Section



[Code of Federal Regulations]
[Title 40, Volume 30]
[Revised as of July 1, 2004]
From the U.S. Government Printing Office via GPO Access
[CITE: 40CFR799.9510]

[Page 408-415]
 
                   TITLE 40--PROTECTION OF ENVIRONMENT
 
         CHAPTER I--ENVIRONMENTAL PROTECTION AGENCY (CONTINUED)
 
PART 799_IDENTIFICATION OF SPECIFIC CHEMICAL SUBSTANCE AND MIXTURE TESTING 
REQUIREMENTS--Table of Contents
 
                Subpart H_Health Effects Test Guidelines
 
Sec. 799.9510  TSCA bacterial reverse mutation test.

    (a) Scope. This section is intended to meet the testing requirements 
under section 4 of TSCA.
    (1) The bacterial reverse mutation test uses amino-acid requiring 
strains of Salmonella typhimurium and Escherichia coli to detect point 
mutations, which involve substitution, addition or deletion of one or a 
few DNA base pairs. The principle of this bacterial reverse mutation 
test is that it detects mutations which revert mutations present in the 
test strains and restore the functional capability of the bacteria to 
synthesize an essential amino acid. The revertant bacteria are detected 
by their ability to grow in the absence of the amino acid required by 
the parent test strain.
    (2) Point mutations are the cause of many human genetic diseases and 
there is substantial evidence that point mutations in oncogenes and 
tumor suppressor genes of somatic cells are involved in tumor formation 
in humans and experimental animals. The bacterial reverse mutation test 
is rapid, inexpensive and relatively easy to perform. Many of the test 
strains have several features that make them more sensitive for the 
detection of mutations, including responsive DNA sequences at the 
reversion sites, increased cell permeability to large molecules and 
elimination of DNA repair systems or enhancement of error-prone DNA 
repair processes. The specificity of the test strains can provide some 
useful information on the types of mutations that are induced by 
genotoxic agents. A very large data base of results for a wide variety 
of structures is available for bacterial reverse mutation tests and 
well-established methodologies have been developed for testing chemicals 
with different physico-chemical properties, including volatile 
compounds.
    (b) Source. The source material used in developing this TSCA test 
guideline are the OECD replacement guidelines for 471 and 472 (February 
1997). This source is available at the address in paragraph (g) of this 
section.
    (c) Definitions. The following definitions apply to this section:
    A reverse mutation test in either Salmonella typhimurium or 
Escherichia coli detects mutation in an amino-acid requiring strain 
(histidine or tryptophan, respectively) to produce a strain independent 
of an outside supply of amino-acid.
    Base pair substitution mutagens are agents that cause a base change 
in DNA. In a reversion test this change may occur at the site of the 
original mutation, or at a second site in the bacterial genome.
    Frameshift mutagens are agents that cause the addition or deletion 
of one or more base pairs in the DNA, thus changing the reading frame in 
the RNA
    (d) Initial considerations. (1) The bacterial reverse mutation test 
utilizes prokaryotic cells, which differ from mammalian cells in such 
factors as uptake, metabolism, chromosome structure and DNA repair 
processes. Tests conducted in vitro generally require the use of an 
exogenous source of metabolic activation. In vitro metabolic activation 
systems cannot mimic entirely the mammalian in vivo conditions. The test 
therefore does not provide direct information on the mutagenic and 
carcinogenic potency of a substance in mammals.
    (2) The bacterial reverse mutation test is commonly employed as an 
initial screen for genotoxic activity and, in particular, for point 
mutation-inducing activity. An extensive data base has demonstrated that 
many chemicals that are positive in this test also exhibit mutagenic 
activity in other tests. There are examples of mutagenic agents which 
are not detected by this

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test; reasons for these shortcomings can be ascribed to the specific 
nature of the endpoint detected, differences in metabolic activation, or 
differences in bioavailability. On the other hand, factors which enhance 
the sensitivity of the bacterial reverse mutation test can lead to an 
overestimation of mutagenic activity.
    (3) The bacterial reverse mutation test may not be appropriate for 
the evaluation of certain classes of chemicals, for example highly 
bactericidal compounds (e.g. certain antibiotics) and those which are 
thought (or known) to interfere specifically with the mammalian cell 
replication system (e.g. some topoisomerase inhibitors and some 
nucleoside analogues). In such cases, mammalian mutation tests may be 
more appropriate.
    (4) Although many compounds that are positive in this test are 
mammalian carcinogens, the correlation is not absolute. It is dependent 
on chemical class and there are carcinogens that are not detected by 
this test because they act through other, non-genotoxic mechanisms or 
mechanisms absent in bacterial cells.
    (e) Test method--(1) Principle. (i) Suspensions of bacterial cells 
are exposed to the test substance in the presence and in the absence of 
an exogenous metabolic activation system. In the plate incorporation 
method, these suspensions are mixed with an overlay agar and plated 
immediately onto minimal medium. In the preincubation method, the 
treatment mixture is incubated and then mixed with an overlay agar 
before plating onto minimal medium. For both techniques, after 2 or 3 
days of incubation, revertant colonies are counted and compared to the 
number of spontaneous revertant colonies on solvent control plates.
    (ii) Several procedures for performing the bacterial reverse 
mutation test have been described. Among those commonly used are the 
plate incorporation method, the preincubation method, the fluctuation 
method, and the suspension method. Suggestions for modifications for the 
testing of gases or vapors are described in the reference in paragraph 
(g)(12) of this section.
    (iii) The procedures described in this section pertain primarily to 
the plate incorporation and preincubation methods. Either of them is 
acceptable for conducting experiments both with and without metabolic 
activation. Some compounds may be detected more efficiently using the 
preincubation method. These compounds belong to chemical classes that 
include short chain aliphatic nitrosamines, divalent metals, aldehydes, 
azo-dyes and diazo compounds, pyrollizidine alkaloids, allyl compounds 
and nitro compounds. It is also recognized that certain classes of 
mutagens are not always detected using standard procedures such as the 
plate incorporation method or preincubation method. These should be 
regarded as ``special cases'' and it is strongly recommended that 
alternative procedures should be used for their detection. The following 
``special cases'' could be identified (together with examples of 
procedures that could be used for their detection): azo-dyes and diazo 
compounds (alterative procedures are described in the references in 
paragraphs (g)(3), (g)(5), (g)(6), and (g)(13) of this section), gases 
and volatile chemicals (alterative procedures are described in the 
references in paragraphs (g)(12), (g)(14), (g)(15), and (g)(16) of this 
section), and glycosides (alterative procedures are described in the 
references in paragraphs (g)(17) and (g)(18) of this section). A 
deviation from the standard procedure needs to be scientifically 
justified.
    (2) Description--(i) Preparations--(A) Bacteria. (1) Fresh cultures 
of bacteria should be grown up to the late exponential or early 
stationary phase of growth (approximately 10⁹ cells per ml). 
Cultures in late stationary phase should not be used. The cultures used 
in the experiment shall contain a high titre of viable bacteria. The 
titre may be demonstrated either from historical control data on growth 
curves, or in each assay through the determination of viable cell 
numbers by a plating experiment.
    (2) The culture temperature shall be 37 [deg]C.
    (3) At least five strains of bacteria should be used. These should 
include four strains of S. typhimurium (TA1535; TA1537 or TA97a or TA97; 
TA98; and

[[Page 410]]

TA100) that have been shown to be reliable and reproducibly responsive 
between laboratories. These four S. typhimurium strains have GC base 
pairs at the primary reversion site and it is known that they may not 
detect certain oxidizing mutagens, cross-linking agents, and hydrazines. 
Such substances may be detected by E. coli WP2 strains or S. typhimurium 
TA102 (see reference in paragraph (g)(19) of this section) which have an 
AT base pair at the primary reversion site. Therefore the recommended 
combination of strains is:
    (i) S. typhimurium TA1535.
    (ii) S. typhimurium TA1537 or TA97 or TA97a.
    (iii) S. typhimurium TA98.
    (iv) S. typhimurium TA100.
    (v) E. coli WP2 uvrA, or E. coli WP2 uvrA (pKM101), or S. 
typhimurium TA102. In order to detect cross-linking mutagens it may be 
preferable to include TA102 or to add a DNA repair-proficient strain of 
E.coli [e.g. E.coli WP2 or E.coli WP2 (pKM101).]
    (4) Established procedures for stock culture preparation, marker 
verification and storage should be used. The amino-acid requirement for 
growth should be demonstrated for each frozen stock culture preparation 
(histidine for S. typhimurium strains, and tryptophan for E. coli 
strains). Other phenotypic characteristics should be similarly checked, 
namely: the presence or absence of R-factor plasmids where appropriate 
[i.e. ampicillin resistance in strains TA98, TA100 and TA97a or TA97, 
WP2 uvrA and WP2 uvrA (pKM101), and ampicillin = tetracycline resistance 
in strain TA102]; the presence of characteristic mutations (i.e. rfa 
mutation in S. typhimurium through sensitivity to crystal violet, and 
uvrA mutation in E. coli or uvrB mutation in S. typhimurium, through 
sensitivity to ultra-violet light). The strains should also yield 
spontaneous revertant colony plate counts within the frequency ranges 
expected from the laboratory's historical control data and preferably 
within the range reported in the literature.
    (B) Medium. An appropriate minimal agar (e.g. containing Vogel-
Bonner minimal medium E and glucose) and an overlay agar containing 
histidine and biotin or tryptophan, to allow for a few cell divisions, 
shall be used. The procedures described in the references under 
paragraphs (g)(1), (g)(2), and (g)(9) of this section may be used for 
this analysis.
    (C) Metabolic activation. Bacteria shall be exposed to the test 
substance both in the presence and absence of an appropriate metabolic 
activation system. The most commonly used system is a cofactor-
supplemented post-mitochondrial fraction (S9) prepared from the livers 
of rodents treated with enzyme-inducing agents such as Aroclor 1254 (the 
system described in the references under paragraphs (g)(1) and (g)(2) of 
this section may be used) or a combination of phenobarbitone and [beta]-
naphthoflavone (the system described in the references under paragraphs 
(g)(18), (g)(20), and (g)(21) of this section may be used). The post-
mitochondrial fraction is usually used at concentrations in the range 
from 5 to 30% v/v in the S9-mix. The choice and condition of a metabolic 
activation system may depend upon the class of chemical being tested. In 
some cases it may be appropriate to utilize more than one concentration 
of post-mitochondrial fraction. For azo-dyes and diazo-compounds, using 
a reductive metabolic activation system may be more appropriate (the 
system described in the references under paragraphs (g)(6) and (g)(13) 
of this section may be used).
    (D) Test substance/preparation. Solid test substances should be 
dissolved or suspended in appropriate solvents or vehicles and diluted 
if appropriate prior to treatment of the bacteria. Liquid test 
substances may be added directly to the test systems and/or diluted 
prior to treatment. Fresh preparations should be employed unless 
stability data demonstrate the acceptability of storage.
    (ii) Test conditions--(A) Solvent/vehicle. The solvent/vehicle 
should not be suspected of chemical reaction with the test substance and 
shall be compatible with the survival of the bacteria and the S9 
activity (for further information see the reference in paragraph (g)(22) 
of this section). If other than well-known

[[Page 411]]

solvent/vehicles are used, their inclusion should be supported by data 
indicating their compatibility. It is recommended that wherever 
possible, the use of an aqueous solvent/vehicle be considered first. 
When testing water-unstable substances, the organic solvents used be 
free of water.
    (B) Exposure concentrations. (1) Amongst the criteria to be taken 
into consideration when determining the highest amount of test substance 
to be used are cytotoxicity and solubility in the final treatment 
mixture. It may be useful to determine toxicity and insolubility in a 
preliminary experiment. Cytotoxicity may be detected by a reduction in 
the number of revertant colonies, a clearing or diminution of the 
background lawn, or the degree of survival of treated cultures. The 
cytotoxicity of a substance may be altered in the presence of metabolic 
activation systems. Insolubility should be assessed as precipitation in 
the final mixture under the actual test conditions and evident to the 
unaided eye. The recommended maximum test concentration for soluble non-
cytotoxic substances is 5 mg/plate or 5 [mu]l/plate. For non-cytotoxic 
substances that are not soluble at 5mg/plate or 5[mu]l/plate, one or 
more concentrations tested should be insoluble in the final treatment 
mixture. Test substances that are cytotoxic already below 5mg/plate or 
5[mu]l/plate should be tested up to a cytotoxic concentration. The 
precipitate should not interfere with the scoring.
    (2) At least five different analyzable concentrations of the test 
substance shall be used with approximately half log (i.e. [radic]10) 
intervals between test points for an initial experiment. Smaller 
intervals may be appropriate when a concentration-response is being 
investigated.
    (3) Testing above the concentration of 5 mg/plate or 5[mu]l/plate 
may be considered when evaluating substances containing substantial 
amounts of potentially mutagenic impurities.
    (C) Controls. (1) Concurrent strain-specific positive and negative 
(solvent or vehicle) controls, both with and without metabolic 
activation, shall be included in each assay. Positive control 
concentrations that demonstrate the effective performance of each assay 
should be selected.
    (2)(i) For assays employing a metabolic activation system, the 
positive control reference substance(s) should be selected on the basis 
of the type of bacteria strains used. The following chemicals are 
examples of suitable positive controls for assays with metabolic 
activation:

------------------------------------------------------------------------
                 Chemical                              CAS No.
------------------------------------------------------------------------
9,10-Dimethylanthracene...................  [CAS no. 781-43-1]
7,12-Dimethylbenzanthracene...............  [CAS no. 57-97-6]
Congo Red (for the reductive metabolic      [CAS no. 573-58-0]
 activation method).
Benzo(a)pyrene............................  [CAS no. 50-32-8]
Cyclophosphamide (monohydrate)............  [CAS no. 50-18-0]
                                            [CAS no. 6055-19-2]
2-Aminoanthracene.........................  [CAS no. 613-13-8]
------------------------------------------------------------------------

    (ii) 2-Aminoanthracene should not be used as the sole indicator of 
the efficacy of the S9-mix. If 2-aminoanthracene is used, each batch of 
S9 should also be characterized with a mutagen that requires metabolic 
activation by microsomal enzymes, e.g., benzo(a)pyrene, 
dimethylbenzanthracene.
    (3) For assays performed without metabolic activation system, 
examples of strain-specific positive controls are:

------------------------------------------------------------------------
            Chemical                    CAS No.             Strain
------------------------------------------------------------------------
(a) Sodium azide................  [CAS no. 26628-22-  TA1535 and TA100
                                   8].
(b) 2-Nitrofluorene.............  [CAS no. 607-57-8]  TA 98
(c) 9-Aminoacridine or ICR 191..  [CAS no. 90-45-9]   TA1537, TA97 and
                                   or.                 TA97a
                                  [CAS no. 17070-45-
                                   0].
(d) Cumene hydroperoxide........  [CAS no. 80-15-9].  TA102
(e) Mitomycin C.................  [CAS no. 50-07-7].  WP2 uvrA and TA102
(f) N-Ethyl-N-nitro-N-            [CAS no. 70-25-7]   WP2, WP2 uvrA and
 nitrosoguanidine or               or.                 WP2 uvrA (pKM101)
4-nitroquinoline 1-oxide........  [CAS no. 56-57-5].
(g) Furylfuramide (AF-2)........  [CAS no. 3688-53-   Plasmid-containing
                                   7].                 strains
------------------------------------------------------------------------


[[Page 412]]

    (4) Other appropriate positive control reference substances may be 
used. The use of chemical class-related positive control chemicals may 
be considered, when available.
    (5) Negative controls, consisting of solvent or vehicle alone, 
without test substance, and otherwise treated in the same way as the 
treatment groups, shall be included. In addition, untreated controls 
should also be used unless there are historical control data 
demonstrating that no deleterious or mutagenic effects are induced by 
the chosen solvent.
    (3) Procedure--(i) Treatment with test substance. (A) For the plate 
incorporation method, without metabolic activation, usually 0.05 ml or 
0.1 ml of the test solutions, 0.1 ml of fresh bacterial culture 
(containing approximately 10⁸ viable cells) and 0.5 ml of 
sterile buffer are mixed with 2.0 ml of overlay agar. For the assay with 
metabolic activation, usually 0.5 ml of metabolic activation mixture 
containing an adequate amount of post-mitochondrial fraction (in the 
range from 5 to 30% v/v in the metabolic activation mixture) are mixed 
with the overlay agar (2.0 ml), together with the bacteria and test 
substance/test solution. The contents of each tube are mixed and poured 
over the surface of a minimal agar plate. The overlay agar is allowed to 
solidify before incubation.
    (B) For the preincubation method the test substance/test solution is 
preincubated with the test strain (containing approximately 
10⁸ viable cells) and sterile buffer or the metabolic 
activation system (0.5 ml) usually for 20 min. or more at 30-37 [deg]C 
prior to mixing with the overlay agar and pouring onto the surface of a 
minimal agar plate. Usually, 0.05 or 0.1 ml of test substance/test 
solution, 0.1 ml of bacteria, and 0.5 ml of S9-mix or sterile buffer, 
are mixed with 2.0 ml of overlay agar. Tubes should be aerated during 
pre-incubation by using a shaker.
    (C) For an adequate estimate of variation, triplicate plating should 
be used at each dose level. The use of duplicate plating is acceptable 
when scientifically justified. The occasional loss of a plate does not 
necessarily invalidate the assay.
    (D) Gaseous or volatile substances should be tested by appropriate 
methods, such as in sealed vessels (methods described in the references 
under paragraphs (g)(12), (g)(14), (g)(15), and (g)(16) of this section 
may be used).
    (ii) Incubation. All plates in a given assay shall be incubated at 
37 [deg]C for 48-72 hrs. After the incubation period, the number of 
revertant colonies per plate is counted.
    (f) Data and reporting--(1) Treatment of results. (i) Data shall be 
presented as the number of revertant colonies per plate. The number of 
revertant colonies on both negative (solvent control, and untreated 
control if used) and positive control plates shall also be given.
    (ii) Individual plate counts, the mean number of revertant colonies 
per plate and the standard deviation shall be presented for the test 
substance and positive and negative (untreated and/or solvent) controls.
    (iii) There is no requirement for verification of a clear positive 
response. Equivocal results shall be clarified by further testing 
preferably using a modification of experimental conditions. Negative 
results need to be confirmed on a case-by-case basis. In those cases 
where confirmation of negative results is not considered necessary, 
justification should be provided. Modification of study parameters to 
extend the range of conditions assessed should be considered in follow-
up experiments. Study parameters that might be modified include the 
concentration spacing, the method of treatment (plate incorporation or 
liquid preincubation), and metabolic activation conditions.
    (2) Evaluation and interpretation of results. (i) There are several 
criteria for determining a positive result, such as a concentration-
related increase over the range tested and/or a reproducible increase at 
one or more concentrations in the number of revertant colonies per plate 
in at least one strain with or without metabolic activation system. 
Biological relevance of the results should be considered first. 
Statistical methods may be used as an aid in evaluating the test 
results. However, statistical significance should not be the only 
determining factor for a positive response.

[[Page 413]]

    (ii) A test substance for which the results do not meet the criteria 
described under paragraph (f)(2)(i) of this section is considered non-
mutagenic in this test
    (iii) Although most experiments will give clearly positive or 
negative results, in rare cases the data set will preclude making a 
definite judgement about the activity of the test substance. Results may 
remain equivocal or questionable regardless of the number of times the 
experiment is repeated.
    (iv) Positive results from the bacterial reverse mutation test 
indicate that a substance induces point mutations by base substitutions 
or frameshifts in the genome of either Salmonella typhimurium and/or 
Escherichia coli. Negative results indicate that under the test 
conditions, the test substance is not mutagenic in the tested species.
    (3) Test report. The test report shall include the following 
information:
    (i) Test substance:
    (A) Identification data and CAS no., if known.
    (B) Physical nature and purity.
    (C) Physicochemical properties relevant to the conduct of the study.
    (D) Stability of the test substance, if known.
    (ii) Solvent/vehicle:
    (A) Justification for choice of solvent/vehicle.
    (B) Solubility and stability of the test substance in solvent/
vehicle, if known.
    (iii) Strains:
    (A) Strains used.
    (B) Number of cells per culture.
    (C) Strain characteristics.
    (iv) Test conditions:
    (A) Amount of test substance per plate (mg/plate or ml/plate) with 
rationale for selection of dose and number of plates per concentration.
    (B) Media used.
    (C) Type and composition of metabolic activation system, including 
acceptability criteria.
    (D) Treatment procedures.
    (v) Results:
    (A) Signs of toxicity.
    (B) Signs of precipitation.
    (C) Individual plate counts.
    (D) The mean number of revertant colonies per plate and standard 
deviation.
    (E) Dose-response relationship, where possible.
    (F) Statistical analyses, if any.
    (G) Concurrent negative (solvent/vehicle) and positive control data, 
with ranges, means and standard deviations.
    (H) Historical negative (solvent/vehicle) and positive control data, 
with e.g. ranges, means and standard deviations.
    (vi) Discussion of the results.
    (vii) Conclusion.
    (g) References. For additional background information on this test 
guideline, the following references should be consulted. These 
references are available for inspection at the TSCA Nonconfidential 
Information Center, Rm. NE-B607, Environmental Protection Agency, 401 M 
St., SW., Washington, DC, 12 noon to 4 p.m., Monday through Friday, 
except legal holidays.
    (1) Ames, B.N., McCann, J., and Yamasaki, E. Methods for Detecting 
Carcinogens and Mutagens With the Salmonella/Mammalian-Microsome 
Mutagenicity Test. Mutation Research. 31, 347-364 (1975).
    (2) Maron, D.M. and Ames, B.N. Revised Methods for the Salmonella 
Mutagenicity Test. Mutation Research. 113, 173-215 (1983).
    (3) Gatehouse, D., Haworth, S., Cebula, T., Gocke, E., Kier, L., 
Matsushima, T., Melcion, C., Nohmi, T., Venitt, S., and Zeiger, E. 
Recommendations for the Performance of Bacterial Mutation Assays. 
Mutation Research. 312, 217-233 (1994).
    (4) Kier, L.D., Brusick, D.J., Auletta, A.E., Von Halle, E.S., 
Brown, M.M., Simmon, V.F., Dunkel, V., McCann, J., Mortelmans, K., 
Prival, M., Rao, T.K., and Ray V. The Salmonella Typhimurium/Mammalian 
Microsomal Assay: A Report of the U.S. Environmental Protection Agency 
Gene-Tox Program. Mutation Research. 168, 69-240 (1986).
    (5) Yahagi, T., Degawa, M., Seino, Y.Y., Matsushima, T., Nagao, M., 
Sugimura, T., and Hashimoto, Y. Mutagenicity of Carcinogen Azo Dyes and 
Their Derivatives. Cancer Letters, 1. 91-96 (1975).
    (6) Matsushima, M., Sugimura, T., Nagao, M., Yahagi, T., Shirai, A., 
and

[[Page 414]]

Sawamura, M. Factors Modulating Mutagenicity Microbial Tests. Eds. 
Norpoth, K.H. and Garner, R.C. Short-Term Test Systems for Detecting 
Carcinogens (Springer, Berlin-Heidelberg-New York, 1980) pp. 273-285.
    (7) Gatehouse, D.G., Rowland, I.R., Wilcox, P., Callender, R.D., and 
Foster, R. Bacterial Mutation Assays. Ed. Kirkland, D.J. Basic 
Mutagenicity Tests. UKEMS Part 1 Revised (Cambridge University Press, 
1990) pp. 13-61.
    (8) Aeschbacher, H.U., Wolleb, U., and Porchet, L.J. Liquid 
Preincubation Mutagenicity Test for Foods. Food Safety. 8, 167-177 
(1987).
    (9) Green, M.H.L., Muriel, W.J., and Bridges, B.A. Use of a 
Simplified Fluctuation Test to Detect Low Levels of Mutagens. Mutation 
Research. 38, 33-42 (1976).
    (10) Hubbard, S.A., Green, M.H.L., Gatehouse, D., and J.W. Bridges. 
The Fluctuation Test in Bacteria. 2nd Edition. Ed. Kilbey, B.J., 
Legator, M., Nichols, W., and Ramel C. Handbook of Mutagenicity Test 
Procedures (Elsevier, Amsterdam-New York-Oxford, 1984) pp. 141-161.
    (11) Thompson, E.D. and Melampy, P.J. An Examination of the 
Quantitative Suspension Assay for Mutagenesis With Strains of Salmonella 
Typhimurium. Environmental Mutagenesis. 3, 453-465 (1981).
    (12) Araki, A., Noguchi, T., Kato, F., and T. Matsushima. Improved 
Method for Mutagenicity Testing of Gaseous Compounds by Using a Gas 
Sampling Bag. Mutation Research. 307, 335-344 (1994).
    (13) Prival, M.J., Bell, S.J., Mitchell, V.D., Reipert, M.D., and 
Vaughn, V.L. Mutagenicity of Benzidine and Benzidine-Congener Dyes and 
Selected Monoazo Dyes in a Modified Salmonella Assay. Mutation Research. 
136, 33-47 (1984).
    (14) Zeiger, E., Anderson, B. E., Haworth, S, Lawlor, T., and 
Mortelmans, K. Salmonella Mutagenicity Tests. V. Results from the 
Testing of 311 Chemicals. Environ. Mol. Mutagen. 19, 2-141 (1992).
    (15) Simmon, V., Kauhanen, K., and Tardiff, R.G. Mutagenic Activity 
of Chemicals Identified in Drinking Water. Ed. Scott, D., Bridges, B., 
and Sobels, F. Progress in Genetic Toxicology (Elsevier, Amsterdam, 
1977) pp. 249-258.
    (16) Hughes, T.J., Simmons, D.M., Monteith, I.G., and Claxton, L.D. 
Vaporization Technique to Measure Mutagenic Activity of Volatile Organic 
Chemicals in the Ames/Salmonella Assay. Environmental Mutagenesis. 9, 
421-441 (1987).
    (17) Matsushima, T., Matsumoto, A., Shirai, M., Sawamura, M., and 
Sugimura, T. Mutagenicity of the Naturally Occurring Carcinogen Cycasin 
and Synthetic Methylazoxy Methane Conjugates in Salmonella Typhimurium. 
Cancer Research. 39, 3780-3782 (1979).
    (18) Tamura, G., Gold, C., Ferro-Luzzi, A., and Ames. B.N. Fecalase: 
A Model for Activation of Dietary Glycosides to Mutagens by Intestinal 
Flora. Proc. National Academy of Science. (USA, 1980) 77, 4961-4965.
    (19) Wilcox, P., Naidoo, A., Wedd, D. J., and Gatehouse, D. G. 
Comparison of Salmonella Typhimurium TA 102 With Escherichia Coli WP2 
Tester Strains. Mutagenesis. 5, 285-291 (1990).
    (20) Matsushima, T., Sawamura, M., Hara, K., and Sugimura, T. A Safe 
Substitute for Polychlorinated Biphenyls as an Inducer of Metabolic 
Activation Systems. Ed. F.J. de Serres et al. In Vitro Metabolic 
Activation in Mutagenesis Testing. (Elsevier, North Holland, 1976) pp. 
85-88.
    (21) Elliott, B.M., Combes, R.D., Elcombe, C.R., Gatehouse, D.G., 
Gibson, G.G., Mackay, J.M., and Wolf, R.C. Alternatives to Aroclor 1254-
Induced S9 in In Vitro Genotoxicity Assays. Mutagenesis. 7, 175-177 
(1992).
    (22) Maron, D., Katzenellenbogen, J., and Ames, B.N. Compatibility 
of Organic Solvents With the Salmonella/Microsome Test. Mutation 
Research. 88, 343-350 (1981).
    (23) Claxton, L.D., Allen, J., Auletta, A., Mortelmans, K., 
Nestmann, E., and Zeiger, E. Guide for the Salmonella Typhimurium/
Mammalian Microsome Tests for Bacterial Mutagenicity. Mutation Research. 
189, 83-91 (1987).
    (24) Mahon, G.A.T., Green, M.H.L., Middleton, B., Mitchell, I., 
Robinson, W.D., and Tweats, D.J. Analysis of Data from Microbial Colony 
Assays. UKEMS Sub-Committee on Guidelines for Mutagenicity Testing Part 
II. Ed.

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Kirkland, D.J. Statistical Evaluation of Mutagenicity Test Data 
(Cambridge University Press, 1989) pp. 28-65.

[62 FR 43824, Aug. 15, 1997, as amended at 64 FR 35079, June 30, 1999]