Early Life Stage test explained

An early life stage (ELS) test is a chronic toxicity test using sensitive early life stages like embryos or larvae to predict the effects of toxicants on organisms.[1] ELS tests were developed to be quicker and more cost-efficient than full life-cycle tests, taking on average 1–5 months to complete compared to 6–12 months for a life-cycle test. They are commonly used in aquatic toxicology, particularly with fish. Growth and survival are the typically measured endpoints, for which a Maximum Acceptable Toxicant Concentration (MATC) can be estimated. ELS tests allow for the testing of fish species that otherwise could not be studied due to length of life, spawning requirements, or size. ELS tests are used as part of environmental risk assessments by regulatory agencies including the U.S. Environmental Protection Agency (EPA) and Environment Canada, as well as the Organisation for Economic Co-operation and Development (OECD).[2] [3]

Development

ELS tests were adapted from full life-cycle toxicity tests, chronic tests that expose an organism to a contaminant for its entire life-cycle. These are widely considered to be the best tests for estimating long-term "safe" concentrations of toxicants in aquatic organisms. The first full life-cycle tests on fish were developed for the fathead minnow (Pimephales promelas),[4] [5] and later for bluegill (Lepomis macrochirus), brook trout (Salvelinus fontinalis), flagfish (Jordanella floridae), and sheepshead minnow (Cyprinodon variegatus).[6] While useful, full life-cycle tests require a high number of test organisms and extensive exposure time in the lab, especially for vertebrates. Typically, life-cycle tests take 6–12 months for fathead minnow and 30 months for brook trout.

Following the passage of the Toxic Substances Control Act (TSCA) in the United States in 1976, there was an increased need for quicker, more efficient vertebrate toxicity tests. The EPA was now required to assess the environmental effects of new chemicals before they could be commercially produced. Less costly and time-intensive tests were needed to evaluate a multitude of new chemicals. Researchers began developing toxicity tests that focused on early life stages, since these have been shown to be more sensitive to environmental stressors than later life stages. Many critical events occur in a short period of time in the early stages of development.[7] If a stressor disrupts developmental events (including their timing), it could result in adverse effects that reduce the organism's chances of survival. Meta-analysis has found that early life-cycle portions of full life-cycle tests usually estimate an MATC within a factor of 2 of full life-cycle estimates in saltwater and freshwater fish. In 83% of 72 tests, the ELS portion resulted in the same MATC as the full life-cycle estimate, and the remaining 17% were within a factor of 2.

Limitations

There remain some limitations with early life stage toxicity testing. Although ELS tests are quicker and more cost-efficient than full life cycle tests, they remain resource- and time-intensive. Fish early life stage (FELS) tests require hundreds of fish and 1 to 5 months to complete.[8] Other issues include the lack of mechanistic information, differing sensitivities between species, and insensitivity to parental exposure. ELS tests don't provide information on the toxicant's mechanism of action. Sensitivity to specific toxicants varies with species, so the most sensitive or most important species should be tested in each case. ELS tests appear to be insensitive to parental exposure, and MATCs are generally the same for embryos of both exposed and unexposed parents. This could be due to the mode of action of the toxicant or the variability and insensitivity of ELS test design. Additionally, growth response has been found to be an insensitive endpoint in ELS tests with fish, having little bearing on the estimation of an MATC.[9] Growth response could be omitted to reduce the duration and cost of screening tests.

Methodology

In a typical early life stage toxicity test, a flow-through dilutor system administers different concentrations of a toxicant to different test chambers. At least five different concentrations of a toxicant are tested, plus controls, with at least two exposure chambers for each treatment. The length of the exposure depends on the test species. For example, fathead minnow tests are 1–2 months long, while brook trout tests are around 5 months long. Growth and survival are the typical endpoints, for which an MATC can be found.

Standard methods for ELS tests have been established by the OECD, ASTM International,[10] the EPA,[11] and Environment Canada.[12] [13]

Regulatory uses

Current developments

An extended ELS test has been examined as a potential surrogate for a fish full life-cycle test to detect weak environmental estrogens.[16] Endocrine active chemicals (EACs) are ubiquitous in the environment, prompting the need for better screening assays to predict their effects, especially in aquatic species. Slightly longer ELS tests could be used instead of full life-cycle tests, taking into account sensitive windows of exposure like sexual differentiation and early gonadal development. Extended ELS tests have proven successful in detecting the effects of weak estrogens in fathead minnows.

Additionally, adverse outcome pathways (AOPs) are being used to develop an alternative to FELS testing. Industry and regulatory agencies are increasingly interested in an animal-free, cost-efficient surrogate.[17] Researchers are developing FELS-related AOPs to create a high-throughput, less costly screening strategy for toxicants that takes the mechanism of action into account.

Notes and References

  1. McKim JM. 1985. Early life stage toxicity tests. In Rand GM (1995). Fundamentals of Aquatic Toxicology: Effects, Environmental Fate, and Risk Assessment (2nd ed.). Boca Raton: CRC Press. pp 974–1010. .
  2. http://www.epa.gov/oppefed1/ecorisk_ders/toera_analysis_eco.htm Technical Overview of Ecological Risk Assessment Analysis Phase: Ecological Effects Characterization.
  3. Organisation for Economic Co-operation and Development. 1992. Guideline 210: Fish early-life stage toxicity test. OECD Guidelines for the Testing of Chemicals. Paris, France.
  4. Mount DI, Stephan CE. 1967. A method for establishing acceptable limits for fish-Malathion and the butoxyethanol ester of 2,4-D. Trans Am Fish Soc 96:185-193.
  5. Benoit DA, Puglisi FA, Olson DL. 1982. A fathead minnow (Pimephales promelas) early life stage toxicity test method evaluation and exposure to four organic chemicals. Environ Pollution Series A, Ecological and Biological 28:189-197.
  6. Hansen DJ, Parrish PR, Schimmel SC, Goodman LR. 1978. Life-cycle toxicity test using sheepshead minnows (Cyprinodon variegatus). Bioassay Procedures for the Ocean Disposal Permit Program, EPA-600/9-78-010.
  7. McKim JM. 1977. Evaluation of tests with early life stages of fish for predicting long-term toxicity. J Fish Res Board Can 34:1148–1154.
  8. Villeneuve D, Volz DC, Embry MR, Ankley GT, Belanger SE, Léonard M, Schirmer K, Tanguay R, Truong L, Wehmas L. 2014. Investigating alternatives to the fish early-life stage test: a strategy for discovering and annotating adverse outcome pathways for early fish development. Environ Toxicol Chem 33:158-69.
  9. Woltering DM. 1984. The growth response in fish chronic and early life stage toxicity tests: A critical review. Aquat Toxicol 5:1–21.
  10. ASTM International. Standard Guide for Conducting Early Life-Stage Toxicity Tests with Fishes, designation E1241. Conshohochen (PA): Annual book of ASTM standards. Section 11.06: Environmental Assessment, Risk Management and Corrective Action.
  11. United States Environmental Protection Agency. 2002. Short-term methods for estimating chronic toxicity of effluent and receiving waters to marine and estuarine organisms. Third edition. Cincinnati (OH): Environmental Monitoring Systems Laboratory, U.S. Environmental Protection Agency. EPA/821/R-02/014, October 2002.
  12. Environment Canada. 1992. Biological test method: test of larval growth and survival using fathead minnows. Ottawa (ON): Environmental Technology Centre. Report EPS 1/RM/22, February 1992, Amended in September 2008.
  13. Environment Canada. 1998. Biological test method: toxicity tests using the early life stages of salmonid fish (rainbow trout). Report EPS 1/RM/28, 2nd ed., July. Ottawa (ON): Environmental Technology Centre.
  14. Environment Canada. Metal Mining Technical Guidance for Environmental Effects Monitoring.
  15. United States Environmental Protection Agency. 2002. TSCA New Chemicals Program (NCP) Chemical Categories.
  16. Panter GH, Hutchinson TH, Hurd KS, Bamforth J, Stanley RD, Duffell S, Hargreaves A, Gimeno S, Tyler CR. 2006. Development of chronic tests for endocrine active chemicals: Part 1. An extended fish early-life stage test for oestrogenic active chemicals in the fathead minnow (Pimephales promelas) Aquat Toxicol 77:279-290.
  17. Knapen D, Vergauwen L, Verstraelen S, Dardenne F, Witters H, Blust R, Villeneuve DL, Ankley GT. 2013. Development of an alternative testing strategy for the fish early life-stage for predicting chronic toxicity." Toxicology Letters 221: S104.