Level 1 — Absolute Beginner
Plastic is everywhere. Tiny pieces of plastic are even in our water. The small pieces are called microplastics.
Microplastics are bad for fish, animals and people. We need a way to take them out of water.
Scientists in the United States made a special kind of algae. Algae are tiny green plants that live in water.
The new algae sticks to plastic like a magnet. In one hour, it cleans 91 out of every 100 small plastic pieces. That is very good!
- plastic
- a soft, man-made material used for bags, bottles and toys
- tiny
- very, very small
- water
- the clear liquid we drink
- fish
- an animal that lives in water
- algae
- very small green plants that live in water
- magnet
- a thing that pulls metal towards itself
- clean
- to take away dirt
- hour
- sixty minutes
Level 2 — Elementary
Microplastics are tiny pieces of plastic, smaller than five millimeters across. They come from bottles, packaging and even the wash cycles of clothes made from polyester. Today, they are found in rivers, oceans, soil and even human blood.
Researchers at the University of Missouri wanted to find a clean and cheap way to take them out of water. They worked on a small green plant called algae and gave it new abilities through bioengineering.
The new algae makes a natural oil called limonene, which smells a little like orange peel. Limonene does not like water but it does like plastic. The plastic particles in the water stick to the oil-covered algae and form little clumps that sink to the bottom of the tank.
In tests reported in the journal Nature Communications, the algae removed about 91.4 percent of polystyrene microplastics in just one hour. As an added benefit, the algae also helped clean other dirty parts of wastewater while it grew. Lead scientist Susie Dai hopes one day to use the captured plastic to make safer, recycled materials.
- millimeter
- a small unit of length, one thousandth of a meter
- polyester
- a kind of man-made cloth
- researcher
- a person who studies a subject closely
- bioengineering
- changing living things on purpose to give them new abilities
- limonene
- a natural oil from orange peels with a strong smell
- clump
- a small group of things stuck together
- wastewater
- dirty water that has been used and needs cleaning
- recycle
- to turn used material into something new
Level 3 — Intermediate
A team at the University of Missouri has engineered a strain of green algae that pulls microplastics out of water like a living magnet, achieving 91.4 percent removal of polystyrene particles in only one hour of contact. The work, led by environmental engineer Susie Dai and published in Nature Communications, sets a new benchmark for low-cost, biological microplastic capture.
Microplastics — fragments smaller than five millimeters — are now ubiquitous, found in oceans, soils, drinking water and human tissue. Filtering them out is technically possible but typically expensive and energy-intensive, especially at the volumes a sewage plant or river system must handle. Biological approaches, by contrast, can scale alongside the water itself if the organism is engineered correctly.
The Missouri team chose to engineer Chlamydomonas reinhardtii, a well-studied unicellular green algae, to secrete elevated levels of limonene. Limonene is a hydrophobic monoterpene more commonly associated with citrus peel, and crucially it shares its water-aversion with most common microplastics. When the modified algae are added to a contaminated sample, the plastic particles bind to limonene-coated cell surfaces, aggregate into denser clumps, and settle at the bottom of the vessel where they can be skimmed or filtered out.
The same algae continue to perform their everyday job of consuming nutrients from wastewater, so the system doubles as a tertiary treatment step. Dai's longer-term goal is to recover the captured plastic and convert it into composite films and other bioplastics, closing the loop on a pollution problem that today moves mostly in one direction. Pilot studies are planned at municipal treatment plants in the United States before the team considers commercial deployment.
- engineer (verb)
- to design or modify something using technical knowledge
- strain
- a specific variant of an organism
- ubiquitous
- found everywhere at once
- secrete
- to produce and release a substance from a cell or body
- hydrophobic
- tending to repel or fail to mix with water
- aggregate
- to gather into a group or clump
- tertiary treatment
- the final cleaning stage in a wastewater plant
- pilot study
- a small initial test of a new technology or method
Level 4 — Advanced
An engineered strain of Chlamydomonas reinhardtii developed by Susie Dai's laboratory at the University of Missouri has demonstrated 91.4 percent removal of polystyrene microplastics within an hour of contact, redefining what biological remediation can plausibly achieve. The findings, published this month in Nature Communications, also document concurrent uptake of nitrogen and phosphorus nutrients, signalling that the same biomass can serve as both a plastic-capture medium and a tertiary nutrient-removal step.
The mechanism rests on a familiar piece of physical chemistry. Polystyrene and the limonene monoterpene the algae secretes are both strongly hydrophobic, with octanol-water partition coefficients well outside the range associated with water-soluble compounds. When dispersed in an aqueous matrix the two phases segregate together, with limonene preferentially wetting the surface of suspended microplastic particles. The plastic-laden cells in turn flocculate, increase in effective density and settle out of suspension within minutes, leaving a clarified upper layer that the team reports can be returned to a treatment-plant flow without additional polishing.
Engineering limonene-overexpressing strains of C. reinhardtii is not new, but Dai's team coupled the construct to a carbon-flux tuning that maintains photosynthetic efficiency under high terpenoid output, a known bottleneck in earlier work. Pilot vessels have been operated continuously for two-week stretches, with biomass yields stable enough to project realistic dosing rates for municipal-scale flows. Crucially, the algal cells can be harvested by standard dissolved-air flotation and either incinerated for energy recovery or, in the team's preferred route, processed into composite films that lock the captured polymer into a long-lived solid form.
Several open questions remain. Polystyrene is only one of the dominant microplastic chemistries; the authors have not yet published comparable removal data for polyethylene terephthalate or polypropylene, which together account for much of the marine microplastic load. Regulatory pathways for releasing engineered microalgae into open systems are also unsettled, and Dai's team has emphasized that initial deployments will be confined to closed, monitored treatment trains. Even with those caveats, the result tightens an emerging case that biological remediation, long dismissed as a niche curiosity for environmental engineering, may turn out to be one of the more scalable answers to a pollution problem currently measured in millions of tonnes per year.
- remediation
- the act of cleaning up or correcting environmental damage
- monoterpene
- a class of natural hydrocarbons with ten carbon atoms
- octanol-water partition coefficient
- a measure of how strongly a substance prefers oil over water
- flocculate
- to clump together into larger particles that settle out
