Microplastic biodegradation and environmental safety: From microbial mechanisms to engineered systems and circular bio-based implementation

Microplastics, defined as synthetic polymer particles smaller than 5 mm, have become pervasive environmental contaminants across aquatic, terrestrial, and atmospheric systems. Their chemical stability, hydrophobicity, and resistance to natural attenuation limit the effectiveness of conventional physical and chemical removal technologies. Microbial and enzymatic approaches have therefore emerged as promising strategies for microplastic transformation and controlled degradation, although complete mineralization is not consistently achieved. Degradation outcomes vary widely depending on polymer structure, environmental conditions, and microbial community dynamics, and incomplete depolymerization may generate intermediate products with distinct ecological implications. This review provides a mechanistically integrated analysis of microplastic biodegradation, explicitly distinguishing surface modification, depolymerization, biotransformation, and complete mineralization. Abiotic preconditioning processes, enzyme–polymer interactions, kinetic constraints in real environmental matrices, and the functional roles of single strains, microbial consortia, and genetically engineered systems are examined. Particular attention is given to environmental safety considerations, including degradation byproducts, additive release, horizontal gene transfer risks, and biosafety containment strategies. The feasibility of integrating microbial degradation into circular bio-based recycling frameworks is critically assessed through translational strategies, pilot-scale considerations, and life cycle perspectives. Although advances in enzyme engineering and synthetic biology have significantly improved depolymerization efficiency under controlled conditions, scalability, regulatory compliance, and ecosystem-level risk assessment remain central challenges. Bridging mechanistic insight with environmental realism and regulatory preparedness is essential to ensure that biodegradation strategies reduce environmental burden without redistributing ecological risk. • Integrates microbial, enzymatic and abiotic mechanisms of microplastic degradation • Links biodegradation efficiency with environmental safety and ecotoxicology • Evaluates engineered enzymes and microbial systems for plastic depolymerization • Analyzes factors controlling microplastic biodegradation across environments • Explores circular bioeconomy pathways for plastic bioremediation and recycling