Toughening by Nanodroplets: Polymer–Droplet Biocomposite with Anomalous Toughness

In-situ formation of thermo-responsive petal-like cellulose nanocrystals hybridized particles towards optimizing mechanical, rheological and dielectric properties of polylactic acid blends

Enhancing the toughness of biodegradable polylactic acid (PLA) blends with minimal filler content meanwhile preserving their thermomechanical properties remains a highly desirable objective. Here, through a simple in situ mixing of PLA with cellulose nanocrystals (CNC) and cellulose nanocrystal nanofluids (CNCfs), the electrostatic interaction between CNCfs (+22.6 mv) and CNC (-9.07 mv) formed petal-like hybridized particles with CNCfs as the core and CNC particles as the outer layer. The rheological tests indicated a significant reduction in the zero-shear viscosity and storage modulus of PLA/CNCfs blends, while the viscosity of PLA/CNCfs@CNC slightly decreased but retained its storage modulus compared to pure PLA. The optimized PLA/CNCfs@CNC blends not only exhibited excellent melt processing performance, but also increased the elongation at break (increased by 184 % and 375 % at 8 °C and 45 °C, respectively) and enhanced toughness remarkably (increased by 3.5 and 3.3-fold at 8 °C and 45 °C, respectively) meantime retaining the modulus with 1 GPa. The addition of CNCfs@CNC hardly affects the glass transition temperature and thermo-mechanical properties of PLA. The dielectric properties of PLA/CNCfs1.0/CNC2.0 blends were maximized at 1000 Hz, reaching a value of 21, which can be attributed to the synergistic effect of multilayer interfacial polarization.

Colombian Sustainability Perspective on Fused Deposition Modeling Technology: Opportunity to Develop Recycled and Biobased 3D Printing Filaments

In the context of the preservation of natural resources, researchers show a growing interest in developing eco-friendly materials based on recycled polymers and natural fiber biocomposites to minimize plastic and agroindustrial waste pollution. The development of new materials must be integrated within the circular economy concepts to guarantee sustainable production. In parallel, fused deposition modeling, an additive manufacturing technology, provides the opportunity to use these new materials in an efficient and sustainable manner. This review presents the context of plastics and agro-industrial fiber pollution, followed by the opportunity to give them added value by applying circular economy concepts and implementing these residues to develop new materials for the manufacture of fused deposition modeling 3D printing technique feedstock. Colombian perspective is highlighted since 3D printing technology is growing there, and Colombian biodiversity represents a high reservoir of materials. Also, recycling in Colombia promotes compliance with the 2030 Agenda and the Sustainable Development Goals.

Green Polymer Nanocomposites for Skin Tissue Engineering

Fabrication of an appropriate skin scaffold needs to meet several standards related to the mechanical and biological properties. Fully natural/green scaffolds with acceptable biodegradability, biocompatibility, and physiological properties quite often suffer from poor mechanical properties. Therefore, for appropriate skin tissue engineering and to mimic the real functions, we need to use synthetic polymers and/or additives as complements to green polymers. Green nanocomposites (either nanoscale natural macromolecules or biopolymers containing nanoparticles) are a class of scaffolds with acceptable biomedical properties window (drug delivery and cardiac, nerve, bone, cartilage as well as skin tissue engineering), enabling one to achieve the required level of skin regeneration and wound healing. In this review, we have collected, summarized, screened, analyzed, and interpreted the properties of green nanocomposites used in skin tissue engineering and wound dressing. We particularly emphasize the mechanical and biological properties that skin cells need to meet when seeded on the scaffold. In this regard, the latest state of the art studies directed at fabrication of skin tissue and bionanocomposites as well as their mechanistic features are discussed, whereas some unspoken complexities and challenges for future developments are highlighted.