assessed sex hormones in relation to serum PFC
concentrations. In two occupational studies (Olsen 1998, Costa 2009) no significant associations were
found between PFC exposure and sex hormones. In contrast, in one occupational study a significant
association was found in men with serum estradiol and testerone and PFOA in linear regression
models. No significant findings for hormones were found in women (n=243). The investigators did not
propose an explanation for this finding.
In short, the role of sex hormones and associations with PFC exposure remains unclear and data is
insufficient to draw conclusions.
PFC Exposure and Health Effects: Diabetes, Cardiovascular Disease and Cancer

Diabetes
Animal data do not indicate PFCs are associated with diabetes as a disease endpoint, however, some
epidemiological studies of humans have addressed it. The studies are limited to two principal
occupational studies. In a study of Dupont workers exposed to PFCs, with a sample size of 6,027
individuals, an increase in the standardized mortality ratio (SMR) was not observed in exposed
workers when compared to U.S. or West Virginia expected rates (Leonard 2008). However, an
increased SMR for diabetes was observed in these workers when compared to non-exposed Dupont
workers (SMR 1.97; 95% CI, 1.23-2.98; 22 deaths).
In another 3M worker study, diabetes-related deaths were significantly elevated among workers with
moderate exposure, with an (RR= 3.7; 95% CI (1.4–10.1); 18 vs. 5 deaths). This category of workers
was classified as probably or definitely exposed workers vs. nonexposed workers. No deaths from
diabetes occurred in workers with high exposure (Lundin 2009).
Diabetes in relation to a community that was exposed to PFOA via drinking water was examined by
MacNeil (2009). Median serum PFOA levels were 28 ng/mL and self-reported diabetes prevalence was
7.8% in sample size of 54,468 adults. Overall, no relationship between diabetes prevalence and serum
PFOA measurements was found. Also, no increasing trend was detected with fasting serum glucose
and increasing serum PFOA concentrations.
80

Thus, the role of diabetes in relationship to PFC exposure remains very limited and inconsistent, and
no firm conclusions can be drawn.
Cardiovascular Diseases
Cardiovascular endpoints have been studied given that some studies report lipid abnormalities
associated with PFC exposure, although these remain inconsistent as well. The data are sparse and
consist mostly of mortality studies in workers. Workers at the Dupont plant exposed to PFOA
(Leonard 2008, Sakr 2007) have been studied for decades (1948-2002) and did not show a significant
association with ischemic heart disease and PFOA exposure. Melzer (2010) found no association
between PFOA levels and self-reported history of heart disease in a sample of background serum
PFOA levels in the U.S. population. This data is limited by the lack of validation from self-report and
the cross-sectional nature of the analysis.
Overall, the data for heart disease and PFC exposure remain sparse and are too limited to draw
conclusions.
Cancer
The International Agency for Research on Cancer has not evaluated PFCs for carcinogenicity. In 2005,
EPA in its draft risk assessment described PFOA as having “suggestive evidence of carcinogenicity,
but not sufficient to assess human carcinogenic potential” based on no adequate human studies and
uncertain human relevance from rat studies (US EPA 2005).
Cancer mortality studies among workers are limited in number and demonstrate inconsistencies. In a
3M mortality study, a statistically significant association was reported for prostate cancer mortality and
employment duration in a plant that manufactures PFOA. But this association was not observed in a
follow-up study which included more specific exposure measures (Gilliland and Mandel, 1993;
Alexander, 2003). The biologic mechanism for an association between PFOA and prostate cancer is
not clear. No histologic evidence of prostate neoplasia was detected in rats dosed with PFOA
(Kennedy 2004).
Leonard (2008) reported a statistically nonsignificant elevation in mortality risk for kidney cancer
among workers at a Dupont facility. But this study did not find evidence of increased deaths due to
neoplasms in the following areas: liver and biliary passages, pancreas, kidney and urinary tract,
bronchus, trachea or lungs, and prostate.
In a non-occupational group, a Danish study of 55,053 people with much lower serum PFOA/PFOS
concentrations than occupational exposures did not observe any significant excesses of cancer (Eriksen
2009). Median serum PFOA concentrations were 6-7 ng/ml with a range of 1-76 ng/mL in this
population and median serum PFOS concentrations were 29 -35 ng/mL with a range of 1 -130.5
ng/mL.
Overall, the data for PFC exposure and cancer remain sparse and inconclusive.

81

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Butenhoff J, Costa G, Elcombe C, Farrar, D, Hansen K, Hiroyuki I, Jung, R, Kennedy G, Lieder P,
Olsen G, and Thomford P. 2002. Toxicity of ammonium perfluorooctanoate in male cynomolgus
monkeys after oral dosing for 6 months. Toxicol Sci 69(1):244-257.
Costa G, Sartori S, Consonni D. 2009. Thirty years of medical surveillance in perfluooctanoic acid
production workers. J Occup Environ Med 51: 364–372.
Emmett EA, Shofer FS, Zhang H, Freeman D, Desai C, Shaw LM. 2006a. Community exposure to
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Eriksen KT, Sørensen M, McLaughlin JK, Lipworth L, Tjønneland A, Overvad K, et al.
2009. Perfluorooctanoate and perfluorooctanesulfonate plasma levels and risk of cancer
in the general Danish population. J Natl Cancer Inst 101: 605–609.
Gilliland FD and Mandel JS. 1993. Mortality among employees of a perfluorooctanoic
acid production plant. J Occup Med 35(9):950-954.
Grice MM, Alexander BH, Hoffbeck R, Kampa DM. 2007. Self reported medical
conditions in perfluoroooctanesulfonyl fluoride manufacturing workers. J Occup Environ
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Kennedy GL. 1987. Increase in mouse liver weight following feeding of ammonium
perfluorooctanoate and related fluorochemicals. Toxicol Lett 39(2-3):295-300.
Kennedy GL, Buttenhoff JL, Olsen GW, O’Connor JC, Seacat AM, Perkins RG et al. 2004. The
toxicology of perfluorooctanoate. Crit Rev Toxicol 34:351-384.
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workers in a polymer production plant including a reference population of regional workers. Ann
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associations between low-dose serum perfluorinated chemicals and liver enzymes in US adults. Am J
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Lundin JI, Alexander BH, Olsen GW, Church TR. 2009. Ammonium perfluorooctanoate production
and occupational mortality. Epidemiology 20(6): 921–928.
MacNeil J, Steenland K, Shankar A, Ducatman A. 2009. A cross-sectional analysis of type II diabetes
in a community with exposure to perfluorooctanoic acid (PFOA). Environ Res 109(8): 997–1003.
Melzer D, Rice N, Depledge MH, Henley WE, Galloway TS 2010. Association between serum
perfluoroctanoic acid (PFOA) and thyroid disease in the NHANES study. Environ Health Perspect
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Nelson J, Hatch E, Webster T. 2010. Exposure to polyfluoroalkyl chemicals and cholesterol, body
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Olsen GW, Burris JM, Burlew MM, Mandel JH 2003. Epidemiologic assessment of worker serum
perfluorooctanesulfonate (PFOS) and perfluorooctanoate (PFOA) concentrations and medical
surveillance examinations. J Occup Environ Med 45: 260–270.
Olsen GW, Burlew MM, Marshall JC, Burris JM, Mandel JH. 2004. Analysis of episodes of care in a
perfluorooctanesulfonyl fluoride production facicility. J Occup Environ Med. 46:837-846.
Olsen GW, Zobel LR. 2007. Assessment of lipid, hepatic, and thyroid parameters with serum
perfluorooctanoate (PFOA) concentrations in fluorochemical production workers. Int Arch Occup
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Sakr CJ, Kreckmann KH, Green JW, Gillies PJ, Reynolds JL, Leonard JC. 2007a. Cross-sectional
study of lipids and liver enzymes related to a serum biomarker of exposure (ammonium
perfluoroooctanoate or APFO) as part of a general health survey in a cohort of occupationally exposed
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Sakr CJ, Leonard RC, Kreckmann KH, Slade Md, Cullen MR. 2007b. Longitudinal study of serum
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Occup Environ Med 49:872-879.
Shankar A, Xiao J, Ducatman A. 2011. Perfluoroalkyl Chemicals and Chronic Kidney Disease in US
Adults. Am. J. Epidemiol. 174: 893-900.
Steenland K, Jin C, MacNeil J, Lally C, Ducatman A, Vieira V, et al. 2009. Predictors of PFOA levels
in a community surrounding a chemical plant. Environ Health Perspect 117: 1083–1088.
Steenland K, Tinker S, Frisbee S, Ducatman A, Vaccarino A. 2009. Association of perfluorooctanic
acid (PFOA) and perfluoroctanesulfonate (PFOS) with serum lipids among adults living near a
chemical plant. Am J Epidemiol 170: 1268–1278
US EPA (Environmental Protection Agency). 2005. Draft Risk Assessment of the Potential for Human
Health Effects Associated with Exposure to Perflourooctanoic Acids and Salts. Available:
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APPENDIX E: Investigation Summary and Health Information Sheet

85

Blood PFC Testing and Health Information Summary
Morgan, Lawrence and Limestone Counties, Alabama

What are Perfluorochemicals (PFCs)?
Perfluorochemicals (PFCs) are a class of man-made chemicals. In most cases, PFCs are not regulated by the U.S.
Environmental Protection Agency (EPA). PFCs have been used for many years to make products that resist heat,
stains, grease and water. Because of their widespread use, most people in the United States have some PFCs in their
body. Once the PFCs are in a person’s body, it takes about two to four years before those PFC levels go down by half,
even if no more is taken in.
Some products that may have used PFCs when they were made or that might contain PFCs include:








Furniture and carpets treated for stain resistance
Treated clothing that is stain resistant or waterproof
Foams used to fight fires
Fast food or packaged food containers, such as french fry boxes, pizza boxes, hamburger wrappers, and
microwave popcorn bags
Makeup and personal care products, such as dental floss, pressed powders, nail polish and shaving cream with
ingredients that have ‘perfluoro’ in the name
Floor care products
Cleaning products

Why did ATSDR become involved in the investigation of PFCs in this region?
In May 2007, a PFC manufacturer in Decatur, Alabama, notified the EPA that it had unknowingly discharged large
amounts of perfluorocarboxylic acids (PFCA), a class of compounds that include perfluorooctanoic acid (PFOA) and
other PFCs, into the Decatur Utilities’ Dry Creek Wastewater Treatment Plant. From 1996 to 2008, treated sewage
sludge (biosolids) from Decatur Utilities were used as a soil amendment on about 5000 acres of privately owned
agricultural fields in Lawrence, Morgan and Limestone Counties, Alabama.
Decatur Utilities Dry Creek Waste Water Treatment Plant (Decatur Utilities) in Decatur, Alabama receives wastewater
from domestic and industrial sources, including PFC manufacturing and use facilities in the area. To date, the U.S.
Environmental Protection Agency (EPA), the Alabama Department of Environmental Management (ADEM), and
Decatur Utilities have identified several direct sources of PFCs to Decatur Utilities.
As with all waste water treatment plants, solids and many chemicals are removed from the water. The solids are called
“biosolids.” They are rich in nutrients and can be used as fertilizer. Biosolid content is tested regularly and must meet
regulatory requirements. However, PFCs in water and biosolids are generally not regulated by EPA, so testing of
biosolids for these chemicals is typically not required. EPA has not established an action level for PFOA or
perfluorooctane sulfonate (PFOS) in soil, sewage sludge, biosolids, groundwater, surface water, or air.
In September 2007, EPA tested the farm fields for PFCs. EPA collected biosolids and soil from a small number of the
farm fields that received biosolids from Decatur Utilities. The results showed raised levels of PFCs compared with
background levels. In February and March of 2009, EPA followed up with more sample collection of surface water,
groundwater, drinking water, and soils in areas near the treated fields. EPA found PFCs in the soils from the farm
fields on which the biosolids were spread, and in surface water, groundwater, and drinking water.
In January 2009, EPA set up a drinking water Provisional Health Advisory level for PFOA and PFOS—two of the PFC
compounds about which we have the most toxicological data. EPA set the Provisional Health Advisory level at 0.4
parts per billion (ppb) for PFOA and 0.2 ppb for PFOS. In February 2009, EPA tested for PFCs in six private drinking

Agency for Toxic Substances and Disease Registry
Division of Community Health Investigations

water wells near the farm fields. Two private drinking water wells had PFOA concentrations above the EPA
Provisional Health Advisory levels. EPA supplied other drinking water to residents who used those wells and then
arranged for the residences’ connection to the public water supply system. After EPA’s February–March 2009
sampling and at EPA’s request, a local industries group did a complete private drinking water well survey and did
sampling in the areas near the farm lands where the biosolids were spread. From August 2009 through August 2010,
the local-industries group sampled 12 private drinking water wells. One of the 12 wells had levels of PFOS above
EPA’s Provisional Health Advisory values. Residents who used this well were supplied other drinking water, and their
home was linked to the local public water supply system.
In addition, EPA sampled five local public drinking water systems. No PFCs were detected in four of the five public
water supply systems. PFOA and PFOS were detected in the West Morgan/East Lawrence public water supply but at
concentrations below EPA’s Provisional Health Advisory levels. The West Morgan/East Lawrence public water
supply system draws its water from the Tennessee River approximately 13 miles downstream from an industrial center
where several PFC manufacturers and users are located. A study funded by one of the local industries detected PFOA
and PFOS in samples collected in 2000 from the Tennessee River. The agricultural fields that received the Decatur
Utilities’ biosolids are not suspected to be the source of PFCs in the West Morgan/East Lawrence public water supply
system.
In October 2009 EPA released residential soil screening guidance values for PFOA and PFOS that are protective of
children’s health (which are also protective of adult health). These soil screening values are 16,000 ppb [micrograms /
kilogram] for PFOA and 6,000 ppb for PFOS. All soil and water sampling data collected can be obtained from the
following website: http://www.epa.gov/region4/water/PFCindex.html
In 2009 EPA contacted ATSDR to request that an exposure investigation be conducted.

Why was blood testing done for PFCs?
It was not known how much PFCs might be in a person’s body from contact with contaminated soil, water or other
exposure pathways. The Agency for Toxic Substances and Disease Registry (ATSDR), a federal public health agency,
tested people’s blood for PFCs to find out how much of this chemical may be entering a person’s body.

Who was eligible for testing?
People who were 12 and older and who
 Lived on or near fields that received biosolids from Decatur Utilities; and
 Had private drinking water wells located near these biosolids application sites; or
 Drank water from the West Morgan / East Lawrence public water system.
A total of 155 persons—63 males and 92 females—volunteered for blood testing. Of these, 147 were adults and 8 were
children.

Why was the PFC blood testing not offered to children under age 12?
At this time, PFC comparison values for the U.S. population are limited to children 12 years of age and older. If
children under 12 were tested, we would not be able to tell them how their PFC level compared with the levels seen in
the general U.S. population.

How many PFCs were tested in the blood of participants?
Eight PFCs were tested in the blood of participants. These PFCs are listed below:
Abbreviation

Complete Chemical Name



PFOA

Perfluorooctanoic acid



PFOS

Perfluorooctane sulfonate



PFHxS

Perfluorohexane sulfonate



PFOSA

Perfluorooctane sulfonamide



PFNA

Perfluorononanoate



PFDeA

Perfluorodecanoate



Et-PFOSA-AcOH

2-(N-ethyl-perfluorooctane sulfonamido) acetate



Me-PFOSA-AcOH

2-(N-methyl-perfluorooctane sulfonamido) acetate

Scientists know the most about PFOA and PFOS. Less is known about the other PFCs. This information sheet is
mostly about PFOA and PFOS.

What were the PFC blood test results?



Five PFCs in the blood were at levels similar to or lower than the average levels in a person in the United
States.
Three PFCs (PFOA, PFOS and PFHx) in the blood were two to four times higher than average levels in the
United States. These levels were similar to or lower than levels found in other U.S. communities with PFCs in
their drinking water.



This investigation found that drinking well or public water with detectable levels of PFCs may contribute to an
increase in blood PFC levels. The investigation did not show that living on or near a biosolids application
field, eating local cattle, fish or vegetables or gardening are associated with blood PFC levels in participants.
However the investigation could not exclude these possible sources of exposure.



Older people and men tended to have higher blood PFC levels than others tested.

How do results of this testing compare to other studies?
The chart below shows the average blood levels of PFOA found in the U.S. population, in this investigation (PFC
testing in the Decatur, Alabama area), other community studies, and in PFC manufacturing workers. The results are
listed as nanograms per milliliter (ng/mL) – the same as parts per billion (ppb). Concentration is the measure of how
much of a given substance, such as a chemical, is mixed with another substance (blood, for example). Just as one
percent means one part out of a hundred, one ppb means one part out of a billion.

PFOA Studies: Comparison of Average Blood
Levels
3M Workers
Dupont Workers
Little Hocking, OH
Ohio River Valley
Minnesota Pilot Study
Decatur, AL PFC Testing
Red Cross Blood Donors
U.S. Population
0

200

400

600

800

1000

1200

PFOA Mean Serum Concentration (ng/mL)

What do these results mean for your health?
As a result of this investigation the community has learned that there has been an exposure to PFCs. The participants
have received their individual test results. At this time we do not have enough information to say what level of PFC’s
in the blood might result in a health problem. This investigation will not tell a person if the PFC levels in their blood
will make them sick now or later in life, or if their current health problems are related to the PFC levels found in their
body. However, there are recent studies that show a possible link to health effects from PFCs although more research
needs to be done by scientists who work in this field.

Animal Studies
Animal studies have found that PFCs may affect animals’ health. Animals exposed to PFCs at much higher levels than
the levels found in this investigation can result in changes in the function of the liver, thyroid, pancreas and hormone
levels. Animals may be more sensitive to the effects of PFCs than humans.

Human Studies
In humans, research has not clearly shown that PFCs are related to specific illnesses. Recent studies have found
possible links to some PFC-related health problems. Science experts who work in this field need to do more research.

Worker Studies
Much of the research on humans has been done with people who were exposed to PFCs on the job. Workers involved
in the manufacture or use of PFCs as part of their job duties usually have higher blood PFC levels than the general
population.

Studies on PFC workers have looked for effects on cholesterol levels, male hormones, heart disease, liver changes and
other effects. So far, these studies have not consistently shown that PFC exposure is linked to health problems.

General Population Studies
Currently, a large study of 70,000 people is being done in the Ohio River Valley. The drinking water was
contaminated and people were exposed to PFOA. So far, testing in this large group of people has found that the
average PFOA levels in blood were higher when compared to the national average and about twice as high as what was
found in the Decatur area, but lower than levels found in workers involved in the manufacture or use of PFCs as part of
their job duties. This study will look to see if PFOA exposure is linked with heart disease, immune system function,
liver function, hormone disorders, cancer, diabetes, and birth outcomes. In the most recent updates from December
2011, April 2012, July 2012 and October 2012, the C8 Scientific Panel (C8 is a shorthand name for PFOA), a panel
that was formed to look at whether there is a probable link between C8 exposure and any human disease, released C8
Probable Link Reports which focused on several different health outcomes.
These reports noted a probable link between exposure to PFOA (C8) and pregnancy-induced hypertension, thyroid
disease, ulcerative colitis, testicular cancer, kidney cancer and high cholesterol. The reports found no link between
PFOA and other forms of cancer reviewed in the study. These reports also noted that there is not a probable link
between exposure to PFOA (C8) and birth defects, miscarriage or stillbirth, and preterm birth or low birth weight.
They also did not find a link between Type II diabetes, stroke, asthma or chronic obstructive airways disease (COPD),
neurodevelopmental disorders in children (such as attention deficit disorders and learning disabilities), common
infections or autoimmune disorders other than ulcerative colitis (to include rheumatoid arthritis, lupus, Type I diabetes,
Crohn’s disease or multiple sclerosis), Parkinson’s disease, osteoarthritis, liver disease, chronic kidney disease,
hypertension or coronary artery disease. Results from this large study will continue to be shared over the next few
years and should add to our knowledge about health effects associated with PFCs.
For more information see: http://www.c8sciencepanel.org

Do PFCs cause cancer?
The C8 study noted above has recently reported a probable link to testicular and kidney cancer. Additional studies are
needed to better evaluate this link. Studies of workers involved in the manufacture or use of PFCs as part of their job
duties who were exposed to PFCs have looked at whether PFCs are linked with prostate, bladder, and liver cancer.
None of these existing studies have found a link between exposures to PFCs and cancer. However, additional health
studies are underway.

Should other members of my family get tested for PFCs?
ATSDR does not advise that everyone get their PFC levels tested. The test may be very costly and cannot predict
health effects or be linked to current health problems. There is also no way to remove PFCs from the body other than
the body’s normal elimination processes.

What are the next steps?
•

Continue efforts to reduce the level of PFCs present in the Tennessee River which is used as source water for the
WM/EL public water supply system.

•

Continue monitoring for PFCs in the WM/EL public water supply and other potentially impacted public water
supplies downstream of Decatur, Alabama. The WM/EL public water system has already taken steps to improve

water treatment which is expected to reduce PFC levels in finished drinking water. If PFOA and/or PFOS
concentrations in the finished drinking water of the WM/EL public water system increase and remain above the
EPA’s Provisional Health Advisory levels, we recommend that the public water system evaluate modifications to
their treatment processes to reduce contaminant levels.
•

Conduct routine periodic monitoring of other local area public water supplies for potential contamination with
PFCs. Although these water supplies are considered to be at a lower risk for PFC contamination because of their
location and have no detectable PFCs to date, it is good public health practice to conduct routine periodic
monitoring.

•

Owners of private drinking water wells located on or near biosolids application fields not previously tested should
consider conducting periodic monitoring for PFCs. If levels are consistently above EPA’s Provisional Health
Advisory levels, residents should use alternate drinking water sources. Some private drinking water wells in the
area were sampled quarterly for a year and those that exceeded EPA’s provisional health advisory levels for
PFOA/PFOS were placed on public water. All other sampled wells did not exceed the public health advisory levels.

• The community’s exposure to PFCs is expected to decline because of the actions taken to remove or decrease PFCs
in the environment. Follow-up serum PFC testing in this community should be considered to verify that serum PFC
concentrations are declining and to identify whether additional public health actions may be needed.
•

Continue providing the community with any new science about health effects of PFC exposure as new information
is documented.

What can people do to avoid PFC exposure?
Consumer Products
PFCs are found in the blood of people and animals all over the world. How people get PFCs into their bodies from
products with PFCs in them is not clear. It is also not clear whether a person can avoid getting PFCs into their body by
limiting the use of products that were made using PFCs. Because there is so little information about how people are
exposed to PFCs from products, ATSDR is not able to recommend ways to reduce a person’s exposure to PFCs from
using products that contain PFCs.

Water
Private well
People with private wells that contain PFCs above the current guidelines have been provided an alternate drinking
water source. If you have questions about your private well, contact the U.S. Environmental Protection Agency,
Region 4, Lee Thomas at 404-562-9786.

Public water
PFCs were not detected in the Decatur and Moulton public drinking water systems. PFCs levels were below EPA’s
current Provisional Health Advisory level in the West Morgan/East Lawrence public drinking water system. These
levels have remained below EPA’s Provisional Health Advisory levels.
However, if you are worried about PFC chemicals in your drinking water, a study by the Minnesota Department of
Health and other studies in recent scientific journals found that some water filtration devices (point of use devices that
are put in at a single tap, faucet, or outlet) may remove some of these compounds from water. You should contact the
company that makes the water filtration device to find out how well the device works in removing PFC chemicals.
Also ask about how often you should change the filters.

Fish Consumption
PFCs, including both PFOA and PFOS, were detected in fish tissue samples taken from catfish and large-mouth bass in
the Tennessee River near Decatur. The PFOA analytical results averaged 0.74 ppb and the PFOS analytical results
averaged 806.06 ppb. Based on the PFOS results, the Alabama Department of Public Health has issued a 'no
consumption' fish advisory for all species of fish in the Baker's Creek embayment of Wheeler Reservoir. Future
testing will determine if this advisory needs to be expanded. The entire advisory can be found at
http://adph.org/news/assets/120831.pdf. ATSDR recommends that people follow this fish consumption advisory to
reduce potential exposure to PFCs.

More Information
Because this investigation was designed to select individuals with the greatest likelihood of PFC exposure, these
results cannot be generalized nor inferred to represent others living in the area or to other locations /
populations.

Questions about PFC blood testing:
ATSDR: 1-888-529-1906 (toll-free) or 404-639-3311
ATSDR website: http://www.atsdr.cdc.gov/

PFC environmental information from EPA:
EPA website: http://www.epa.gov/region4/water/PFCindex.html
EPA, Region 4 – Atlanta: Lee Thomas: 404-562-9786 or Thomas.lee@epa.gov
Note: Some of the material in this information sheet was adapted from the East Metro Perfluorochemical Biomonitoring Pilot Project,
Minnesota Department of Health, July 21, 2009.


File Typeapplication/pdf
File TitleExposure Investigation Protocol
AuthorATSDR
File Modified2013-03-26
File Created2013-03-25

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