The pesticides in contact with plastics for mulch take longer to degrade

December 09, 2020

The use of plastic mulch (plastic covering on crop lines) is a widespread technique used in agricultural regions in order to increase the profitability of the crops. According to the European Commission, 100,000 tonnes of plastic mulch was used per year in the European Union in 2016. Taking these figures into account and the fact that after the harvest some plastic usually remains in the soil, the accumulation of plastic in territories of intensive agriculture is an environmental problem that is of concern in the sector and also for the public administrations.

Low-density polyethylene (LDPE) is the most used plastic for the mulch and, in turn, is also that which takes longest to degrade. For that reason, another type of plastics has been created - the 'oxo-degradable' (PAC) - which are those that contain pro-oxidant additives that improve degradation in the presence of solar light, or biodegradable plastics, those that can be degraded by the soil's microorganisms.

As pesticides are used in many cases to treat the crops that are under the mulch, a team from the Diverfarming project made up of staff from the universities of Wageningen and Cartagena has analysed the interaction of these plastics with 38 pesticides under laboratory conditions. Although this study had previously been carried out in LDPE plastics, this is the first time that PAC and biodegradable plastics have been analysed.

After analysing the sorption process (retention of a substance by another when they are in contact) of the 38 active ingredients of 17 insecticides, 15 fungicides and 6 herbicides commonly used with plastic mulch in the Region of Murcia with the three types of plastics, it was seen that the bio plastics had a greater percentage of pesticide sorption. On average, the percentage of sorption was 23% in LDPE and PAC, and 50% in Bio. The decomposition of the active ingredients in the presence of plastic was 30% lower than when there was no plastic present.

For one of the researchers involved in the project, Nicolas Beriot, the results lead to two worrying hypotheses: 'the microorganisms responsible for degrading those biodegradable plastics could become contaminated and the efficiency of the pesticides could also be affected since the substances that remain in the plastics are not available in the soil to do their job'. Thus, the modification of the degradation patterns of the active ingredients could affect the community of soil organisms due to the toxicity of the active ingredients.

This laboratory study opens the door to new research in the field to verify how this affects both the question of soil contamination as well as the delay in the degradation capacity of the plastics.

The Diverfarming project seeks a change in paradigm in European agriculture towards a more environmentally and economically sustainable agriculture through crop diversification and the reduction of inputs such as pesticides. In this way, it can contribute to avoiding situations of contamination such as that posed by the interaction between plastics and pesticides.
Diverfarming is a project financed by the Horizon 2020 Programme of the European Commission, within the challenge of "Food Security, Sustainable Agriculture and Forestry, Marine, Maritime and Inland Water Research and the Bioeconomy", under agreement 728003. It counts on the participation of the Universities of Cartagena and Córdoba (Spain), Tuscia (Italy), Exeter and Portsmouth (United Kingdom), Wageningen (Netherlands), Trier (Germany), Pecs (Hungary) and ETH Zurich (Switzerland), the research centres Consiglio per la ricerca in agricoltura e l'analisi dell'economia agraria (Italy), the Consejo Superior de Investigaciones Científicas (Spain) and the Natural Resources Institute LUKE (Finland), the agrarian organisation ASAJA, and the companies Casalasco and Barilla (Italy), Arento, LogísticaDFM and Industrias David (Spain), Nieuw Bromo Van Tilburg and Ekoboerdeij de Lingehof (Netherlands), Weingut Dr. Frey (Germany), Nedel-Market KFT and Gere (Hungary) and Paavolan Kotijuustola and Polven Juustola (Finland).

Beriot N, Zomer P, Zornoza R, Geissen V. 2020. A laboratory comparison of the interactions between three plastic mulch types and 38 active substances found in pesticides. PeerJ 8:e9876

University of Córdoba

Related Pesticides Articles from Brightsurf:

More plant diversity, less pesticides
Increasing plant diversity enhances the natural control of insect herbivory in grasslands.

In pursuit of alternative pesticides
Controlling crop pests is a key element of agriculture worldwide, but the environmental impact of insecticides is a growing concern.

Two pesticides approved for use in US harmful to bees
A previously banned insecticide, which was approved for agricultural use last year in the United States, is harmful for bees and other beneficial insects that are crucial for agriculture, and a second pesticide in widespread use also harms these insects.

Dingoes have gotten bigger over the last 80 years - and pesticides might be to blame
The average size of a dingo is increasing, but only in areas where poison-baits are used, a collaborative study led by UNSW Sydney shows.

Pesticides can protect crops from hydrophobic pollutants
Researchers have revealed that commercial pesticides can be applied to crops in the Cucurbitaceae family to decrease their accumulation of hydrophobic pollutants, thereby improving crop safety.

Honeybee lives shortened after exposure to two widely used pesticides
The lives of honeybees are shortened -- with evidence of physiological stress -- when they are exposed to the suggested application rates of two commercially available and widely used pesticides.

Pesticides increase the risk of schistosomiasis, a tropical disease
Schistosomiasis is a severe infectious disease caused by parasitic worms.

A proposal to change environmental risk assessment for pesticides
Despite regulatory frameworks designed to prevent environmental damage, pesticide use is still linked to declines in insects, birds and aquatic species, an outcome that raises questions about the efficacy of current regulatory procedures.

SDHI pesticides are toxic for human cells
French scientists led by a CNRS researcher have just revealed that eight succinate dehydrogenase inhibitor pesticide molecules do not just inhibit the SDH activity of fungi, but can also block that of earthworms, bees, and human cells in varying proportions.

Pesticides deliver a one-two punch to honey bees
A new paper in Environmental Toxicology and Chemistry reveals that adjuvants, chemicals commonly added to pesticides, amplify toxicity affecting mortality rates, flight intensity, colony intensity, and pupae development in honey bees.

Read More: Pesticides News and Pesticides Current Events is a participant in the Amazon Services LLC Associates Program, an affiliate advertising program designed to provide a means for sites to earn advertising fees by advertising and linking to