Periodic Reporting for period 2 - ENZYCLE (Microbial ENZYmes for treatment of non-recyCLEd plastic fractions)
Período documentado: 2021-12-01 hasta 2023-05-31
The European Union has taken a global initiative to make 100% of plastic packaging recyclable, reusable or compostable by 2030, thereby moving towards a circular economy model. It is therefore essential to find new recycling processes for the fraction of plastic packaging that is currently not recycled, in particular PET trays and clamshells, PET/PE and PET/PP multilayers or microplastics.
Biotechnology is a highly dynamic and constantly evolving area of biology that is playing an important role in economics, health and the environment. New biotechnological processes are being developed to include plastics in the circular economy, enabling their reuse and recovery at the end of their useful life. These processes greatly benefit the environment and create new business opportunities in the sector.
The ENZYCLE project, funded by the Bio-based Industries Joint Undertaking (BBI JU) under the EU's Horizon 2020 program, is developing new processes to enzymatically recycle plastics that are currently not recyclable, such as PET trays and multilayer PET/PE packaging. For this reason, enzymes with high hydrolytic activity in polyesters and polyolefins are being identified and improved in order to establish efficient recycling processes. In addition, ENZYCLE is developing a system for the degradation of microplastics, thus mitigating their impact on the environment and human health.
ENZYCLE activities are focused on the selection and development of a set of enzymes that have the potential to degrade non-recyclable plastic fractions such as polyesters and polyolefins. These enzymes are being produced in continuous production, and subsequently validated in the new recycling processes developed within the ENZYCLE framework. The enzymatic treatment provides monomers and polymers that can be reused to produce new materials such as virgin PET, polyurethane and other polyols.
The enzymatic treatment is following 4 phases, related to the different stages of technology development:
- Identification and selection of new enzymes.
- Production of these enzymes on a pilot scale.
- Development of an efficient enzymatic depolymerisation process to depolymerise different plastic fractions such as PET and PE, multilayer packaging and microplastics.
- Validation of the enzymatic recycling processes at pilot scale and of the products obtained.
New technologies and solutions will reduce the amount of non-biodegradable polymers sent to landfill. In addition, it will help solve the problem of microplastics in wastewater by using the technology developed to degrade these pollutants. ENZYCLE will show a new opportunity to create new markets, as the envisaged products and processes are applicable in packaging, transport, building materials or the textile industry. In addition, the project expands the range of raw materials that can be efficiently and sustainably processed by biocatalytic systems.
Within WP1 and WP2, the identification of enzymes to be applied to the recycling processes has taken place. In WP3, scaled-up enzyme production strategies have been defined and optimized in both E. coli and P. pastoris, both with good results in terms of expression level and activity of the enzymes produced, so environmental impacts and economic costs can be reduced.
Within WP4, pre-treatments capable of inducing oxidation in polyolefin fractions and decreasing chrysotile in PET fractions have been developed, as well as enzyme depolymerization technologies for monolayer PET, multilayer materials and microplastics (TRL3-4).
WP5 has advanced in the identification and quantification of the microplastics present in the wastewater streams, a pilot plant has been designed for the separation of these microplastics and the evaluation of the biodegradation processes using bacterial isolates obtained within WP1 and recombinant enzymes developed within WP2 and WP3 for the development of a microplastics degradation system has been performed. Also, the evaluation of microplastics degradation assisted by enzymatic treatments in composting and anaerobic digestion processes has been carried out.
Within WP7, environmental and economic evaluations of the development processes are being done, with the aim of developing processes that are environmentally sustainable as well as industrially competitive.
Within WP8, an intense positioning and dissemination exercise of ENZYCLE has been carried out in all the sectors involved in its value chain, where, together with WP9, a network of synergies with other European projects are being created.
In this sense, during the last 36 months, a number of microbial strains and genes with potential for the biodegradation of polyolefins have been identified, isolated, and are currently being tested in synergy with oxidative treatments as a solution to increase the degradation rates of these polymers of fossil origin.
Technologies are also being developed to enable more cost-effective enzyme production, as well as the development of new processes for the depolymerization of PET containers and multilayers composed of polyesters and polyolefins, and the treatment of microplastics in wastewater streams.
This project is deepening on the scientific and technical understanding of these developments, and exploring new industrial sectors for enzyme applications by creating new sectoral interconnections. In addition, it will foster the creation of new value chains between the biotechnology sector and the chemical and waste management sector, which will have a positive impact in the creation of new jobs, transforming traditional low-skilled jobs into high-skilled jobs.
In environmental terms, the environmental impact will be reduced by reducing GHGs and energy consumption. In addition, landfilling of non-recycled fractions will be reduced, as the processes proposed by Enzycle represent a new paradigm in the treatment of complex waste fractions. Likewise, these types of processes are positioned as safer technologies.