Recent Advances in Solid-State Modification for Thermoplastic Polymers: A Comprehensive Review.

This review introduces groundbreaking insights in polymer science, specifically spotlighting a novel review of the solid-state modification (SSM) approach of thermoplastic polymers, a method not extensively explored. Unlike traditional melt polymer modification, SSM stands out by incorporating monomers or oligomers into the amorphous phase of polymers through innovative exchange reactions. The background of the study places thermoplastics within the context of their increased use over the past century, highlighting their versatility in various applications and the associated environmental and health concerns due to certain additives. The results section outlines the unique aspects of SSM and its increasing recognition for its potential to enhance material performance in areas such as catalysts and composites. It also discusses the application of SSM in modifying different thermoplastic polymers, highlighting various studies demonstrating the method's effectiveness in altering polymer properties. Finally, this work emphasizes SSM's importance in environmental sustainability and its potential in the recycling and upcycling of plastic materials. It acknowledges the challenges and future perspectives in the field, particularly regarding the scalability of SSM techniques for industrial applications and their role in advancing a circular economy in the polymer industry.

Chitosan/starch beads as bioinoculants carrier: long-term survival of bacteria and plant growth promotion.

Immobilization of microorganisms in biodegradable polymeric matrices constitutes a promising technology for plant growth promoting to overcome the challenging conditions of the rhizosphere. Previously, we demonstrated that beads prepared from blends of chitosan/starch of analytical grades ionically cross-linked are useful carriers for Azospirillum brasilense and Pseudomonas fluorescens. The aims of this work were to study A. brasilense Az39 and P. fluorescens ZME4 immobilization in industrial quality beads produced with a blend of chitosan/starch, to assess bacterial survival during long-term storage and biofilm distribution in the beads. We also proposed to analyze the consortia root colonization and its performance as plant growth-promoting bioinoculants compared to liquid counterpart. Our results revealed that A. brasilense Az39 and P. fluorescens ZME4 can coexist in industrial grade chitosan/starch beads, and this mixed immobilization benefits the survival rates of both species, even for more than a year under shelf storage. Confocal laser scanning microscopy with fluorescent dyed strains showed that both species remain mainly in different locations inside and over the beads. Additionally, maize seed treatment with beads-loaded bacteria resulted in growth promotion of roots in a similar manner than traditional liquid-based inoculation. The evidence collected here demonstrate that low-cost chitosan/starch beads are a suitable carrier for bacteria consortia and could be a reliable alternative to liquid inoculation in agronomic practices with additional benefits for industrial management. KEY POINTS: • Mixed immobilization increases bacterial survival in chitosan/starch industrial beads • Beads increase competence of bacteria in rhizosphere of maize • Inoculation mediated by beads promotes plant growth of maize.