Swelling Behaviour of Polystyrene Microsphere Enhanced PEG-Based Hydrogels in Seawater and Evolution Mechanism of Their Three-Dimensional Network Microstructure

Development of Poly(ether sulfone)/Poly(vinyl alcohol)/Magnesium-Doped Carbon Quantum Dot Scaffolds for Bone Tissue Engineering

Bone tissue engineering plays a critical role in overcoming the limitations of traditional bone grafts and implants by enhancing bone integration and regeneration. In this study, we developed a novel membrane scaffold comprising poly(ether sulfone) (PES), poly(vinyl alcohol) (PVA), and magnesium-doped carbon quantum dots (CQDs.Mg) for potential bone tissue engineering applications. Four distinct scaffold formulations (PE-CM0, PE-CM2, PE-CM3, and PE-CM4) were developed using a film applicator machine. The morphology and porosity of the scaffolds, characterized via scanning electron microscopy (SEM), revealed increased porosity with higher CQDs.Mg content. Fourier transform infrared spectroscopy (FTIR) confirmed the successful integration of functional groups from each component. Water contact angle (WCA) measurements indicated improved hydrophilicity with the addition of CQDs.Mg, which is beneficial for cell attachment and proliferation. Mechanical testing demonstrated that the scaffolds maintained adequate tensile strength and flexibility, with PE-CM3 and PE-CM4 exhibiting superior properties. Swelling assays indicated enhanced water absorption with increased CQDs.Mg content, while 14-day degradation studies showed excellent structural stability. Biocompatibility was also assessed using L929 and NIH3T3 cell lines, with cytotoxicity assays demonstrating nearly 100% cell viability across all samples. These findings suggest that the PES/PVA/CQDs.Mg scaffolds exhibit a promising combination of mechanical robustness, hydrophilicity, and biocompatibility, making them strong candidates for bone tissue engineering applications.

Methyl methacrylate-modified polystyrene microspheres: an effective strategy to enhance the fluorescence of Eu-complexes

The in vitro detection applications of europium complex-doped microspheres mainly rely on strong fluorescence intensity and a well-defined morphology. In this work, using methyl methacrylate-modified polystyrene microspheres has been proven an effective strategy to enhance the fluorescence and morphology of Eu-complexes. The experimental results showed that the modification resulted in the formation of a porous structure within the polystyrene microspheres, enhancing the doping uniformity and facilitating a more significant accumulation of fluorescent molecules. Furthermore, because of their encapsulation ability, microspheres efficiently confine the fluorescent molecules within them. In addition, the nano-scale porous structure endowed the microspheres with enhanced properties without compromising solvent swelling capability, thereby significantly boosting the fluorescence performance of porous PSMMA. In lateral flow immunoassays (LFIAs), PSMMA-Eu microspheres were effectively utilized to detect fentanyl with exceptional sensitivity by capitalizing on these benefits, capable of detecting concentrations as low as 0.10 ng mL-1. This technology has significant potential for rapid point-of-care screening and clinical applications.

Enhanced Hemostatic and Procoagulant Efficacy of PEG/ZnO Hydrogels: A Novel Approach in Traumatic Hemorrhage Management

Managing severe bleeding, particularly in soft tissues and visceral injuries, remains a significant challenge in trauma and surgical care. Traditional hemostatic methods often fall short in wet and dynamic environments. This study addresses the critical issue of severe bleeding in soft tissues, proposing an innovative solution using a polyethylene glycol (PEG)-based hydrogel combined with zinc oxide (ZnO). The developed hydrogel forms a dual-network structure through amide bonds and metal ion chelation, resulting in enhanced mechanical properties and adhesion strength. The hydrogel, exhibiting excellent biocompatibility, is designed to release zinc ions, promoting coagulation and accelerating hemostasis. Comprehensive characterization, including gelation time, rheological properties, microstructure analysis, and swelling behavior, demonstrates the superior performance of the PEG/ZnO hydrogel compared to traditional PEG hydrogels. Mechanical tests confirm increased compression strength and adhesive properties, which are crucial for withstanding tissue dynamics. In vitro assessments reveal excellent biocompatibility and enhanced procoagulant ability attributed to ZnO. Moreover, in vivo experiments using rat liver and tail bleeding models demonstrate the remarkable hemostatic performance of the PEG/ZnO hydrogel, showcasing its potential for acute bleeding treatment in both visceral and peripheral scenarios.