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Cadmium   0.850
Chromium (III)   0.316
Chromium (VI)   0.982
Copper   0.960
Lead   0.875
Mercury   0.850
Nickel   0.998
Selenium   0.922
Silver   0.850
Zinc   0.978
NR 105.05(5)(b) (b) The translation of the WQCD into the water quality criterion which accounts for site-specific conditions (WQCTRAN) shall be performed as follows:
WQCTRAN = (Translator)(WQCD)
Where: Translator (unitless) = ((MP)(TSS) + MD)/MD
  MP = Particle-bound concentration of the pollutant         (ug/g) in receiving water.
  MD = Dissolved concentration of the pollutant in           receiving water (ug/L).
  TSS = Total Suspended Solids (g/L) concentration in         receiving water.
NR 105.05(5)(c) (c) The procedures in pars. (a) and (b) may also be used for the conversion of secondary values from total recoverable to dissolved.
NR 105.05 History History: Cr. Register, February, 1989, No. 398, eff. 3-1-89; am. (1) (a) 1. to 5., (1) (b), (2) (a) to (f), (3) (a) and (f) to (L), r. and recr. (1) (a) 6., cr. (1) (a) 7. to 10., (4) and (5), Register, August, 1997, No. 500, eff. 9-1-97; CR 03-050: am. (3) (L) and (m) Register February 2004 No. 578, eff. 3-1-04.
NR 105.06 NR 105.06Chronic toxicity criteria and secondary chronic values for fish and aquatic life.
NR 105.06(1)(1)Minimum database for chronic criterion development.
NR 105.06(1)(a) (a) To derive a chronic toxicity criterion for aquatic life, the minimum information required shall be results of acceptable chronic toxicity tests with one or more species of freshwater animal in at least 8 different families provided that of the 8 species:
NR 105.06(1)(a)1. 1. At least one is a salmonid fish, in the family Salmonidae in the class Osteichthyes,
NR 105.06(1)(a)2. 2. At least one is a non-salmonid fish, from another family in the class Osteichthyes, preferably a commercially or recreationally important warmwater species,
NR 105.06(1)(a)3. 3. At least one is a planktonic crustacean (e.g., cladoceran, copepod),
NR 105.06(1)(a)4. 4. At least one is a benthic crustacean (e.g., ostracod, isopod, amphipod, crayfish),
NR 105.06(1)(a)5. 5. At least one is an insect (e.g., mayfly, dragonfly, damselfly, stonefly, caddisfly, mosquito, midge),
NR 105.06(1)(a)6. 6. At least one is a fish or amphibian from a family in the phylum Chordata not already represented in one of the other subdivisions,
NR 105.06(1)(a)7. 7. At least one is an organism from a family in a phylum other than Arthropoda or Chordata (e.g., Rotifera, Annelida, Mollusca), and
NR 105.06(1)(a)8. 8. At least one is an organism from a family in any order of insect or any other phylum not already represented in subds. 1. to 7.
NR 105.06(1)(a)9. 9. If all 8 of the families in subds. 1. to 8. are represented, a chronic toxicity criterion may be developed for surface waters classified as cold water using information on all of those families. If a chronic toxicity criterion is developed for surface waters classified as cold water, chronic toxicity criteria may also be developed for any of the surface water classifications in s. NR 102.04 (3) (b) to (e) using the procedure in sub. (2) or (3) and data on families in subds. 1. to 8. which are representative of the aquatic life communities associated with those classifications. For each substance, in no case may the criterion for a lower quality fish and aquatic life subcategory as defined in s. NR 102.04 be less than the criterion for a higher quality fish and aquatic life subcategory.
NR 105.06(1)(a)10. 10. For a substance, if all the families in subds. 1. to 8. are not represented, acute-chronic ratios as calculated in sub. (5) may be used to generate the chronic toxicity values necessary to calculate a chronic toxicity criterion.
NR 105.06(1)(a)11. 11. For a substance, if all of the families in subds. 1. to 8. are not represented, a chronic toxicity criterion may not be developed for that substance except as provided in subd. 10. Instead, any available data may be used to develop a secondary acute value (SAV) for that substance according to sub. (4).
NR 105.06(1)(b) (b) The acceptability of chronic toxicity test results shall be judged according to the guidelines in section VI of the United States environmental protection agency's 1985 “Guidelines for Deriving National Numerical Water Quality Criteria for the Protection of Aquatic Organisms and Their Uses" or 40 CFR Part 132 Appendix A, sections VI and VII as stated on September 1, 1997, is incorporated by reference.
NR 105.06 Note Note: Copies of 40 CFR Part 132, Appendix A, Sections VI and VII are available for inspection in the offices of the department of natural resources, secretary of state and the legislative reference bureau, Madison, WI or may be purchased from the superintendent of documents, US government printing office, Washington, D.C. 20402.
NR 105.06(2) (2) Calculation of a chronic concentration. A chronic concentration is obtained by calculating the geometric mean of the chronic lowest observable adverse effect level and the chronic no observable adverse effect level.
NR 105.06(3) (3) Chronic toxicity criteria for substances with toxicity unrelated to water quality parameters. If the chronic toxicity of a substance has not been adequately shown to be related to a water quality parameter, i.e., hardness, pH, temperature, etc., the chronic toxicity criterion (CTC) is calculated using the procedures specified in this subsection.
NR 105.06(3)(a)1.1. For each species for which at least one chronic value is available, the species mean chronic value (SMCV) is calculated as the geometric mean of all acceptable chronic toxicity tests using the guidelines in sub. (1) (b).
NR 105.06(3)(a)2. 2. For each genus for which one or more SMCVs are available, the genus mean chronic value (GMCV) is calculated as the geometric mean of the SMCVs available for the genus.
NR 105.06(3)(b) (b) The GMCVs are ordered from high to low.
NR 105.06(3)(c) (c) Ranks (R) are assigned to the GMCVs from 1 for the lowest to N for the highest. If 2 or more GMCVs are identical, successive ranks are arbitrarily assigned.
NR 105.06(3)(d) (d) The cumulative probability (P) is calculated for each GMCVs as P=R/(N + 1).
NR 105.06(3)(e) (e) The 4 GMCVs are selected which have P closest to 0.05. If there are less than 59 GMCVs, these will always be the lowest GMCVs.
NR 105.06(3)(f) (f) Using the selected GMCVs and Ps, the final chronic value (FCV) is calculated using the following:
NR 105.06(3)(f)1. 1. Let EV = sum of the 4 ln GMCVs,
      EW = sum of the 4 squares of the ln GMCVs,
      EP = sum of the 4 P values,
      EPR = sum of the 4 square roots of P, and
      JR = square root of 0.05.
NR 105.06(3)(f)2. 2. S = ((EW - (EV)2 /4)/(EP-(EPR) 2/4)) 0.5
NR 105.06(3)(f)3. 3. L = (EV - S(EPR))/4.
NR 105.06(3)(f)4. 4. A = (JR)(S) + L.
NR 105.06(3)(f)5. 5. FCV = eA.
NR 105.06(3)(g) (g) If, for a commercially, recreationally or ecologically important species, the geometric mean of the chronic values is lower than the calculated FCV then that geometric mean is used as the FCV instead of the calculated one.
NR 105.06(3)(h) (h) The chronic toxicity criterion (CTC) equals the lower of the FCV and the final plant value calculated using the procedure in s. NR 105.11.
NR 105.06(3)(i) (i) Table 3 contains the chronic toxicity criteria for the fish and aquatic life subcategories listed in s. NR 102.04 (3) that are calculated using the procedures described in this subsection for substances meeting the database requirements indicated in sub. (1).
NR 105.06(4) (4) Chronic toxicity criteria for substances with toxicity related to water quality parameters.
NR 105.06(4)(a) (a) If data are available on a substance to show that chronic toxicity to 2 or more species is similarly related to a water quality parameter (i.e., hardness, pH, temperature, etc.), the chronic toxicity criterion (CTC) is calculated using the procedures specified in this paragraph.
NR 105.06(4)(a)1. 1. For each species for which acceptable chronic toxicity tests using the guidelines in sub. (1) (b) are available at 2 or more different values of the water quality parameter, a least squares regression of the chronic toxicity values on the corresponding values of the water quality parameter is performed to obtain the slope of the curve that best describes the relationship. Because the most commonly documented relationship is that between hardness and the chronic toxicity of metals and a log-log relationship fits these data, geometric means and natural logarithms of both toxicity and water quality are used in the rest of this subsection to illustrate this method. For relationships based on other water quality parameters, no transformation or a different transformation might fit the data better, and appropriate changes shall be made as necessary throughout this subsection.
NR 105.06(4)(a)2. 2. For each species, the geometric mean of the available chronic values (W) is calculated and then each of the chronic values is divided by the mean for that species. This normalizes the chronic values so that the geometric mean of the normalized values for each species individually and for any combination of species is 1.0.
NR 105.06(4)(a)3. 3. For each species, the geometric mean of the available corresponding water quality parameter values (X) is calculated and then each of the water quality parameter values is divided by the mean for that species. This normalizes the water quality parameter values so that the geometric mean of the normalized values for each species individually and for any combination of species is 1.0.
NR 105.06(4)(a)4. 4. A least squares regression of all the normalized chronic values on the corresponding normalized values of the water quality parameter is performed to obtain the pooled chronic slope (V). If the coefficient of determination, or r value, calculated from that regression is found not to be significant based on a standard F-test at a 0.05 level, then the pooled chronic slope shall be set equal to zero.
NR 105.06(4)(a)5. 5. For each species the logarithmic intercept (Y) is calculated using the equation: Y = ln W - V(ln X).
NR 105.06(4)(a)6.a.a. For each species the species mean chronic intercept (SMCI) is calculated as eY.
NR 105.06(4)(a)6.b. b. For each genus for which one or more SMCIs are available, the genus mean chronic intercept (GMCI) is calculated as the geometric mean of the SMCIs available for the genus.
NR 105.06(4)(a)7. 7. The GMCIs are ordered from high to low.
NR 105.06(4)(a)8. 8. Ranks (R) are assigned to the GMCIs from 1 for the lowest to N for the highest. If 2 or more GMCIs are identical, successive ranks are arbitrarily assigned.
NR 105.06(4)(a)9. 9. The cumulative probability (P) is calculated for each GMCI as P=R/(N + 1).
NR 105.06(4)(a)10. 10. The 4 GMCIs are selected which have P closest to 0.05. If there are less than 59 GMCIs, these will always be the lowest GMCIs.
NR 105.06(4)(a)11. 11. Using the selected GMCIs and Ps, the final chronic value (FCV) is calculated using the following:
NR 105.06(4)(a)11.a. a. Let EV = sum of the 4 ln GMCIs,
    EW = sum of the 4 squares of the ln GMCIs,
    EP = sum of the 4 P values,
    EPR = sum of the 4 square roots of P, and
    JR = square root of 0.05.
NR 105.06(4)(a)11.b. b. S = ((EW-(EV)2/4)/(EP-(EPR)2/4))0.5
NR 105.06(4)(a)11.c. c. L = (EV - S(EPR))/4.
NR 105.06(4)(a)11.d. d. A = (JR)(S) + L.
NR 105.06(4)(a)11.e. e. Final Chronic Intercept (FCI) = eA.
NR 105.06(4)(a)12. 12. The final chronic equation (FCE) is written as:
FCV = e(V ln(water quality parameter) + ln FCI).
The FCE shall be applicable only over the range of water quality parameters equivalent to the mean ± 2 standard deviations using the entire freshwater chronic toxicity data base and the water quality parameter transformation employed in subd. 1. If the value at a specific location is outside of that range, the endpoint of the range nearest to that value shall be used to determine the criterion. Additional information may be used to modify those ranges.
NR 105.06(4)(a)13. 13. If, for a commercially, recreationally or ecologically important species, the SMCI is lower than the calculated FCI, then that SMCI is used as the FCI instead of the calculated one.
NR 105.06(4)(b) (b) At a value of the water quality parameter, the chronic toxicity criterion (CTC) equals the lower of the FCV and the final plant value calculated using the procedure in s. NR 105.11.
NR 105.06(4)(c) (c) Table 4 contains the chronic toxicity criteria for the fish and aquatic life subcategories listed in s. NR 102.04 (3) that are calculated using the procedures described in this subsection for substances meeting the database requirements indicated in sub. (1). Table 4A contains the water quality parameter ranges calculated in par. (a) 1.
NR 105.06(5) (5) Acute-chronic ratios.
NR 105.06(5)(a)(a) The acute-chronic ratio is used to estimate the chronic toxicity of a substance to fish or other aquatic species when the database of sub. (1) (a) is not satisfied.
NR 105.06(5)(b) (b) The acute-chronic ratio for a species equals the acute concentration from data considered under s. NR 105.05 (1) divided by the chronic concentration from data calculated under sub. (1), subject to the following conditions:
NR 105.06(5)(b)1. 1. If the acute toxicity of a substance is related to any water quality parameter, the acute-chronic ratio shall be based on acute and chronic toxicity data obtained from organisms exposed to test water with similar, if not identical, values of those water quality parameters. Preference under this paragraph shall be given to data from acute and chronic tests done by the same author or reference in order to increase the likelihood of comparable test conditions.
NR 105.06(5)(b)2. 2. If the acute and chronic toxicity data indicate that the acute-chronic ratio varies with changes in the values of the water quality parameters, the acute-chronic ratio used at specified values of the water quality parameters shall be based on the ratios at values closest to that specified.
NR 105.06(5)(b)3. 3. If the acute toxicity of a substance is unrelated to water quality parameters, the acute-chronic ratio may be derived from any acute and chronic test on a species regardless of the similarity in values of those parameters. Preference under this paragraph shall be given to data from acute and chronic tests done by the same author or reference to increase the likelihood of comparable test conditions.
NR 105.06(5)(c) (c) A final chronic value shall be calculated for a substance under this subsection only if at least one acute-chronic ratio is available for at least one species of aquatic animal in at least 3 different families, provided that of the 3 species, one is a fish, one is an invertebrate, and the third is a relatively sensitive freshwater species on an acute toxicity basis. The other 2 may be saltwater species.
NR 105.06(5)(d) (d) The geometric mean acute-chronic ratio is calculated for each species using the available acute-chronic ratios for that species. That mean ratio shall be called the species mean acute-chronic ratio (SMACR).
NR 105.06(5)(e) (e) For a given substance, if the SMACR appears to increase or decrease as the species or genus mean acute values (SMAVs or GMAVs) calculated for that substance using the procedure described in s. NR 105.05 increase, the final acute-chronic ratio (FACR) shall be equal to the geometric mean of the SMACRs for species with SMAVs closest to the final acute value.
NR 105.06(5)(f) (f) For a given substance, if no trend is apparent regarding changes in SMACRs and GMAVs, the FACR shall be equal to the geometric mean of all SMACRs available for that substance.
NR 105.06(5)(g) (g) For a given substance, the final chronic value (FCV) shall be equal to the final acute value (FAV) divided by the final acute-chronic ratio (FACR). The chronic toxicity criterion shall be equal to the lower of the FCV and the final plant value as calculated using the procedure in s. NR 105.11, if available.
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Published under s. 35.93, Stats. Updated on the first day of each month. Entire code is always current. The Register date on each page is the date the chapter was last published.