EPA/600/R-17/348 | September 2017
www.epa.gov/homeland-security-research
United States
Environmental Protection
Agency
&EPA
Remediation Options for Porous
Materials Contaminated with
Persistent Chemical Warfare
Agents VX and HD
Office of Research and Development
Homeland Security Research Program
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Remediation Options for Porous Materials
Contaminated with Persistent Chemical
Warfare Agents VX and HD
U.S. Environmental Protection Agency
Office of Research and Development
National Homeland Security Research Center
Research Triangle Park, North Carolina 27711
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DISCLAIMER
The U.S. Environmental Protection Agency, through its Office of Research and Development,
funded and managed the research described here under Contract Number EP-C-11-037, Task
Order 10 with Tetra Tech, Inc. It has been subjected to the Agency's review and has been
approved for publication. Note that approval does not signify that the contents necessarily reflect
the views of the Agency. Mention of trade names, products, or services does not convey official
EPA approval, endorsement, or recommendation.
Questions concerning this document or its application should be addressed to:
Lukas Oudejans, Ph.D.
National Homeland Security Research Center
Office of Research and Development
U.S. Environmental Protection Agency (MD-E343-06)
109 T.W. Alexander Drive
Research Triangle Park, NC 27711
Phone: 919-541-2973
Fax:919-541-0496
E-mail: Oudeians.Lukas@epa.gov
or
Sandip Chattopadhyay, Ph.D.
National Homeland Security Research Center
Office of Research and Development
U.S. Environmental Protection Agency
26 W. Martin Luther King Drive, MS NG16
Cincinnati, OH 45268
Phone: 513-569-7549
Fax: 513-487-2555
E-mail: Chattopadhyav.sandip@epa.gov
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ACKNOWLEDGMENTS
This effort was initiated following discussions with the U.S. Environmental Protection
Agency's (EPA's) Office of Land and Emergency Management (OLEM)'s Office of
Emergency Management (OEM) and EPA Regional On-Scene Coordinators on high-priority
research needs to support response and recovery following incidents involving chemical,
biological, or radiological (CBR) agents or materials. This work was managed by two
principal investigators from EPA's Office of Research and Development (ORD) National
Homeland Research Center (NHSRC) with input from US EPA project team members:
Lukas Oudejans, Ph.D. (Principal Investigator), ORD/NHSRC
Sandip Chattopadhyay, Ph.D. (Co-Principal Investigator), ORD/NHSRC
Paul Lemieux, Ph.D., ORD/NHSRC
Lawrence Kaelin, OLEM/OEM/Consequence Management Advisory Division
(CMAD)
Catherine Young, EPA Region 1
Charlie Fitzsimmons, EPA Region 3
This effort was completed under U.S. EPA contract EP-C-11-037, Task Order 10, with Tetra
Tech, Inc. and their partner Southwest Research Institute (SwRI). The research efforts of
William Williamson and Robert Martinez with SwRI are greatly appreciated.
The authors would like to acknowledge Joan Bursey for her technical editing; EPA QA
reviewers Ramona Sherman and Eletha Brady-Roberts; and reviewers Amy Mysz (Region
5) and Stuart Willison (ORD/NHSRC) for their contributions to this report.
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EXECUTIVE SUMMARY
Under the National Response Framework, the U.S. Environmental Protection Agency (EPA) is
designated as the coordinating agency to prepare for, respond to, and recover from a threat to
public health, welfare, or the environment caused by hazardous materials incidents including
chemical, biological, and radiological substances. The imminent threat of a chemical warfare
agent release on infrastructural materials as part of a building or a transportation hub is driving
U.S. EPA's Homeland Security Research Program (HSRP) to develop a research program that
systematically evaluates potential decontamination technologies for chemical (warfare) agents.
The U.S. EPA is tasked to remediate infrastructure or equipment contaminated with these agents
after they are released. It is unknown how effective many of the available technologies are,
especially for decontamination of porous or permeable materials. Previous Department of
Defense and EPA's National Homeland Security Research Center (NHSRC) studies have
focused on nonporous materials, included sealed surfaces. In this study, U.S. EPA addressed a
high priority gap as identified by the HSRP's EPA Program Office partners by evaluating the
effectiveness of several decontaminant solutions on porous or permeable materials. In addition,
the effect of the decontaminant on the building material was also assessed (qualitatively).
Four commercially available decontaminant solutions were quantitatively evaluated for their
ability to decontaminate two persistent chemical warfare agents (VX and HD) on permeable
surfaces associated with subway-related materials of construction. Decontamination efficacies,
defined as the percentage of agent removed from the material surface by decontamination efforts,
were determined through testing to evaluate performance of each decontaminant for each surface
type.
Coupons (approximately 4-inch x 4-inch) from each of the surface types (glazed ceramic tile,
rubber molding, and concrete sealant, Sure Klean® Siloxane PD, applied to sandstone) were
prepared and were spiked with neat chemical agent and allowed to be in contact with the surface
(4 hours [h] for HD and 24 h for VX) prior to surface treatment by the decontaminant. Either
Clorox® Bleach, hydrogen peroxide solution (3.1%), or EasyDecon® DF-200 was applied to the
contaminated coupons. The decontaminant remained in contact with the coupons for 1 h with the
exception of the DeconGel® 1108, which required a three-day drying time as the gel was still
tacky after 25 to 48 h. The drying time for the DeconGel® 1108 depends on a combination of
temperature, relative humidity, film thickness, air flow, and material. It is unclear what caused
the curing time to exceed the normal drying time of approximately 16-24 h. After treatment and
removal of excess residual decontaminant from the surface, a wipe sample of the coupon surface
was collected, and the whole coupon was subsequently extracted. Extracts were assayed by gas
chromatography/mass spectrometry (GC/MS) for HD and liquid chromatography triple quad
mass spectrometry (LC-MS/MS) for VX to determine residual agent left on the surface.
Decontamination efficacy results are shown in Table ES-1.
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Table ES-1: Summary of Decontamination Efficacy Results
Agent
Decontaminant
Glass
(%)
Ceramic
(%)
Sealant
(%)
Rubber
(%)
VX
Bleach
99.996
99
88
15
Peroxide
96
96
50
13
EasyDecon®
99.995
99.992
71
8
DeconGel®
99.9
99.7
32
74
HD
Bleach
99.992
99.97
98
65
Peroxide
43
76
39
35
EasyDecon®
99
97
64
52
DeconGel®
ND
ND
99.981
75
Percent of agent decontaminated was calculated considering agent recovered from both wipe
and coupon extracts. Significant digits are based on calculated standard deviation which is in
the order of the last digit. ND: Not determined; positive control recoveries were too low to
calculate meaningful decontamination efficacy. 1 Based on 2% recovery of HD from positive
control
Decontamination efficacy for DeconGel® 1108 could not be calculated for HD on the nonporous
glass and ceramic materials because less than 0.3% of the HD spiked on the positive controls
was recovered after three days due to the volatility of HD under these test conditions. Bleach
performed the best across all of the materials, except rubber, and peroxide performed the worst
among the selected materials. Even though the main active ingredient was peroxide, EasyDecon®
DF-200 performed better than the peroxide. Application of DeconGel® 1108 resulted in similar
efficacy values for VX on glass and ceramic, lower on the sealed surface and higher for the
rubber surface when compared to the other three decontaminants.
Low collection efficiencies (positive control recoveries) were observed for the sealant,
suggesting that the agent is sorbed into the material and is protected from collection processes, or
the agent is attenuated from the surface. The low agent collection efficiencies bias these
decontamination efficacy results high. Since floors in underground transportation systems mostly
consist of concrete sealed with concrete sealant, further studies should address the fate of this
material, i.e., whether agent sorbs through the sealant or the agent is neutralized by the Sure
Klean® Siloxane PD sealant. Public health may be at subsequent risk if the sealant allows agent
sorption and protects the agent from decontamination processes or extraction processes.
The results obtained from this study showed that VX and HD can be neutralized (greater than
97%) by full strength bleach, EasyDecon® DF-200, and DeconGel® when the decontaminants are
used for remediation of nonporous materials. These commercial decontaminants are noticeably
less effective for decontamination of permeable elastomers (sealant and rubber). Elastomers have
low intermolecular forces and relatively unhindered single bonds that link the silicon and oxygen
backbone chain atoms together. It results in a higher than normal amount of free volume and a
high degree of chain mobility and make sealant and rubber permeable to these agents. Due to an
impervious layer or coating of the vitreous substance, glazed ceramic tile behaved as a
nonporous material. One should be careful to extrapolate the controlled-environment laboratory
vi
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testing data to field applications of these decontaminants. Interferences from debris, oil, grease,
and other intrusive materials of imperfections such as cracks or aged material can impact the
performance of the decontaminants. The study did not measure amount of agents present in the
spent material (decontamination liquid or gel) that was removed from the coupon surface prior to
the sampling. These spent materials may require specialized hazardous waste handling and
additional treatment prior to proper disposal as waste.
vii
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TABLE OF CONTENTS
Page
Disclaimer iii
Acknowledgments iv
Executive Summary v
Table of Contents viii
List of Figures x
List of Tables x
List of Appendices xi
Abbreviations/Acronyms xii
1. Introduction 1
1.1 Background 1
1.2 Objectives 1
1.3 Approach 2
1.4 Experimental Design 2
2. Procedures 4
2.1 Decontamination Solutions 4
2.2 Surface Materials 4
2.3 Chemical Warfare Agent Purity 6
2.4 Testing Timeline 6
2.5 Agent Spiking 6
2.6 Agent-Material Contact Time 7
2.7 Decontamination 7
2.7.1 Spray Application 7
2.7.2 DeconGel® 1108 Application 9
2.8 Sample Collection 10
2.8.1 Wipe Collection Method 10
2.9 Extraction Methods 10
2.9.1 Laboratory Wipe Method Development 10
2.9.2 Wipe Extraction Method 11
2.9.3 Whole Coupon Extraction 11
2.10 Analytical Methods 12
2.10.1 GC/MS (HD-Targeted Analysis) 13
2.10.2 LC-MS/MS (VX-Targeted Analysis) 13
viii
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2.10.3 GC x GC/TOFMS (Survey Analysis) 14
2.10.4 LC/qTOF (Survey Analysis) 15
2.11 Calculations 16
3. Quality Assurance / Quality Control 18
3.1 Process and Data Quality Audit 18
3.2 Quality Performance Indicators for Wipe Method Demonstration 18
3.3 Wipe Demonstration Quality Control Samples 18
3.4 Quality Performance Indicators for Decontamination Efficacy 19
3.5 Efficacy Quality Control Samples 20
3.6 QAPP Deviations 21
4. Results and Discussion 23
4.1 Test Conditions 23
4.1.1 Environmental Conditions during Agent-Material Contact 23
4.1.2 Agent-Material Contact Time 23
4.1.3 Decontaminant/ Material Treatment Time 23
4.1.4 Spray Decontaminant Application 24
4.1.5 DeconGel® 1108 Application 24
4.1.6 Decontaminant Coverage 25
4.2 Test Results — Decontamination Efficacy 26
4.3 Toxic Compounds Detected from the Treated Coupons 28
5. Conclusions 29
6. References 30
7. Appendices 31
ix
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LIST OF FIGURES
Figure No. Page
Figure 1: Decontamination Efficacy Test Scheme 2
Figure 2: Glass, Ceramic, Rubber, and Sealant/Sandstone Coupons 5
Figure 3: Storage Container for Agent Contaminated Coupons 6
Figure 4: Glass Oil Mister 8
Figure 5: Application Chamber for Spraying Decontaminant Solution 8
Figure 6: DeconGel® 1108 Syringe Applicator and Application onto a Coupon 9
Figure 7: Stainless Steel Coupon Extraction Vessel 12
Figure 8: DeconGel® 1108 applied to ceramic tile with glass plate covering 24
Figure 9: DeconGel® 1108 initial application (left) and DeconGel® 1108 after 72-h cure (right) 25
Figure 10: Decontaminant applied to rubber coupon 26
LIST OF TABLES
Table No. Page
Table ES-1: Summary of Decontamination Efficacy Results vi
Table 1: Decontamination Efficacy Test Matrix 3
Table 2: Decontamination Solution 4
Table 3: Coupon Materials to be Used for Decontamination Efficacy Testing 5
Table 4: Spray Bottle Calibration Results 9
Table 5: Calibration Acceptance Criteria 12
Table 6: Internal Standard Acceptance Criteria 13
Table 7: GC/MS Parameters for HD Analysis 13
Table 8: LC-MS/MS Parameters for VX Analysis 14
Table 9: GC x GC/TOFMS Parameters for Survey Analysis 15
Table 10: LC-qTOF Parameters for Survey Analysis 16
Table 11: Agent Acceptance Criteria for Wipe Method Demonstration 18
Table 12: Summary of Wipe Positive Control Results 19
Table 13: Decontamination Efficacy Performance Indicators 20
Table 14: Summary of Positive Control Results 21
Table 15: Summary of Recovery Standard Results 21
Table 16: Temperature and Relative Humidity Range during Agent-Material Contact 23
Table 17: Decontamination Efficacy Results 27
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LIST OF APPENDICES
Appendix A - Wipe Method Development and Demonstration
Appendix B - Summary of Wipe Method Quality Control (QC)
Appendix C - Summary of QC Recovery (Rec) Standard
Appendix D - Summary of Test Results
xi
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ABBREVIATIONS/ACRONYMS
°c
degree(s) Celsius
Mg
microgram(s)
jiL
microliter(s)
(im
micrometer(s)
avg.
average
CASARM
Chemical Agent Standard Analytical Reference Material
CCV
continuing calibration verification
DCM
dichloromethane
DIMP-di4
diisopropyl methylphosphonate deuterated
EI
electron ionization
EPA
U.S. Environmental Protection Agency
ESI
electrospray ionization
eV
electron volt(s)
g
gram(s)
GC
Gas chromatograph(y)
GC/MS
Gas chromatograph/mass spectrometer
GC x GC/TOFMS
Two Dimensional Gas Chromatography Time-of-Flight Mass Spectrometry
HD
sulfur mustard (bis(2-chloroethyl) sulfide)
h
hour(s)
HSRP
Homeland Security Research Program
i.d.
inner diameter
ICAL
initial calibration
ICV
initial calibration verification
IS
internal standard
ISO
International Organization for Standardization
LC-MS/MS
Liquid chromatography triple quadrupole mass spectrometry
LC/qTOF
Liquid chromatography quadrupole Time-of-Flight Mass Spectrometry
LCS
laboratory control spike
m/z
mass to charge ratio
min
minute (s)
mL
milliliter(s)
MRM
multiple reaction monitoring
MS
mass spectrometer
msec
millisecond(s)
ND
not determined
ng
nanogram(s)
NHSRC
National Homeland Security Research Center
NIST
National Institute of Standards and Technology
NMR
Nuclear magnetic resonance
ORD
Office of Research and Development
PB
procedural blank
PC
positive control
PN
part number
ppm
part(s) per million
QA
Quality Assurance
QAPP
Quality Assurance Project Plan
QC
quality control
R2
coefficient of determination
rec
recovery
xii
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RPD
relative percent difference
RS
recovery standard
RSD
relative standard deviation
SB
surface blank
sec
second(s)
SIM
selected ion monitoring
temp
temperature
TR
test replicate
VOA
volatile organic analysis
VX
O-ethyl S-[2-(diisopropylamino)ethyl] methylphosphonothioate
xiii
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1. INTRODUCTION
1.1
Background
Under the National Response Framework, the U.S. Environmental Protection Agency (EPA) is designated
as the coordinating agency to prepare for, respond to, and recover from a threat to public health, welfare,
or the environment caused by hazardous materials incidents to include chemical, biological, and
radiological substances. The threat and potential consequences of a chemical agent release, such as a
building or a transportation hub, is driving U.S. EPA's Homeland Security Research Program (HSRP) to
develop a research program that systematically evaluates potential decontamination technologies for
chemical agents. The U.S. EPA is tasked to remediate sites contaminated with these agents after they are
released, and it is unknown how effective many of these available technologies are. In this study, a high
priority research gap is addressed as identified by EPA program office partners through the evaluation of
the effectiveness of decontamination solutions on porous or permeable materials.
1.2 Objectives
The main objectives for this study were to provide decontamination efficacies of four chemical agent
decontaminants on porous or permeable materials. Secondary objectives were to develop a laboratory
wipe method for determining residual agent on surface materials and to demonstrate that this method
neutralizes the decontaminant to avoid bias in efficacy results.
Four decontamination products were evaluated for their ability to decontaminate porous surfaces that
have been contaminated by chemical warfare agents, O-ethyl S-[2-(diisopropylamino)ethyl]
methylphosphonothioate (VX) and bis(2-chloroethyl) sulfide (sulfur mustard, HD). The commercially
available decontaminant solutions tested were household bleach (Clorox® Company, Oakland,
California), household peroxide solution (HEB Grocery Company, San Antonio, Texas), EasyDecon®
DF-200 (Intelagard, Inc., Lafayette, Colorado), and DeconGel® 1108 (CBI Polymers, Richardson, Texas).
The surfaces tested were all associated with various materials of construction used in (underground)
transportation systems. These materials included: standard window glass, glazed ceramic tile, rubber
molding, and concrete sealant. To evaluate the concrete sealant, the sealant was applied to sandstone tile.
These materials provided different surface porosities that could affect decontamination efficacies. Glass
was included as a nonporous reference material.
The decontaminants were evaluated by determining the decontamination efficacy for each surface.
Decontamination efficacy is derived from the amount of agent removed from the material surface by the
decontaminant and normalized to the amount recovered if no decontamination had occurred, as shown in
Equation 1. Using the agent amount recovered without decontamination normalizes the results to focus on
agent losses from the decontamination process and ignores agent losses associated with natural
attenuation.
To determine collection efficiency, a wipe collection method was developed and used to measure residual
agent on the material surface. Since the wipe would also collect residual decontaminant, the developed
extraction method included a biphasic solution (dichloromethane and aqueous buffer) and additives to
neutralize and remove residual decontaminant to accurately quantify agent mass in the extracts.
Recognizing that an agent would penetrate porous material and would not be collected by the wipe
sample, a coupon extraction method was also used. Decontamination efficacy was based on both the wipe
results and the combined wipe and coupon results.
Decontamination Efficacy =
Residual Agenter decontamination
Residual Agenti^0 decontamination
x 100%
Equation 1
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A demonstration of the wipe method was conducted to assess agent stability in wipe extracts, high
extraction efficiency and precision, high collection efficiency and precision, and to verify the
decontamination efficacy testing process.
1.3 Approach
The approach used to evaluate the four commercially available decontamination solutions on the four
surface materials is identified in the scheme shown in Figure 1.
Times Recorded
>
f \
f
>
r
>
f \
f
Coupon
Coupon
Contamination
(5 - 2uL drops)
Weathering Time
for Test Coupons
(VX - 24 h; HD - 4 h)
Treatment Time
(Spray Appl: 1 h)
(DeconGel® Appl: 72 h)
Drain/Peel
Decontaminant
(< 30 sec)
Wipe Surface
Sampling
(< 1 min)
Coupon Extraction
by Sonication
(10 min)
Preparation
Weathering Time for Positive Controls
(Spray Application Decontaminants: VX - 25 h; HD - 5 h)
(DeconGel® Application: VX - 96 h; HD - 76 h)
T
Start Time
End Time
Figure 1: Decontamination Efficacy Test Scheme
Coupons for each surface material were prepared and visually inspected for defects. Agent was applied to
the test coupons in five uniform droplets (oriented as five dots on a die). After agent application, the
coupons were stored for 24 h for VX and 4 h for HD in closed plastic containers to prevent air flow from
effecting sorption or attenuation on the surface. During this agent-material contact period, temperature
and percent relative humidity were monitored. After the agent-material contact period expired, the
decontaminant was applied to the test coupons. Positive control coupons were not treated with
decontaminant. Bleach, peroxide, and EasyDecon® DF-200 solutions were sprayed onto the test coupons
and were allowed to interact with the surface for 60 minutes. DeconGel® 1108, designed to form a
removable dry film over the contaminated material, was applied to the surface and allowed to dry for 72 h
before removing. After coupon treatment, wipe samples were taken from the coupon surface, and the
coupon was then extracted.
Collected wipe samples were extracted using a method specifically developed to neutralize residual
decontaminant collected during the wiping process. Wipe and coupon extracts were assayed to determine
the amount of agent on the coupon after decontamination and to identify toxic agent decomposition
products formed from decontamination.
1.4 Experimental Design
The decontamination efficacy test matrix is presented in Table 1.
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Table 1: Decontamination Efficacy Test Matrix
Agent
Decontaminant
Agent-
Material
Treatment
# of Coupon2 Replicates per Surface and Sample
Type3
Contact
Time1
Glass
Ceramic
Tile
Concrete
Sealant
Rubber
Molding
Spray Control
25-h
--
1-SB 3-PC
1-SB 3-PC
1-SB 3-PC
1-SB 3-PC
Bleach
24-h
1 h
2-PB|5-TR
2-PB|5-TR
2-PB|5-TR
2-PB|5-TR
VX
Peroxide
24-h
1 h
2-PB|5-TR
2-PB|5-TR
2-PB|5-TR
2-PB|5-TR
Easy Decon®
24-h
1 h
2-PB|5-TR
2-PB|5-TR
2-PB|5-TR
2-PB|5-TR
Gel Control
96-h
--
3-PC
3-PC
3-PC
3-PC
DeconGel®
24-h
72-h
2-PB|5-TR
2-PB|5-TR
2-PB|5-TR
2-PB|5-TR
Spray Control
5-h
--
1-SB 3-PC
1-SB 3-PC
1-SB 3-PC
1-SB 3-PC
Bleach
4-h
1 h
2-PB|5-TR
2-PB|5-TR
2-PB|5-TR
2-PB|5-TR
HD
Peroxide
4-h
1 h
2-PB|5-TR
2-PB|5-TR
2-PB|5-TR
2-PB|5-TR
Easy Decon®
4-h
1 h
2-PB|5-TR
2-PB|5-TR
2-PB|5-TR
2-PB|5-TR
Gel Control
76-h
--
3-PC
3-PC
3-PC
3-PC
DeconGel®
4-h
72-h
2-PB|5-TR
2-PB|5-TR
2-PB|5-TR
2-PB|5-TR
1. Agent-Material Contact Time is time from agent contamination to initial treatment.
2. Coupons (4-inch x 4-inch) represent materials found in underground transportation systems.
3. SB: Surface Blank not contaminated and not treated; PC: Positive Control contaminated but not treated; PB: Procedural Blank
not contaminated but treated; TR: Test Replicate contaminated and treated.
For the spray decontamination solutions (bleach, peroxide, and EasyDecon® DF-200), decontamination
efficacy testing was segregated by surface material type and agent type, i.e., all HD decontamination tests
on glass coupons were conducted together. For DeconGel® 1108, testing was conducted on all surface
materials at the same time.
For each agent and material type, there were one surface blank (SB), three positive controls (PC), two
procedural blanks (PB) for each decontamination solution, and five test replicate (TR) coupons for each
decontamination solution. The surface blank was not spiked with agent and not treated by any of the
decontamination solutions (negative control). Positive controls were spiked with agent but not treated
with any of the decontamination solutions. These control coupons remained in contact with agent for the
total duration of both agent-material contact time and decontamination treatment time. The positive
controls were used to calculate decontamination efficacy for given agent/surface contact time to allow for
separation of decontaminant efficacy from other losses in the amount of agent recovered due to, e.g.,
evaporation losses from the surfaces. The procedural blanks were not spiked with agent but were treated
by one of the decontamination solutions. The procedural blanks were used to verify that there were no
contaminants observed from the decontamination solution or the interaction of the decontamination
solution and the surface material that could interfere with agent detection. The procedural blanks were
also used to verify that there was no cross-contamination from the handling and extraction process. The
test replicates were spiked with agent and treated with one of the decontamination solutions.
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2. PROCEDURES
2.1 Decontamination Solutions
This study evaluated four chemical agent decontamination solutions: household bleach solution, 3%
peroxide solution, EasyDecon®DF-200, and DeconGel® 1108. The first two products are readily available
in retail stores. The latter two products were developed for chemical and/or biological agent
decontamination or encapsulation purposes. Decontamination solution information is presented in Table
2.
Table 2: Decontamination Solution
Decontaminant
Lot#
Distributor
Active Ingredient
Clorox® Bleach
A515101TX-1
11:38R
Clorox® Company
Oakland, California
7.3% sodium hypochlorite1
Topical Solution
USP
L0014877FA
HEB Grocery Company
San Antonio, Texas
3.1% hydrogen peroxide2
EasyDECON®
DF200
(Part 1) 1537
Intelagard
Lafayette, Colorado
;?-Alkyl(C 12-C16) N, N-dimethyl N-
benzylammonium chloride
(Part 2) 120314
8.0% hydrogen peroxide
(Part 3) 16119
Diacetin
DeconGel® 1108
Not available
CBI Polymers, Metis
Scientific
Richardson Texas
Polymer gel designed to encapsulate
Verified by Iodometric Method 4500-C1 B (American Public Health Association Method 4500-CL: Standard
Methods for the Examination of Water and Wastewater, 21CFR 165.110(b)(4)).
2 Verified by American Chemical Society Specification, Reagent Chemicals 8th ed. -Hydrogen Peroxide Assay.
The first three solutions are aqueous-based and were applied via spray bottle. The DeconGel® 1108 is a
thick polymer and is typically applied to surfaces via paint brush, roller, or trowel. The DeconGel® 1108
was applied using a large syringe.
EasyDecon® DF-200 consists of three solutions. For each test, the three EasyDecon® DF-200 solutions
were combined within six h of application.
2.2 Surface Materials
The four surface types selected to evaluate the decontamination solutions were glass, ceramic tile, rubber
base molding, and concrete sealant applied to sand stone. Sure Klean® Weather Seal Siloxane PD
concrete sealant was applied to sandstone to simulate application to concrete. While the texture of
sandstone is similar to concrete, sandstone does not have the pits and cracks that concrete does. Each
material was acquired or cut into approximately four-inch square coupons. Information for each material
is provided in Table 3.
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Table 3: Coupon Materials to be Used for Decontamination Efficacy Testing
Material
Retailer
Dimensions
Part Number
Description
Glass
Tliad Ziegler Glass, Ltd.
2202 Jackson Keller
San Antonio, Texas 78230
Length 4 inch
Width 4 inch
Thickness 0.09 inch
NA
Window glass
Glazed Ceramic
Tile
Floor Decor
5776 Stemmons
San Antonio, Texas 78238
Length 4.25 inch
Width 4.25 inch
Thickness 0.25 inch
914100885
Bright White Ice
Rubber Base
Molding
Professional Flooring
Supply
12625 Wetmore Rd.
San Antonio. Texas 78247
Length 4 inch
Width 4 inch
Thickness 0.125 inch
#60CR1P100
Roppe "Pinnacle
Rubber Black" Wall
Cove Base (coupons
cut)
SandStone Teak
Honed
(substrate for
concrete sealant)
Floor Decor
5776 Stemmons
San Antonio, Texas 78238
Length 3.75 inch
Width 3.75 inch
Thickness 0.44 inch
933100122
Sandstone Honed
4x4 Teak CASA
ANTICA
Concrete Sealant
San Antonio Masonry' and
Tool Supply
7480 FM 1560 N
San Antonio, Texas 78254
NA; applied to
backside of sandstone
tile
SKWS1
Sure Klean"
Siloxane PD
Lawrence, Kansas
Photographs of the coupons are shown in Figure 2. The glass was ordered from a local glass company
already cut to specifications. The glazed ceramic bathroom tile was purchased and used as is. The
rubber base molding was purchased as a roll (6-inch x 120-foot). Coupons (4-inch x 4-inch) were cut
from the roll by removing an inch from both top and bottom of the roll and cutting 4 inch sections.
Figure 2: Glass, Ceramic, Rubber, and Sealant/Sandstone Coupons
Sure Klean® Siloxane PD is a water-based silane/siloxane water repellent sealant used on concrete and
masonry surfaces. The sealant was applied to sandstone coupons for decontamination efficacy evaluation.
Prior to application, the sandstone tiles were inspected for defects, cleaned, dried in an oven at 90
degrees Celsius (°C) for 24 h, and left under ambient conditions for one week. The cleaning process
included washing the coupons with labware detergent (Contrex AP, Decon Labs, Inc., King of Prussia,
Pennsylvania) and tap water, rinsing with warm tap water (49 °C) followed by two rinses with deionized
water. The sealant was applied to the back side of the sandstone because the face appeared to have a
finish. Two coats of Sure Klean" Weather Seal Siloxane PD Sealant were applied by paint brush to each
sandstone coupon with 48 h drying time between coats. After four days of air drying, coupons were
stored in a closed container until testing.
The other coupons were inspected for defects on the test surface, washed and rinsed thoroughly to
remove any residues from the test surface. Coupons with divots, cracks, scratches, or any observable
defects were excluded from testing. Coupons were washed with labware detergent and tap water, rinsed
with warm tap water followed by two rinses with deionized water, and dried. Glass and ceramic coupons
were placed in the oven at 90 °C for 20 minutes (min). The rubber was allowed to air dry under ambient
conditions on a laboratory bench. Coupons were stored in sealed Ziploc bags until needed for testing.
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2.3
Chemical Warfare Agent Purity
Chemical Agent Standard Analytical Reference Material (CASARM) stocks were used to prepare
analytical standards for instrument calibration. HD, lot# HD-U-5032-CTF-N, 98% purity used for
decontamination testing was CASARM-certified material with a purity of 98%. VX, lot# VX-U-5251-
CTF-N. 98.5% purity, was not CASARM-certified. VX purity was determined by 'C-Nuclear magnetic
resonance (NMR) and 1P-NMR to be 98.5%.
2.4 Testing Timeline
Figure 1 illustrates the test process from agent spiking through coupon extraction. Timing for agent-
material contact and decontaminant treatment was critical for reducing variation in the test results. A
timeline was developed that specified actions on each coupon at a specific time to ensure that each
coupon was kept under the same time constraints. The timeline was maintained by an individual who
communicated instructions to the operators performing the work, documenting issues/observations as
they occurred, and recording times. This process was essential to ensure all test sequences were
performed in the same sequence and across identical time intervals.
2.5 Agent Spiking
To address safety concerns and mitigate agent loss from airflow across coupon surfaces, coupons were
placed in plastic storage containers with removable lids prior to agent spiking and remained in the
containers through the agent-material contact time and the decontamination treatment processes. The
storage container is presented in Figure 3. The dimensions of the storage containers used were 10.5-inch
* 14-inch M 4-inch, and the containers would hold up to six coupons.
Figure 3: Storage Container for Agent Contaminated Coupons
Liquid agents VX and HD were applied to the coupons using a Hamilton 1700 Series Gastight syringe
(Fisher Scientific, Houston, Texas; model 8()920-50uL) affixed to a Hamilton Repeating dispenser
(Model 8370-PB600). In this configuration, the syringe is capable of delivering 2 microliter (|llL) drops.
Five droplets were spiked onto each coupon in the pattern of a square with a dot in the middle. The
droplet pattern was centered on the coupon with all agent droplets at least 1 inch from the coupon edges.
Initial extraction tests conducted for the wipe demonstration indicated poor agent collection efficiency
from the sealant/sandstone. To ensure that sufficient agent is recovered to calculate decontamination
efficacy, the amount of agent applied was increased. For the sealant/sandstone coupons, five 10 j.iL
droplets were applied (total volume applied was 50 pL) using Fppcndorf ; Repeater Stream (Fisher
Scientific, Houston, Texas; catalog 022460803) with 0.1 mL Hppendorf Combitips (Fisher Scientific,
Houston, Texas; catalog 0030089405). All other coupon types were spiked with five 2 pL droplets (total
volume applied was 10 pL).
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2.6 Agent-Material Contact Time
The agent-material contact period was the time between spiking the agent and the decontaminant
application on the coupons. Agent spike, decontaminant application, and coupon extraction times were
recorded to ensure accurate agent-material contact and decontamination treatment times. The agent-
material contact time was four h for HD and 24 h for VX test replicate coupons. The extended contact
times (typically 30 min to one h for nonporous material decontamination studies) were intended to allow
for potential permeation of agent into the porous materials to occur. For positive control samples, the
agent-material contact period was extended to include the decontaminant treatment time. For example, the
HD positive control samples for the spray decontaminants were left for five hours and the positive control
samples for DeconGel® 1108 were left for 76 h.
Coupons were stored in multiple plastic containers according to agent, decontaminant, and test/control
type. For example, test coupons treated with bleach were not stored with control samples or test coupons
for other decontaminants. After the coupons were spiked with agent, the containers were closed using the
container lids to prevent air flow across the coupons and minimize attenuation during the agent-material
contact period. Calibrated Omega temperature and humidity data loggers (Omega Engineering, Stamford,
Connecticut; part number (PN) OM-EL-USB-2) were used to monitor environmental conditions in the
plastic containers during agent-material contact time. The data loggers were programmed to collect
temperature and humidity readings at one-minute intervals.
2.7 Decontamination
Once the agent-material contact time had elapsed, the test coupons were treated with decontaminant
solutions (bleach, 3% peroxide, and EasyDecon® DF-200) using a glass oil mister (Prepara Kitchen
Tools, New York). The decontamination treatment duration was one hour for bleach, peroxide, and
EasyDecon® DF-200. Midway through the decontamination treatment duration, coupons were visually
checked to verify that the surface still had decontaminant on the material surface. After application of the
decontaminants, the containers were closed to prevent airflow across the coupon surface. Temperature
and humidity were not monitored during decontamination treatment. One hour after application, test
coupons were turned onto their side to drain residual decontaminant solution that was discarded to waste.
Coupon wiping and extraction followed thereafter. Liquid waste potentially containing residual chemical
agent was not analyzed in this study.
Preliminary application testing of DeconGel® 1108 indicated that the film was still tacky after 48 h. To
ensure that the film was completely dry, the decontamination treatment duration for DeconGel® 1108 was
72 h. After application of the DeconGel® 1108, the containers were left open to allow air flow across the
coupon surface to promote DeconGel® 1108 drying. The containers for the positive controls associated
with the DeconGel® 1108 were kept closed for the entire duration.
2.7.1 Spray Application
The decontamination solutions were applied using a glass oil mister (shown in Figure 4). This sprayer
was small, easy to handle, and had a consistent misting spray result. The container was pressurized using
the white top, and the liquid was atomized as the trigger was pressed. An application method was
developed using water and verified using each of the decontaminant solutions.
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Figure 4: Glass Oil Mister
The application method included the following steps. The mister bottle was filled with decontamination
solution to the maximum fill line identified on the bottle. The green top was tightened snugly to prevent
pressure loss. The white cap was placed over the green top and pumped four times. A four-sided acrylic
box (application chamber shown in Figure 5) was placed around the coupon being treated to prevent
overspray. The bottle was positioned horizontally and resting against the top of the application chamber.
The trigger was pressed for seven seconds while moving the bottle side to side to get even coverage over
the coupon. Before spraying the next coupon, the green cap was loosened to vent the pressure, tightened
snugly, and the bottle was pumped four times.
Figure 5: Application Chamber for Spraying Decontaminant Solution
Bottles were dedicated to a particular decontaminant solution. Each bottle was calibrated using the
decontaminant solution before and after each test set. At the end of the test set, the decontamination
solution was removed and the bottle/nozzle rinsed thoroughly with water. The calibration consisted of a
total of 14 replicate sprays (seven before testing and seven after testing). Each spray was collected in a
beaker, and the mass of the decontamination solution was measured using a balance. The average and
standard deviation for the 14 data points was calculated. Calibration results are summarized in Table 4.
There were observable losses during treatment due to some of the decontaminant coating the sides of the
application chamber. The gravimetric loss was determined to be 21% (seven replicates, 11% RSD). The
corrosive nature of the decontamination solutions did affect the sprayer and resulted in spray bottles being
replaced frequently.
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Table 4: Spray Bottle Calibration Results
Test Material
Agent
Mass of Bleach
Solution Applied
Mass of Peroxide
Solution Applied
Mass of EasyDecon" DF-2G0
Solution Applied
Glass
HD
4.7 g/11% RSD
5.0 grams (g)/
16% RSD
4.0 g/9.3% RSD
VX
4.4 g/10% RSD
4.9 g/5.7% RSD
4.3 g/6.7% RSD
Ceramic
HD
3.8 g/6.7% RSD
5.1 g/6.6% RSD
4.4 g/5.1% RSD
VX
4.6 g/6.6% RSD
5.0 g/7.3% RSD
4.5 g/6.6% RSD
Sealant
HD
5.9 g/6.9% RSD
5.5 g/6.2% RSD
5.0 g/6.7% RSD
VX
5.8 g/9.0% RSD
5.6 g/6.6% RSD
5.0 g/5.2% RSD
Rubber
HD
5.6 g/7.4% RSD
6.2 g/4.8% RSD
5.0 g/11% RSD
VX
5.6 g/12% RSD
6.2 g/4.7% RSD
4.3 g/7.6% RSD
2.7.2 DeconGef 1108 Application
The DeconGel® 1108 solution was applied using a 60 mL plastic syringe (Becton, Dickinson and
Company, Franklin Lakes, New Jersey) with a 1 cm diameter bored opening at the syringe tip, as shown
in Figure 6. For each applicable coupon, 25 mL of the viscous solution was slowly poured onto the
coupon in a circular motion to minimize bubble formation and generate an even surface. The
decontamination contact time for the DeconGel* 1108 was set for 72 h. After application of the
DeconGel1" 1108, the containers were left open to allow air flow across the coupon surface. At the end of
this period, the dried DeconGel® 1108 was peeled off the test coupons and disposed of via hazardous
waste. The dried DeconGel0" 1108 was not analyzed for presence of residual chemical agent. Coupon
wiping and extraction followed.
Figure 6: DeconGef® 1108 Syringe Applicator and Application onto a Coupon
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2.8 Sample Collection
Residual agent remaining on the coupon was determined by collecting a wipe sample and by extracting
the whole coupon. The surface wipe allowed for quantification of agent residue on the surface and
represents a contact hazard. The coupon extraction can remove more of the agent residue on the surface
and to some degree can extract agent that has penetrated into the material.
2.8.1 Wipe Collection Method
A white microfiber cloth (Anypromo, Chino, California) (2-inch x 3-inch) was used for collecting wipe
samples. This material was selected following wipe method development. The microfiber was cleaned by
washing with dichloromethane (Fisher Scientific, Houston, Texas) wetting with solvent (isopropyl
alcohol or acetone) and air drying at room temperature covered with foil rinsed with acetone (Fisher
Scientific, Houston, Texas). Once the microfibers were dry, they were stored in a Ziploc® bag until
testing. Control blank wipes were conducted by wetting the wipe material with solvent and wiping a clean
glass plate. The microfiber cloth was placed in a 20 mL Volatile Organic Analyte (VOA) vial with cap
(Thermo Scientific, Grand Island, New York) and wetted with 1 mL of isopropyl alcohol (Fisher
Scientific, Houston, Texas) prior to starting the tests. When the coupon was placed on the tray ready for
wiping, the damp microfiber cloth was removed from the capped vial with forceps. The wipe was folded
in half and wiped back and forth (east/west) motion from top to bottom moving in an 'S' pattern. The
wipe was folded in half so that the cloth surface used to wipe the surface was folded inward. The coupon
was wiped a second time in an up and down (north/south) motion from top to bottom. The wipe was
folded in half, dirty side inward. The coupon was wiped a third time starting from the outside corners and
following a circular pattern inward. The coupon was folded, dirty side inward, and placed into the
appropriately labeled vial already containing extraction solvent (5 mL dichloromethane and 5 mL of pH
buffer with sodium thiosulfate).
The wipe controls (two wipe blanks and three laboratory control spike [LCS] wipes) were also prepared.
For the wipe blank, the damp microfiber cloth was removed from the capped vial and placed into the
appropriately labeled vial already containing extraction solvent. For the wipe LCS, the damp microfiber
cloth stored in the capped vial was spiked with dilute agent (HD 2,500 nanograms (ng) or VX 1250 ng),
removed from the vial, and placed into the appropriately labelled vial already containing extraction
solvent. The agent spike amount was selected based on the detection limits of the analysis and the
anticipated agent recovery of the test replicates.
Special care was taken to prevent contamination between coupons. Butyl gloves and forceps were rinsed
with acetone and dried using Kimwipes™ (Fisher Scientific, Houston, Texas) prior to handling each
coupon.
2.9 Extraction Methods
2.9.1 Laboratory Wipe Method Development
The requirements for the laboratory wipe method development included a decontaminant quench and
method demonstration. Since the microfiber wipe would sorb residual decontaminant on the coupon
during collection, it was necessary for the extraction to neutralize the decontaminant to prevent further
agent decomposition in the extract. Decomposition in the extract could significantly affect variability and
overestimate decontaminant performance. A detailed description of the method development effort is
provided in Appendix A.
The wipe method was developed in three steps: wipe comparison, solvent system, and decontaminant
neutralization tests. The wipe comparison tests evaluated the collection efficiency of three types of wipes
(microfiber cloth from Anypromo, Chino, California; cotton gauze from Dukal Corporation, Hauppauge,
New York, Lot# A17610 27; and polyester cotton blend from Fruit of the Loom) using two types of
wetting solvent (acetone and isopropyl alcohol). The microfiber cloth performed slightly better than the
other materials on average but the performance was not statistically different. Wipes wetted with
isopropyl alcohol performed better than wipes wetted with acetone. The solvent system tests evaluated the
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wipe extraction efficiency of two volumes of the triphasic (dichloromethane and aqueous buffer) solvent
system at three agent spike levels. There was not a significant performance difference between the two
extraction volumes tested. Therefore, the extraction volume selected was 10 mL of the 1/1
dichloromethane/aqueous solvent system. The decontaminant neutralization tests were conducted to
investigate additives for neutralizing residual decontaminant solution that may be collected during the
wiping process. The three decontamination solutions tested were bleach, peroxide, and EasyDecon® DF-
200. EasyDecon® DF-200 consists of peroxide and an amine surfactant. Agent recovery performance was
compared from triplicate extract solutions with and without additives for each decontaminant solution.
Test results indicated that sodium thiosulfate (Fisher Scientific, Houston, Texas) was effective for
preserving agent in the presence of bleach and additives were not necessary for 3% peroxide. The amine
surfactant in EasyDecon® DF-200 was basic (pH 10) and caused HD to decompose.
Aqueous buffers were incorporated into the extraction system because the decontaminants were all
aqueous-based and the proposed additives were all miscible in aqueous solution. During wipe extraction,
the decontaminant should partition into the aqueous phase, immediately diluting and neutralizing the
decontaminant. Separate pH buffers were used for each agent. VX used a pH 10 buffer that consisted of
0.5 M Carbonate (Sigma Aldrich, St. Louis, Missouri) buffer and 1.25 M sodium thiosulfate, and HD
used apH 5 buffer that consisted of 1.0 M acetate (Fisher Scientific, Houston, Texas) buffer and 1.25 M
sodium thiosulfate. For VX, the pH 10 buffer was needed to partition VX into the dichloromethane layer.
The pH 5 buffer was used to prevent HD decomposition. The resulting method is described in Section
2.9.2.
2.9.2 Wipe Extraction Method
In a 20 mL VOA vial with Teflon-lined cap, 5.0 mL of dichloromethane and 5.0 mL of buffer (pH 10
carbonate buffer with sodium thiosulfate for VX extracts and pH 5 acetate buffer with sodium thiosulfate
for HD extracts) was added. After wiping each coupon with the 2-inch x 3-inch microfiber cloth, the
folded wipe sample was placed into the 20 mL VOA vial containing the extraction solution. The vials
were vortexed for 15 minutes. The wipe remained in the solvent system for a minimum of 30 min. The
extract, including the microfiber wipe, was filtered through 0.45 micrometer ((.un) Nylon syringe filter.
Sufficient time was allowed for the solution to separate into two layers. In some cases, a centrifuge was
used to expedite the separation. Approximately 4 mL of the dichloromethane layer (bottom) was removed
and placed into a 1 dram vial containing sodium sulfate to dry the dichloromethane. Aliquots of the dried
dichloromethane were prepared for analysis.
2.9.3 Whole Coupon Extraction
In addition to collecting a surface wipe, the coupon was extracted to provide information regarding
collection efficiency and determine agent penetration into the material. After collecting the wipe sample,
the coupon was carefully lowered into a stainless steel vessel as shown in Figure 7. The vessel contained
seven modules, each filled with dichloromethane for extracting coupons. The amount of dichloromethane
in each module was based on the coupon material type to ensure that the coupon was completely
submerged in solvent throughout the extraction process (Glass 200 mL, Rubber 200 mL, Ceramic tile 150
mL, and Sealant 130 mL). Once all of the holders were filled, the stainless steel vessel was covered with
foil and placed into a sonicator. The samples were sonicated for 10 minutes. Effective cooling (ice-cold
water bath - no floating ice) was used to control temperature to minimize evaporation loss. The coupons
remained submerged in the extraction solvent for a minimum of one hour prior to collecting 4 mL aliquot
of the dichloromethane extract for analysis.
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Figure 7; Stainless Steel Coupon Extraction Vessel
After testing and collecting the extract, the coupons and excess extract were discarded to waste. The
vessel was cleaned between uses by thoroughly rinsing three times with acetone and drying.
2.10 Analytical Methods
The main focus of the analytical method was to quantify residual VX and HD to calculate the
decontamination efficacy. However, it is important to determine whether other toxic materials are being
formed from the decontamination process. Analysis was conducted using targeted methods and survey
methods. Targeted methods focused specifically on quantification of VX and HD. This analysis included
all of the calibration and QC analysis to support the calculated results. The survey methods were focused
on identification of unknowns (qualitative analysis).
Compound calibration curves consisted of six calibration points. The initial calibrations (ICALs) were
performed and met calibration criteria prior to assaying samples. The calibration curve was verified using
an initial calibration verification (ICY) standard at the mid-level that was independently prepared.
Samples were bracketed by passing continuing calibration verification (CCV) standards, assayed at a
minimum frequency of one CCV for every ten samples. Calibration acceptance criteria are identified in
Table 5. Failure to meet acceptance criteria requires instrument maintenance and performing another
initial calibration curve.
Table 5: Calibration Acceptance Criteria
Type
Acceptance criteria
Frequency
Calibration Curve (ICAL)
(coefficient of determination, RJ > 0.99 or
%RSD <20%) and
70-130% accuracy of the true concentration
Before sample analysis begins and
after ICV or CCV failure
Initial Calibration
Verification (ICV)
75-125% accuracy
After Calibration but before sample
analysis begins
Continuing Calibration
Verification (CCV)
75-125% accuracy
Between the sample series, every
ten samples at a minimum
Instrument Solvent Blank
No hits in the agent retention time window
Bracketing CCV standards and after
ICV
Internal standards (ISs) were used for determining instrument drift or matrix interferences that affect
response. Internal standards were spiked into all standards and samples at the same level and included in
the calibration curve calculations. The internal standard acceptance criteria are identified in Table 6. All
results met these criteria.
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Table 6: Internal Standard Acceptance Criteria
Type
Acceptance Criteria
Frequency
Calibration (ICAL)
%RSD < 20%
All Standards
Continuing Calibration Verification (CCV)
100 ±25% of ICAL
All Standards
All Samples and QC
100±50% of previous CCV
All Samples
2.10.1 GC/MS (HD-Targeted Analysis)
The instrument used for HD analysis was an Agilent (Santa Clara, California) 6890 gas chromatograph
and 5973 quadrupole mass spectrometer operated in electron ionization (EI)+ selected ion monitoring
(SIM) mode. Acquisition parameters are provided in Table 7. The samples were analyzed using a six-
point standard calibration curve ranging from 5 to 100 ng/mL calculated using relative response factors
The instrument detection limit was 1 ng/mL. The internal standard naphthalene-d8 was spiked into all
standards and samples at 100 ng/mL.
Table 7; GC/MS Parameters for HD Analysis
Column Type
RTX-VGC, 30 m x 0.32 mm inner diameter (i.d.)
1.8 pm film thickness (No. 19419, Restek
Corporation, Bellefonte, Pennsylvania)
Column Program
60 °C initial temperature (temp), hold 0 min, 14
°C/min to 200 °C, hold 0 min, 40 °C/min to 240 °C,
hold 5 min
Transfer line Temperature
240 °C
Injection Port Temperature
210 °C
Carrier Flow Rate
1.5 mL/min constant flow
Injection
Pulsed Splitless (25 psi until 0.5 min., split 60
mL/min at 1 min.)
Injection Volume
2 |j,L
Acquisition Mode
Selected ion monitoring (SIM)
HD ions: 158 (quant), 109, 111, and 160 m/z*
napthalene-Ds: 136 (quant) and 108 m/z)
Electron Impact
70 electron volts (eV)
Ion Dwell Time/Scan Rate
100 milliseconds (msec) or approximately 2 scans
per second (sec)
MS Quad Temperature
Ui
o
o
O
MS Source Temperature
230 °C
*m/z = mass to charge ratio
2.10.2 LC-MS/MS (VX-Targeted Analysis)
The instrument used for VX analysis was an Agilent 6410 triple quadrupole mass spectrometer detector
(Santa Clara, California), with Agilent 1200 series pump and autosampler, operated in Electrospray
Ionization (ESI) positive ion multiple reaction monitoring (MRM) mode. The acquisition parameters are
identified in Table 8. The samples were analyzed using a six-point standard calibration curve ranging
from 2 to 60 ng/mL calculated using linear regression. The instrument detection limit was 0.5 ng/mL. The
internal standard deuterated diisopropyl methyl phosphonate (DIMP-di4) (Cerilliant, Austin, Texas, PN:
ERD-086) was spiked into all standards and samples at 4.0 ng/mL. Samples were also screened for EA-
2192, a toxic decomposition product of VX that could present a public health risks during VX cleanup
operations. EA-2192 transition ions were monitored, and a standard was assayed to determine the
retention time window, but the response was not calibrated.
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Table 8: LC-MS/MS Parameters for VX Analysis
Mass spectrometric source
Electrospray Ionization, positive ion mode
HPLC column
Allure PFP propyl, 2.1 mm x 150 mm, 5 (un or
equivalent (Restek No. 9169562)
HPLC column temperature
Ambient
Mobile phase components
A = water containing 2 mM formic acid and 2 mM
ammonium formate
B = acetonitrile containing 0.1% formic acid
Gradient profile - Group A
Time
(min)
% A
% B
Flow rate
(mL/min)
0
20
80
0.4
3
20
80
0.4
10
0
100
0.4
12
0
100
0.4
12.5
20
80
0.4
15
20
80
0.4
Injection volume
5 jiL
Drying gas (Type, flow, Temp)
Nitrogen, 11 L/min, 300 °C
Nebulizer
30 psig
Capillary Voltage
3500 V
Fragmentor
130 V
Acquisition Mode
Multiple reaction monitoring (MRM)
VX transition ions: 268—>128 (quant), 268—>86,
268—>167, and 268^139
DIMP-dw transition ions: 195—>99 (quant) and 195 —>80
EA-2192 transition ions: 240—>128 and 240 —>86
2.10.3 GC x GC/TOFMS (Survey Analysis)
Survey analyses for VX and HD extracts were conducted to identify agent decomposition products
formed from the decontamination process. The Pegasus® 4D GCxGC/TOFMS (Leco, St. Joseph,
Michigan) is a Two-Dimensional Gas Chromatograph Time-of-Flight Mass Spectrometer. The acquisition
parameters are identified in Table 9. Two orthogonal columns separated by a thermal modulator offer
high resolution chromatography. The TOF mass spectrometer provided spectra for National Institute of
Standards and Technology (NIST) library identification for eluting peaks. Spectral results were reviewed
for detections related to HD and VX. Most reported detections had a match quality greater than 650 out of
1000 with the exception of HD- and VX-related unknowns. These detections had characteristic HD and
VX ions but their spectra did not precisely match any of the library spectra. The samples were spiked with
semivolatile internal standard mix (Restek PN. 31206) at 1.0 micrograms per milliliter ((.ig/rnL). The
responses and retention times for the internal standards were used to monitor instrument drift.
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Table 9: GC x GC/TOFMS Parameters for Survey Analysis
Column 1 Type
RXI-1MS, 30 m x 0.25 mm i.d., 0.25 (un film
thickness (RestekNo. 13323)
Column 2 Type
RXI-17SilMS, 1.5 m x 0.18 mm i.d. 0.18 (im film
thickness (RestekNo. 14102)
Column 1 Program
50 °C initial temp, hold 2 min, 10 °C/min to 260 °C,
hold 0 min, 20 °C/min to 300 °C, hold 2 min
Column 2 Program
55 °C initial temp, hold 2 min, 10 °C/min to 265 °C,
hold 0 min, 20 °C/min to 305 °C, hold 2 min
Modulation
3 sec (0.75 sec hot pulse and 0.75 sec cold pulse) 2
cycles
Modulator Offset Temperature
+ 20 °C
Injection Port Temperature
260 °C
Transfer line Temperature
300 °C
Carrier Flow Rate
1.0 mL/min constant flow
Injection
Splitless (split 30 mL/min. at 1 min)
Injection Volume
1 |o,L
Acquisition Mode
EI, scan range 45-600 m/z
Acquisition Rate
100 spectra/sec
Electron Impact
70 eV
MS Source Temperature
225 °C
2.10.4 LC/qTOF (Survey Analysis)
An Agilent 6540 UHD Accurate Mass Q-TOF LC/MS instrument used to survey VX sample extracts was
operated in ESI+ scan mode. The acquisition parameters are identified in Table 10. Samples were
processed using Agilent Mass Hunter software. An internal standard, diisopropyl methyl phosphonate-di4,
was spiked into all samples at 100 ng/mL and was used to verify instrument stability and estimate relative
concentrations of peaks detected. Data results identified molecular formulas based on mass accuracy of
less than 5 parts per million (ppm).
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Table 10: LC-qTOF Parameters for Survey Analysis
Mass spectrometric source
Agilent Jet Stream Electrospray Ionization, positive ion
mode
HPLC column
Allure PFP propyl, 2.1 mm x 150 mm, 5 (.un or
equivalent (RestekNo. 9169562)
HPLC column temperature
Ambient
Mobile phase components
A = water containing 0.1% formic acid
B = methanol containing 0.1% formic acid
Time
% A
% B
Flow rate
(min)
(mL/min)
0
98
2
0.4
2
98
2
0.4
Gradient profile - Group A
17
25
75
0.4
20
0
100
0.4
23
0
100
0.4
23.01
98
2
0.4
25
98
2
0.4
Injection volume
5 jiL
Drying gas (type, flow, temp)
Nitrogen, 8 L/min, 325 °C
Nebulizer
35 psig
Capillary Voltage
3500 V
Fragmentor
175 V
Skimmer
65 V
Sheath gas temp, and flow
350
°C and 11 L/min
Acquisition Mode
Scan
2.11 Calculations
The following calculations were used to evaluate the data and determine decontamination efficacy. These
calculations are documented in Chemical Contaminant and Decontaminant Test Methodology Source
Document [1]. All wipe and coupon extract results were converted to total mass (nanograms) using
Equation 2. Average total mass was calculated for each set.
Total Mass= Extract Concentration,na , x Extract Volume x Dilution Factor
mL '
Equation 2
Recoveries were calculated for all spiked samples. Percent recovery was based on the theoretical spike
amount using Equation 3. Average percent recovery and percent Relative Standard Deviation (RSD) were
calculated for each set.
Recovery(o/o) = (Found Total Mass^g^ x 100 )/Spike Mass^g^
Equation 3
RSD was calculated for positive control and test replicates using Equation 4.
Standard Deviation of Replicates
%RSD =
Average of Replicates
Equation 4
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The percent efficacy calculation is presented in Equation 5. This equation uses the positive control to
normalize the data to exclude losses from attenuation, collection, and extraction efficiencies. For most
materials, efficacies were calculated for wipe only and combined wipe and coupon. For the
sealant/sandstone, efficacies were calculated from the coupon only.
Efficacy =
Average Total MassTest
Replicates
Average Total Massp0S(£(ve controls -
x 100%
Equation 5
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3. QUALITY ASSURANCE I QUALITY CONTROL
This work was conducted under a certified quality system that meets International Organization for
Standardization (ISO) 9001:2008 Quality Management requirements.
3.1 Process and Data Quality Audit
Quality Assurance (QA) personnel reviewed the Quality Assurance Project Plan (QAPP), all procedures,
and conducted surveillances on the method demonstration and efficacy testing processes to verify
compliance. The method demonstration surveillance identified several recommendations that were
incorporated into efficacy testing. The efficacy surveillance identified one unsatisfactory finding,
DeconGel® 1108 was not sufficiently dry for collection at 24 h. EPA was notified and the finding was
addressed by repeating the tests with a 72-hour drying time.
Analytical data packages were assembled according to contract requirements. The data were peer
reviewed and validated by QA personnel. There were several findings, and corrective actions are
identified as follows: 1) DeconGel® coupons were still wet after 24 h. Subsequent tests were performed
using a 72 h drying time. 2) Initial tables were put together using data where the ending CCVs failed.
Affected samples were reanalyzed with passing CCV values; tables were updated with these data meeting
all criteria. 3) Injection log and extraction log pages were not approved within a timely manner. Logs
were reviewed and approved. All of these findings were classified as minor, corrective actions were taken
immediately and none of the findings affected the data quality.
3.2 Quality Performance Indicators for Wipe Method Demonstration
Performance indicators for wipe method demonstration testing are presented in Table 11. The percent
difference between analytical results conducted on day 0 and day 3 after extraction was used to determine
whether residual decontaminant collected during wipe collection was sufficiently neutralized and agent
was preserved in the extract. The wipe LCS recovery and precision criteria were used to determine
whether the extraction process of the wipe only was sufficient. The positive control wipe recovery and
precision criteria were used to determine whether the collection efficiency of the wipe method was
sufficient. Failing recovery criteria would be an indication that a coupon extraction method would be
needed for efficacy testing. No recovery criterion was assigned for the decontaminant-treated coupons
because the decontamination was expected to neutralize most of the agent spiked onto the coupon.
Table 11: Agent Acceptance Criteria for Wipe Method Demonstration
Siimple Types
Purpose
Crilerfci
Wipe Blank
Verify no method interferences
No detections for VX/HD
Wipe LCS
Determine wipe extraction efficiency and
precision; verify extract stability
Rec: 100±25%, %RSD: < 25%
% Difference (Day 0 & 3) <20%
Positive Controls
Determine wipe collection efficiency and
precision; verify extract stability
Rec: 100±50%, %RSD: < 25%
% Difference (Day 0 &3) <20%
Test Replicates
Verify extract stability
% Difference (Day 0 &3) <30%
3.3 Wipe Demonstration Quality Control Samples
There were no agent detections for any of the control blanks (surface, procedural, and wipe method
blanks). A total of 12 LCS samples were assayed for each agent. All LCS samples met recovery criteria
(HD average (avg.) Recovery 96%, 9% RSD; VX avg. Recovery 95%, 13% RSD) demonstrating
acceptable extraction efficiency. A summary of the wipe positive control results is presented in Table 12.
Collection efficiency was demonstrated for glass and ceramic. However, the more porous materials did
not meet requirements. Based on these results, a coupon extraction was included for efficacy testing.
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Table 12: Summary of Wipe Positive Control Results
Test Set
HD
VX
Average Recovery
%RSD
Average Recovery
%RSD
Glass
95%
17
103%
11
Ceramic
64%
5.3
81%
15
Rubber
36%
15
40%
82
Sealant
<0.2%
43
<0.2%
53
Stability was demonstrated by assaying the extracts twice. The intention was to assay extracts
immediately after extraction (day 0) and on day 3. However, scheduling conflicts resulted in the second
analysis being assayed on day 4 for VX and day 9 for HD. The average concentration for all HD extracts
increased by 18%. VX samples were assayed on day 0 and day 4 after collection and extraction, showing
an average concentration increase of 7%. Both results indicate that the method preserved the agent.
Several observations were made during the validation effort that allowed changes and adjustments to be
made for decontamination efficacy testing. The wipe only recovered trace amounts of agent from the
sealant/sandstone. The low overall recovery was assumed to be associated with the permeability of the
sealant/material combination. Considering that the agent-material contact time would be extended from 1
h to 4 h for HD and 24 h for VX, the agent spike amount on the coupon was increased from 10 (iL to 50
l_iL for sealant/sandstone. Collecting wipe samples from the sealant/sandstone was difficult due to surface
roughness and yielded less than 0.2% recovery for both agents. Based on this information, wipe samples
were not collected during decontamination efficacy testing. Interference problems for HD/rubber (coupon
and wipe) extracts were observed through high background, failing CCVs, and poor chromatography,
presumably due to high levels of phthalates (determined by GC x GC/TOFMS). This problem was
resolved by diluting all of the extracts by at least lOx. The above-mentioned changes were incorporated
prior to starting decontamination efficacy testing.
3.4 Quality Performance Indicators for Decontamination Efficacy
Performance indicators for efficacy testing are presented in Table 13.
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Table 13: Decontamination Efficacy Performance Indicators
Control Type
Purpose
Criteria
Surface Blank
Verify that the material has no interferences or cross-
contamination (1 per surface and agent type)
VX /HD less than 0.2 total |ig'
Positive Control
Determine collection efficiency (three per surface and
agent type)
Rec: > 10%, %RSD: < 30%
Recovery Standards
Verify agent spike amount (three per deposition batch
and agent type)
Rec: 100±15%, %RSD: < 15%
Procedural Blanks
Verify that there are no interferences from
decontaminant material interaction (two per
decontaminant surface and agent type)
VX /HD less than 0.2 total |ig
Wipe Blank
Verify that there are no interferences from extraction
process (one per 20 wipe samples)
VX /HD less than 0.02 total |ig
Wipe LCS
Determine extraction efficiency (one per 20 wipe
samples)
Rec: 100±35%RPD2: < 30%
1 Total |ig is the amount found from both wipe and coupon extracts
2 Relative percent difference
3.5 Efficacy Quality Control Samples
There were no agent detections for any of the control blanks (surface, procedural, and wipe method
blanks) with the exception of HD (0.35 pg) detected for the glass surface blank in the coupon extract.
This detection was below the calibration range (3xMDL) and less than 0.01% of the positive control
result. Based on the non-detection for the wipe extract, the detection resulted from cross contamination
with the positive controls during coupon extraction.
No significant interference issues were noted other than for dichloromethane extraction of the rubber
material (wipe and coupon). This issue affected HD-targeted GC/MS analysis. To mitigate this issue, all
rubber material HD extracts were assayed with a minimum dilution of lOx.
Two method blanks and three LCS samples were collected for every test set, resulting in eight method
blanks and 12 LCS samples for each agent. Wipe method QC results are presented in Appendix A. These
QC samples verified the performance of wipe extraction. All wipe QC samples met criteria. There were
no detections in the method blanks. The average recovery for all of the HD and VX replicates were 100%
and 92%, respectively, and the %RSD values were 6% and 4%, respectively.
A summary of the positive control results is presented in Table 16. The average recovery reported is
based on theoretical yield to include density and purity of the agent. During the initial wipe
demonstration, the positive control recoveries for the sealant and rubber materials were observed to be
low (less than 20% recovered) and highly variable. As a result, the recovery acceptance limit was set to
greater than 10% and %RSD set to less than 30%. The positive control failures were attributed to the
porosity of the sealant/sandstone substrate and HD attenuation over the three-day period. The porosity of
the sealant/sandstone also resulted in high variability between sample coupons. This variability is most
likely related to extraction inefficiencies due to agent penetration and possible substrate-induced
decontamination. The other failures were associated with the long HD material contact time. While HD is
considered persistent, it attenuates from surfaces overtime. Only a trace level of material was recovered
from the two most nonporous materials, glass and ceramic, whereas the sealant and rubber showed
recovery of substantially more material.
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Table 14: Summary of Positive Control Results
Agent
Type
Parameter
Glass
(Wipe Coupon)
Ceramic
(Wipe Coupon)
Sealant
(Coupon)
Rubber
(Wipe Coupon)
VX
Spray Control
(24 h)
Average
94%
74%
29%
77%
%RSD
20%
11%
10%
18%
Pass /Fail
P
P
P
P
Gel Control
(96 h)
Average
110%
73%
16%
69%
%RSD
7.1%
20%
55%
10%
Pass /Fail
P
P
F
P
HD
Spray Control
(5 h)
Average
61%
120%
27%
130%
%RSD
12%
7.0%
84%
19%
Pass /Fail
P
P
F
P
Gel Control
(76 h)
Average
<0.5%
<0.5%
2.2%
130%
%RSD
8%
20%
16%
13%
Pass /Fail
F
F
F
P
Three recovery standards (RSs) were prepared for each test set to determine the precision of the agent
applied to surfaces. Recovery standards were prepared by spiking agent directly into a glass vial. The
average recovery reported is based on theoretical yield to include density and purity of the agent. A
summary of the recovery standard results is presented in Table 15, and individual results are presented in
Appendix B. The recovery standard sets prepared for the HD Rubber tests and VX Sealant tests failed
with high recovery, while all recovery standard sets met precision guidelines of percent relative standard
deviation (%RSD) of less than 15%.
Table 15: Summary of Recovery Standard Results
Test Set
HD
VX
Average Recovery
%RSD
Average Recovery
%RSD
Glass
94%
5.1
99%
1.7
Ceramic
98%
12
96%
5.3
Rubber
160%
5.3
100%
6.3
Sealant
85%
15
140%
6.0
DeconGel®
89%
5.4
100%
8.0
3.6 QAPP Deviations
QAPP deviations included the following: the spray application chamber was modified to remove the top
plate, DeconGel® 1108 application process was modified, DeconGel® 1108 drying time extended from
one day to three days, wipe samples were not collected for sealant/sandstone samples, and the agent spike
amount on sealant/sandstone coupons was increased from 10 |_iL to 50 (.iL.
The spray application chamber identified in the QAPP assumed that the spray bottles would have a nozzle
that would protrude through a hole in the top plate. However, the selected spray bottle did not have a
protruding nozzle. The top plate would have interfered with the decontaminant application. As a result,
the top plate was not incorporated with the spray application chamber.
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The application process for DeconGel® 1108 included using a cover plate and weight to smooth out the
DeconGel® 1108. Preliminary testing revealed that the DeconGel® 1108 could spread out evenly across
the surface. The glass plate interfered with the drying process, and early removal of the plate disrupted the
DeconGel® 1108 coverage. As a result, the cover plate was not used.
Based on manufacturer's recommendations, DeconGel® 1108 was expected to dry within 24 h; however,
testing revealed that the DeconGel® 1108 was not completely dry within this time. Since DeconGel® 1108
was formulated to sorb agent into the gel, wet DeconGel® 1108 left behind after peeling would be
collected by wipe sampling and coupon extraction, resulting in inaccurate measurement of
decontamination efficacy. To insure adequate drying of DeconGel® 1108, the drying time was increased
from one to three days.
The sealant/sandstone test process was modified following wipe demonstration testing. Based on low
recoveries of the positive controls and the extended agent-material contact time for decontamination
efficacy testing, sealant/sandstone recoveries for decontamination efficacy testing were expected to be
lower with agent potentially not detected. As a result, the agent spike amount on the coupon was
increased from 10 (iL to 50 (iL for sealant/sandstone. Also, wipe collection from sealant/sandstone
yielded less than 0.2% recovery for both agents, and wipe samples were difficult to collect on the rough
surface. Thus, wipe samples were not collected during decontamination efficacy testing.
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4. RESULTS AND DISCUSSION
4.1 Test Conditions
4.1.1 Environmental Conditions during Agent-Material Contact
Temperature and humidity were tightly controlled during the agent-material contact period. Typical
tolerances for agent decontamination efficacy testing under controlled conditions were ±3 °C.
Temperature and relative humidity were monitored inside the storage containers during agent-material
contact time using data loggers recording at one-minute intervals. Temperatures and humidity ranges
were combined from multiple containers according to coupon type and are presented in Table 16. All
temperatures were 22 ±2 °C. Percent relative humidity was within the range of 56 ± 5%, with the
exception of the ceramic coupons. The high humidity observed for ceramic coupons was attributed to
moisture sorbed during the cleaning process. There were no visible signs of moisture on the ceramic
coupons during the spiking process. For HD ceramic containers, the humidity had not reached the
equilibrium at the end of the four-h agent-material contact period for most containers. The sorbed water in
the ceramic coupons could have affected agent penetration. Relative humidity readings for all other
coupons were consistent with laboratory ambient conditions.
Table 16: Temperature and Relative Humidity Range during Agent-Material Contact
Coupon Type
HD
VX
Temperature
(°C)
Relative
Humidity
(%)
Temperature
(°C)
Relative
Humidity
(%)
Glass
21.5-23.5
53-61
20.0-24.5
52-60
Ceramic
21.5-23.0
53-95
20.0-23.5
52-98
Rubber
21.0-23.0
53-58
20.0-24.0
52-61
Sealant
21.0-22.5
53-61
20.0-23.5
52-59
4.1.2 Agent-Material Contact Time
The agent-material contact time is the duration between the agent spiking event and application of the
decontamination solution. Since decontamination solution was not applied to the positive control samples,
the agent-material contact time for these samples extended to the coupon wipe collection and extraction
event. The agent-material contact time was controlled for each replicate to reduce the likelihood of this
parameter affecting variability in the results. The typical criterion is ±10% of the target time. The test
time schedule was set up for a maximum deviation of the target time to be less than five minutes. This
schedule was followed for all coupons except DeconGel® 1108 positive controls. Unexpected delays for
removal of DeconGel® 1108 test replicates affected the extraction time of DeconGel® 1108 positive
controls. This delay affected four positive control data sets: VX/sealant (20 min), HD/sealant (45 min),
VX/rubber (30 min), and HD/rubber (56 min). While the deviation exceeds the five-minute target, the
deviation between the actual time and the targeted time was less than 2%. In each of these cases, the
range between replicates in the set was within five minutes. For all tests, the maximum range between
replicates within a test set was eight minutes. Considering the agent-material contact time was between
four h and 96 h, these deviations were insignificant and do not affect decontamination efficacy results.
4.1.3 Decontaminant/ Material Treatment Time
The decontamination/material interaction time is the duration between the application of decontaminant
and the coupon wipe collection and extraction event. For the spray decontaminant solutions (bleach,
peroxide, and EasyDecon® DF-200), the interaction time was 60 minutes. For DeconGel®, the interaction
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time was three days (4320 min). The typical criterion is ±10% of the target time. The test time schedule
was setup for a maximum deviation of the target time to be less than three minutes with a maximum range
of three minutes between test replicates. For the spray decontaminants, only the HD/glass/peroxide and
HD/glass/EasyDecon® DF-200 exceeded the three-minute deviation between the actual and targeted time
duration (five min). These values were within the standard ±10% of the target time. Several of the
DeconGe! 1108 tests exceeded the targeted duration up to 38 min; however, over the duration of three
days, this amounts to less than a 1% difference. The deviations between the targeted time and actual
duration and the duration range between test replicates were insignificant and do not affect
decontamination efficacy results.
4.1.4 Spray Decontaminant Application
The requirements for decontaminant delivery include the use of a sprayer that would not spray the
decontaminant on the surface material with a force that could dislodge agent droplets from the surface
material, that would evenly coat the coupon surface, and the decontaminant would saturate the surface. A
number of sprayers were tested for qualification, and only one type met these requirements. A
standardized application method was developed to apply the decontaminants to the materials consistently.
A typical criterion for decontaminant delivery is ±10% of the target amount. Based on calibration results,
this criterion was not met for a number of tests conducted. Calibration results are shown in Table 4. The
calibration results do not take overspray into account but provide an optimistic amount of decontaminant
applied to the coupon surface. While the deviation of the decontaminant amount applied to the different
test replicates could affect the sample results, this is probably irrelevant considering that the entire surface
was saturated with decontaminant during application, and visual observations were noted after
application.
4.1.5 DeconGel® 1108 Application
The DeconGel* 1108 application process changed significantly from original intentions. The approach
initially included the use of a glass plate and weight to distribute the DeconGel® 1108 uniformly. Initial
testing indicated that the glass plate and weight were not needed and interfered with the drying process.
Furthermore, sides of the coupons had to be elevated to contain the DeconGel® 1108 on the surface (see
Figure 8).
Figure 8: DeconGef® 1108 applied to ceramic tile with glass plate covering
Based on manufacturer's recommendations, the DeconGel " 1108 should be applied at 1/8-inch thickness
(wet) and allowed to dry for approximately 24 h. Modifications to contain the DeconGel 1108 on the
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surface included adhesive tape on the side edges and underneath the coupon. Initial demonstrations
indicated that these modifications would work, assuming adequate air flow across the coupon surface.
Decontamination efficacy testing was initially conducted with a 25-h drying/cure time. Most coupons
recovered after 25 h after DeconGel' 1108 application were dry on the top surface but consistently tacky
underneath. Coupons collected at 48 h were more cured and less tacky, while coupons collected at 72 h
after application appeared to be completely cured/dry. DeconGel " 1108 efficacy was re-tested using a 72-
hour cure time. For the DeconGel 1108 efficacy testing (72-h), there were a few coupons that were still
slightly tacky on the edges, but the film that contacted the surface directly over the agent deposition spot
was dry. Photographs of DeconGel * 1108 with an initial application of 25 niL and after curing for 72 h
are presented in Figure 9. The application of 25 mL yields a uniform thickness of 0.125 inch wet and less
than 0.0625 inch dry.
Figure 9: DeconGel 1108 initial application (left) and DeconGef 1108 after 72-h cure
(right)
4.1,6 Decontaminant Coverage
Inconsistent decontaminant coverage over the coupon surface for bleach and peroxide after application
was observed. Bleach, peroxide, and EasyDecoir DF-200 decontaminant solutions were all aqueous-
based. During application of bleach and peroxide, the decontaminant coverage was relatively uniform and
consistent. However, immediately after application, the decontamination solution migrates and collects in
spots resulting in uneven and inconsistent coverage. Conversely, EasyDecon® DF-200 contains a
surfactant that breaks the surface tension and keeps the decontaminant evenly spread across the surface.
An example is shown in Figure 10, where bleach was applied to rubber coupons (left) and EasyDecoir"
DF-200 (right).
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EasyDecon® DF-200
Figure 10: Decontaminant applied to rubber coupon
This phenomenon was observed for all coupons with bleach and peroxide applied. Significant differences
can occur with replicate coupons depending on whether the decontaminant collects over the agent
deposition spots on the surface. Since the active ingredient in EasyDecon" DF-200 is peroxide, it can be
inferred that the differences in effectiveness between EasyDecon1'" DF-200 and peroxide solution are due
to the uniformity of the application. The peroxide content in the EasyDecon " DF-200 applied formulation
was 4%, and the peroxide content in the USP solution was 3%.
4.2 Test Results - Decontamination Efficacy
Coupon recovery and decontamination efficacy results are presented in Appendices C and D. A summary
of the efficacy results is presented in Table 17. Two efficacy calculations are presented for the evaluation
of DeconGel14 1108: a) one calculation based on the spray positive control values, and b) one calculation
based on the DeconGel* 1108 positive control values. The difference in the two types of positive controls
is the agent-material contact time. The DeconGel'" 1108 positive controls are more appropriate for
mimicking sorption/penetration into the material surface. Assuming the low recovery for the HD positive
controls was the result of evaporation, the spray positive controls may be more representative because the
application of DeconGel® 1108 would prevent evaporation from the surface.
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Table 17: Decontamination Efficacy Results
Agent
Decontamination Type
Glass
(%)
Ceramic
(%)
Sealant
(%)
Rubber
(%)
VX
Spray Control (24 h)
Bleach
99.996
99
88
15
Peroxide
96
96
50
13
Easy Decon®
99.995
99.992
71
8
DeconGel®
99.9
99.7
62
74
Gel Control (96 h)
DeconGel®
99.9
99.7
32
70
HD
Spray Control (5 h)
Bleach
99.992
99.97
98
65
Peroxide
43
76
39
35
Easy Decon®
99
97
64
52
DeconGel®
97
78
99.998
75
Gel Control (76 h)
DeconGel®
ND
ND
99.98
75
Percent of agent decontaminated was based on agent recovered from both wipe and coupon extracts.
Significant digits are based on calculated standard deviation which is in the order of the last digit.
Decontamination efficacy calculations for DeconGel® 1108 were presented using both control types.
ND = not determined; positive control recoveries were too low to calculate a meaningful
decontamination efficacy
The efficacy results are based on a scale from 0 to 100, where 100 is complete decontamination of the
chemical agent, and 0 is no decontamination of the chemical agent. Overall, the bleach performed best,
and 3% peroxide performed worst over the range of materials tested, with the exception of rubber. Note,
the efficacy values are normalized to collection efficiency to allow a direct comparison of the
decontaminants for each material. For example, the bleach/sealant HD efficacy results suggest that 98%
of the HD was decontaminated. However, only 27% of the HD spiked onto the positive controls was
recovered, leaving 73% unaccounted for and possibly still sorbed in the sealant/sandstone coupon.
Efficacy results varied among the materials. The glass material was used as a nonporous reference
material for comparison purposes. Generally, the decontaminants performed best on glass. The glazed
ceramic coupon also performed reasonably well; however, sorbed moisture may have affected efficacy
results. For both glass and ceramic, efficacy results calculated using only wipe results and results using
combined wipe and coupon extracts were approximately the same, indicating little penetration. Wipe
sampling was not used for the sealant/sandstone coupons because of poor performance during method
demonstration. Whether the low agent collection efficiency for the sealant/sandstone coupons (< 30%)
was the result of sorbed agent that was not recovered or decontamination by the surface is unknown. This
issue should be addressed in future studies. There were significant differences in the efficacy results for
the wipe extracts and for the combined extracts. Wipe efficacy results for the rubber indicated greater
than 90% destruction of agent, while the combined results indicated significantly less. Results clearly
indicate that the agent was sorbed into the material and partially protected from surface decontamination.
The decontaminant test replicates showed a number of anomalies. For example, the HD-contaminated
ceramic coupons treated with bleach yielded nondetects for four of the five test replicates. For the one
detection, HD was not detected in the wipe extract but 0.2% or 22 (.ig was detected from the coupon
extract. Other examples show that the variations for the coupon replicates were high. The cause for the
anomalies was not determined; however, the nonuniform treatment of the surface discussed in Section 4.6
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and the imperfections of the surface could affect agent sorption and to some degree protect agent from the
decontaminant solution.
4.3 Toxic Compounds Detected from the Treated Coupons
In addition to determining decontamination efficacy, extracts were assayed in the survey mode. The GC x
GC/TOFMS and LC/qTOF qualitative survey results are summarized here. Reported detections focused
on compounds related to HD and VX. Given the large number of signals detected, 20% of the sample set
was screened to generate a list of target compounds. The entire sample set was re-processed from the
target list using the retention time and mass spectrum of the identified compounds. The GC x GC/TOFMS
detections were based on NIST library matches and reviewed manually. Ten unknown but HD-related
peaks were found. Likewise, four unknown VX-related peaks were found. Concentrations of tentatively
identified compounds were estimated using the internal standard naphthalene- Ds. Specific compounds of
interest related to HD include: bis(2-chloroethyl) sulfone, bis(2-chloroethyl) sulfoxide, and divinyl
sulfone. Note that HD is not a single pure component - some of these compounds could be decomposition
products of HD, not compounds resulting from reaction with a decontaminant [2],
A compound of interest related to VX is the toxic O-Ethyl S-vinyl methyl phosphonothioate [2]; note two
separate peaks were identified by library searching to match this compound. Presumably one of these
compounds is the exact structure and the other is a similar compound (e.g., isomer yielding a similar mass
spectral pattern). By LC/qTOF, several additional compounds were detected. Their exact masses suggest
elemental compositions consistent with diisopropyl amine and O-ethyl 0-[2-(diisopropylamino) ethyl]
methyl phosphonate (retention times not verified). Another unknown compound was also detected with an
elemental composition (C8H2oN02PS) consistent with that of VX (CnH26N02PS) minus C2H6 (net).
EA-2192 was screened by LC/qTOF during VX-targeted analysis and was not detected. This toxic
compound is formed from VX hydrolysis under neutral to basic conditions and was expected to be
present. The EA-2192, a water-soluble compound, most likely partitioned to the aqueous portion of the
biphasic extraction media, which were discarded/not analyzed.
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5. CONCLUSIONS
The objectives for this study included developing a laboratory wipe method to determine residual agent
on the surface, demonstrating method performance, and providing efficacies for four decontaminants on
porous and nonporous surfaces.
A laboratory wipe method was developed using a microfiber cloth wetted with isopropyl alcohol to
sample surfaces for residual VX and HD. The microfiber cloth was extracted with a biphasic
(dichloromethane and pH buffer) solution to quench residual decontaminant and determine the mass of
VX and HD collected. The method was evaluated to verify agent stability in the extracts and to
demonstrate collection and extraction efficiency. Results indicated that the agent was stable in the extracts
for over four days for VX and nine days for HD, the collection efficiency was over 50% for glass and
ceramic, and average extraction efficiencies were greater than 95% and less than 15% RSD. Collection
efficiencies were low for the more porous materials (rubber and sealant/sandstone). The sealant/sandstone
surface was rough, making it difficult to collect wipe samples, and collection efficiency was less than
0.2%. Based on observations during wipe method demonstration testing, adjustments were made for
decontamination efficacy testing to include: not collecting wipe samples for sealant/sandstone coupons
and increasing the amount of agent added to the sealant/sandstone coupons.
Four commercially available chemical agent decontaminants (household bleach, household peroxide,
EasyDecon® DF-200, and DeconGel® 1108) were evaluated for effectiveness on four test surfaces (glass,
ceramic tile, concrete sealant, and rubber base molding) typically found in public areas. Generally, full
strength bleach performed better than the other decontaminants; however, it is difficult to compare
DeconGel® 1108 to the other decontaminants due to (over three days) natural attenuation of the associated
positive controls. Household (3%) peroxide showed the lowest destruction efficiency. EasyDecon® DF-
200, which consists of peroxide and a surfactant, performed better than household peroxide.
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6. REFERENCES
[1] Lalain, T., Mantooth, B., Shue, M., Pusey, S., and D. Wylie. 2012. Chemical Contaminant and
Decontaminant Test Methodology Source Document, Second Edition. Edgewood Chemical
Biological Center, U.S. Army Research, Development and Engineering Command, Aberdeen
Proving Ground, Maryland. ECBC-TR-980.
[2] Munro, N.B., Talmage, S.S., Griffin, G.D., Waters, L.C., Watson, A.P., King, J.F., and
Hauschild, V. 1999. The Sources, Fate, and Toxicity of Chemical Warfare Agent Degradation
Products. Environmental Health Perspectives 107, 12, 933-974
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7. APPENDICES
Appendix A - Wipe Method Development and Demonstration
Appendix B - Summary of Wipe Method QC
Appendix C - Summary of QC Recovery Standards
Appendix D - Summary of Test Results
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Appendix A -Wipe Method Development and Demonstration
The wipe method was optimized in three steps: wipe comparison tests, solvent system tests, and
decontaminant neutralization tests.
Wipe Comparison:
The wipe comparison tests were conducted to investigate performance of three wipe materials:
microfiber cloth (Anypromo, Chino, California), cotton gauze (Dukal Corporation, sterile:
Hauppauge, New York, Lot# A17610 27), and polyester cotton blend (Fruit of the Loom). The
tests were conducted by spiking simulants chloroethyl ethyl sulfide (CEES) (Sigma Aldrich, St.
Louis, Missouri, Lot # 02314JJ) for HD and diethyl ethylthiophosphonate (DEETP) (SwRI, San
Antonio, Texas) for VX onto glass coupons and wiping the glass coupons using the wipe
materials. In both cases, the surrogates were more volatile than the actual agents. The test was
conducted by spiking 10 |iL of CEES and DEETP onto a 4 inch x 4 inch glass coupon. The
surface was then covered using a Petri dish for ten minutes. The wipe material was wetted with
0.5 mL of either acetone or isopropyl alcohol. The glass coupon was uncovered and wiped using
the wetted wipe material. The wipe was placed into a 40 mL VOA vial and extracted with 20 mL
of chloroform (Fisher Scientific, Houston, Texas). The sample was mixed for 15 minutes, and
the solvent remained in contact for at least an hour prior to removing an aliquot for analysis by
GC/MS.
Laboratory control spikes (LCSs) were prepared by spiking 10 |iL of CEES and DEETP directly
onto the wipe material. The wipe material was placed into the VOA vial prior to spiking CEES
and DEETP and was not wetted with acetone or isopropyl alcohol. After spiking the wipe
material, the VOA vials were covered for ten minutes to allow CEES and DEETP to soak into
the wipe material before 20 mL of chloroform was added. Control blank wipes were prepared by
wetting the wipe material with solvent (isopropyl alcohol or acetone) and wiping a clean (not
spiked with CEES or DEETP) glass plate.
Wipe Comparison Results
The LCS results were used to determine the wipe extraction efficiency. Results are shown in
Table Al. The expected recovery from 10 |iL of CEES and DEETP spiked directly onto the wipe
materials is 10.4 mg and 10.1 mg, based on density and purity. Recovery results were all within
± 5% of the target amount with the exception of CEES on the cotton/polyester material that
yielded -80% recovery. Based on calibration verification standards and recovery standards
assayed, the 80% recovery was probably due to CEES calibration drift.
-32-
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Table Al: Wipe Extraction Efficiency
Sample Name
Micro fiber Cloth
Cotton Gauze
Cotton/Polyester
CEES
DEETP
CEES
DEETP
CEES
DEETP
(mg)
(mg)
(mg)
(mg)
(mg)
(mg)
LCS-R1
9.85
10.36
9.32
9.53
9.00
10.17
LCS-R2
9.94
10.17
10.00
10.11
8.15
10.53
LCS-R3
9.51
10.25
9.86
10.04
7.69
10.37
Average
9.76
10.26
9.73
9.89
8.28
10.36
Recovery (%)
94
102
94
98
80
103
%RSD
2%
1%
4%
3%
8%
2%
Wipe collection efficiency results are shown in Tables A2 and A3. Using isopropyl alcohol as
the wetting solvent, CEES recovery ranged between 14 to 58% (calculations not shown in the
tables) with high variability between replicates. The low recoveries and high variability are
probably due to the volatility of CEES. DEETP recovery ranged between 41 and 101% with
relatively low variability, with the exception of the first replicate for cotton gauze. Based on
duplicate analytical injections for all three cotton gauze replicates, the variability was not
associated with instrumental analysis. Using acetone as the wetting solvent, CEES recovery
ranged between 21 to 43% with high variability between replicates. The low recoveries and high
variability are probably due to the volatility of CEES. DEETP recovery ranged between 76 and
105% with relatively low variability.
Table A 2: Wipe Collection Efficiency using 0.5 mL Isopropyl Alcohol
Micro fiber Cloth
Cotton Gauze
Cotton/Polyester
Sample Name
CEES
DEETP
CEES
DEETP
CEES
DEETP
(mg)
(mg)
(mg)
(mg)
(mg)
(mg)
Wipe Blank
0.00
0.00
0.00
0.00
0.00
0.00
Wipe Replicate #1
6.17
10.01
1.47
4.21
3.29
9.38
Wipe Replicate #2
4.88
9.64
2.44
8.12
3.64
10.21
Wipe Replicate #3
4.15
9.06
2.22
7.55
3.17
9.35
Average
5.07
9.57
2.04
6.63
3.37
9.64
%RSD
20%
5%
25%
32%
7%
5%
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Table A3: Wipe Collection Efficiency using 0.5 mL Acetone
Microfiber Cloth
Cotton Gauze
Cotton/Polyester
Sample Name
CEES
DEETP
CEES
DEETP
CEES
DEETP
(mg)
(mg)
(mg)
(mg)
(mg)
(mg)
Wipe Blank
0.00
0.00
0.00
0.00
0.00
0.00
Wipe Replicate #1
4.45
9.87
2.89
8.46
4.28
10.61
Wipe Replicate #2
4.14
9.90
2.71
7.74
3.44
9.56
Wipe Replicate #3
2.49
8.83
3.41
8.26
2.19
9.08
Average
3.69
9.53
3.00
8.15
3.30
9.75
%RSD
29%
6%
12%
5%
32%
8%
The wipe collection efficiency results showed high variability. The high variability is mostly
associated with CEES, which is a volatile organic compound. DEETP, which is less volatile, had
less than 10% RSD for most replicates. For the acetone-wetted wipes, there was not a significant
difference in the CEES results for the three materials. The acetone-wetted microfiber cloth and
cotton polyester materials were equivalent for DEETP, while the cotton gauze yielded lower
recoveries. For the isopropyl alcohol-wetted wipes, the microfiber cloth showed higher
recoveries for CEES than the other two materials. DEETP recovery from the isopropyl alcohol-
wetted microfiber cloth was not significantly different from the cotton polyester material but was
higher than the cotton gauze.
Based on the collection efficiency results, the microfiber cloth using isopropyl alcohol as the
wetting solvent was carried forward for wipe method optimization and decontamination efficacy
testing. The amount of isopropyl alcohol used was increased to 1.0 mL in effort to improve
collection efficiency.
Solvent System Tests:
The purpose of this test was to determine an appropriate solvent extraction volume and verify
that the solvent used to extract agent from the wipe yields acceptable results. This test compared
extraction results of two solvent volumes and three spike amounts for both VX and HD spiked
directly onto 2 inch x 3 inch white microfiber cloth wipes. The extraction solvent used was a
biphasic solution containing 1:1 dichloromethane and deionized water. The two extraction
volumes compared were 10 and 20 mL. The spike ranges tested were:
• HD (10 mL) - 0.050 to 2.5 |ig
• HD (20 mL) - 0.10 to 5.0 |ig
• VX (10 mL)-0.025 to 1.25 |ig
• VX (20 mL) - 0.050 to 2.5 |ig
White microfiber cloth wipes were folded in half and placed into 20 mL VOA vials. Agent (HD
or VX) diluted in isopropyl alcohol was spiked directly onto the wipe material. The sample was
held for 10 min to allow the solvent to evaporate prior to extracting the samples. The sample was
extracted with a 1:1 ratio of dichloromethane and deionized water. For HD extracts, the aqueous
solution consisted of distilled water. For VX extracts, the aqueous solution consisted of pH 10
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buffer (Fisher Scientific, Houston, Texas) to ensure that the VX partitioned into the organic
phase. The samples were vortexed for 30 seconds and then allowed to sit for at least 30 minutes
before removing the organic fraction and filtering through 0.45 |im nylon filter.
Solvent System Test Results:
HD test results are presented in Tables A4 thru A5.
Table A4: HD Results for 5 mL Dichloromethane (DCM) Extraction Volume
Spike Amount
(50 ng)
Spike Amount
(500 ng)
Spike Amount
(2500 ng)
Rep 1
53.6
485
2990
Rep 2
61.6
491
2760
Rep 3
60.8
515
2720
Avg. (ng)
58.7
497
2820
Avg (% Rec)
117%
99.4%
113%
SD
4.41
15.5
146
%RSD
7.5%
3.2%
5.1%
Table A5: HD Results for 10 mL DCM Extraction Volume
Spike Amount
(100 ng)
Spike Amount
(1,000 ng)
Spike Amount
(5,000 ng)
Rep 1
103
830
5430
Rep 2
129
942
5880
Rep 3
128
913
5300
Avg. (ng)
120
895
5540
Avg (% Rec)
120%
89.5%
111%
SD
14.9
58.1
304
%RSD
12%
6.5%
5.5%
VX results are presented in Tables A6 and A7.
Table A6: VX Results for 5 mL DCM Extraction Volume
Spike Amount
(25 ng)
Spike Amount
(250 ng)
Spike Amount
(1250 ng)
Rep 1
23.5
232
1620
Rep 2
27.2
220
1620
Rep 3
23.7
222
1650
Avg. (ng)
24.8
225
1630
Avg (% Rec)
99.3%
90.0%
130%
SD
2.08
6.42
17.3
%RSD
8.4%
2.8%
1.1%
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Table A7: VX Results for 10 mL DCM Extraction Volume
Spike Amount
(50 ng)
Spike Amount
(500 ng)
Spike Amount
(2500 ng)
Rep 1
42.8
478
2690
Rep 2
47.6
508
3360
Rep 3
45.8
451
5480*
Avg. (ng)
45.4
479
3840
Avg (% Rec)
90.8%
95.8%
154%
SD
2.42
28.7
1460
%RSD
5.5%
5.9%
38%
*- Suspect that the sample was double spiked
Acceptance criteria for this testing sequence included average percent recovery of 100 ± 35%
and percent relative standard deviation less than 25%. This criterion was met for all tests with the
exception of the VX (2500 ng, 10 mL) replicates, which failed for both recovery and variability.
In this set, one of the replicates appeared to be double spiked (> 200% recovery).
The preference was to use the smaller extraction volumes to lower detection limits, minimize
generated waste, and minimize extract storage space. Since the criterion was met using 5 mL
dichloromethane (10 mL or 1:1 dichloromethane:aqueous solution) extraction volume for both
VX and HD extractions, the wipe extraction solvent parameters for decontaminant neutralization
testing used 5 mL of dichloromethane. The solvent volume was sufficient to cover the wipe.
Decontaminant Neutralization tests
The decontaminant neutralization tests were conducted to investigate additives for neutralizing
residual decontaminant solution that may have been collected during the wiping process. The
three decontamination solutions tested were bleach (The Clorox® Company, Oakland, CA, Lot#
A5:5101TX-1), 3% peroxide ((HEB-brand, obtained from HEB Grocery stores in San Antonio,
Texas, Lot# 10014877BA), and EasyDecon® (EFT Holdings, Inc., Lafayette, Colorado).
EasyDecon® consists of peroxide and an amine surfactant. Tests were conducted by spiking VX
and HD into 10 mL of 1:1 dichloromethane:aqueous solvent system and 0.5 mL of
decontaminant solution. VX and HD recovery performance was compared from triplicate extract
solutions with and without neutralizing additives. Test results indicated that sodium thiosulfate
(Sigma Aldrich, St. Louis, Missouri, Lot # MKBS3720V) was effective for preserving agent in
the presence of bleach, and additives were not necessary for 3% peroxide. The amine surfactant
in EasyDecon® was basic (pH 10) and negatively affected HD performance. Based on this
information, the aqueous portion of the extraction solvent system was set as follows:
• VX: pH 10 buffer (0.5 molar (M) carbonate buffer and 1.25 M sodium thiosulfate)
• HD: pH 5 buffer (1.0 M acetate buffer and 1.25 M sodium thiosulfate)
All three decontamination solutions were tested in triplicate for each agent using the aqueous
buffer. Results are presented in Table A8.
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Table A8: Verification of Agent Preservation in the Wipe Extracts
Decontaminant
H
ID
VX
Average
Recovery
%RSD
Average
Recovery
%RSD
Bleach
74%
8.8%
100%
5.5%
Peroxide
89%
1.2%
97%
4.7%
EasyDecon®
96%
3.6%
89%
4.0%
Wipe Method Demonstration Test Results
The wipe method demonstration was performed to validate the optimized wipe method,
determine analytical performance for each surface material and decontamination solution
combination, and verify processes under tightly timed constraints as a prelude to
decontamination efficacy testing. The wipe demonstration test matrix is presented in Table A9.
Table A9: Wipe Demonstration Test Matrix
Agent
Decontaminant
Agent-
Material
Contact
Time
Treatment
Time
# of Coupon Replicates
Glass
Ceramic
Sealant
Rubber
VX
Control
1 h
--
1-SB 3-PC
1-SB 3-PC
1-SB 3-PC
1-SB 3-PC
Bleach
1 h
15 min
1-PB|3-TR
1-PB|3-TR
1-PB|3-TR
1-PB|3-TR
Peroxide
1 h
15 min
1-PB|3-TR
1-PB|3-TR
1-PB|3-TR
1-PB|3-TR
Easy Decon
1 h
15 min
1-PB|3-TR
1-PB|3-TR
1-PB|3-TR
1-PB|3-TR
HD
Control
1 h
--
1-SB 3-PC
1-SB 3-PC
1-SB 3-PC
1-SB 3-PC
Bleach
1 h
15 min
1-PB|3-TR
1-PB|3-TR
1-PB|3-TR
1-PB|3-TR
Peroxide
1 h
15 min
1-PB|3-TR
1-PB|3-TR
1-PB|3-TR
1-PB|3-TR
Easy Decon
1 h
15 min
1-PB|3-TR
1-PB|3-TR
1-PB|3-TR
1-PB|3-TR
SB and PB coupons were not spiked. All other coupons were spiked with 10 |iL of agent (5x2 |iL). For each
agent/material set, four wipe control samples were prepared (1 wipe method blank and three LCSs).
Liquid agent (VX, lot# VX-U-5251-CTF-N, 98.5% purity; HD, lot# HD-U-5032-CTF-N, 98%
purity) was applied to the coupons using a Hamilton 1700 Series Gastight Syringe (Model
80920-50 uL; Hamilton Robotics, Reno, Nevada) affixed to a Hamilton Repeating dispenser
(Model 8370-PB600). The test process was started by spiking 10 |iL of agent (five x 2 |iL) using
a 50 |iL Hamilton 1700 Series Gastight syringe (Model 80920-50 [xL) affixed to a Hamilton
Repeating dispenser (Model 8370-PB600). After the coupons were spiked with agent, the
container lid was closed for 60 min. Once the 60-min agent-material contact time had elapsed, the
test coupons were treated with decontaminant solutions (bleach, 3% peroxide, and EasyDecon®
DF-200). The positive control coupons were not treated, but wiped and extracted after the 60-min
agent-material contact time had elapsed. The decontaminant solution was applied to the coupons
using a glass oil mister (Prepara Kitchen Tools, New York, New York) and remained in contact
for 15 min. At the end of the treatment period, test coupons were turned onto
-37-
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their side to drain residual decontamination solution to waste. Coupons were wiped, extracted,
and assayed.
Agent preservation was demonstrated by assaying the extracts twice. The intention was to assay
extracts immediately after extraction (day 0) and on day 3; however, scheduling conflicts
resulted in the second analysis being assayed on day 4 for VX and day 9 for HD. Wipe collection
efficiency was determined from glass positive control results. Extraction efficiency was
determined from LCS samples from each set.
Wipe Method Demonstration Tests:
Overall, the optimized wipe method performed well and met test objectives:
• Preservation of agent in the extracts;
• High extraction efficiency and precision;
• High collection efficiency and precision; and
• Verify decontamination efficacy testing process.
Agent preservation in the extract was demonstrated by assaying the extracts two times. The
requirement to discern agent decomposition was an interval of three days. To ensure that the first
analysis was assayed on day 0, the interval between the analyses was extended to four days for
VX and nine days for HD. Even with the extended time, there was less than 30% difference
between the two analyses for the treated replicates. Based on the data collected from the two
analyses, the biggest concern is the observed increase in concentration for the second analysis.
The average increase in concentration for HD was 18% and for VX was 7%. The increase in
concentration demonstrates that the agent is adequately preserved in the extracts.
Extraction efficiency of the wipes was demonstrated via LCSs analyzed in triplicate each day.
All replicates had recoveries between 75% and 125%, and precision was less than 20% RSD for
all of the replicates.
Collection efficiency was demonstrated via agent-spiked coupons not decontaminated (positive
control samples). Results varied based on coupon material. Window glass and ceramic tile met
performance criteria, while the sealant and rubber failed to meet performance criteria. In many
decontamination efficacy tests, glass and/or stainless steel are used as controls for determining
process performance. Following the same standard, results from the glass material met collection
efficiency and precision performance objectives. Average HD and VX recoveries were over 90%
with %RSDs less than 20%. Although the agent recovery was lower than observed on glass,
glazed ceramic material also met collection efficiency and precision performance objectives for
both agents (HD 64%/5% RSD: VX 81 %/15% RSD). Based on LCS information collected the
same day, the lower recovery is directly related to the coupon material, not the wipe method.
The sealant, Sure Klean® Siloxane PD, applied to sandstone coupons in two separate coats failed
agent recovery criteria. Less than 0.2% of the agent was recovered by the wipe method and less
than 30% was recovered by coupon extraction. There was a deviation with the wipe collection
method for this surface. Wiping the coupon was similar to wiping sandpaper. As a result, the
operator had to abandon the back and forth motion and resorted to pulling the wipe across the
coupon in each direction. Despite the difficulties with wiping the material, the poor recovery
appears to be associated more with agent penetration into the porous material as evidenced by
good recovery of wipe LCS samples and by 20-3 0% agent recovered from the coupon
-38-
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extractions. Observations during agent spiking documented that the agent soaked into the
materia] immediately. Pictures of the sandstone/sealant tile immediately after spiking agent and
after the fifteen min decontamination application time are presented in Figure Al.
Figure A1: Sealant coupon after agent spike (left), after decontaminant application (right)
The rubber material failed agent recovery criteria. For HI), the average wipe recovery was 36%
with a 15% RSD. Adding the results of the coupon extraction, the total FID recovery was 77%
with a 7% RSD. For VX, the average wipe recovery was 40% with an 82% RSD. Adding the
results of the coupon extraction, the total VX recovery was 59% with a 54% RSD. The low
recovery and high variability are associated with the first wipe replicate. While this point does
not pass an outlier test, it significantly affects the precision and is the difference for these data
meeting criteria. Extraction notes indicated that there were phase separation issues associated
with the rubber extracts, which offers one possible explanation. Pictures of the rubber filtered
extracts are presented in Figure A2
-39-
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Figure A2: Rubber filtered extracts
The wipe and coupon extraction results for the rubber suggest that intermediate agent penetration
occurs into the material. While the results do not meet test requirements, the deficiencies are
related to the porosity of the material and not the method. This observation is supported by the
wipe LCS samples collected that day indicating good extraction efficiency, and 20-40% of the
agent was recovered from the coupon extractions.
In conclusion, performance issues were not associated with the wipe method but with the coupon
material. The performance of all wipe LCSs demonstrated good extraction efficiency; the
performance of the standardized material, glass, demonstrated good collection efficiency; and the
consistency between the duplicate analyses demonstration good agent preservation. There were
some issues associated with the rubber extracts. Examples included phase separation of the
filtered extracts and chromatography issues associated with HD GC/MS analysis. The phase
separation issues were addressed by additional filtration and using a centrifuge. The
chromatographic issues included poor HD peak shape, noisy baseline, and poor response for
calibration standards. Resolving these chromatographic issues resulted in delays for assaying the
2nd analyses for the other materials. Also, only one set of data was collected for the HD rubber
extracts and was analyzed almost two weeks after sample collection. These issues were resolved
by diluting the extracts by a factor of 10, which affected the reporting limit.
-40-
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Appendix B - Summary of Wipe Method QC
Table Bl: Summary of HD Wipe Method Blanks
Table B2: Summary of HD Laboratory Control Spikes
Table B3: Summary of VX Wipe Method Blanks
Table B4: Summary of VX Laboratory Control Spikes
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Table B1: Summary of HD Wipe Method Blanks
Wipe Controls
ID#
Spike Amount
(ng)
Found
(ng)
Wipe Blk-1 (Glass)
578545
--
<15 U
Wipe Blk-2 (Glass)
578546
--
<15 U
Wipe Blk-1 (Ceramic)
578706
--
<15 U
Wipe Blk-2 (Ceramic)
578707
--
<15 U
Wipe Blk-1 (Rubber)
578867
--
<150 U
Wipe Blk-2 (Rubber)
578868
--
<150 U
Wipe Blk-1 (DeconGel®)
584219
--
<15 U
Wipe Blk-2 (DeconGel®)
584220
--
<15 U
U - HD not detected; value reported is the detection limit
Table B2: Summary of HD Laboratory Control Spikes
Wipe Controls
ID#
Spike Amount
(ng)
Found
(ng)
% Recovery
LCS 1 (Glass)
578542
2.5x103
2.7x103
110%
LCS 2 (Glass)
578543
2.5x103
2.5x103
100%
LCS 3 (Glass)
578544
2.5x103
2.7x103
110%
LCS 1 (Ceramic)
578708
2.5x103
2.5x103
100%
LCS 2 (Ceramic)
578709
2.5x103
2.7x103
110%
LCS 3 (Ceramic)
578710
2.5x103
2.6x103
100%
LCS 1 (Rubber)
578864
2.5x103
2.3x103
92%
LCS 2 (Rubber)
578865
2.5x103
2.2x103
88%
LCS 3 (Rubber)
578866
2.5x103
2.5x103
100%
LCS 1 (DeconGel®)
584221
2.5x103
2.6x103
100%
LCS 2 (DeconGel®)
584222
2.5x103
2.7x103
110%
LCS 3 (DeconGel®)
584223
2.5x103
2.5x103
100%
AVG
--
--
2.5x103
100%
%RSD
--
--
6.4%
--
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Table B3: Summary of VX Wipe Method Blanks
Wipe Controls
ID#
Spike Amount
(ng)
Found
(ng)
Wipe Blk-1 (Glass)
578620
--
<10 u
Wipe Blk-2 (Glass)
578621
--
<10 u
Wipe Blk-1 (Ceramic)
578786
--
<10 u
Wipe Blk-2 (Ceramic)
578787
--
<10 u
Wipe Blk-1 (Rubber)
578949
--
<10 u
Wipe Blk-2 (Rubber)
578950
--
<10 u
Wipe Blk-1 (DeconGel®)
584454
--
<10 u
Wipe Blk-2 (DeconGel®)
584455
~
<10 u
U - VX not detected; value reported is the detection limit
Table B4: Summary of VX Laboratory Control Spikes
Wipe Controls
ID#
Spike Amount
(ng)
Found
(ng)
% Recovery
LCS 1 (Glass)
578622
1.3x103
1.2x103
92%
LCS 2 (Glass)
578623
1.3x103
1.2x103
92%
LCS 3 (Glass)
578624
1.3x103
1.3x103
100%
LCS 1 (Ceramic)
578788
1.3x103
1.1x103
85%
LCS 2 (Ceramic)
578789
1.3x103
1.2x103
92%
LCS 3 (Ceramic)
578790
1.3x103
1.2x103
92%
LCS 1 (Rubber)
578946
1.3x103
1.2x103
92%
LCS 2 (Rubber)
578947
1.3x103
1.2x103
92%
LCS 3 (Rubber)
578948
1.3x103
1.2x103
92%
LCS 1 (DeconGel®)
584456
1.3x103
1.2x103
92%
LCS 2 (DeconGel®)
584457
1.3x103
1.2x103
92%
LCS 3 (DeconGel®)
584458
1.3x103
1.2x103
92%
AVG
--
~
1,200
92%
%RSD
--
~
3.5%
--
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Appendix C - Summary of QC Recovery Standard
Table CI: Summary of HD Recovery Standard Information
Table C2: Summary of VX Recovery Standard Information
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Table C1: Summary of HD Recovery Standard Information
Recovery
Spike Amount
Found
%
Standards
ID#
(ng)
(ng)
Recovery
RS-1 (Glass)
578497
1.2x107
1.2x107
100%
RS-2 (Glass)
578498
1.2x107
1.1x107
92%
RS-3 (Glass)
578499
1.2x107
1.1x107
92%
AVG
--
~
1.1x107
94%
%RSD
~
--
5.1%
RS-1 (Ceramic)
578625
1.2x107
1.3x107
110%
RS-2 (Ceramic)
578626
1.2x107
1.1x107
92%
RS-3 (Ceramic)
578627
1.2x107
1.1x107
92%
AVG
--
--
1.2x107
98%
%RSD
~
~
12%
RS-1 (Rubber)
578791
1.2x107
2.0x107
170%
RS-2 (Rubber)
578792
1.2x107
1.8x107
150%
RS-3 (Rubber)
578793
1.2x107
1.9x107
160%
AVG
--
~
1.9x107
160%
%RSD
~
~
5.3%
RS-1 (Sealant)
578970
6.2x107
6.2x107
100%
RS-2 (Sealant)
578971
6.2x107
4.8x107
77%
RS-3 (Sealant)
578972
6.2x107
4.9x107
79%
AVG
--
--
5.3x107
85%
%RSD
~
~
15%
RS-1 (DeconGel®)
584216
1.2x107
1.0x107
83%
RS-2 (DeconGel®)
584217
1.2x107
1.1x107
92%
RS-3 (DeconGel®)
584218
1.2x107
1.1x107
92%
AVG
--
~
1.1x107
89%
%RSD
~
~
5.4%
-45-
-------�
Table C2: Summary of VX Recovery Standard Information
Recovery
Spike Amount
Found
%
Standards
ID#
(ng)
(ng)
Recovery
RS-1 (Glass)
578547
9.9x10®
1.0x107
100%
RS-2 (Glass)
578548
9.9x10®
9.7x10®
98%
RS-3 (Glass)
578549
9.9x10®
1.0x107
100%
AVG
~
--
9.9x10®
99%
%RSD
~
~
1.7%
RS-1 (Ceramic)
578711
9.9x10®
1.0x107
100%
RS-2 (Ceramic)
578712
9.9x10®
9.5x10®
96%
RS-3 (Ceramic)
578713
9.9x10®
9.0x10®
91%
AVG
--
--
9.5x10®
96%
%RSD
~
~
5.3%
RS-1 (Rubber)
578901
9.9x10®
1.0x107
100%
RS-2 (Rubber)
578902
9.9x10®
9.8x10®
99%
RS-3 (Rubber)
578903
9.9x10®
1.1x107
110%
AVG
--
--
1.0x107
100%
%RSD
~
~
6.3%
RS-1 (Sealant)
579008
5.0x107
6.8x107
140%
RS-2 (Sealant)
579009
5.0x107
6.6x107
130%
RS-3 (Sealant)
579010
5.0x107
7.4x107
150%
AVG
--
--
6.9x107
140%
%RSD
~
~
6.0%
RS-1 (DeconGel®)
584451
9.9x10®
9.6x10®
97%
RS-2 (DeconGel®)
584452
9.9x10®
9.6x10®
97%
RS-3 (DeconGel®)
584453
9.9x10®
1.1x107
110%
AVG
--
--
1.0x107
101%
%RSD
~
~
8.0%
-46-
-------�
Appendix D - Summary of Test Results
Table
Dl:
Summary of HD Glass Results
Table
D2:
Summary of HD Ceramic Results
Table
D3:
Summary of HD Rubber Results
Table
D4:
Summary of HD Sealant/Sandstone
Results
Table
D5:
Summary of VX Glass Results
Table
D6:
Summary of VX Ceramic Results
Table
D7:
Summary of VX Rubber Results
Table
D8:
Summary of VX Sealant/Sandstone
Results
-47-
-------�
Table D1: Summary ofHD Glass Results
Controls
Spike Amount
Wipe
Coupon
Total
Wipe
Total
(5 h)
(ng)
(ng)
(ng)
(ng)
Recovery
Recovery
Surface Blank
-
<1.5x101 U
3.5x10z
3.5x10z
-
-
PC 1
1.2x10'
8.0x10"
2.7x10"
8.3x10"
67%
69%
PC 2
1.2x10'
6.5x10"
7.5x10"
6.5x10"
54%
54%
PC 3
1.2x10'
7.2x10"
2.8x104
7.2x10"
60%
60%
AVG
-
7.2x10"
1.0x10"
7.3x10"
60%
61%
%RSD
-
10%
150%
12%
-
-
Spike Amount
Wipe
Coupon
Total
Wipe
Total
Bleach
(ng)
(ng)
(ng)
(ng)
Recovery
Recovery
PB 1
-
<1.5x10 ' U
<6.0x10^ U
<6.0x10^ U
-
-
PB 2
-
<1.5x10' U
<6.0x10^ U
<6.0x10^ U
-
-
TR 1
1.2x10'
5.4x10'
<6.0x10^ U
5.4x10'
0.0000%
0.0000%
TR 2
1.2x10'
4.6x10^
<6.0x10^ U
4.6x10^
0.0038%
0.0038%
TR 3
1.2x10'
5.3x10'
<6.0x10^ U
5.3x10'
0.0000%
0.0000%
TR 4
1.2x10'
9.0x10"
<6.0x10^ U
9.0x10"
0.0001%
0.0001%
TR 5
1.2x10'
9.9x10^
<6.0x10^ U
9.9x10^
0.0083%
0.0083%
AVG
-
3.0x10^
NC
3.0x10^
0.0026%
0.0026%
%RSD
-
140%
NC
140%
-
-
3% Peroxide
Spike Amount
Wipe
Coupon
Total
Wipe
Total
(ng)
(ng)
(ng)
(ng)
Recovery
Recovery
PB 1
-
<1.5x101 U
<6.0x10^ U
<6.0x10^ U
-
-
PB 2
-
<1.5x10' U
<6.0x10^ U
<6.0x10^ U
-
-
TR 1
1.2x10'
4.1x10"
2.2x10"
4.1x10"
34%
34%
TR 2
1.2x10'
3.9x10"
5.4x10"
3.9x10"
32%
32%
TR 3
1.2x10'
3.6x10"
5.9x10"
3.6x10"
30%
30%
TR 4
1.2x10'
5.3x10"
5.6x10"
5.3x10"
44%
44%
TR 5
1.2x10'
3.8x10"
4.1x104
3.8x10"
32%
32%
AVG
-
4.1x10"
1.2x104
4.1x10"
35%
35%
%RSD
-
16%
140%
16%
-
-
EasyDecon"
Spike Amount
Wipe
Coupon
Total
Wipe
Total
DF-200
(ng)
(ng)
(ng)
(ng)
Recovery
Recovery
PB 1
-
<1.5x10 ' U
<6.0x10^ U
<6.0x10^ U
-
-
PB 2
-
<1.5x10' U
<6.0x10^ U
<6.0x10^ U
-
-
TR 1
1.2x10'
1.0x10"
<6.0x10^ U
1.0x10"
0.0083%
0.0083%
TR 2
1.2x10'
1.4x104
2.9x10^
1.4x104
0.12%
0.12%
TR 3
1.2x10'
2.6x104
3.3x10"
2.9x104
0.22%
0.24%
TR 4
1.2x10'
2.6x10"
6.7x10"
2.7x10"
2.2%
2.3%
TR 5
1.2x10'
4.9x104
4.4x10"
5.3x104
0.41%
0.44%
AVG
-
7.0x104
3.7x10"
7.4x104
0.58%
0.61%
%RSD
-
150%
72%
150%
-
-
Controls (76 h)
Spike Amount
Wipe
Coupon
Total
Wipe
Total
(ng)
(ng)
(ng)
(ng)
Recovery
Recovery
Surface Blank
-
<1.5x101 U
<6.0x10zU
<6.0x10zU
-
-
PC 1
1.2x10'
7.9x10'
<6.0x10^ U
7.9x10'
0.001%
0.001%
PC 2
1.2x10'
8.3x10'
<6.0x10^ U
8.3x10'
0.001%
0.001%
PC 3
1.2x10'
7.0x10'
<6.0x10^ U
7.0x10'
0.001%
0.001%
AVG
-
7.7X101
NC
7.7X101
0.001%
0.001%
%RSD
-
8.3%
NC
8.3%
-
-
Spike Amount
Wipe
Coupon
Total
Wipe
Total
DeconGel" 1108
(ng)
(ng)
(ng)
(ng)
Recovery
Recovery
PB 1
-
<1.5x10 ' U
<6.0x10^ U
<6.0x10^ U
-
-
PB 2
-
<1.5x10' U
<6.0x10^ U
<6.0x10^ U
-
-
TR 1
1.2x10'
3.9x104
1.3x10"
4.0x104
0.33%
0.34%
TR 2
1.2x10'
6.4x10"
1.8x104
6.6x10"
5.3%
5.5%
TR 3
1.2x10'
<1.5x10" U
<6.0x10^ U
<1.5x10" U
NC
NC
TR 4
1.2x10'
<1.5x10" U
<6.0x10^ U
<1.5x10" U
NC
NC
TR 5
1.2x10'
2.5x10"
3.2x10^
2.5x10"
2.1%
2.1%
AVG
-
1.9x10"
6.6x10^
1.9x10"
2.6%
2.6%
%RSD
-
98%
150%
150%
-
-
NC - Not calculated
U - Analyte not detected. The detection limit was adjusted with extraction factor to identify the level that could be observed. The '<'
identifies that the result is less than the adjusted detection limit.
— Not applicable
-48-
-------�
Table D2: Summary of HD Ceramic Results
Controls (5 h)
Spike Amount
Wipe
Coupon
Total
Wipe
Total
(ng)
(ng)
(ng)
(ng)
Recovery
Recovery
Surface Blank
-
<1.5x101 U
<4.5x10zU
<4.5x10zU
-
-
PC 1
1.2x10'
1.4x10'
2.5x10"
1.4x10'
120%
120%
PC 2
1.2x10'
1.5x10'
6.4x10^
1.5x10'
130%
130%
PC 3
1.2x10'
1.3x10'
3.6x10"
1.3x10'
110%
110%
AVG
-
1.4x10'
210,000
1.4x10'
120%
120%
%RSD
-
7.0%
86%
7.0%
-
-
Spike Amount
Wipe
Coupon
Total
Wipe
Total
Bleach
(ng)
(ng)
(ng)
(ng)
Recovery
Recovery
PB 1
-
<1.5x101 U
<4.5x10^ U
<4.5x10^ U
-
-
PB 2
-
<1.5x10' U
<4.5x10^ U
<4.5x10^ U
-
-
TR 1
1.2x10'
<1.5x10' U
2.2x104
2.2x104
NC
0.18%
TR 2
1.2x10'
<1.5x10' U
<4.5x10^ U
<4.5x10^ U
NC
NC
TR 3
1.2x10'
6.0x10"
<4.5x10^ U
6.0x10"
0.0000%
0.0000%
TR 4
1.2x10'
<1.5x10' U
<4.5x10^ U
<4.5x10^ U
NC
NC
TR 5
1.2x10'
<1.5x10' U
<4.5x10^ U
<4.5x10^ U
NC
NC
AVG
-
NC
NC
NC
NC
NC
%RSD
-
NC
NC
NC
-
-
3% Peroxide
Spike Amount
Wipe
Coupon
Total
Wipe
Total
(ng)
(ng)
(ng)
(ng)
Recovery
Recovery
PB 1
-
<1.5x10 ' U
<4.5x10^ U
<4.5x10^ U
-
-
PB 2
-
<1.5x10' U
<4.5x10^ U
<4.5x10^ U
-
-
TR 1
1.2x10'
3.6x10"
8.6x104
3.7x10"
30%
31%
TR 2
1.2x10'
3.5x10"
7.2x104
3.6x10"
29%
30%
TR 3
1.2x10'
2.2x10"
1.2x104
2.2x10"
18%
18%
TR 4
1.2x10'
3.6x10"
2.7x10"
3.9x10"
30%
32%
TR 5
1.2x10'
4.2x10"
1.5x104
4.2x10"
35%
35%
AVG
-
3.4x10"
9.1x104
3.5x10"
29%
29%
%RSD
-
22%
120%
22%
-
-
EasyDecon"
Spike Amount
Wipe
Coupon
Total
Wipe
Total
DF-200
(ng)
(ng)
(ng)
(ng)
Recovery
Recovery
PB 1
-
<1.5x10 ' U
<4.5x10^ U
<4.5x10^ U
-
-
PB 2
-
<1.5x10' U
<4.5x10^ U
<4.5x10^ U
-
-
TR 1
1.2x10'
1.2x10"
6.0x104
1.8x10"
1.0%
1. 5%
TR 2
1.2x10'
1.3x10"
8.9x10"
1.0x10"
1.1%
8.3%
TR 3
1.2x10'
1.3x10"
1.5x10"
2.8x10"
1.1%
2.3%
TR 4
1.2x10'
1.4x104
6.0x10"
6.1x10"
0.12%
5.1%
TR 5
1.2x10'
9.2x10"
2.4x104
3.3x104
0.077%
0.28%
AVG
-
8.1x104
3.4x10"
4.2x10"
0.67%
3.5%
%RSD
-
78%
110%
92%
-
-
Controls (76 h)
Spike Amount
Wipe
Coupon
Total
Wipe
Total
(ng)
(ng)
(ng)
(ng)
Recovery
Recovery
Surface Blank
-
<1.5x101 U
<4.5x10zU
<4.5x10zU
-
-
PC 1
1.2x10'
2.5x10^
2.4x104
2.4x104
0.0021%
0.20%
PC 2
1.2x10'
3.0x10^
3.2x104
3.2x104
0.0025%
0.27%
PC 3
1.2x10'
2.4x10^
3.6x104
3.6x104
0.0020%
0.30%
AVG
-
2.6x10^
3.1x104
3.1x104
0.0022%
0.26%
%RSD
-
12%
20%
20%
-
-
Spike Amount
Wipe
Coupon
Total
Wipe
Total
DeconGel" 1108
(ng)
(ng)
(ng)
(ng)
Recovery
Recovery
PB 1
-
<1.5x101 U
<4.5x10^ U
<4.5x10^ U
-
-
PB 2
-
<1.5x10' U
<4.5x10^ U
<4.5x10^ U
-
-
TR 1
1.2x10'
1.4x104
5.3x10"
5.3x10"
0.12%
44%
TR 2
1.2x10'
5.2x104
1.1x10"
1.2x10"
0.43%
10%
TR 3
1.2x10'
1.1x10"
2.6x10"
2.6x10"
0.009%
22%
TR 4
1.2x10'
3.5x104
4.9x10"
4.9x10"
0.29%
40%
TR 5
1.2x10'
2.2x10^
2.3x10"
2.3x10"
0.002%
19%
AVG
-
20,000
3.2x10"
3.2x10"
0.17%
27%
%RSD
-
110%
56%
53%
-
-
NC - Not calculated
U - Analyte not detected
— Not applicable
-49-
-------�
Table D3: Summary of HD Rubber Results
Controls (5 h)
Spike Amount
Wipe
Coupon
Total
Wipe
Total
(ng)
(ng)
(ng)
(ng)
Recovery
Recovery
Surface Blank
-
<1.5x10z U
<6.0x10" U
<6.0x10" U
-
-
PC 1
1.2x10'
2.6x10"
1.6x10'
1.9x10'
22%
160%
PC 2
1.2x10'
1.6x10"
1.3x10'
1.5x10'
13%
130%
PC 3
1.2x10'
1.3x10"
1.2x10'
1.3x10'
11%
110%
AVG
-
1.8x10"
1.4x10'
1.6x10'
15%
130%
%RSD
-
38%
15%
19%
-
-
Spike Amount
Wipe
Coupon
Total
Wipe
Total
Bleach
(ng)
(ng)
(ng)
(ng)
Recovery
Recovery
PB 1
-
<1.5x10^ U
<6.0x10" U
<6.0x10" U
-
-
PB 2
-
<1.5x10^ U
<6.0x10" U
<6.0x10" U
-
-
TR 1
1.2x10'
1.3x10^
4.7x10"
4.7x10"
0.0011%
39%
TR 2
1.2x10'
2.1x10^
5.1x10"
5.1x10"
0.0018%
43%
TR 3
1.2x10'
3.1x10^
5.0x10"
5.0x10"
0.0026%
41%
TR 4
1.2x10'
2.7x10^
5.8x10"
5.8x10"
0.0023%
48%
TR 5
1.2x10'
2.5x10^
6.6x10"
6.6x10"
0.0021%
55%
AVG
-
2.3x10^
5.4x10"
5.4x10"
0.0020%
45%
%RSD
-
30%
14%
14%
-
-
3% Peroxide
Spike Amount
Wipe
Coupon
Total
Wipe
Total
(ng)
(ng)
(ng)
(ng)
Recovery
Recovery
PB 1
-
<1.5x10^ U
<6.0x10" U
<6.0x10" U
-
-
PB 2
-
<1.5x10^ U
<6.0x10" U
<6.0x10" U
-
-
TR 1
1.2x10'
1.2x10"
1.1x10'
1.1x10'
1.0%
92%
TR 2
1.2x10'
1.5x10"
1.0x10'
1.0x10'
1.3%
83%
TR 3
1.2x10'
1.4x10"
1.0x10'
1.0x10'
1.2%
83%
TR 4
1.2x10'
1.3x10"
9.5x10"
9.6x10"
1.1%
80%
TR 5
1.2x10'
1.1x10"
9.5x10"
9.6x10"
0.92%
80%
AVG
-
1.3x10"
1.0x10'
1.0x10'
1.0%
81%
%RSD
-
12%
6.1%
5.7%
-
-
EasyDecon"
Spike Amount
Wipe
Coupon
Total
Wipe
Total
DF-200
(ng)
(ng)
(ng)
(ng)
Recovery
Recovery
PB 1
-
<1.5x10^ U
<6.0x10" U
<6.0x10" U
-
-
PB 2
-
<1.5x10^ U
<6.0x10" U
<6.0x10" U
-
-
TR 1
1.2x10'
1.6x10"
8.6x10"
8.8x10"
1.3%
73%
TR 2
1.2x10'
2.8x10"
7.2x10"
7.5x10"
2.3%
63%
TR 3
1.2x10'
1.6x10"0
7.0x10"
7.2x10"
1.3%
60%
TR 4
1.2x10'
1.2x10"
7.5x10"
7.6x10"
1.0%
63%
TR 5
1.2x10'
1.8x10"
6.4x10"
6.6x10"
1. 5%
55%
AVG
-
1.8x10"
7.3x10"
7.6x10"
1.5%
63%
%RSD
-
33%
11%
11%
-
-
Controls (76 h)
Spike Amount
Wipe
Coupon
Total
Wipe
Total
(ng)
(ng)
(ng)
(ng)
Recovery
Recovery
Surface Blank
-
<1.5x10z U
<6.0x10" U
<6.0x10" U
-
-
PC 1
1.2x10'
5.0x104
1.5x10'
1.5x10'
0.42%
130%
PC 2
1.2x10'
5.3x104
1.8x10'
1.8x10'
0.44%
150%
PC 3
1.2x10'
4.7x104
1.4x10'
1.4x10'
0.40%
120%
AVG
-
5.0x104
1.6x10'
1.6x10'
0.42%
130%
%RSD
-
6.0%
13%
13%
-
-
Spike Amount
Wipe
Coupon
Total
Wipe
Total
DeconGel" 1108
(ng)
(ng)
(ng)
(ng)
Recovery
Recovery
PB 1
-
<1.5x10^ U
<6.0x10" U
<6.0x10" U
-
-
PB 2
-
<1.5x10^ U
<6.0x10" U
<6.0x10" U
-
-
TR 1
1.2x10'
1.4x104
4.2x10"
4.2x10"
0.11%
35%
TR 2
1.2x10'
1.7x104
4.4x10"
4.4x10"
0.14%
37%
TR 3
1.2x10'
1.1x104
3.9x10"
3.9x10"
0.092%
33%
TR 4
1.2x10'
1.2x104
3.4x10"
3.4x10"
0.10%
28%
TR 5
1.2x10'
2.0x104
3.7x10"
3.7x10"
0.17%
31%
AVG
-
1.5x104
3.9x10"
3.9x10"
0.12%
33%
%RSD
-
25%
10%
10%
-
-
NC - Not calculated
U - Analyte not detected
— Not applicable
-50-
-------�
Table D4: Summary of HD Sealant/Sandstone Results
Controls (5 h )
Spike Amount
Wipe
Total
(ng)
Wipe(ng)
Coupon(ng)
Total (ng)
Recovery
Recovery
Surface Blank
-
-
< 3.9x10Z U
< 3.9x10z U
-
-
PC 1
6.2x10'
-
1.4x10'
1.4x10'
-
23%
PC 2
6.2x10'
-
4.1x10"
4.1x10"
-
6.6%
PC 3
6.2x10'
-
3.2x10'
3.2x10'
~
52%
AVG
-
-
1.7x10'
1.7x10'
-
27%
%RSD
83%
83%
-
-
Spike Amount
Wipe
Coupon
Total
Wipe
Total
Bleach
(ng)
(ng)
(ng)
(ng)
Recovery
Recovery
PB 1
-
-
< 3.9x10^ U
< 3.9x10^ U
-
-
PB 2
-
-
< 3.9x10^ U
< 3.9x10^ U
-
-
TR 1
6.2x10'
-
4.0x10°
4.0x10"
-
0.65%
TR 2
6.2x10'
-
1.2x104
1.2x104
-
0.019%
TR 3
6.2x10'
-
2.1x10J
2.1x10J
-
0.0034%
TR 4
6.2x10'
-
1.0x10"
1.0x10"
-
1.6%
TR 5
6.2x10'
-
1.3x10"
1.3x10"
--
0.21%
AVG
-
-
3.1x10"
3.1x10"
-
0.50%
%RSD
-
-
140%
140%
-
-
3% Peroxide
Spike Amount
Wipe
Coupon
Total
Wipe
Total
(ng)
(ng)
(ng)
(ng)
Recovery
Recovery
PB 1
-
-
< 3.9x10^ U
< 3.9x10^ U
-
-
PB 2
-
-
< 3.9x10^ U
< 3.9x10^ U
-
-
TR 1
6.2x10'
-
1.1x10'
1.1x10'
-
18%
TR 2
6.2x10'
-
1.2x10'
1.2x10'
-
19%
TR 3
6.2x10'
-
1.2x10'
1.2x10'
-
19%
TR 4
6.2x10'
-
8.4x10"
8.4x10"
-
14%
TR 5
6.2x10'
-
7.2x10"
7.2x10"
-
12%
AVG
-
-
1.0x10'
1.0x10'
-
16%
%RSD
-
-
22%
22%
--
--
EasyDecon"
Spike Amount
Wipe
Coupon
Total
Wipe
Total
DF-200
(ng)
(ng)
(ng)
(ng)
Recovery
Recovery
PB 1
-
-
< 3.9x10^ U
< 3.9x10^ U
-
-
PB 2
-
-
< 3.9x10^ U
< 3.9x10^ U
-
-
TR 1
6.2x10'
-
6.5x10"
6.5x10"
-
10%
TR 2
6.2x10'
-
5.3x10"
5.3x10"
-
8.5%
TR 3
6.2x10'
-
5.9x10"
5.9x10"
-
9.5%
TR 4
6.2x10'
-
6.2x10"
6.2x10"
-
10%
TR 5
6.2x10'
-
6.4x10"
6.4x10"
-
10%
AVG
-
-
6.1x10"
6.1x10"
-
9.8%
%RSD
-
-
8.0%
8.0%
--
--
Controls (76 h)
Spike Amount
Wipe
Coupon
Total
Wipe
Total
(ng)
(ng)
(ng)
(ng)
Recovery
Recovery
Surface Blank
-
-
< 3.9x10^ U
< 3.9x10^ U
-
-
PC 1
6.2x10'
-
1.4x10"
1.4x10"
-
2.3%
PC 2
6.2x10'
-
1.5x10"
1.5x10"
-
2.4%
PC 3
6.2x10'
-
1.1x10"
1.1x10"
-
1.8%
AVG
-
-
1.3x10"
1.3x10"
-
2.2%
%RSD
-
-
16%
16%
--
--
Spike Amount
Wipe
Coupon
Total
Wipe
Total
DeconGel" 1108
(ng)
(ng)
(ng)
(ng)
Recovery
Recovery
PB 1
-
-
< 3.9x10^ U
< 3.9x10^ U
-
-
PB 2
-
-
< 3.9x10^ U
< 3.9x10^ U
-
-
TR 1
6.2x10'
-
< 3.9x10^ U
< 3.9x10^ U
-
NC
TR 2
6.2x10'
-
3.7x10^
3.7x10^
-
0.0006%
TR 3
6.2x10'
-
< 3.9x10^ U
< 3.9x10^ U
-
NC
TR 4
6.2x10'
-
2.7x10^
2.7x10^
-
0.0004%
TR 5
6.2x10'
-
1.3x10^
1.3x10^
--
0.0002%
AVG
-
-
2.5x10^
2.5x10^
-
0.0004%
%RSD
-
-
48%
48%
-
-
NC - Not calculated
U - Analyte not detected
— Not applicable
-51-
-------�
Table D5: Summary of VX Glass Results
Controls (5 h)
Spike Amount
Wipe
Coupon
Total
Wipe
Total
(ng)
(ng)
(ng)
(ng)
Recovery
Recovery
Surface Blank
-
< 1.0x101 U
< 4.0x10z U
< 4.0x10Z U
-
-
PC 1
9.9x10"
1.1x10'
2.3x10"
1.1x10'
110%
110%
PC 2
9.9x10"
7.7x10"
6.3x10"
8.3x10"
78%
84%
PC 3
9.9x10"
8.1x10"
6.4x10"
8.7x10"
82%
88%
AVG
-
8.9x10"
5.0x10"
9.3x10"
90%
94%
%RSD
-
20%
47%
16%
-
-
Spike Amount
Wipe
Coupon
Total
Wipe
Total
Bleach
(ng)
(ng)
(ng)
(ng)
Recovery
Recovery
PB 1
-
< 1.0x101 U
< 4.0x10^ U
< 4.0x10^ U
-
-
PB 2
-
< 1.0x10' U
< 4.0x10^ U
< 4.0x10^ U
-
-
TR 1
9.9x10"
9.7x10^
< 4.0x10^ U
9.7x10^
0.0098%
0.0098%
TR 2
9.9x10"
3.7x10'
< 4.0x10^ U
3.7x10'
0.0004%
0.0004%
TR 3
9.9x10"
1.7x10'
< 4.0x10^ U
1.7x10'
0.0002%
0.0002%
TR 4
9.9x10"
1.9x10'
< 4.0x10^ U
1.9x10'
0.0002%
0.0002%
TR 5
9.9x10"
< 1.0x10' U
< 4.0x10^ U
< 4.0x10^ U
NC
NC
AVG
-
261
NC
-
0.0026%
0.0026%
%RSD
-
180%
NC
-
-
-
3% Peroxide
Spike Amount
Wipe
Coupon
Total
Wipe
Total
(ng)
(ng)
(ng)
(ng)
Recovery
Recovery
PB 1
-
< 1.0x10 ' U
< 4.0x10^ U
< 4.0x10^ U
-
-
PB 2
-
< 1.0x10' U
< 4.0x10^ U
< 4.0x10^ U
-
-
TR 1
9.9x10"
3.4x10"
2.4x104
3.6x10"
3.4%
3.6%
TR 2
9.9x10"
2.7x10"
2.3x104
2.9x10"
2.7%
2.9%
TR 3
9.9x10"
3.5x10"
2.6x104
3.8x10"
3.5%
3.8%
TR 4
9.9x10"
4.0x10"
3.0x104
4.3x10"
4.0%
4.3%
TR 5
9.9x10"
4.8x10"
5.3x104
5.3x10"
4.8%
5.3%
AVG
-
3.7x10"
3.1x104
4.0x10"
3.7%
4.0%
%RSD
-
21%
40%
22%
-
-
EasyDecon"
Spike Amount
Wipe
Coupon
Total
Wipe
Total
DF-200
(ng)
(ng)
(ng)
(ng)
Recovery
Recovery
PB 1
-
< 1.0x10 ' U
< 4.0x10^ U
< 4.0x10^ U
-
-
PB 2
-
< 1.0x10' U
< 4.0x10^ U
< 4.0x10^ U
-
-
TR 1
9.9x10"
7.5x10^
1.4x10^
8.9x10^
0.0076%
0.0090%
TR 2
9.9x10"
3.0x10^
1.1x10^
4.1x10^
0.0030%
0.0041%
TR 3
9.9x10"
2.7x10^
< 4.0x10^ U
2.7x10^
0.0027%
0.0027%
TR 4
9.9x10"
1.3x10^
< 4.0x10^ U
1.3x10^
0.0013%
0.0013%
TR 5
9.9x10"
1.2x10^
< 4.0x10^ U
1.2x10^
0.0012%
0.0012%
AVG
-
3.1x10^
NC
3.6x10^
0.0032%
0.0037%
%RSD
-
83%
NC
88%
-
-
Controls (76 h)
Spike Amount
Wipe
Coupon
Total
Wipe
Total
(ng)
(ng)
(ng)
(ng)
Recovery
Recovery
Surface Blank
-
< 1.0x101 U
< 4.0x10z U
< 4.0x10Z U
-
-
PC 1
9.9x10"
8.8x10"
9.1x10"
9.7x10"
89%
98%
PC 2
9.9x10"
1.0x10'
7.5x10"
1.1x10'
100%
110%
PC 3
9.9x10"
9.8x10"
8.3x10"
1.1x10'
99%
110%
AVG
-
9.5x10"
8.3x10"
1.1x10'
96%
110%
%RSD
-
6.7%
10%
7.1%
-
-
Spike Amount
Wipe
Coupon
Total
Wipe
Total
DeconGel" 1108
(ng)
(ng)
(ng)
(ng)
Recovery
Recovery
PB 1
-
< 1.0x101 U
< 4.0x10^ U
< 4.0x10^ U
-
-
PB 2
-
< 1.0x10' U
< 4.0x10^ U
< 4.0x10^ U
-
-
TR 1
9.9x10"
1.3x10J
4.4x10J
5.7x10J
0.013%
0.057%
TR 2
9.9x10"
1.9x10J
2.4x104
2.6x104
0.019%
0.26%
TR 3
9.9x10"
2.6x10J
2.0x10J
4.6x10J
0.026%
0.047%
TR 4
9.9x10"
6.3x10^
2.1x10J
2.7x10J
0.0064%
0.028%
TR 5
9.9x10"
1.1x10J
1.4x10J
2.5x10J
0.011%
0.025%
AVG
-
1.5x10J
6.8x10J
8.3x10J
0.015%
0.084%
%RSD
-
51%
140%
120%
-
-
NC - Not calculated
U - Analyte not detected
— Not applicable
-52-
-------�
Table D6: Summary of VX Ceramic Results
Controls (5 h)
Spike Amount
Wipe
Coupon
Total
Wipe
Total
(ng)
(ng)
(ng)
(ng)
Recovery
Recovery
Surface Blank
-
< 1.0x101 U
< 4.0x10z U
< 4.0x10Z U
-
-
PC 1
9.9x10"
7.6x10"
6.4x10"
8.2x10"
77%
83%
PC 2
9.9x10"
6.7x10"
1.7x10"
6.9x10"
68%
70%
PC 3
9.9x10"
5.7x10"
1.1x10"
6.8x10"
58%
69%
AVG
-
6.7x10"
6.4x10"
7.3x10"
67%
74%
%RSD
-
14%
73%
11%
-
-
Spike Amount
Wipe
Coupon
Total
Wipe
Total
Bleach
(ng)
(ng)
(ng)
(ng)
Recovery
Recovery
PB 1
-
1.1
< 4.0x10^ U
< 4.0x10^ U
-
-
PB 2
-
< 1.0x10' U
< 4.0x10^ U
< 4.0x10^ U
-
-
TR 1
9.9x10"
1.4x10"
< 4.0x10^ U
1.4x10"
1.4%
1.4%
TR 2
9.9x10"
2.9x10'
< 4.0x10^ U
2.9x10'
0.0003%
0.0003%
TR 3
9.9x10"
2.9x10"
1.5x10^
2.9x10"
2.9%
2.9%
TR 4
9.9x10"
< 1.0x10' U
< 4.0x10^ U
< 4.0x10^ U
NC
NC
TR 5
9.9x10"
< 1.0x10' U
< 4.0x10^ U
< 4.0x10^ U
NC
NC
AVG
-
1.4x10"
NC
1.4x10"
1.4%
1.4%
%RSD
-
100%
NC
100%
-
-
3% Peroxide
Spike Amount
Wipe
Coupon
Total
Wipe
Total
(ng)
(ng)
(ng)
(ng)
Recovery
Recovery
PB 1
-
< 1.0x10 ' U
< 4.0x10^ U
< 4.0x10^ U
-
-
PB 2
-
< 1.0x10' U
< 4.0x10^ U
< 4.0x10^ U
-
-
TR 1
9.9x10"
3.2x10"
9.2x104
4.0x10"
3.2%
4.0%
TR 2
9.9x10"
1.5x10"
4.6x104
2.0x10"
1.5%
2.0%
TR 3
9.9x10"
2.1x10"
5.6x104
2.7x10"
2.1%
2.7%
TR 4
9.9x10"
2.7x10"
8.0x104
3.5x10"
2.7%
3.5%
TR 5
9.9x10"
2.4x10"
8.3x104
3.2x10"
2.4%
3.2%
AVG
-
2.4x10"
7.1x104
3.1x10"
2.4%
3.1%
%RSD
-
27%
27%
25%
-
-
EasyDecon"
Spike Amount
Wipe
Coupon
Total
Wipe
Total
DF-200
(ng)
(ng)
(ng)
(ng)
Recovery
Recovery
PB 1
-
< 1.0x10 ' U
< 4.0x10^ U
< 4.0x10^ U
-
-
PB 2
-
< 1.0x10' U
< 4.0x10^ U
< 4.0x10^ U
-
-
TR 1
9.9x10"
2.5x10^
1.1x10J
1.4x10J
0.0025%
0.014%
TR 2
9.9x10"
1.2x10^
1.2x10^
2.4x10^
0.0012%
0.0024%
TR 3
9.9x10"
9.0X101
9.6x10^
1.1x10J
0.0009%
0.011%
TR 4
9.9x10"
6.0x10'
1.0x10^
1.6x10^
0.0006%
0.0016%
TR 5
9.9x10"
4.0x10'
1.9x10^
2.3x10^
0.0004%
0.0023%
AVG
-
110
4.9x10^
6.3x10^
0.0011%
0.0063%
%RSD
-
74%
100%
92%
-
-
Controls (76 h)
Spike Amount
Wipe
Coupon
Total
Wipe
Total
(ng)
(ng)
(ng)
(ng)
Recovery
Recovery
Surface Blank
-
< 1.0x101 U
< 4.0x10z U
< 4.0x10Z U
-
-
PC 1
9.9x10"
7.8x10"
3.5x10"
8.2x10"
79%
83%
PC 2
9.9x10"
7.5x10"
3.9x10"
7.9x10"
76%
80%
PC 3
9.9x10"
5.2x10"
3.8x10"
5.6x10"
53%
57%
AVG
-
6.8x10"
3.7x10"
7.2x10"
69%
73%
%RSD
-
21%
5.5%
20%
-
-
Spike Amount
Wipe
Coupon
Total
Wipe
Total
DeconGel" 1108
(ng)
(ng)
(ng)
(ng)
Recovery
Recovery
PB 1
-
< 1.0x101 U
< 4.0x10^ U
< 4.0x10^ U
-
-
PB 2
-
< 1.0x10' U
< 4.0x10^ U
< 4.0x10^ U
-
-
TR 1
9.9x10"
1.3x104
1.4x10J
1.4x104
0.13%
0.14%
TR 2
9.9x10"
6.0x10J
6.8x104
7.4x104
0.061%
0.75%
TR 3
9.9x10"
4.1x10J
2.7x10J
6.8x10J
0.041%
0.069%
TR 4
9.9x10"
4.5x10J
1.3x10J
5.8x10J
0.046%
0.059%
TR 5
9.9x10"
3.3x10J
1.2x10J
4.5x10J
0.033%
0.046%
AVG
-
6.2x10J
1.5x104
2.1x104
0.062%
0.21%
%RSD
-
63%
200%
140%
-
-
NC - Not calculated
U - Analyte not detected
— Not applicable
-53-
-------�
Table D7: Summary of VX Rubber Results
Controls (5 h)
Spike Amount
Wipe
Coupon
Total
Wipe
Total
(ng)
(ng)
(ng)
(ng)
Recovery
Recovery
Surface Blank
-
< 1.0x101 U
< 4.0x10z U
< 4.0x10Z U
-
-
PC 1
9.9x10"
1.2x10"
6.6x10"
7.8x10"
12%
79%
PC 2
9.9x10"
1.5x10"
7.5x10"
9.0x10"
15%
91%
PC 3
9.9x10"
9.5x10"
5.2x10"
6.2x10"
10%
62%
AVG
-
1.2x10"
6.4x10"
7.7x10"
12%
77%
%RSD
-
23%
18%
18%
-
-
Spike Amount
Wipe
Coupon
Total
Wipe
Total
Bleach
(ng)
(ng)
(ng)
(ng)
Recovery
Recovery
PB 1
-
< 1.0x101 U
< 4.0x10^ U
< 4.0x10^ U
-
-
PB 2
-
< 1.0x10' U
< 4.0x10^ U
< 4.0x10^ U
-
-
TR 1
9.9x10"
5.7x104
7.6x10"
7.7x10"
0.58%
78%
TR 2
9.9x10"
6.8x104
7.2x10"
7.3x10"
0.69%
74%
TR 3
9.9x10"
3.6x104
6.0x10"
6.0x10"
0.36%
61%
TR 4
9.9x10"
5.1x104
6.1x10"
6.2x10"
0.52%
63%
TR 5
9.9x10"
6.0x104
6.5x10"
6.6x10"
0.61%
67%
AVG
-
5.4x104
6.7x10"
6.8x10"
0.55%
68%
%RSD
-
22%
10%
11%
-
-
3% Peroxide
Spike Amount
Wipe
Coupon
Total
Wipe
Total
(ng)
(ng)
(ng)
(ng)
Recovery
Recovery
PB 1
-
< 1.0x10 ' U
< 4.0x10^ U
< 4.0x10^ U
-
-
PB 2
-
< 1.0x10' U
< 4.0x10^ U
< 4.0x10^ U
-
-
TR 1
9.9x10"
1.0x10"
6.7x10"
7.7x10"
10%
78%
TR 2
9.9x10"
1.0x10"
7.1x10"
8.1x10"
10%
82%
TR 3
9.9x10"
9.9x10"
5.8x10"
6.8x10"
10%
69%
TR 4
9.9x10"
1.2x10"
6.8x10"
8.0x10"
12%
81%
TR 5
9.9x10"
1.0x10"
6.3x10"
7.3x10"
10%
74%
AVG
-
1.0x10"
6.5x10"
6.5x10"
10%
77%
%RSD
-
8.7%
7.7%
7.1%
-
-
EasyDecon"
Spike Amount
Wipe
Coupon
Total
Wipe
Total
DF-200
(ng)
(ng)
(ng)
(ng)
Recovery
Recovery
PB 1
-
< 1.0x10 ' U
< 4.0x10^ U
< 4.0x10^ U
-
-
PB 2
-
< 1.0x10' U
< 4.0x10^ U
< 4.0x10^ U
-
-
TR 1
9.9x10"
8.4x104
7.5x10"
7.6x10"
0.85%
77%
TR 2
9.9x10"
1.0x10"
7.2x10"
7.3x10"
1.0%
74%
TR 3
9.9x10"
5.8x104
6.1x10"
6.2x10"
0.59%
63%
TR 4
9.9x10"
1.3x10"
6.4x10"
6.5x10"
1.3%
66%
TR 5
9.9x10"
5.0x104
7.5x10"
7.6x10"
0.51%
77%
AVG
-
84,000
6.9x10"
7.0x10"
0.85%
71%
%RSD
-
39%
9.4%
9.2%
-
-
Controls (76 h)
Spike Amount
Wipe
Coupon
Total
Wipe
Total
(ng)
(ng)
(ng)
(ng)
Recovery
Recovery
Surface Blank
-
< 1.0x101 U
< 4.0x10z U
< 4.0x10Z U
-
-
PC 1
9.9x10"
4.7x10"
7.2x10"
7.7x10"
4.7%
78%
PC 2
9.9x10"
5.6x10"
5.8x10"
6.4x10"
6.5%
64%
PC 3
9.9x10"
4.5x10"
6.0x10"
6.5x10"
4.5%
65%
AVG
-
4.9x10"
6.3x10"
6.9x10"
5.0%
69%
%RSD
-
12%
12%
10%
-
-
Spike Amount
Wipe
Coupon
Total
Wipe
Total
DeconGel" 1108
(ng)
(ng)
(ng)
(ng)
Recovery
Recovery
PB 1
-
< 1.0x101 U
< 4.0x10^ U
< 4.0x10^ U
-
-
PB 2
-
< 1.0x10' U
< 4.0x10^ U
< 4.0x10^ U
-
-
TR 1
9.9x10"
1.4x104
1.4x10"
1.4x10"
0.14%
14%
TR 2
9.9x10"
3.2x104
2.1x10"
2.1x10"
0.32%
21%
TR 3
9.9x10"
2.4x104
1.9x10"
1.9x10"
0.24%
19%
TR 4
9.9x10"
2.6x104
2.1x10"
2.1x10"
0.26%
21%
TR 5
9.9x10"
1.8x104
2.5x10"
2.5x10"
0.18%
25%
AVG
-
2.2x104
2.0x10"
2.0x10"
0.23%
20%
%RSD
-
30%
20%
20%
-
-
NC - Not calculated
U - Analyte not detected
— Not applicable
-54-
-------�
Table D8: Summary of VX Sealant/Sandstone Results
Controls (5 h)
Spike Amount
Wipe
Coupon
Total
Wipe
Total
(ng)
(ng)
(ng)
(ng)
Recovery
Recovery
Surface Blank
-
-
< 2.6x10z U
< 2.6x10z U
-
-
PC 1
5.0x10'
-
1.5x10'
1.5x10'
-
30%
PC 2
5.0x10'
-
1.3x10'
1.3x10'
-
26%
PC 3
5.0x10'
-
1.6x10'
1.6x10'
-
32%
AVG
-
-
1.5x10'
1.5x10'
-
29%
%RSD
-
-
10%
10%
--
Spike Amount
Wipe
Coupon
Total
Wipe
Total
Bleach
(ng)
(ng)
(ng)
(ng)
Recovery
Recovery
PB 1
-
-
< 2.6x10^ U
< 2.6x10^ U
-
-
PB 2
-
-
< 2.6x10^ U
< 2.6x10^ U
-
-
TR 1
5.0x10'
-
6.3x104
6.3x104
-
0.13%
TR 2
5.0x10'
-
8.6x10°
8.6x10"
-
1.7%
TR 3
5.0x10'
-
4.8x104
4.8x104
-
0.096%
TR 4
5.0x10'
-
2.6x10"
2.6x10"
-
5.2%
TR 5
5.0x10'
-
4.8x10"
4.8x10"
-
9.6%
AVG
-
-
1.7x10"
1.7x10"
-
3.4%
%RSD
-
-
120%
120%
--
--
3% Peroxide
Spike Amount
Wipe
Coupon
Total
Wipe
Total
(ng)
(ng)
(ng)
(ng)
Recovery
Recovery
PB 1
-
-
< 2.6x10^ U
< 2.6x10^ U
-
-
PB 2
-
-
< 2.6x10^ U
< 2.6x10^ U
-
-
TR 1
5.0x10'
-
6.4x10"
6.4x10"
-
13%
TR 2
5.0x10'
-
3.3x10"
3.3x10"
-
6.6%
TR 3
5.0x10'
-
1.0x10'
1.0x10'
-
20%
TR 4
5.0x10'
-
8.4x10"
8.4x10"
-
17%
TR 5
5.0x10'
-
7.2x10"
7.2x10"
-
14%
AVG
-
-
7.1x10"
7.1x10"
-
14%
%RSD
-
-
35%
35%
-
-
EasyDecon"
Spike Amount
Wipe
Coupon
Total
Wipe
Total
DF-200
(ng)
(ng)
(ng)
(ng)
Recovery
Recovery
PB 1
-
-
< 2.6x10^ U
< 2.6x10^ U
-
-
PB 2
-
-
< 2.6x10^ U
< 2.6x10^ U
-
-
TR 1
5.0x10'
-
5.1x10"
5.1x10"
-
10%
TR 2
5.0x10'
-
1.7x10"
1.7x10"
-
3.4%
TR 3
5.0x10'
-
3.4x10"
3.4x10"
-
6.8%
TR 4
5.0x10'
-
6.3x10"
6.3x10"
-
13%
TR 5
5.0x10'
-
4.7x10"
4.7x10"
--
9.4%
AVG
-
-
4.2x10"
4.2x10"
-
8.5%
%RSD
-
-
42%
42%
-
-
Controls (76 h)
Spike Amount
Wipe
Coupon
Total
Wipe
Total
(ng)
(ng)
(ng)
(ng)
Recovery
Recovery
Surface Blank
-
-
< 2.6x10z U
< 2.6x10z U
-
-
PC 1
5.0x10'
-
8.5x10"
8.5x10"
-
17%
PC 2
5.0x10'
-
1.2x10'
1.2x10'
-
24%
PC 3
5.0x10'
-
3.3x10"
3.3x10"
--
6.6%
AVG
-
-
7.9x10"
7.9x10"
-
16%
%RSD
-
-
55%
55%
-
Spike Amount
Wipe
Coupon
Total
Wipe
Total
DeconGel" 1108
(ng)
(ng)
(ng)
(ng)
Recovery
Recovery
PB 1
-
-
< 2.6x10^ U
< 2.6x10^ U
-
-
PB 2
-
-
< 2.6x10^ U
< 2.6x10^ U
-
-
TR 1
5.0x10'
-
4.3x10"
4.3x10"
--
8.6%
TR 2
5.0x10'
-
3.7x10"
3.7x10"
-
7.4%
TR 3
5.0x10'
-
7.4x10"
7.4x10"
-
15%
TR 4
5.0x10'
-
4.8x10"
4.8x10"
-
9.6%
TR 5
5.0x10'
-
6.8x10"
6.8x10"
-
14%
AVG
-
-
5.4x10"
5.4x10"
-
11%
%RSD
-
-
30%
30%
--
--
NC - Not calculated; U
- Analyte not detected; — Not applicable
-55-
-------�
vvEPA
United States
Environmental Protection
Agency
PRESORTED STANDARD
POSTAGE & FEES PAID
EPA
PERMIT NO. G-35
Office of Research and Development (8101R)
Washington, DC 20460
Official Business
Penalty for Private Use
$300
-------� |