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ASTM E2186-02a(2016)

(Guide)

Standard Guide for Determining DNA Single-Strand Damage in Eukaryotic Cells Using the Comet Assay

Standard Guide for Determining DNA Single-Strand Damage in Eukaryotic Cells Using the Comet Assay

SIGNIFICANCE AND USE
5.1 A common result of cellular stress is an increase in DNA damage. DNA damage may be manifest in the form of base alterations, adduct formation, strand breaks, and cross linkages (19). Strand breaks may be introduced in many ways, directly by genotoxic compounds, through the induction of apoptosis or necrosis, secondarily through the interaction with oxygen radicals or other reactive intermediates, or as a consequence of excision repair enzymes (20-22). In addition to a linkage with cancer, studies have demonstrated that increases in cellular DNA damage precede or correspond with reduced growth, abnormal development, and reduced survival of adults, embryos, and larvae (16, 23, 24).  
5.1.1 The Comet assay can be easily utilized for collecting data on DNA strand breakage (9, 25, 26). It is a simple, rapid, and sensitive method that allows the comparison of DNA strand damage in different cell populations. As presented in this guide, the assay facilitates the detection of DNA single strand breaks and alkaline labile sites in individual cells, and can determine their abundance relative to control or reference cells  (9, 16, 26). The assay offers a number of advantages; damage to the DNA in individual cells is measured, only extremely small numbers of cells need to be sampled to perform the assay ((2, 27) .  
5.1.2 These are general guidelines. There are numerous procedural variants of this assay. The variation used is dependent upon the type of cells being examined, the types of DNA damage of interest, and the imaging and analysis capabilities of the lab conducting the assay. To visualize the DNA, it is stained with a fluorescent dye, or for light microscope analysis the DNA can be silver stained (28). Only fluorescent staining methods will be described in this guide. The microscopic determination of DNA migration can be made either by eye using an ocular micrometer or with the use of image analysis software. Scoring by eye can be performed using a calibrated ocular...
SCOPE
1.1 This guide covers the recommended criteria for performing a single-cell gel electrophoresis assay (SCG) or Comet assay for the measurement of DNA single-strand breaks in eukaryotic cells. The Comet assay is a very sensitive method for detecting strand breaks in the DNA of individual cells. The majority of studies utilizing the Comet assay have focused on medical applications and have therefore examined DNA damage in mammalian cells in vitro and in vivo (1-4).2 There is increasing interest in applying this assay to DNA damage in freshwater and marine organisms to explore the environmental implications of DNA damage.  
1.1.1 The Comet assay has been used to screen the genotoxicity of a variety of compounds on cells in vitro and in vivo (5-7), as well as to evaluate the dose-dependent anti-oxidant (protective) properties of various compounds (3, 8-11). Using this method, significantly elevated levels of DNA damage have been reported in cells collected from organisms at polluted sites compared to reference sites (12-15). Studies have also found that increases in cellular DNA damage correspond with higher order effects such as decreased growth, survival, and development, and correlate with significant increases in contaminant body burdens (13, 16).  
1.2 This guide presents protocols that facilitate the expression of DNA alkaline labile single-strand breaks and the determination of their abundance relative to control or reference cells. The guide is a general one meant to familiarize lab personnel with the basic requirements and considerations necessary to perform the Comet assay. It does not contain procedures for available variants of this assay, which allow the determination of non-alkaline labile single-strand breaks or double-stranded DNA strand breaks (8), distinction between different cell types (13), identification of cells undergoing apoptosis (programmed cell death, (1, 17)), measurement of cellular DNA repair...

General Information

Status
Historical
Publication Date
31-Jan-2016
ICS
07.100.01 - Microbiology in general
Technical Committee
E50 - Environmental Assessment, Risk Management and Corrective Action
Drafting Committee
E50.47 - Biological Effects and Environmental Fate
Current Stage
Ref Project

Relations

Replaces
ASTM E2186-02a(2010) - Standard Guide for Determining DNA Single-Strand Damage in Eukaryotic Cells Using the Comet Assay
Effective Date
01-Feb-2016
Replaced By
ASTM E2186-02a(2023) - Standard Guide for Determining DNA Single-Strand Damage in Eukaryotic Cells Using the Comet Assay
Effective Date
01-Dec-2023
Refers
ASTM E1706-19 - Standard Test Method for Measuring the Toxicity of Sediment-Associated Contaminants with Freshwater Invertebrates
Effective Date
01-Apr-2019
Refers
ASTM E1706-05(2010) - Standard Test Method for Measuring the Toxicity of Sediment-Associated Contaminants with Freshwater Invertebrates (Withdrawn 2019)
Effective Date
01-Sep-2010
Referred By
ASTM F3294-18 - Standard Guide for Performing Quantitative Fluorescence Intensity Measurements in Cell-based Assays with Widefield Epifluorescence Microscopy
Effective Date
01-Feb-2016
Referred By
ASTM F1439-03(2018) - Standard Guide for Performance of Lifetime Bioassay for the Tumorigenic Potential of Implant Materials
Effective Date
01-Feb-2016

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This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the
Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.
Designation: E2186 − 02a (Reapproved 2016)
Standard Guide for
Determining DNA Single-Strand Damage in Eukaryotic Cells
Using the Comet Assay
This standard is issued under the fixed designation E2186; the number immediately following the designation indicates the year of
original adoption or, in the case of revision, the year of last revision.Anumber in parentheses indicates the year of last reapproval.A
superscript epsilon (´) indicates an editorial change since the last revision or reapproval.
1. Scope cellular DNA repair rates (10), detection of the presence of
photoactive DNA damaging compounds (14), or detection of
1.1 This guide covers the recommended criteria for per-
specific DNA lesions (3, 18).
formingasingle-cellgelelectrophoresisassay(SCG)orComet
1.3 This standard does not purport to address all of the
assay for the measurement of DNA single-strand breaks in
safety concerns, if any, associated with its use. It is the
eukaryotic cells. The Comet assay is a very sensitive method
responsibility of the user of this standard to establish appro-
for detecting strand breaks in the DNAof individual cells.The
priate safety and health practices and determine the applica-
majority of studies utilizing the Comet assay have focused on
bility of regulatory requirements prior to use.
medical applications and have therefore examined DNAdam-
1.4 This guide is arranged as follows:
age in mammalian cells in vitro and in vivo (1-4). There is
increasing interest in applying this assay to DNA damage in
Section
freshwater and marine organisms to explore the environmental
Scope 1
implications of DNA damage.
Referenced Documents 2
1.1.1 The Comet assay has been used to screen the geno-
Terminology 3
Summary of Guide 4
toxicityofavarietyofcompoundsoncellsinvitroandinvivo
Significance and Use 5
(5-7), as well as to evaluate the dose-dependent anti-oxidant
Equipment and Reagents 6
(protective) properties of various compounds (3, 8-11). Using
Assay Procedures 7
Treatment of Data 8
thismethod,significantlyelevatedlevelsofDNAdamagehave
Reporting Data 9
been reported in cells collected from organisms at polluted
Keywords 10
sites compared to reference sites (12-15). Studies have also Annex Annex A1
References
found that increases in cellular DNAdamage correspond with
higher order effects such as decreased growth, survival, and
2. Referenced Documents
development, and correlate with significant increases in con-
2.1 ASTM Standards:
taminant body burdens (13, 16).
E1706TestMethodforMeasuringtheToxicityofSediment-
1.2 This guide presents protocols that facilitate the expres-
Associated Contaminants with Freshwater Invertebrates
sion of DNA alkaline labile single-strand breaks and the
E1847Practice for Statistical Analysis of Toxicity Tests
determination of their abundance relative to control or refer-
Conducted Under ASTM Guidelines
ence cells. The guide is a general one meant to familiarize lab
personnel with the basic requirements and considerations
3. Terminology
necessary to perform the Comet assay. It does not contain
3.1 Thewords“must,”“should,”“may,”“can,”and“might”
proceduresforavailablevariantsofthisassay,whichallowthe
have very specific meanings in this guide. “Must” is used to
determination of non-alkaline labile single-strand breaks or
expressthestrongestpossiblerecommendation,justshortofan
double-stranded DNA strand breaks (8), distinction between
absolute requirement. “Must” is only used in connection with
different cell types (13), identification of cells undergoing
factors that relate directly to the acceptability of the test.
apoptosis (programmed cell death, (1, 17)), measurement of
“Should” is used to state that the specific condition is recom-
mended and ought to be met if possible.Although violation of
on “should” is rarely a serious matter, the violation of several
ThisguideisunderthejurisdictionofASTMCommitteeE50onEnvironmental
will often render the results questionable. Terms such as “is
Assessment, Risk Management and CorrectiveAction and is the direct responsibil-
ity of Subcommittee E50.47 on Biological Effects and Environmental Fate.
Current edition approved Feb. 1, 2016. Published May 2016. Originally
approved in 2002. Last previous edition approved 2010 as E2186–02a(2010). DOI: For referenced ASTM standards, visit the ASTM website, www.astm.org, or
10.1520/E2186-02AR16. contact ASTM Customer Service at service@astm.org. For Annual Book of ASTM
Theboldfacenumbersinparenthesesrefertothelistofreferencesattheendof Standards volume information, refer to the standard’s Document Summary page on
this standard. the ASTM website.
Copyright © ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959. United States
E2186 − 02a (2016)
desirable,” “is often desirable,” and “might be desirable” are 3.2.12 single-stranded DNA, n—linear polymers of DNA
used in connection with less important factors. “May” is used resulting from the breaking of hydrogen bonds between
to mean “is (are) allowed to,” “can” is used to mean “is (are) complementary base pairs in double-stranded DNA.
able to,” and “might” is used to mean “could possibly.” Thus
3.3 Definitions of Terms Specific to This Standard:
the classic distinction between “may” and “can” is preserved
3.3.1 comet, n—namebasedontheappearanceofindividual
and “might” is never used as a synonym for either “may” or
stained nuclear DNA and associated relaxed or fragmented
“can.”
DNAmigrating out from the nuclear DNAobserved under the
3.2 Definitions: microscope following these assay procedures.
3.2.1 CCD camera, n—charge coupled device (CCD) cam-
3.3.2 DNAmigration distance, tail length, comet tail length,
era is a light sensitive silicon solid state device composed of
n—distance in microns between the leading edge of electro-
manysmallpixels.Thelightfallingonapixelisconvertedinto
phoretically migrating DNA and the closest edge of the
a charge pulse which is then measured by the CCD electronics
associated nuclear DNA (head).
and represented by a number.Adigital image is the collection
3.3.3 head, comet head, n—portionofacometcomprisedof
of such light intensity numbers for all of the pixels from the
the intact/immobile nuclear DNA.
CCD. A computer can reconstruct the image by varying the
3.3.4 tail,comettail,n—portionofacometcomprisedofthe
light intensity for each spot on the computer monitor in the
DNA migrating away from the intact/immobile nuclear DNA.
proper order. Such digital images can be stored on disk,
transmitted over a computer network, and analyzed using 3.3.5 tail moment, n—a calculated value used to express the
distribution of DNA migrating from the comet head. Image
image processing techniques.
analysissoftwareappliesanalgorithmtothedigitizedimageof
3.2.2 cell lysis, n—the process of breaking open a cell by
stained DNA and associated migrating DNA tail, which in
disruption of the plasma membrane.
essence defines the limits of the comet, subtracts background,
3.2.3 DNA, n—acronym for deoxyribonucleic acid, the sub-
and determines the boundaries and staining intensity of the
stance that is the carrier of genetic information found in the
nucleusandcomettail.Thecalculatedproductofthepercentof
chromosomes of the nucleus of a cell.
DNAinthetailandthetaillengthisdefinedasthetailmoment.
3.2.4 DNA denaturation, n—refers to breaking hydrogen
4. Summary of Guide
bonds between base pairs in double-stranded nucleic acid
moleculestoproducetwosingle-strandedpolynucleotidepoly-
4.1 Cells collected from organisms under different levels or
mers.
typesofstressaredispersedandimmobilizedinagarosegelon
microscope slides. The slides are placed in a solution to lyse
3.2.5 DNA lesion, n—a portion of a DNA molecule which
and disperse cell components, leaving the cellular DNA
has been structurally changed.
immobilized in the agarose. The DNA is denatured for a
3.2.6 DNA supercoiling, n—the condition of DNA coiling
specified period of minutes by immersing the slides in an
up on itself because its helix has been bent, overwound, or
alkaline solution. Strand breaks in the denatured cellular DNA
underwound.
results in higher degree of supercoil relaxation: the more
3.2.7 DNA supercoil relaxation, n—upon denaturation,
breaks, the greater the degree of relaxation. Given a sufficient
DNA strand breaks allow the supercoiled DNA to unwind or
degree of relaxation, the application of an electric field across
relax.
the slides creates a motive force by which the charged DNA
may migrate through the surrounding agarose, away from the
3.2.8 double-stranded DNA, n—a structural form of DNA
immobilized main bulk of cellular DNA. Following
where two polynucleotide molecular chains are wound around
electrophoresis, the alkaline conditions are neutralized by
each other, with the joining between the two strands via
rinsingtheslidesinaneutralpHbufferandfixationofslideand
hydrogen bonds between complementary bases.
its contents in ethanol. The DNA in the fixed slides is stained
3.2.9 electrophoresis, n—a method of separating large mol-
with fluorescent DNAstain and visualized using a fluorescent
ecules (such as DNAfragments or proteins) from a mixture of
microscope. Migration distance of DNA away from the
similar molecules. An electric current is passed through a
nucleus, comet tail length, can be measured by eye using an
medium containing the mixture, and each kind of molecule
ocular micrometer. Comet tail length, percent DNAin tail, tail
travelsthroughthemediumatadifferentrate,dependingonits
moment, and other DNA migration values can be calculated
electrical charge and size. Separation is based on these differ-
with the use of image analysis software.
ences. Agarose and acrylamide gels are the media commonly
used for electrophoresis of proteins and nucleic acids.
5. Significance and Use
3.2.10 eukaryotic cell, n—cell with a membrane-bound,
5.1 AcommonresultofcellularstressisanincreaseinDNA
structurally discrete nucleus and other well-developed subcel-
damage. DNA damage may be manifest in the form of base
lular compartments. Eukaryotes include all organisms except
alterations,adductformation,strandbreaks,andcrosslinkages
viruses, bacteria, and cyanobacteria (blue-green algae).
(19). Strand breaks may be introduced in many ways, directly
3.2.11 ocular micrometer, n—a graduated grid placed be- bygenotoxiccompounds,throughtheinductionofapoptosisor
tween the viewer’s eye and an object being observed under a necrosis, secondarily through the interaction with oxygen
microscope, to measure the object’s size. radicalsorotherreactiveintermediates,orasaconsequenceof
E2186 − 02a (2016)
excision repair enzymes (20-22). In addition to a linkage with cycle, cell turnover frequency, culture or growth conditions,
cancer, studies have demonstrated that increases in cellular and other factors that may influence levels of DNA strand
DNA damage precede or correspond with reduced growth, damage. Different cell types may have vastly different back-
abnormal development, and reduced survival of adults, ground levels of DNAsingle-strand breaks due to variations in
embryos, and larvae (16, 23, 24). excision repair activity, metabolic activity, anti-oxidant
concentrations, or other factors. It is recommended that cells
5.1.1 The Comet assay can be easily utilized for collecting
representingthosetobestudiedusingtheSCG/Cometassaybe
data on DNAstrand breakage (9, 25, 26). It is a simple, rapid,
examined under the light or fluorescent microscope using
and sensitive method that allows the comparison of DNA
stains capable of differentially staining different cell types.
stranddamageindifferentcellpopulations.Aspresentedinthis
Morphological differences, staining characteristics, and fre-
guide, the assay facilitates the detection of DNAsingle strand
quencies of the different cell types should be noted and
breaks and alkaline labile sites in individual cells, and can
compared to SCG/Comet damage profiles to identify any
determinetheirabundancerelativetocontrolorreferencecells
possiblecelltypespecificdifferences.Inmostcases,theuseof
(9, 16, 26). The assay offers a number of advantages; damage
homogenous cell populations reduces inter-cell variability of
to the DNA in individual cells is measured, only extremely
SCG/Comet values. The procedures for this assay, using cells
smallnumbersofcellsneedtobesampledtoperformtheassay
from many different species and cell types, have been pub-
(<10000), the assay can be performed on practically any
lishedpreviously (1, 2, 3, 5, 8, 10, 13, 14, 17, 18, 32-38).These
eukaryotic cell type, and it has been shown in comparative
references and others should be consulted to obtain details on
studies to be a very sensitive method for detecting DNA
the collection, handling, storage, and preparation of specific
damage (2, 27).
cell types.
5.1.2 These are general guidelines. There are numerous
procedural variants of this assay. The variation used is depen-
5.3 The experimental design should incorporate appropriate
dent upon the type of cells being examined, the types of DNA
controls, reference samples, and replicates to delineate the
damageofinterest,andtheimagingandanalysiscapabilitiesof
influence of the major sources of experimental variability.
thelabconductingtheassay.TovisualizetheDNA,itisstained
with a fluorescent dye, or for light microscope analysis the
6. Equipment and Reagents
DNA can be silver stained (28). Only fluorescent staining
6.1 Equipment:
methods will be described in this guide. The microscopic
6.1.1 Water Bath,setatatemperatureof35to40°Ctokeep
determination of DNA migration can be made either by eye
slidecoatingagaroseliquefiedduringthepreparationofslides.
using an ocular micrometer or with the use of image analysis
6.1.2 Centrifuge, capable of exerting a 600X g force and of
software. Scoring by eye can be performed using a calibrated
handling 1.5 mL microcentrifuge tubes. Lower g force will
ocular micrometer or by categorizing cells into four to five
require longer centrifugation times and refrigeration to mini-
classes based on the extent of migration (29, 30). Image
mize stress to cells.
analysis systems are comprised of a CCD camera attached to a
6.1.3 Electrophoresis Chamber and Power Supply, a sub-
fluorescent microscope and software and hardware designed
marine electrophoresis chamber, and a power supply able to
specifically to capture and analyze images of fluorescently
deliver a constant current up to 300 mAand a voltage gradient
stained nuclei. Using such a system, it is possible to measure
of 0.4 to 1.3 V/cm.
thefluorescenceintensityanddistributionofDNAina
...


NOTICE: This standard has either been superseded and replaced by a new version or withdrawn.
Contact ASTM International (www.astm.org) for the latest information
Designation: E2186 − 02a (Reapproved 2016)
Standard Guide for
Determining DNA Single-Strand Damage in Eukaryotic Cells
Using the Comet Assay
This standard is issued under the fixed designation E2186; the number immediately following the designation indicates the year of
original adoption or, in the case of revision, the year of last revision. A number in parentheses indicates the year of last reapproval. A
superscript epsilon (´) indicates an editorial change since the last revision or reapproval.
1. Scope cellular DNA repair rates (10), detection of the presence of
photoactive DNA damaging compounds (14), or detection of
1.1 This guide covers the recommended criteria for per-
specific DNA lesions (3, 18).
forming a single-cell gel electrophoresis assay (SCG) or Comet
1.3 This standard does not purport to address all of the
assay for the measurement of DNA single-strand breaks in
safety concerns, if any, associated with its use. It is the
eukaryotic cells. The Comet assay is a very sensitive method
responsibility of the user of this standard to establish appro-
for detecting strand breaks in the DNA of individual cells. The
priate safety and health practices and determine the applica-
majority of studies utilizing the Comet assay have focused on
bility of regulatory requirements prior to use.
medical applications and have therefore examined DNA dam-
1.4 This guide is arranged as follows:
age in mammalian cells in vitro and in vivo (1-4). There is
increasing interest in applying this assay to DNA damage in
Section
freshwater and marine organisms to explore the environmental
Scope 1
implications of DNA damage.
Referenced Documents 2
1.1.1 The Comet assay has been used to screen the geno-
Terminology 3
Summary of Guide 4
toxicity of a variety of compounds on cells in vitro and in vivo
Significance and Use 5
(5-7), as well as to evaluate the dose-dependent anti-oxidant
Equipment and Reagents 6
(protective) properties of various compounds (3, 8-11). Using Assay Procedures 7
Treatment of Data 8
this method, significantly elevated levels of DNA damage have
Reporting Data 9
been reported in cells collected from organisms at polluted
Keywords 10
sites compared to reference sites (12-15). Studies have also Annex Annex A1
References
found that increases in cellular DNA damage correspond with
higher order effects such as decreased growth, survival, and
2. Referenced Documents
development, and correlate with significant increases in con-
2.1 ASTM Standards:
taminant body burdens (13, 16).
E1706 Test Method for Measuring the Toxicity of Sediment-
1.2 This guide presents protocols that facilitate the expres-
Associated Contaminants with Freshwater Invertebrates
sion of DNA alkaline labile single-strand breaks and the
E1847 Practice for Statistical Analysis of Toxicity Tests
determination of their abundance relative to control or refer-
Conducted Under ASTM Guidelines
ence cells. The guide is a general one meant to familiarize lab
personnel with the basic requirements and considerations
3. Terminology
necessary to perform the Comet assay. It does not contain
3.1 The words “must,” “should,” “may,” “can,” and “might”
procedures for available variants of this assay, which allow the
have very specific meanings in this guide. “Must” is used to
determination of non-alkaline labile single-strand breaks or
express the strongest possible recommendation, just short of an
double-stranded DNA strand breaks (8), distinction between
absolute requirement. “Must” is only used in connection with
different cell types (13), identification of cells undergoing
factors that relate directly to the acceptability of the test.
apoptosis (programmed cell death, (1, 17)), measurement of
“Should” is used to state that the specific condition is recom-
mended and ought to be met if possible. Although violation of
on “should” is rarely a serious matter, the violation of several
This guide is under the jurisdiction of ASTM Committee E50 on Environmental
will often render the results questionable. Terms such as “is
Assessment, Risk Management and Corrective Action and is the direct responsibil-
ity of Subcommittee E50.47 on Biological Effects and Environmental Fate.
Current edition approved Feb. 1, 2016. Published May 2016. Originally
approved in 2002. Last previous edition approved 2010 as E2186–02a(2010). DOI: For referenced ASTM standards, visit the ASTM website, www.astm.org, or
10.1520/E2186-02AR16. contact ASTM Customer Service at service@astm.org. For Annual Book of ASTM
The boldface numbers in parentheses refer to the list of references at the end of Standards volume information, refer to the standard’s Document Summary page on
this standard. the ASTM website.
Copyright © ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959. United States
E2186 − 02a (2016)
desirable,” “is often desirable,” and “might be desirable” are 3.2.12 single-stranded DNA, n—linear polymers of DNA
used in connection with less important factors. “May” is used resulting from the breaking of hydrogen bonds between
to mean “is (are) allowed to,” “can” is used to mean “is (are) complementary base pairs in double-stranded DNA.
able to,” and “might” is used to mean “could possibly.” Thus
3.3 Definitions of Terms Specific to This Standard:
the classic distinction between “may” and “can” is preserved
3.3.1 comet, n—name based on the appearance of individual
and “might” is never used as a synonym for either “may” or
stained nuclear DNA and associated relaxed or fragmented
“can.”
DNA migrating out from the nuclear DNA observed under the
3.2 Definitions: microscope following these assay procedures.
3.2.1 CCD camera, n—charge coupled device (CCD) cam-
3.3.2 DNA migration distance, tail length, comet tail length,
era is a light sensitive silicon solid state device composed of
n—distance in microns between the leading edge of electro-
many small pixels. The light falling on a pixel is converted into
phoretically migrating DNA and the closest edge of the
a charge pulse which is then measured by the CCD electronics
associated nuclear DNA (head).
and represented by a number. A digital image is the collection
3.3.3 head, comet head, n—portion of a comet comprised of
of such light intensity numbers for all of the pixels from the
the intact/immobile nuclear DNA.
CCD. A computer can reconstruct the image by varying the
3.3.4 tail, comet tail, n—portion of a comet comprised of the
light intensity for each spot on the computer monitor in the
DNA migrating away from the intact/immobile nuclear DNA.
proper order. Such digital images can be stored on disk,
3.3.5 tail moment, n—a calculated value used to express the
transmitted over a computer network, and analyzed using
image processing techniques. distribution of DNA migrating from the comet head. Image
analysis software applies an algorithm to the digitized image of
3.2.2 cell lysis, n—the process of breaking open a cell by
stained DNA and associated migrating DNA tail, which in
disruption of the plasma membrane.
essence defines the limits of the comet, subtracts background,
3.2.3 DNA, n—acronym for deoxyribonucleic acid, the sub-
and determines the boundaries and staining intensity of the
stance that is the carrier of genetic information found in the
nucleus and comet tail. The calculated product of the percent of
chromosomes of the nucleus of a cell.
DNA in the tail and the tail length is defined as the tail moment.
3.2.4 DNA denaturation, n—refers to breaking hydrogen
4. Summary of Guide
bonds between base pairs in double-stranded nucleic acid
molecules to produce two single-stranded polynucleotide poly-
4.1 Cells collected from organisms under different levels or
mers.
types of stress are dispersed and immobilized in agarose gel on
microscope slides. The slides are placed in a solution to lyse
3.2.5 DNA lesion, n—a portion of a DNA molecule which
and disperse cell components, leaving the cellular DNA
has been structurally changed.
immobilized in the agarose. The DNA is denatured for a
3.2.6 DNA supercoiling, n—the condition of DNA coiling
specified period of minutes by immersing the slides in an
up on itself because its helix has been bent, overwound, or
alkaline solution. Strand breaks in the denatured cellular DNA
underwound.
results in higher degree of supercoil relaxation: the more
3.2.7 DNA supercoil relaxation, n—upon denaturation,
breaks, the greater the degree of relaxation. Given a sufficient
DNA strand breaks allow the supercoiled DNA to unwind or
degree of relaxation, the application of an electric field across
relax.
the slides creates a motive force by which the charged DNA
may migrate through the surrounding agarose, away from the
3.2.8 double-stranded DNA, n—a structural form of DNA
immobilized main bulk of cellular DNA. Following
where two polynucleotide molecular chains are wound around
electrophoresis, the alkaline conditions are neutralized by
each other, with the joining between the two strands via
rinsing the slides in a neutral pH buffer and fixation of slide and
hydrogen bonds between complementary bases.
its contents in ethanol. The DNA in the fixed slides is stained
3.2.9 electrophoresis, n—a method of separating large mol-
with fluorescent DNA stain and visualized using a fluorescent
ecules (such as DNA fragments or proteins) from a mixture of
microscope. Migration distance of DNA away from the
similar molecules. An electric current is passed through a
nucleus, comet tail length, can be measured by eye using an
medium containing the mixture, and each kind of molecule
ocular micrometer. Comet tail length, percent DNA in tail, tail
travels through the medium at a different rate, depending on its
moment, and other DNA migration values can be calculated
electrical charge and size. Separation is based on these differ-
with the use of image analysis software.
ences. Agarose and acrylamide gels are the media commonly
used for electrophoresis of proteins and nucleic acids.
5. Significance and Use
3.2.10 eukaryotic cell, n—cell with a membrane-bound,
5.1 A common result of cellular stress is an increase in DNA
structurally discrete nucleus and other well-developed subcel-
damage. DNA damage may be manifest in the form of base
lular compartments. Eukaryotes include all organisms except
alterations, adduct formation, strand breaks, and cross linkages
viruses, bacteria, and cyanobacteria (blue-green algae).
(19). Strand breaks may be introduced in many ways, directly
3.2.11 ocular micrometer, n—a graduated grid placed be- by genotoxic compounds, through the induction of apoptosis or
tween the viewer’s eye and an object being observed under a necrosis, secondarily through the interaction with oxygen
microscope, to measure the object’s size. radicals or other reactive intermediates, or as a consequence of
E2186 − 02a (2016)
excision repair enzymes (20-22). In addition to a linkage with cycle, cell turnover frequency, culture or growth conditions,
cancer, studies have demonstrated that increases in cellular and other factors that may influence levels of DNA strand
DNA damage precede or correspond with reduced growth, damage. Different cell types may have vastly different back-
abnormal development, and reduced survival of adults, ground levels of DNA single-strand breaks due to variations in
embryos, and larvae (16, 23, 24). excision repair activity, metabolic activity, anti-oxidant
concentrations, or other factors. It is recommended that cells
5.1.1 The Comet assay can be easily utilized for collecting
representing those to be studied using the SCG/Comet assay be
data on DNA strand breakage (9, 25, 26). It is a simple, rapid,
examined under the light or fluorescent microscope using
and sensitive method that allows the comparison of DNA
stains capable of differentially staining different cell types.
strand damage in different cell populations. As presented in this
Morphological differences, staining characteristics, and fre-
guide, the assay facilitates the detection of DNA single strand
quencies of the different cell types should be noted and
breaks and alkaline labile sites in individual cells, and can
compared to SCG/Comet damage profiles to identify any
determine their abundance relative to control or reference cells
possible cell type specific differences. In most cases, the use of
(9, 16, 26). The assay offers a number of advantages; damage
homogenous cell populations reduces inter-cell variability of
to the DNA in individual cells is measured, only extremely
SCG/Comet values. The procedures for this assay, using cells
small numbers of cells need to be sampled to perform the assay
from many different species and cell types, have been pub-
(<10 000), the assay can be performed on practically any
lished previously (1, 2, 3, 5, 8, 10, 13, 14, 17, 18, 32-38). These
eukaryotic cell type, and it has been shown in comparative
references and others should be consulted to obtain details on
studies to be a very sensitive method for detecting DNA
the collection, handling, storage, and preparation of specific
damage (2, 27).
cell types.
5.1.2 These are general guidelines. There are numerous
procedural variants of this assay. The variation used is depen-
5.3 The experimental design should incorporate appropriate
dent upon the type of cells being examined, the types of DNA
controls, reference samples, and replicates to delineate the
damage of interest, and the imaging and analysis capabilities of
influence of the major sources of experimental variability.
the lab conducting the assay. To visualize the DNA, it is stained
with a fluorescent dye, or for light microscope analysis the
6. Equipment and Reagents
DNA can be silver stained (28). Only fluorescent staining
6.1 Equipment:
methods will be described in this guide. The microscopic
6.1.1 Water Bath, set at a temperature of 35 to 40°C to keep
determination of DNA migration can be made either by eye
slide coating agarose liquefied during the preparation of slides.
using an ocular micrometer or with the use of image analysis
6.1.2 Centrifuge, capable of exerting a 600X g force and of
software. Scoring by eye can be performed using a calibrated
handling 1.5 mL microcentrifuge tubes. Lower g force will
ocular micrometer or by categorizing cells into four to five
require longer centrifugation times and refrigeration to mini-
classes based on the extent of migration (29, 30). Image
mize stress to cells.
analysis systems are comprised of a CCD camera attached to a
6.1.3 Electrophoresis Chamber and Power Supply, a sub-
fluorescent microscope and software and hardware designed
marine electrophoresis chamber, and a power supply able to
specifically to capture and analyze images of
...


This document is not an ASTM standard and is intended only to provide the user of an ASTM standard an indication of what changes have been made to the previous version. Because
it may not be technically possible to adequately depict all changes accurately, ASTM recommends that users consult prior editions as appropriate. In all cases only the current version
of the standard as published by ASTM is to be considered the official document.
Designation: E2186 − 02a (Reapproved 2010) E2186 − 02a (Reapproved 2016)
Standard Guide for
Determining DNA Single-Strand Damage in Eukaryotic Cells
Using the Comet Assay
This standard is issued under the fixed designation E2186; the number immediately following the designation indicates the year of
original adoption or, in the case of revision, the year of last revision. A number in parentheses indicates the year of last reapproval. A
superscript epsilon (´) indicates an editorial change since the last revision or reapproval.
1. Scope
1.1 This guide covers the recommended criteria for performing a single-cell gel electrophoresis assay (SCG) or Comet assay
for the measurement of DNA single-strand breaks in eukaryotic cells. The Comet assay is a very sensitive method for detecting
strand breaks in the DNA of individual cells. The majority of studies utilizing the Comet assay have focused on medical
applications and have therefore examined DNA damage in mammalian cells in vitro and in vivo (1-4). There is increasing interest
in applying this assay to DNA damage in freshwater and marine organisms to explore the environmental implications of DNA
damage.
1.1.1 The Comet assay has been used to screen the genotoxicity of a variety of compounds on cells in vitro and in vivo (5-7),
as well as to evaluate the dose-dependent anti-oxidant (protective) properties of various compounds (3, 8-11). Using this method,
significantly elevated levels of DNA damage have been reported in cells collected from organisms at polluted sites compared to
reference sites (12-15). Studies have also found that increases in cellular DNA damage correspond with higher order effects such
as decreased growth, survival, and development, and correlate with significant increases in contaminant body burdens (13, 16).
1.2 This guide presents protocols that facilitate the expression of DNA alkaline labile single-strand breaks and the determination
of their abundance relative to control or reference cells. The guide is a general one meant to familiarize lab personnel with the basic
requirements and considerations necessary to perform the Comet assay. It does not contain procedures for available variants of this
assay, which allow the determination of non-alkaline labile single-strand breaks or double-stranded DNA strand breaks (8),
distinction between different cell types (13), identification of cells undergoing apoptosis (programmed cell death, (1, 17)),
measurement of cellular DNA repair rates (10), detection of the presence of photoactive DNA damaging compounds (14), or
detection of specific DNA lesions (3, 18).
1.3 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility
of the user of this standard to establish appropriate safety and health practices and determine the applicability of regulatory
requirements prior to use.
1.4 This guide is arranged as follows:
Section
Scope 1
Referenced Documents 2
Terminology 3
Summary of Guide 4
Significance and Use 5
Equipment and Reagents 6
Assay Procedures 7
Treatment of Data 8
Reporting Data 9
Keywords 10
Annex A1
Annex Annex A1
References
This guide is under the jurisdiction of ASTM Committee E50 on Environmental Assessment, Risk Management and Corrective Action and is the direct responsibility
of Subcommittee E50.47 on Biological Effects and Environmental Fate.
Current edition approved March 1, 2010Feb. 1, 2016. Published May 2010May 2016. Originally approved in 2002. Last previous edition approved 20022010 as
E2186–02A.E2186–02a(2010). DOI: 10.1520/E2186-02AR10. 10.1520/E2186-02AR16.
The boldface numbers in parentheses refer to the list of references at the end of this standard.
Copyright © ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959. United States
E2186 − 02a (2016)
2. Referenced Documents
2.1 ASTM Standards:
E1706 Test Method for Measuring the Toxicity of Sediment-Associated Contaminants with Freshwater Invertebrates
E1847 Practice for Statistical Analysis of Toxicity Tests Conducted Under ASTM Guidelines
3. Terminology
3.1 The words “must,” “should,” “may,” “can,” and “might” have very specific meanings in this guide. “Must” is used to
express the strongest possible recommendation, just short of an absolute requirement. “Must” is only used in connection with
factors that relate directly to the acceptability of the test. “Should” is used to state that the specific condition is recommended and
ought to be met if possible. Although violation of on “should” is rarely a serious matter, the violation of several will often render
the results questionable. Terms such as “is desirable,” “is often desirable,” and “might be desirable” are used in connection with
less important factors. “May” is used to mean “is (are) allowed to,” “can” is used to mean “is (are) able to,” and “might” is used
to mean “could possibly.” Thus the classic distinction between “may” and “can” is preserved and “might” is never used as a
synonym for either “may” or “can.”
3.2 Definitions:
3.2.1 CCD camera, n—charge coupled device (CCD) camera is a light sensitive silicon solid state device composed of many
small pixels. The light falling on a pixel is converted into a charge pulse which is then measured by the CCD electronics and
represented by a number. A digital image is the collection of such light intensity numbers for all of the pixels from the CCD. A
computer can reconstruct the image by varying the light intensity for each spot on the computer monitor in the proper order. Such
digital images can be stored on disk, transmitted over a computer network, and analyzed using image processing techniques.
3.2.2 cell lysis, n—the process of breaking open a cell by disruption of the plasma membrane.
3.2.3 DNA, n—acronym for deoxyribonucleic acid, the substance that is the carrier of genetic information found in the
chromosomes of the nucleus of a cell.
3.2.4 DNA denaturation, n—refers to breaking hydrogen bonds between base pairs in double-stranded nucleic acid molecules
to produce two single-stranded polynucleotide polymers.
3.2.5 DNA lesion, n—a portion of a DNA molecule which has been structurally changed.
3.2.6 DNA supercoiling, n—the condition of DNA coiling up on itself because its helix has been bent, overwound, or
underwound.
3.2.7 DNA supercoil relaxation, n—upon denaturation, DNA strand breaks allow the supercoiled DNA to unwind or relax.
3.2.8 double-stranded DNA, n—a structural form of DNA where two polynucleotide molecular chains are wound around each
other, with the joining between the two strands via hydrogen bonds between complementary bases.
3.2.9 electrophoresis, n—a method of separating large molecules (such as DNA fragments or proteins) from a mixture of similar
molecules. An electric current is passed through a medium containing the mixture, and each kind of molecule travels through the
medium at a different rate, depending on its electrical charge and size. Separation is based on these differences. Agarose and
acrylamide gels are the media commonly used for electrophoresis of proteins and nucleic acids.
3.2.10 eukaryotic cell, n—cell with a membrane-bound, structurally discrete nucleus and other well-developed subcellular
compartments. Eukaryotes include all organisms except viruses, bacteria, and cyanobacteria (blue-green algae).
3.2.11 ocular micrometer, n—a graduated grid placed between the viewer’s eye and an object being observed under a
microscope, to measure the object’s size.
3.2.12 single-stranded DNA, n—linear polymers of DNA resulting from the breaking of hydrogen bonds between complemen-
tary base pairs in double-stranded DNA.
3.3 Definitions of Terms Specific to This Standard:
3.3.1 comet, n—name based on the appearance of individual stained nuclear DNA and associated relaxed or fragmented DNA
migrating out from the nuclear DNA observed under the microscope following these assay procedures.
3.3.2 DNA migration distance, tail length, comet tail length, n—distance in microns between the leading edge of
electrophoretically migrating DNA and the closest edge of the associated nuclear DNA (head).
3.3.3 head, comet head, n—portion of a comet comprised of the intact/immobile nuclear DNA.
3.3.4 tail, comet tail, n—portion of a comet comprised of the DNA migrating away from the intact/immobile nuclear DNA.
3.3.5 tail moment, n—a calculated value used to express the distribution of DNA migrating from the comet head. Image analysis
software applies an algorithm to the digitized image of stained DNA and associated migrating DNA tail, which in essence defines
For referenced ASTM standards, visit the ASTM website, www.astm.org, or contact ASTM Customer Service at service@astm.org. For Annual Book of ASTM Standards
volume information, refer to the standard’s Document Summary page on the ASTM website.
E2186 − 02a (2016)
the limits of the comet, subtracts background, and determines the boundaries and staining intensity of the nucleus and comet tail.
The calculated product of the percent of DNA in the tail and the tail length is defined as the tail moment.
4. Summary of Guide
4.1 Cells collected from organisms under different levels or types of stress are dispersed and immobilized in agarose gel on
microscope slides. The slides are placed in a solution to lyse and disperse cell components, leaving the cellular DNA immobilized
in the agarose. The DNA is denatured for a specified period of minutes by immersing the slides in an alkaline solution. Strand
breaks in the denatured cellular DNA results in higher degree of supercoil relaxation: the more breaks, the greater the degree of
relaxation. Given a sufficient degree of relaxation, the application of an electric field across the slides creates a motive force by
which the charged DNA may migrate through the surrounding agarose, away from the immobilized main bulk of cellular DNA.
Following electrophoresis, the alkaline conditions are neutralized by rinsing the slides in a neutral pH buffer and fixation of slide
and its contents in ethanol. The DNA in the fixed slides is stained with fluorescent DNA stain and visualized using a fluorescent
microscope. Migration distance of DNA away from the nucleus, comet tail length, can be measured by eye using an ocular
micrometer. Comet tail length, percent DNA in tail, tail moment, and other DNA migration values can be calculated with the use
of image analysis software.
5. Significance and Use
5.1 A common result of cellular stress is an increase in DNA damage. DNA damage may be manifest in the form of base
alterations, adduct formation, strand breaks, and cross linkages (19). Strand breaks may be introduced in many ways, directly by
genotoxic compounds, through the induction of apoptosis or necrosis, secondarily through the interaction with oxygen radicals or
other reactive intermediates, or as a consequence of excision repair enzymes (20-22). In addition to a linkage with cancer, studies
have demonstrated that increases in cellular DNA damage precede or correspond with reduced growth, abnormal development, and
reduced survival of adults, embryos, and larvae (16, 23, 24).
5.1.1 The Comet assay can be easily utilized for collecting data on DNA strand breakage (9, 25, 26). It is a simple, rapid, and
sensitive method that allows the comparison of DNA strand damage in different cell populations. As presented in this guide, the
assay facilitates the detection of DNA single strand breaks and alkaline labile sites in individual cells, and can determine their
abundance relative to control or reference cells (9, 16, 26). The assay offers a number of advantages; damage to the DNA in
individual cells is measured, only extremely small numbers of cells need to be sampled to perform the assay (<10 000), the assay
can be performed on practically any eukaryotic cell type, and it has been shown in comparative studies to be a very sensitive
method for detecting DNA damage (2, 27).
5.1.2 These are general guidelines. There are numerous procedural variants of this assay. The variation used is dependent upon
the type of cells being examined, the types of DNA damage of interest, and the imaging and analysis capabilities of the lab
conducting the assay. To visualize the DNA, it is stained with a fluorescent dye, or for light microscope analysis the DNA can be
silver stained (28). Only fluorescent staining methods will be described in this guide. The microscopic determination of DNA
migration can be made either by eye using an ocular micrometer or with the use of image analysis software. Scoring by eye can
be performed using a calibrated ocular micrometer or by categorizing cells into four to five classes based on the extent of migration
(29, 30). Image analysis systems are comprised of a CCD camera attached to a fluorescent microscope and software and hardware
designed specifically to capture and analyze images of fluorescently stained nuclei. Using such a system, it is possible to measure
the fluorescence intensity and distribution of DNA in and away from the nucleus (8). Using different procedural variants, the assay
can be utilized to measure specific types of DNA alterations and DNA repair activity (1, 3, 8, 10, 13, 14, 17, 18). Alkaline lysis
and electrophoresis conditions are used for the detection of single-stranded DNA damage, whereas neutral pH conditions facilitate
the detection of double-strand breaks (31). Various sample treatments can be used to express specific types of DNA damage, or
as in one method, to preserve strand damage at sites of DNA repair (10). Nuclease digestion steps can be used to introduce strand
breaks at specific lesion sites. Using this approach, oxidative base damage can be detected by the use of endonuclease III (18), as
well as DNA modifications resulting from exposure to ultraviolet light (UV) through the use of T4 endonuclease V (3).
Modifications of this type vastly expand the utility of this assay and are good examples of its versatility.
5.2 A sufficient knowledge of the biology of cells examined using this assay should be attained to understand factors affecting
DNA strand breakage and the distribution of this damage within sampled cell populations. This includes, but is not limited to,
influences such as cell type heterogeneity, cell cycle, cell turnover frequency, culture or growth conditions, and other factors that
may influence levels of DNA strand damage. Different cell types
...

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Standard Guide for Determining DNA Single-Strand Damage in Eukaryotic Cells Using the Comet Assay

SIGNIFICANCE AND USE
5.1 A common result of cellular stress is an increase in DNA damage. DNA damage may be manifest in the form of base alterations, adduct formation, strand breaks, and cross linkages (19). Strand breaks may be introduced in many ways, directly by genotoxic compounds, through the induction of apoptosis or necrosis, secondarily through the interaction with oxygen radicals or other reactive intermediates, or as a consequence of excision repair enzymes (20-22). In addition to a linkage with cancer, studies have demonstrated that increases in cellular DNA damage precede or correspond with reduced growth, abnormal development, and reduced survival of adults, embryos, and larvae (16, 23, 24).  
5.1.1 The Comet assay can be easily utilized for collecting data on DNA strand breakage (9, 25, 26). It is a simple, rapid, and sensitive method that allows the comparison of DNA strand damage in different cell populations. As presented in this guide, the assay facilitates the detection of DNA single strand breaks and alkaline labile sites in individual cells, and can determine their abundance relative to control or reference cells  (9, 16, 26). The assay offers a number of advantages; damage to the DNA in individual cells is measured, only extremely small numbers of cells need to be sampled to perform the assay ((2, 27) .  
5.1.2 These are general guidelines. There are numerous procedural variants of this assay. The variation used is dependent upon the type of cells being examined, the types of DNA damage of interest, and the imaging and analysis capabilities of the lab conducting the assay. To visualize the DNA, it is stained with a fluorescent dye, or for light microscope analysis the DNA can be silver stained (28). Only fluorescent staining methods will be described in this guide. The microscopic determination of DNA migration can be made either by eye using an ocular micrometer or with the use of image analysis software. Scoring by eye can be performed using a calibrated ocular...
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1.1 This guide covers the recommended criteria for performing a single-cell gel electrophoresis assay (SCG) or Comet assay for the measurement of DNA single-strand breaks in eukaryotic cells. The Comet assay is a very sensitive method for detecting strand breaks in the DNA of individual cells. The majority of studies utilizing the Comet assay have focused on medical applications and have therefore examined DNA damage in mammalian cells in vitro and in vivo (1-4).2 There is increasing interest in applying this assay to DNA damage in freshwater and marine organisms to explore the environmental implications of DNA damage.  
1.1.1 The Comet assay has been used to screen the genotoxicity of a variety of compounds on cells in vitro and in vivo (5-7), as well as to evaluate the dose-dependent anti-oxidant (protective) properties of various compounds (3, 8-11). Using this method, significantly elevated levels of DNA damage have been reported in cells collected from organisms at polluted sites compared to reference sites (12-15). Studies have also found that increases in cellular DNA damage correspond with higher order effects such as decreased growth, survival, and development, and correlate with significant increases in contaminant body burdens (13, 16).  
1.2 This guide presents protocols that facilitate the expression of DNA alkaline labile single-strand breaks and the determination of their abundance relative to control or reference cells. The guide is a general one meant to familiarize lab personnel with the basic requirements and considerations necessary to perform the Comet assay. It does not contain procedures for available variants of this assay, which allow the determination of non-alkaline labile single-strand breaks or double-stranded DNA strand breaks (8), distinction between different cell types (13), identification of cells undergoing apoptosis (programmed cell death, (1, 17)), measurement of cellular DNA repair...

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ASTM
ASTM E2196-23(Test Method)
Standard Test Method for Quantification of Pseudomonas aeruginosa Biofilm Grown with Medium Shear and Continuous Flow Using Rotating Disk Reactor

SIGNIFICANCE AND USE
5.1 Bacteria that exist in a biofilm are phenotypically different from suspended cells of the same genotype. The study of biofilm in the laboratory requires protocols that account for this difference. Laboratory biofilms are engineered in growth reactors designed to produce a specific biofilm type. Altering system parameters will correspondingly result in a change in the biofilm. The purpose of this method is to direct a user in the laboratory study of biofilms by clearly defining each system parameter. This method will enable a person to grow, sample, and analyze a laboratory biofilm. The method was originally developed to study toilet bowl biofilms, but may also be utilized for research that requires a biofilm grown under moderate fluid shear.
SCOPE
1.1 This test method is used for growing a reproducible (1)2 Pseudomonas aeruginosa biofilm in a continuously stirred tank reactor (CSTR) under medium shear conditions. In addition, the test method describes how to sample and analyze biofilm for viable cells.  
1.2 Although this test method was created to mimic conditions within a toilet bowl, it can be adapted for the growth and characterization of varying species of biofilm (rotating disk reactor—repeatability and relevance (2)).  
1.3 This test method describes how to sample and analyze biofilm for viable cells. Biofilm population density is recorded as log10 colony forming units per surface area (rotating disk reactor—efficacy test method (3)).  
1.4 Basic microbiology training is required to perform this test method.  
1.5 The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard.  
1.6 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
1.7 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ASTM
ASTM D7847-22(Guide)
Standard Guide for Interlaboratory Studies for Microbiological Test Methods

SCOPE
1.1 Microbiological test methods present challenges that are unique relative to chemical or physical parameters, because microbes proliferate, die off and continue to be metabolically active in samples after those samples have been drawn from their source.  
1.1.1 Microbial activity depends on the presence of available water. Consequently, the detection and quantification of microbial contamination in fuels and lubricants is made more complicated by the general absence of available water from these fluids.  
1.1.2 Detectability depends on the physiological state and taxonomic profile of microbes in samples. These two parameters are affected by various factors that are discussed in this guide, and contribute to microbial data variability.  
1.2 This guide addresses the unique considerations that must be accounted for in the design and execution of interlaboratory studies intended to determine the precision of microbiological test methods designed to quantify microbial contamination in fuels, lubricants and similar low water-content (water activity  
1.3 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
1.4 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ASTM
ASTM E2799-22(Test Method)
Standard Test Method for Testing Disinfectant Efficacy against Pseudomonas aeruginosa Biofilm using the MBEC Assay

SIGNIFICANCE AND USE
5.1 Vegetative biofilm bacteria are phenotypically different from suspended planktonic cells of the same genotype. Biofilm growth reactors are engineered to produce biofilms with specific characteristics. Altering either the engineered system or operating conditions will modify those characteristics. The goal in biofilm research and efficacy testing is to choose the growth reactor that generates the most relevant biofilm for the particular study.  
5.2 The purpose of this test method is to direct a user in how to grow, treat, sample and analyze a Pseudomonas aeruginosa biofilm using the MBEC Assay. Microscopically, the biofilm is sheet-like with few architectural details as seen in Harrison et al (6). The MBEC Assay was originally designed as a rapid and reproducible assay for evaluating biofilm susceptibility to antibiotics (2). The engineering design allows for the simultaneous evaluation of multiple test conditions, making it an efficient method for screening multiple disinfectants or multiple concentrations of the same disinfectant. Additional efficiency is added by including the neutralizer controls within the assay device. The small well volume is advantageous for testing expensive disinfectants, or when only small volumes of the disinfectant are available.
SCOPE
1.1 This test method specifies the operational parameters required to grow and treat a Pseudomonas aeruginosa biofilm in a high throughput screening assay known as the MBEC (trademarked)2 (Minimum Biofilm Eradication Concentration) Physiology and Genetics Assay. The assay device consists of a plastic lid with ninety-six (96) pegs and a corresponding receiver plate with ninety-six (96) individual wells that have a maximum 200 μL working volume. Biofilm is established on the pegs under batch conditions (that is, no flow of nutrients into or out of an individual well) with gentle mixing. The established biofilm is transferred to a new receiver plate for disinfectant efficacy testing.3, 4 The reactor design allows for the simultaneous testing of multiple disinfectants or one disinfectant with multiple concentrations, and replicate samples, making the assay an efficient screening tool.  
1.2 This test method defines the specific operational parameters necessary for growing a Pseudomonas aeruginosa  biofilm, although the device is versatile and has been used for growing, evaluating and/or studying biofilms of different species as seen in Refs (1-4).5  
1.3 Validation of disinfectant neutralization is included as part of the assay.  
1.4 This test method describes how to sample the biofilm and quantify viable cells. Biofilm population density is recorded as log10 colony forming units per surface area. Efficacy is reported as the log10 reduction of viable cells.  
1.5 Basic microbiology training is required to perform this assay.  
1.6 The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard.  
1.7 ASTM International takes no position respecting the validity of any patent rights asserted in connection with any item mentioned in this standard. Users of this standard are expressly advised that determination of the validity of any such patent rights, and the risk of infringement of such rights, are entirely their own responsibility.  
1.8 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety and health practices and determine the applicability of regulatory limitations prior to use.  
1.9 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ASTM
ASTM E2562-22(Test Method)
Standard Test Method for Quantification of Pseudomonas aeruginosa Biofilm Grown with High Shear and Continuous Flow using CDC Biofilm Reactor

SIGNIFICANCE AND USE
5.1 Bacteria that exist in biofilms are phenotypically different from suspended cells of the same genotype. Research has shown that biofilm bacteria are more difficult to kill than suspended bacteria (5, 7). Laboratory biofilms are engineered in growth reactors designed to produce a specific biofilm type. Altering system parameters will correspondingly result in a change in the biofilm. For example, research has shown that biofilm grown under high shear is more difficult to kill than biofilm grown under low shear (5, 8). The purpose of this test method is to direct a user in the laboratory study of a Pseudomonas aeruginosa biofilm by clearly defining each system parameter. This test method will enable an investigator to grow, sample, and analyze a Pseudomonas aeruginosa biofilm grown under high shear. The biofilm generated in the CDC Biofilm Reactor is also suitable for efficacy testing. After the 48 h growth phase is complete, the user may add the treatment in situ or remove the coupons and treat them individually.
SCOPE
1.1 This test method specifies the operational parameters required to grow a reproducible (1)2 Pseudomonas aeruginosa ATCC 700888 biofilm under high shear. The resulting biofilm is representative of generalized situations where biofilm exists under high shear rather than being representative of one particular environment.  
1.2 This test method uses the Centers for Disease Control and Prevention (CDC) Biofilm Reactor. The CDC Biofilm Reactor is a continuously stirred tank reactor (CSTR) with high wall shear. Although it was originally designed to model a potable water system for the evaluation of Legionella pneumophila (2), the reactor is versatile and may also be used for growing and/or characterizing biofilm of varying species (3-5).  
1.3 This test method describes how to sample and analyze biofilm for viable cells. Biofilm population density is recorded as log10 colony forming units per surface area.  
1.4 Basic microbiology training is required to perform this test method.  
1.5 The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard.  
1.6 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety and health practices and determine the applicability of regulatory limitations prior to use.  
1.7 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ASTM
ASTM D8412-21(Guide)
Standard Guide for Quantification of Microbial Contamination in Liquid Fuels and Fuel-Associated Water by Quantitative Polymerase Chain Reaction (qPCR)

SIGNIFICANCE AND USE
5.1 This guide provides a protocol for detecting, characterizing, and quantifying nucleic acids (that is, DNA) of living and recently dead microorganisms in fuels and fuel-associated waters by means of a culture independent qPCR procedure. Microbial contamination is inferred when elevated DNA levels are detected in comparison to the expected background DNA level of a clean fuel and fuel system.  
5.2 A sequence of protocol steps is required for successful qPCR testing.  
5.2.1 Quantitative detection of microorganisms depends on the DNA-extraction protocol and selection of appropriate oligonucleotide primers.  
5.2.2 The preferred DNA extraction protocol depends on the type of microorganism present in the sample and potential impurities that could interfere with the subsequent qPCR reaction.  
5.2.3 Primers vary in their specificity. Some 16S and 18S RNA gene regions present in the DNA of prokaryotic and eukaryotic microorganisms appear to have been conserved throughout evolution and thus provide a reliable and repeatable target for gene amplification and detection. Amplicons targeting these conserved nucleotide sequences are useful for quantifying total population densities. Other target DNA regions are specific to a metabolic class (for example, sulfate reducing bacteria) or individual taxon (for example, the bacterial species Pseudomonas aeruginosa). Primers targeting these unique nucleotide sequences are useful for detecting and quantifying specific microbes or groups of microbes known to be associated with biodeterioration.  
5.3 Just as the quantification of microorganisms using microbial growth media employs standardized formulations of growth conditions enabling the meaningful comparison of data from different laboratories (Practice D6974), this guide seeks to provide standardization to detect, characterize, and quantify nucleic acids associated with living and recently dead microorganisms in fuel-associated samples using qPCR.
Note 3: Many primers, an...
SCOPE
1.1 This guide covers procedures for using quantitative polymerase chain reaction (qPCR), a genomic tool, to detect, characterize and quantify nucleic acids associated with microbial DNA present in liquid fuels and fuel-associated water samples.  
1.1.1 Water samples that may be used in testing include, but are not limited to, water associated with crude oil or liquid fuels in storage tanks, fuel tanks, or pipelines.  
1.1.2 While the intent of this guide is to focus on the analysis of fuel-associated samples, the procedures described here are also relevant to the analysis of water used in hydrotesting of pipes and equipment, water injected into geological formations to maintain pressure and/or facilitate the recovery of hydrocarbons in oil and gas recovery, water co-produced during the production of oil and gas, water in fire protection sprinkler systems, potable water, industrial process water, and wastewater.  
1.1.3 To test a fuel sample, the live and recently dead microorganisms must be separated from the fuel phase which can include any DNA fragments by using one of various methods such as filtration or any other microbial capturing methods.  
1.1.4 Some of the protocol steps are universally required and are indicated by the use of the word must. Other protocol steps are testing-objective dependent. At those process steps, options are offered and the basis for choosing among them are explained.  
1.2 The guide describes the application of quantitative polymerase chain reaction (qPCR) technology to determine total bioburden or total microbial population present in fuel-associated samples using universal primers that allow for the quantification of 16S and 18S ribosomal RNA genes that are present in all prokaryotes (that is, bacteria and archaea) and eucaryotes (that is, mold and yeast collectively termed fungi), respectively.  
1.3 This guide describes laboratory protocols. As described in Practice D7464, the...

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