We can't find the internet
Attempting to reconnect
Something went wrong!
Hang in there while we get back on track
Embedding an esterase mimic inside polyesters to realize rapid and complete degradation without compromising their utility
Summary
Researchers developed an innovative approach to accelerating plastic degradation by embedding a molecular mimic of the enzyme esterase directly inside a biodegradable polyester material. This allowed the plastic to break down rapidly and completely during composting without compromising its performance during normal use. The study presents a practical strategy for managing post-consumer biodegradable plastics and improving composting efficiency.
This work presents an innovative method to manage post-consumer biodegradable plastics by embedding a molecular mimic of esterase into poly(butylene terephthalate/adipate), which holds the potential to elevate composting efficiency and capacity.
Sign in to start a discussion.
More Papers Like This
Enhancing environmmental biodegradation of polyesters
Researchers investigated strategies to enhance the environmental biodegradation of polyester-based packaging polymers, proposing two pathways: a smart material design concept that incorporates degradation-facilitating additives, and an enzymatic approach using engineered polyesterases. The work addresses the practical challenge that biodegradable polyesters degrade too slowly under real environmental conditions, generating persistent microplastic fragments, and aims to close this gap between certified biodegradability and actual environmental breakdown.
Near-complete depolymerization of polyesters with nano-dispersed enzymes
Researchers developed a method to embed tiny enzyme particles inside biodegradable plastics, enabling the plastics to break down almost completely in ordinary compost and tap water within days. This approach achieved up to 98% conversion of the plastic back to small molecules, avoiding the creation of microplastic fragments that occur with conventional degradation. The technology could help solve the microplastic pollution problem by ensuring that biodegradable plastics actually decompose fully rather than fragmenting into harmful microplastic particles.
Thermal Embedding of Humicola insolens Cutinase: A Strategy for Improving Polyester Biodegradation in Seawater
Researchers embedded a commercially available enzyme into biodegradable polyester films to accelerate their breakdown in seawater. The study found that these enzyme-embedded films achieved biodegradability equal to or greater than cellulose standards in natural seawater, while maintaining their original physical properties. This approach suggests a practical strategy for reducing the contribution of slow-degrading biodegradable plastics to marine microplastic pollution.
Enhancing environmmental biodegradation of polyesters
Researchers investigated two pathways for enhancing the environmental biodegradation of polyester-based packaging polymers: a smart additive-based material design concept and an engineered enzymatic degradation approach using optimised polyesterases. The work addresses the gap between the theoretical biodegradability of polyesters like PLA and PBAT and their actual slow degradation in natural environments, which leads to persistent microplastic generation during the end-of-life phase.
Synergistic Enzyme Mixtures to Realize Near‐Complete Depolymerization in Biodegradable Polymer/Additive Blends
Researchers developed synergistic enzyme mixtures capable of achieving near-complete depolymerization of biodegradable polyester blends containing additives, demonstrating that nanoscopically embedded enzymes can be programmed for processive chain-end depolymerization with degradation rates dependent on polymer morphology.