Jun 10, 2025

Protocol for Creating Plastic Leachates V.2

  • Gillian Champoir1
  • 1Bowling Green State University
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Protocol CitationGillian Champoir 2025. Protocol for Creating Plastic Leachates . protocols.io https://dx.doi.org/10.17504/protocols.io.eq2lyqryevx9/v2Version created by Gillian Champoir
License: This is an open access  protocol  distributed under the terms of the  Creative Commons Attribution License,  which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited
Protocol status: Working
We use this protocol and it's working
Created: June 10, 2025
Last Modified: June 10, 2025
Protocol  Integer ID: 219896
Keywords: creating plastic leachate, plastic leachate, using solid plastic, leachate, solid plastic, experimental procedure, plastic
Funders Acknowledgements:
Ohio Sea Grant
Abstract
This protocol was created using a variety of methods from the literature to create leachates using solid plastics. It creates standard operating conditions that can be altered based on experimental procedure.
Protocol for making plastic leachates from solid plastic particles

Note
We developed this protocol for our own plastic experiments that focus on plastic preproduction pellets. The pellets come small enough to be classified as microplastics (<5mm) without altering them in any way. Cutting up post-consumer environmental plastics, consumer plastics, etc. to various sizes as needed for experimentation is acceptable and will work with the protocol. It is recommended to take the average metrics (mass, volume, density, etc.) of the plastic pieces prior to use.

This protocol is also identical across plastic types (the 7 recycling categories used to distinguish between commonly used plastics).

Materials
-Glass receptacles with rubber stopped lids
-Balance Scale
-Benchtop shaker
-Thermometer
-Glass serological pipettes
-Metal mesh colander
-Vacuum filtration system
-Whatman GF/F glass fiber filters in 0.7µm
-Freezer (-20°C)
Protocol
3d
Make leachates in glass bottles to avoid cross contamination. Fill the bottle with a set amount of solvent in mL. Solvent can be interchangeable depending on the experiment (synthetic freshwater/saltwater, algal media, filtered environmental water samples, etc).
Weigh your plastic material. Place a known weight (in milligrams) into a known amount of solvent (in milliliters). It is recommended to make a large batch of the highest concentration (mg/ml) of leachate you intend to use. Using the original solvent, you can dilute the leachate to lower concentrations.

[EXAMPLE: Our experiment required concentrations of 1 mg/mL, 0.1 mg/mL, 0.01 mg/mL, and 0.001 mg/mL
We made 100mLs of leachate at 1mg/mL and diluted small batches of it as needed.]
Place the bottle in a covered benchtop shaker (for incubation in the dark) and seal with cap. If room temperature is 25°C ± 2°C then the shaker can remain unheated; Otherwise use necessary means to achieve the temperature parameter. Set the RPM to 150.

150 rpm, 25°C, 72:00:00
Leave incubating for 3 days.
3d
Upon completion of incubation, leachates are filtered using vacuum filtration through a 0.7 µm Whatman Grade GF/F Filter to remove pellets and biotic contaminants. If the batch of leachate being made contains more than a few pellets, remove with the metal mesh colander prior to filtration.
Leachates are distributed into glass storage receptacles using 25mL borosilicate glass serological pipettes (to avoid plastic cross contamination) that have been previously acid-washed and autoclaved.
Take the pH of the leachates created. Leachates are either used immediately or stored frozen in glass receptacles at -20°C to prevent breakdown of compounds over time.
Protocol references
Almeda, R., Gunaalan, K., Alonso-López, O., Vilas, A., Clérandeau, C., Loisel, T., ... & Beiras, R. (2023). A protocol for lixiviation of micronized plastics for aquatic toxicity testing. Chemosphere, 333, 138894. https://doi.org/10.1016/j.chemosphere.2023.138894 

Bridson, J. H., Gaugler, E. C., Smith, D. A., Northcott, G. L., & Gaw, S. (2021). Leaching and extraction of additives from plastic pollution to inform environmental risk: A multidisciplinary review of analytical approaches. Journal of Hazardous Materials, 414, 125571. https://doi.org/10.1016/j.jhazmat.2021.125571 

Simon, M., Hartmann, N. B., & Vollertsen, J. (2021). Accelerated weathering increases the release of toxic leachates from microplastic particles as demonstrated through altered toxicity to the green algae Raphidocelis subcapitata. Toxics, 9(8), 185. https://doi.org/10.3390/toxics9080185 

U.S. EPA, 1992,  U.S. EPA, Code of Federal Regulations (CFR) 40. Toxicity Characteristic Leaching Procedure (TCLP), U.S. Environmental Protection Agency (1992), Federal Register 40:261(1 July 1991): Appendix II