Role of degrading hydrogels in hepatocellular carcinoma drug delivery applications: A review

Layered double hydroxides for regenerative nanomedicine and tissue engineering: recent advances and future perspectives

With the rapid development of nanotechnology, layered double hydroxides (LDHs) have attracted considerable attention in the biomedical field due to their highly tunable composition and structure, superior biocompatibility, multifunctional bioactivity, and exceptional drug delivery performance. However, a focused and comprehensive review addressing the role of LDHs specifically in tissue regeneration has been lacking. This review aims to fill that gap by providing a systematic and in-depth overview of recent advances in the application of LDHs across various regenerative domains, including bone repair, cartilage reconstruction, angiogenesis, wound healing, and nerve regeneration. Beyond presenting emerging applications, the review places particular emphasis on elucidating the underlying mechanisms through which LDHs exert their therapeutic effects. Although LDHs demonstrate considerable promise in regenerative medicine, their clinical translation remains in its infancy. To address this, we not only provided our insights into the personalized problems that arise in the application of various tissues, but also focused on discussing and prospecting the common challenges in the clinical translation of LDHs. These challenges include optimizing synthesis techniques, enhancing biosafety and stability, improving drug-loading efficiency, designing multifunctional composite materials, and establishing pathways that facilitate the transition from laboratory research to clinical practice.

Cu-MOF-based targeted nanomedicine utilizing biorthogonally catalyzed chemotherapy and chemodynamic therapy with spatiotemporal orchestration to treat hepatocellular carcinoma

A nanomedicine was developed using a Cu-based metal-organic framework (MOF) to co-deliver Cu(I) and prodrugs for targeted biorthogonally catalyzed chemotherapy and chemodynamic therapy of hepatocellular carcinoma.

Rapidly self-crosslinking sodium alginate hydrogel for infected wounds

The risks associated with wound infections are significant, making a snug-fitting hydrogel dressing an optimal choice for wound management. For it, we employed the self-cross-linking method of oxidized sodium alginate (SCSA), incorporating clarithromycin (Cla) and basic fibroblast growth factor (bFGF) to formulate a rapidly forming, bacteriostatic, and wound-healing hydrogel (SCSA@C/b). Bacteriostatic and cytocompatibility assays demonstrated that SCSA@C/b exhibits exceptional antibacterial activity alongside strong biocompatibility. A fractional infected wound model showed that SCSA@C/b accelerated healing of infected wounds by approximately three days compared to the healing time of the control group, with nearly complete wound recovery. H&E staining and SEM analysis of the healed wound sections revealed significant pro-healing effects. Thus, SCSA@C/b is a promising medicinal hydrogel for encouraging wound healing in contaminated areas.