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§797.1600 Fish early life stage toxicity test.
(a) Purpose. This guideline is intended to be used for assessing the propensity of chemical substances to produce adverse effects to fish during the early stages of their growth and development. This guideline describes the conditions and procedures for the continuous exposure of several representative species to a chemical substance during egg, fry and early juvenile life stages. The Environmental Protection Agency (EPA) will use data from this test in assessing the potential hazard of the test substance to the aquatic environment.
(b) Definitions. The definitions in section 3 of the Toxic Substances Control Act (TSCA) and the definitions in part 792 -- Good Laboratory Practice Standards, apply to this section. In addition, the following definitions are applicable to this specific test guideline:
(1) "Acclimation" physiological or behavioral adaptation of organisms to one or more environmental conditions associated with the test method (e.g., temperature, hardness, pH).
(2) "Carrier" solvent or other agent used to dissolve or improve the solubility of the test substance in dilution water.
(3) "Conditioning" exposure of construction materials, test chambers, and testing apparatus to dilution water or to the test solution prior to the start of the test in order to minimize the sorption of test substance onto the test facilities or the leachig of substances from test facilities into the dilution water or the test solution.
(4) "Control" an exposure of test organisms to dilution water only or dilution water containing the test solvent or carrier (no toxic agent is intentionally or inadvertently added).
(5) "Dilution water" the water used to produce the flow-through conditions of the test to which the test substance is added and to which the test species is exposed.
(6) "Early life stage toxicity test" a test to determine the minimum concentration of a substance which produces a statistically significant observable effect on hatching, survival, development and/or growth of a fish species continuously exposed during the period of their early development.
(7) "Embryo cup" a small glass jar or similar container with a screened bottom in which the embryos of some species (i.e., minnow) are placed during the incubation period and which is normally oscillated to ensure a flow of water through the cup.
(8) "Flow through" refers to the continuous or very frequent passage of fresh test solution through a test chamber with no recycling.
(9) "Hardness" the total concentration of the calcium and magnesium ions in
water expressed as calcium carbonate (mg CaCO (10) "Loading" the ratio of biomass (grams of fish, wet weight) to the volume
(liters) of test solution passing through the test chamber during a specific
interval (normally a 24-hr. period).
(11) "No observed effect concentration (NOEC)" the highest tested
concentration in an acceptable early life stage test: (i) which did not cause
the occurrence of any specified adverse effect (statistically different from the
control at the 95 percent level); and (ii) below which no tested concentration
caused such an occurrence.
(12) "Observed effect concentration (OEC)" the lowest tested concentration in
an acceptable early life stage test: (i) Which caused the occurrence of any
specified adverse effect (statistically different from the control at the 95
percent level); and (ii) above which all tested concentrations caused such an
occurrence.
(13) "Replicate" two or more duplicate tests, samples, organisms,
concentrations, or exposure chambers.
(14) "Stock solution" the source of the test solution prepared by dissolving
the test substance in dilution water or a carrier which is then added to
dilution water at a specified, selected concentration by means of the test
substance delivery system.
(15) "Test chamber" the individual containers in which test organisms are
maintained during exposure to test solution.
(16) "Test solution" dilution water with a test substance dissolved or
suspended in it.
(17) "Test substance" the specific form of a chemical substance or mixture
that is used to develop data.
(c) Test Procedures -- (1) Summary of test. (i) The early life
stage toxicity test with fish involves exposure of newly fertilized embryos to
various concentrations of a test substance. Exposure continues for 28 days post
hatch for the minnows and 60 days post hatch for the trout species. During this
time various observations and measurements are made in a specific manner and
schedule in order to determine the lowest effect and highest no-effect
concentrations of the test substance.
(ii) A minimum of five exposure (treatment) concentrations of a test
substance and one control are required to conduct an early life stage toxicity
test. The concentration of the test substance in each treatment is usually 50
percent of that in the next higher treatment level.
(iii) For each exposure concentration of the test substance and for each
control (i.e., regular control and carrier control is required) there shall be:
(A) At least two replicate test chambers, each containing one or more embryo
incubation trays or cups; and there shall be no water connections between the
replicate test chambers;
(B) At least 60 embryos divided equally in such a manner that test results
show no significant bias from the distributions, between the embryo incubation
trays or cups for each test concentration and control (i.e., 30 per embryo cup
with 2 replicates);
(C) All surviving larvae divided equally between the test chambers for each
test concentration and control (e.g., 30 larvae per test chamber with 2
replicates).
(iv) Duration. (A) For fathead minnow and sheepshead minnow a test
begins when the newly fertilized minnow embryos (less than 48-hours old) are
placed in the embryo cups and are exposed to the test solution concentrations.
The test terminates following 28 days of post-hatch exposure, i.e., 28 days
after the newly hatched fry are transferred from the embryo cups into the test
chambers.
(B) For brook trout and rainbow trout a test begins when newly fertilized
trout embryos (less than 96-hours old) are placed in the embryo trays or cups
and are exposed to the test solution concentrations. The test terminates
following 60 days of post-hatch exposure (for an approximate total exposure
period of 90 days).
(C) For silverside a test begins with newly fertilized embryos (less than or
equal to 48 hours old) and is terminated 28 days after hatching. The chorionic
fibrils should be cut before randomly placing the embryos in the egg incubation
cups.
(2) [Reserved]
(3) Range-finding test. (i) A range finding test is normally performed
with the test substance to determine the test concentrations to be used in the
early life stage toxicity test, especially when the toxicity is unknown. It is
recommended that the test substance concentrations be selected based on
information gained from a 4- to 10-day flow-through toxicity test with juveniles
of the selected test species.
(ii) The highest concentration selected for the early life stage toxicity
test should approximate the lowest concentration indicated in any previous
testing to cause a significant reduction in survival. The range of
concentrations selected is expected to include both observed effect and
no-observed effect levels. The dilution factor between concentrations is
normally 0.50, however, other dilution factors may be used as necessary.
(4) Definitive test -- (i) General. (A) A test shall not be
initiated until after the test conditions have been met and the test substance
delivery system has been observed functioning properly for 48-hours. This
includes temperature stability, flow requirements of dilution water, lighting
requirements, and the function of strainers and air traps included in the
water-supply system, and other conditions as specified previously.
(B) New holding and test facilities should be tested with sensitive organisms
(i.e., juvenile test species or daphnids) before use to assure that the
facilities or substances possibly leaching from the equipment will not adversely
affect the test organisms during an actual test.
(C) Embryos should be acclimated for as long as practical to the test
temperature and dilution water prior to the initiation of the test.
(D) When embryos are received from an outside culture source (i.e., rainbow
and brook trout) at a temperature at variance with the recommended test
temperature they shall be acclimated to the test temperature. When eggs are
received, they should be immediately unpacked and the temperature of the
surrounding water determined. Sudden temperature changes should be avoided.
Acclimation to the appropriate test temperature should be accomplished within a
period of 6 hours, and should incorporate the use of dilution water.
(E) Embryos should be visually inspected prior to placement in the embryo
cups or screen trays. All dead embryos shall be discarded. Dead embryos can be
discerned by a change in coloration from that of living embryos (e.g., trout
embryos turn white when dead). During visual inspection, empty shells, opaque
embryos, and embryos with fungus or partial shells attached shall be removed and
discarded. If less than 50 percent of the eggs to be used appear to be healthy,
all embryos in such a lot shall be discarded.
(ii) Embryo incubation procedures. (A) Embryos can be distributed to
the embryo cups or screen trays using a pipette with a large bore or a similar
apparatus. Newly-hatched silverside fry are very sensitive to handling; the egg
incubation cups should not be handled at all the first 5 days after hatching
begins. Just before hatching is expected to begin, the embryos should be
transferred to clean incubation cups. Trout embryos can be distributed by using
a small container which has been precalibrated to determine the approximate
number of embryos it can hold; embryos are measured volumetrically in this
manner, and are then poured onto the screen tray (or embryo cup). Trout embryos
should be separated on the screen tray so that they are not in contact with each
other. A final count will ensure the actual number on the screen tray. After
random assignment, the screen trays or embryo cups are placed in the test
chambers.
(B) Each day until hatch the embryos are visually examined. Minnow embryos
may be examined with the aid of a magnifying viewer. Trout embryos should not be
touched. Trout embryos should be maintained in low intensity light or in
darkness until 1-week post hatch, and are usually examined with the aid of a
flashlight or under low intensity light. Dead embryos should be removed and
discarded. Any embryos which are heavily infected with fungus shall be discarded
and shall be subtracted from the initial number of embryos used as a basis for
the calculations of percentage hatch.
(C) When embryos begin to hatch they should not be handled.
(iii) Initiation of fry exposure. (A) Forty-eight hours after the
first hatch in each treatment level, or when hatching is completed, the live
young fish shall be counted and transferred from each embryo cup into the
appropriate test chamber. For silverside, all surviving fry are not counted
until six days after hatching and are not transferred to embryo cups. All of the
normal and abnormal fry shall be gently released into the test chamber by
allowing the fry to swim out of each embryo cup; nets shall not be used. The
trout embryos incubated on screen trays will hatch out in the test chambers,
therefore handling of fish is not necessary.
(B) If necessary, fry can be transferred from one replicate embryo cup to the
other replicate within a test concentration to achieve equal numbers in each
replicate chamber.
(C) The number of live fry, live normal fry, live embryos, dead embryos and
unaccounted for embryos for each cup shall be recorded when hatching is deemed
complete. Those fry which are visibly (without the use of a dissecting scope or
magnifying viewer) lethargic or grossly abnormal (either in swimming behavior or
physical appearance) shall be counted. Late hatching embryos shall be left in
the embryo cups to determine if they will eventually hatch or not. The range of
time-to-hatch (to the nearest day) for each cup shall be recorded.
(iv) Time to first feeding. (A) The first feeding for the fathead and
sheepshead minnow fry shall begin shortly after transfer of the fry from the
embryo cups to the test chambers. Silversides are fed the first day after hatch.
Trout species initiate feeding at swim-up. The trout fry shall be fed trout
starter mash three times a day ad libitum, with excess food siphoned off
daily. The minnow fry shall be fed live newly-hatched brine shrimp nauplii
(Artemia salina) at least three times a day.
(B) For the first seven days, feeding shall be done at minimum intervals of
four hours (i.e., 8 am, 12 noon, and 4 pm); thereafter the fry shall be fed as
indicated below.
(v) Feeding. (A) The fathead and sheepshead minnow fry shall be fed
newly hatched brine shrimp nauplii for the duration of the test at approximately
4-hour intervals three times a day during the week and twice on the weekend
after the first week. Trout fry shall be fed at similar intervals and may
receive live brine shrimp nauplii in addition to the trout starter food after
the first week. Between days 1 and 8 after first hatching, silverside fry are
fed the rotifer, Brachionus plicatilis, three times daily at a
concentration of 5,000 to 10,000 organisms per egg cup (based on 15 fish/cup).
From days 9 to 11, the fry shall be fed approximately 2,500 newly hatched brine
shrimp (Artemia) nauplii and 5,000 to 10,000 rotifers twice daily. For
the remainder of the test, the fish will be fed brine shrimp exclusively. The
number of organisms used should be gradually increased to approximately 5,000
nauplii by test day 28.
(B) An identical amount of food should be provided to each chamber. Fish
should be fed ad libitum for 30 minutes with excess food siphoned off the
bottom once daily if necessary.
(C) Fish should not be fed for the last 24 hours prior to termination of the
test.
(vi) Carriers. Water should be used in making up the test stock
solutions. If carriers other than water are absolutely necessary, the amount
used should be the minimum necessary to achieve solution of the test substance.
Triethylene glycol and dimethyl formamide are preferred, but ethanol and acetone
can be used if necessary. Carrier concentrations selected should be kept
constant at all treatment levels.
(vii) Controls. Every test requires a control that consists of the
same dilution water, conditions, procedures, and test organisms from the same
group used in the other test chambers, except that none of the test substance is
added. If a carrier (solvent) is used, a separate carrier control is required in
addition to the regular control. The carrier control shall be identical to the
regular control except that the highest amount of carrier present in any
treatment is added to this control. If the test substance is a mixture,
formulation, or commercial product, none of the ingredients is considered a
carrier unless an extra amount is used to prepare the stock solution.
(viii) Randomization. The location of all test chambers within the
test system shall be randomized. A representative sample of the test embryos
should be impartially distributed by adding to each cup or screen tray no more
than 20 percent of the number of embryos to be placed in each cup or screen tray
and repeating the process until each cup or screen tray contains the specified
number of embryos. Alternatively, the embryos can be assigned by random
assignment of a small group (e.g., 1 to 5) of embryos to each embryo cup or
screen tray, followed by random assignment of a second group of equal number to
each cup or tray, which is continued until the appropriate number of embryos are
contained in each embryo cup or screen tray. The method of randomization used
shall be reported.
(ix) Observations. During the embryo exposure period observations
shall be made to check for mortality. During the exposure period of the fry,
observations shall be made to check for mortality and to note the physical
appearance and behavior of the young fish. The biological responses are used in
combination with physical and chemical data in evaluating the overall lethal and
sublethal effects of the test substance. Additional information on the specific
methodology for the data obtained during the test procedure are discussed in the
following sections.
(x) Biological data. (A) Death of embryos shall be recorded daily.
(B) When hatching commences, daily records of the number of embryos remaining
in each embryo cup are required. This information is necessary to quantify the
hatching success. A record of all deformed larvae shall be kept throughout the
entire post-hatch exposure. Time to swim-up shall be recorded for the trout.
Upon transfer of fry from the embryo cups to the test chambers, daily counts of
the number of live fish should be made. At a minimum, live fish shall be counted
on days 4, 11, 18, 25 and (weekly thereafter for the trout species) finally on
termination of the test.
(C) The criteria for death of young fish is usually immobility, especially
absence of respiratory movement, and lack of reaction to gentle prodding. Deaths
should be recorded daily and dead fish removed when discovered.
(D) Daily and at termination of the test, the number of fish that appear
(without the use of a magnifying viewer) to be abnormal in behavior (e.g.,
swimming erratic or uncoordinated, obviously lethargic, hyperventilating, or
over excited, etc.) or in physical appearance (e.g., hemorrhaging, producing
excessive mucous, or are discolored, deformed, etc.) shall be recorded and
reported in detail.
(E) All physical abnormalities (e.g., stunted bodies, scoliosis, etc.) shall
be photographed and the deformed fish which die, or are sacrificed at the
termination of the test, shall be preserved for possible future pathological
examination.
(F) At termination, all surviving fish shall be measured for growth. Standard
length measurements should be made directly with a caliper, but may be measured
photographically. Measurements shall be made to the nearest millimeter (0.1 mm
is desirable). Weight measurements shall also be made for each fish alive at
termination (wet, blotted dry, and to the nearest 0.01 g for the minnows and 0.1
g for the trout). If the fish exposed to the toxicant appear to be edematous
compared to control fish, determination of dry, rather than wet, weight is
recommended.
(G) Special physiological, biochemical and histological investigations on
embryos, fry, and juveniles may be deemed appropriate and shall be performed on
a case by case basis.
(5) Test results. (i) Data from toxicity tests are usually either
continuous (e.g. length or weight measurements) or dichotomous (e.g. number
hatching or surviving) in nature. Several methods are available and acceptable
for statistical analysis of data derived from early life stage toxicity tests;
however, the actual statistical methodology to analyze and interpret the test
results shall be reported in detail.
(ii) The significance level for all statistical testing shall be a minimum of
P=0.05 (95 percent confidence level).
(A) Example of statistical analysis. (1) Mortality data for the
embryonic stage, fry stage and for both stages in replicate exposure chambers
should first be analyzed using a two-way analysis of variance (ANOVA) with
interaction model. This analysis will determine if replicates are significantly
different from each other. If a significant difference between replicates or a
significant interaction exists, cause for the difference should be determined.
Modification should then be made in the test apparatus or in handling procedures
for future toxicity tests. Further calculations should incorporate the
separation of replicates. If no significant difference is observed, replicates
may be pooled in further analyses.
(2) After consideration of replicate responses, mortality data should
then be subjected to one-way ANOVA. The purpose of this analysis is to determine
if a significant difference exists in the percentage mortality between control
fish and those exposed to the test material.
(3) If the one-way ANOVA results in a F ratio that is significant, it
would be acceptable to perform t-tests on the control versus each concentration.
A second technique is to identify treatment means that are significantly
different; this method should involve the additional assumption that the true
mean response decreases generally with increasing concentration. The researcher
may also be interested in determining significant differences between
concentrations.
(4) Growth data should also be analyzed by one-way ANOVA with the
inclusion of a covariate to account for possible differences in growth of
surviving fry in embryo cup(s) that contain fewer individuals. This condition
can occur in cases when the same amount of food is given to each test chamber
regardless of the number of survivors.
(B) Test data to be analyzed. Data to be statistically analyzed are:
(1) Percentage of healthy, fertile embryos at 40-48 hours after
initiation of the test. Percentage is based upon initial number used.
(2) Percentage of embryos that produce live fry for release into test
chambers. Percentage is based on number of embryos remaining after thinning.
(3) Percentage of embryos that produce live, normal fry for release
into test chambers. Percentage is based upon number of embryos remaining after
thinning.
(4) Percentage of fry survival at swim-up for trout. Percentage is
based upon number of embryos remaining after thinning.
(5) Percentage of embryos that produce live fish at end of test.
Percentage is based upon number of embryos remaining after thinning.
(6) Percentage of embryos that produce live, normal fish at end of
test. Percentage is based upon number of embryos remaining after thinning.
(7) Weights and lengths of individual fish alive at the end of the
test.
(C) It is important that fish length and weight measurements be associated
with individual test chambers since the density of the fish and available food
should be considered in the growth of the organism.
(iii) Acceptability criteria. (A) An early life stage toxicity test is
not acceptable unless at least one of the following criteria is significantly
different (p=0.05) from control organisms when compared with treated organisms,
and the responses are concentration-dependent: mortality of embryos, hatching
success, mortality of fry (at swim-up for trout), total mortality throughout the
test, and growth (i.e. weight). If no significant effects occur, but the
concentrations tested were the highest possible due to solubility or other
physio-chemical limitations, the data will be considered for acceptance.
(B) In addition to obtaining significant effects on the exposed test species,
a measure of acceptability in the response of control fish is also required.
(C) A test is not acceptable if the average survival of the control fish at
the end of the test is less than 80 percent or if survival in any one control
chamber is less than 70 percent. For silversides, a test is not acceptable if
the average overall survival of the control embryos and fish at the end of the
test is less than 60 percent.
(D) If a carrier is used, the criteria for effect (mortality of embryos and
fry, growth, etc.) used in the comparison of control and exposed test organisms
shall also be applied to the control and control with carrier chambers. For the
test to be considered acceptable, no significant difference shall exist between
these criteria.
(E) A test is not acceptable if the relative standard deviation (RSD=100
times the standard deviation divided by the mean) of the weights of the fish
that were alive at the end of the test in any control test chamber is greater
than 40 percent.
(6) Analytical measurements -- (i) Analysis of water quality.
Measurement of certain dilution water quality parameters shall be performed
every 6 months, to determine the consistency of the dilution water quality. In
addition, if data in 30-day increments are not available to show that freshwater
dilution water is constant, measurements of hardness, alkalinity, pH, acidity,
conductivity, TOC or COD and particulate matter should be conducted once a week
in the highest test substance concentration. Measurement of calcium, magnesium,
sodium, potassium, chloride, and sulfate is desirable.
(ii) Dissolved oxygen measurement. The dissolved oxygen concentration
shall be measured in each test chamber at the beginning of the test and at least
once weekly thereafter (as long as live organisms are present) in two replicates
of the control and the high, medium, and low test substance concentrations.
(iii) Temperature measurement. Temperatures shall be recorded in all
test chambers at the beginning of the test, once weekly thereafter and at least
hourly in one test chamber. When possible, the hourly measurement shall be
alternated between test chambers and between replicates.
(iv) Test substance measurement. (A) Prior to the addition of the test
substance to the dilution water, it is recommended that the test substance stock
solution be analyzed to verify the concentration. After addition of the test
substance, the concentration of test substance should be measured at the
beginning of the test in each test concentration and control(s), and at least
once a week thereafter. Equal aliquots of test solution may be removed from each
replicate chamber and pooled for analysis. If a malfunction in the delivery
system is discovered, water samples shall be taken from the affected test
chambers immediately and analyzed.
(B) The measured concentration of test substance in any chamber should be no
more than 30 percent higher or lower than the concentration calculated from the
composition of the stock solution and the calibration of the test substance
delivery system. If the difference is more than 30 percent, the concentration of
test substance in the solution flowing into the exposure chamber (influent)
should be analyzed. These results will indicate whether the problem is in the
stock solution, the test substance delivery system or in the test chamber.
Measurement of degradation products of the test substance is recommended if a
reduction of the test substance concentration occurs in the test chamber.
(v) Sampling and analysis methodology. (A) Generally, total test
substance measurements are sufficient; however, the chemical characteristics of
the test substance may require both dissolved and suspended test substance
measurements.
(B) For measurement of the test substance, water samples shall be taken
midway between the top, bottom, and sides of the test chamber and should not
include any surface scum or material stirred up from the bottom or sides.
Samples of test solutions shall be handled and stored appropriately to minimize
loss of test substance by microbial degradation, photodegradation, chemical
reaction, volatilization, or sorption.
(C) Chemical and physical analyses shall be performed using standardized
methods whenever possible. The analytical method used to measure the
concentration of the test substance in the test solution shall be validated
before the beginning of the test. At a minimum, a measure of the accuracy of the
method should be obtained on each of two separate days by using the method of
known additions, and using dilution water from a tank containing test organisms.
Three samples should be analyzed at the next-to-lowest test substance
concentration. It is also desirable to study the accuracy and precision of the
analytical method for test guideline determination by use of reference (split)
samples, or interlaboratory studies, and by comparison with alternative,
reference, or corroborative methods of analysis.
(D) An analytical method is not acceptable if likely degradation products of
the test substance, such as hydrolysis and oxidation products, give positive or
negative interferences, unless it is shown that such degradation products are
not present in the test chambers during the test. In general, atomic absorption
spectrophotometric methods for metals and gas chromatographic methods for
organic compounds are preferable to colorimetric methods.
(E) In addition to analyzing samples of test solution, at least one reagent
blank also should be analyzed when a reagent is used in the analysis. Also, at
least one sample for the method of known additions should be prepared by adding
test substance at the concentration used in the toxicity test.
(d) Test conditions -- (1) Test species. (i) One or more of the
recommended test species will be specified in rules under part 799 of this
chapter requiring testing of specific chemicals. The recommended test species
are:
(A) Fathead minnow (Pimephales promelas Rafinesque).
(B) Sheepshead minnow (Cyprinodon variegatus).
(C) Brook trout (Salvelinus fontinalis).
(D) Rainbow trout (Salmo gairdneri).
(E) Atlantic silverside (Menidia menidia).
(F) Tidewater silverside (Menidia peninsulae).
(ii) Embryos used to initiate the early life stage test shall be less than 48
hours old for the fathead and sheepshead minnows, silversides, and less than 96
hours old for the brook trout and rainbow trout. In addition, the following
requirements shall be met:
(A) All embryos used in the test shall be from the same source. Embryos shall
be obtained from a stock cultured in-house when possible, and maintained under
the same parameters as specified for the test conditions. When it is necessary
to obtain embryos from an external source, caution should be exercised to ensure
embryo viability and to minimize the possibility of fungal growth. A description
of the brood stock history or embryo source shall be made available to EPA upon
request.
(B) Test species shall be cared for and handled properly in order to avoid
unnecessary stress. To maintain test species in good condition and to maximize
growth, crowding shall be prevented, and the dissolved oxygen level shall be
maintained near saturation.
(C) Embryos and fish shall be handled as little as possible. Embryos shall be
counted and periodically inspected until hatching begins. When larvae begin to
hatch, they shall not be handled. Transfer of minnow larvae from embryo cups to
test chambers shall not involve the use of nets. No handling is necessary
following introduction into the test chambers until termination of the test.
(D) If fathead minnow embryos are obtained from in-house culture units, the
embryos should be gently removed from the spawning substrate. The method for
separating the fertilized eggs from the substrate is important and can affect
the viability of the embryos; therefore the finger-rolling procedure is
recommended.
(E) Disease treatment. Chemical treatments to cure or prevent diseases should
not be used before, and should not be used during a test. All prior treatments
of brood stock should be reported in detail. Severely diseased organisms should
be destroyed.
(2) Test facilities -- (i) Construction materials. Construction
materials and equipment that contact stock solutions, test solutions, or
dilution water into which test embryos or fish are placed should not contain any
substances that can be leached or dissolved into aqueous solutions in quantities
that can affect test results. Materials and equipment that contact stock or test
solutions should be chosen to minimize sorption of test chemicals from dilution
water. Glass, #316 stainless steel, nylon screen and perfluorocarbon plastic
(e.g., Teflon#) are acceptable materials. Concrete or rigid (unplasticized)
plastic may be used for holding and acclimation tanks, and for water supply
systems, but they should be thoroughly conditioned before use. If cast iron pipe
is used in freshwater supply systems, colloidal iron may leach into the dilution
water and strainers should be used to remove rust particles. Natural rubber,
copper, brass, galvanized metal, epoxy glues, and flexible tubing should not
come in contact with dilution water, stock solutions, or test solutions.
(ii) Test chambers (exposure chambers). (A) Stainless steel test
chambers should be welded or glued with silicone adhesive, and not soldered.
Glass should be fused or bonded using clear silicone adhesive. Epoxy glues are
not recommended, but if used ample curing time should be allowed prior to use.
As little adhesive as possible should be in contact with the water.
(B) Many different sizes of test chambers have been used successfully. The
size, shape and depth of the test chamber is acceptable if the specified flow
rate and loading requirements can be achieved.
(C) The actual arrangement of the test chambers can be important to the
statistical analysis of the test data. Test chambers can be arranged totally on
one level (tier) side by side, or on two levels with each level having one of
the replicate test substance concentrations or controls. Regardless of the
arrangement, it shall be reported in detail and considered in the data analysis.
(iii) Embryo incubation apparatus. (A) Recommended embryo incubation
apparatus include embryo cups for the minnow species and screen trays for the
trout species, although embryo cups can be used for the trout species. Embryo
cups are normally constructed from approximately 4-5 cm inside diameter, 7-8 cm
high, glass jars with the end cut off or similar sized sections of polyethylene
tubing. One end of the jar or tubing is covered with stainless steel or nylon
screen (approximately 40 meshes per inch is recommended). Embryo cups for
silversides are normally constructed by using silicone adhesive to glue a 10-cm
high, 363-um nylon mesh tube inside a 9-cm I.D. glass Petri dish bottom. The
embryo cups shall be appropriately labeled and then suspended in the test
chamber in such a manner as to ensure that the test solution regularly flows
through the cup and that the embryos are always submerged but are not agitated
too vigorously. Cups may be oscillated by a rocker arm apparatus with a low rpm
motor (e.g., 2 rpm) to maintain the required flow of test water. The
vertical-travel distance of the rocker arm apparatus during oscillation is
normally 2.5-4.0 cm. The water level in the test chambers may also be varied by
means of a self-starting siphon in order to ensure exchange of water in the
embryo cups.
(B) The trout embryo incubation trays can be made from stainless steel screen
(or other acceptable material such as plastic) of about 3-4 mm mesh. The screen
tray should be supported above the bottom of the test chamber by two folds of
screen or other devices which function as legs or supports. The edges of the
screen tray should be turned up to prevent bump spills and to prevent the
embryos from rolling off in the event of excessive turbulence. Suspending or
supporting the screen tray off the bottom ensures adequate water circulation
around the embryos and avoids contact of embryos with possible bottom debris.
(iv) Test substance delivery system. (A) The choice of a specific
delivery system depends upon the specific properties and requirements of the
test substance. The apparatus used should accurately and precisely deliver the
appropriate amount of stock solution and dilution water to the test chambers.
The system selected shall be calibrated before each test. Calibration includes
determining the flow rate through each chamber, and the proportion of stock
solution to dilution water delivered to each chamber. The general operation of
the test substance delivery system shall be checked at least twice daily for
normal operation throughout the test. A minimum of five test substance
concentrations and one control shall be used for each test.
(B) The proportional diluter and modified proportional diluter systems and
metering pump systems have proven suitable and have received extensive use.
(C) Mixing chambers shall be used between the diluter and the test
chamber(s). This may be a small container or flow-splitting chamber to promote
mixing of test substance stock solution and dilution water, and is positioned
between the diluter and the test chambers for each concentration. If a
proportional diluter is used, separate delivery tubes shall run from the
flow-splitting chamber to each replicate test chamber. Daily checks on this
latter system shall be made.
(D) Silverside fry are injured easily and are susceptible to impingement on
the mesh of the incubation cups. Consequently, water flow into and out of the
cups when counting fry must be at a slow rate. This can be accomplished by using
small diameter (e.g., 2 mm I.D.) capillary tubes to drain the test solution from
spitter boxes into the replicate test chambers. The use of a self-starting
siphon to gradually lower (i.e., less than or equal to 1 min.) the water level
approximately 2 cm in the test chamber is recommended. A minimum water depth of
5 cm should be maintained in the cups. Although it may be satisfactory, a
rocker-arm type apparatus has not yet been used with silversides.
(v) Other equipment required. (A) An apparatus for removing
undesirable organisms, particulate matter and air bubbles.
(B) An apparatus for aerating water.
(C) A suitable magnifying viewer for examination of minnow embryos.
(D) A suitable apparatus for the precise measurement of growth of the fish,
including both length (e.g., with metric or ruler caliper or photographic
equipment) and weight.
(E) Facilities for providing a continuous supply of live brine shrimp nauplii
(Artemia salina).
(F) For silversides, facilities for providing a supply of rotifers
(Brachionus plicatilis) for approximately 11 days.
(G) Facilities (or access to facilities) for performing the required water
chemistry analyses.
(vi) Cleaning of equipment. (A) Test substance delivery systems and
test chambers should be cleaned before use. Test chambers should be cleaned
during the test as needed to maintain the dissolved oxygen concentration, and to
prevent clogging of the embryo cup screens and narrow flow passages.
(B) Debris can be removed with a rubber bulb and large pipette or by
siphoning with a glass tube attached to a flexible hose. Debris should be run
into a bucket light enough to observe that no live fish are accidentally
discarded.
(vii) Dilution water -- (A) General. (1) A constant
supply of acceptable dilution water should be available for use throughout the
test. Dilution water shall be of a minimum quality such that the test species
selected will survive in it for the duration of testing without showing signs of
stress (e.g., loss of pigmentation, disorientation, poor response to external
stimuli, excessive mucous secretion, lethargy, lack of feeding, or other unusual
behavior). A better criterion for an acceptable dilution water for tests on
early life stages should be such that the species selected for testing will
survive, grow, and reproduce satisfactorily in it.
(2) The concentration of dissolved oxygen in the dilution water (fresh
or salt) shall be between 90 percent and 100 percent saturation. When necessary,
dilution water should be aerated by means of airstones, surface aerators, or
screen tubes before the introduction of the test substance.
(3) Water that is contaminated with undesirable microoganisms (e.g.,
fish pathogens) shall not be used. If such contamination is suspected, the water
should be passed through a properly maintained ultraviolet sterilizer equipped
with an intensity meter before use. Efficacy of the sterilizer can be determined
by using standard plate count methods.
(B) Freshwater. (1) Natural water (clean surface or ground
water) is preferred, however, dechlorinated tap water may be used as a last
resort. Reconstituted freshwater is not recommended as a practical dilution
water for the early life stage toxicity test because of the large volume of
water required.
(2) Particulate and dissolved substance concentrations should be
measured at least twice a year and should meet the following specifications: (3) During any one month, freshwater dilution water should not vary
more than 10 percent from the respective monthly averages of hardness,
alkalinity and specific conductance; the monthly pH range should be less than
0.4 pH units.
(C) Saltwater. (1) Marine dilution water is considered to be of
constant quality if the minimum salinity is greater than 150/ (2) Artificial sea salts may be added to natural seawater during
periods of low salinity to maintain salinity above 150/ (3) Test parameters -- (i) Dissolved oxygen concentration. It
is recommended that the dissolved oxygen concentration be maintained between 90
and 100 percent saturation; but it shall be no less than 75 percent saturation
at all times for both minnow species and between 90 and 100 percent saturation
for the trout species in all test chambers. Dilution water in the head box may
be aerated, but the test solution itself shall not be aerated.
(ii) Loading and flow rate. (A) The loading in test chambers should
not exceed 0.1 grams of fish per liter of test solution passing through the test
chamber in 24 hours. The flow rate to each chamber should be a minimum of 6 tank
volumes per 24 hours. During a test, the flow rates should not vary more than 10
percent from any one test chamber to any other.
(B) A lower loading or higher flow rate or both shall be used if necessary to
meet the following three criteria at all times during the test in each chamber
containing live test organisms:
(1) The concentration of dissolved oxygen shall not fall below 75
percent saturation for the fathead and sheepshead minnows and 90 percent for the
rainbow and brook trout;
(2) The concentration of un-ionized ammonia should not exceed 1 μ g/1;
and
(3) The concentration of toxicant should not be lowered (i.e., caused
by uptake by the test organisms and/or materials on the sides and bottoms of the
chambers) more than 20 percent of the mean measured concentration.
(iii) Temperature. (A) The recommended test temperatures are:
(1) Fathead minnow -- -- 25 °C for all life stages.
(2) Sheepshead minnow -- -- 30 °C for all life stages.
(3) Rainbow and brook trout -- -- 10 °C for embryos. 12 °C for fry and
alevins.
(4) Atlantic and tidewater silversides -- -- 25 °C for all life
stages.
(B) Excursions from the test temperature shall be no greater than ±2.0°C. It
is recommended that the test system be equipped with an automatic alarm system
to alert staff of instantaneous temperature changes in excess of 2 °C. If the
water is heated (i.e., for minnow species), precautions should be taken to
ensure that supersaturation of dissolved gases is avoided. Temperatures shall be
recorded in all test chambers at the beginning of the test and weekly
thereafter. The temperature shall be recorded at least hourly in one test
chamber throughout the test.
(iv) Light. (A) Brook and rainbow trout embryos shall be maintained in
darkness or very low light intensity through one week post-hatch, at which time
a 14-hour light and 10-hour dark photoperiod shall be provided.
(B) For fathead and sheepshead minnows, a 16-hour light and 8-hour dark (or
12:12) photoperiod shall be used throughout the test period.
(C) For silversides, a 14-hour light and 10-hour dark photoperiod shall be
used throughout the test period.
(D) A 15-minute to 30-minute transition period between light and dark is
optional.
(E) Light intensities ranging from 30 to 100 lumens at the water surface
shall be provided; the intensity selected should be duplicated as closely as
possible for all test chambers.
(e) Reporting. A report of the results of an early life stage toxicity
test shall include the following:
(1) Name of test, sponsor, investigator, laboratory, and dates of test
duration.
(2) Detailed description of the test substance including its source, lot
number, composition (identity and concentration of major ingredients and major
impurities), known physical and chemical properties, and any carriers (solvents)
or other additives used.
(3) The source of the dilution water, its chemical characteristics, and a
description of any pretreatment.
(4) Detailed information about the test organisms including scientific name
and how verified and source history, observed diseases, treatments, acclimation
procedure, and concentration of any contaminants and the method of measurement.
(5) A description of the experimental design and the test chambers, the depth
and volume of the solution in the chambers, the way the test was begun, the
number of organisms per treatment, the number of replicates, the loading, the
lighting, a description of the test substance delivery system, and the flow rate
as volume additions per 24 hours.
(6) Detailed information on feeding of fish during the toxicity test,
including type of food used, its source, feeding frequency and results of
analysis (i.e., concentrations) for contaminants.
(7) Number of embryos hatched, number of healthy embryos, time to hatch,
mortality of embryos and fry, measurements of growth (weight and length),
incidence of pathological or histological effects and observations of other
effects or clinical signs, number of healthy fish at end of test.
(8) Number of organisms that died or showed an effect in the control and the
results of analysis for concentration(s) of any contaminant in the control(s)
should mortality occur.
(9) Methods used for, and the results of (with standard deviation), all
chemical analyses of water quality and test substance concentration, including
validation studies and reagent blanks; the average and range of the test
temperature(s).
(10) Anything unusual about the test, any deviation from these procedures,
and any other relevant information.
(11) A description of any abnormal effects and the number of fish which were
affected during each period between observations in each chamber, and the
average concentration of test substance in each test chamber.
(12) Reference to the raw data location.
[50 FR 39321, Sept. 27, 1985, as amended at 52 FR 19064, May 20,
1987]
------------------------------------------------------------------------
Substance Concentration maximum
------------------------------------------------------------------------
Particulate matter....................... <20 mg/liter.
Total organic carbon (TOC)............... <2 mg/liter.
Chemical oxygen demand (COD)............. <5 mg/liter.
Un-ionized ammonia....................... <1 mg/liter.
Residual chlorine........................ <1 mg/liter.
Total organoposphorus pesticides......... <50 ng/liter.
Total organochlorine pesticides plus <50 ng/liter.
polychlorinated biphenyls (PCBs).
Total organic chlorine................... <25 ng/liter.
------------------------------------------------------------------------
