Catechol-modified chitosan hydrogel containing PLGA microspheres loaded with triclosan and chlorhexidine: a sustained-release antibacterial system for urinary catheters.

Blockage and infection are common in hospitals, especially with long-term indwelling catheters, due to bacterial adhesion, colonization, and other reasons. A drug-sustained-release antibacterial coating for urinary catheters was described in this paper. Chlorhexidine (CHX) and triclosan (TCS) were encapsulated in poly(lactic-co-glycolic acid) microspheres and mixed with a modified chitosan hydrogel deposited on the surface of silicone rubber. The results showed that drugs can be released continuously more than 35 days. Catechol-modified chitosan (Chi-C) hydrogel was successful synthesized according to FT-IR and UV spectrophotometry, as well as 1H NMR. Furthermore, the coating with CHX and TCS presented stable antibacterial ability compared to the other groups. The results of CCK-8 revealed that the coating was cytotoxic-free and had a wide range of applications. The findings could provide a new drug sustained-release system and hydrogel-microsphere assembly for urinary catheters. HighlightsThe microspheres presented a sustained release more than 40 days with a remarkable initial burst release.The microspheres/catechol-modified chitosan (Chi-C)/silicon rubber system emerged stable binding ability in liquid environment more than 14 days.The Chi-C/chlorhexidine (CHX)+triclosan (TCS) microspheres system presented better antimicrobial property for entire experiment period.The coated samples showed no significant difference for relative growth rate (RGR) compared to different groups.

Promoting neurovascularized bone regeneration with a novel 3D printed inorganic-organic magnesium silicate/PLA composite scaffold.

Critical-size bone defect repair presents multiple challenges, such as osteogenesis, vascularization, and neurogenesis. Current biomaterials for bone repair need more consideration for the above functions. Organic-inorganic composites combined with bioactive ions offer significant advantages in bone regeneration. In our work, we prepared an organic-inorganic composite material by blending polylactic acid (PLA) with 3-aminopropyltriethoxysilane (APTES)-modified magnesium silicate (A-M2S) and fabricated it by 3D printing. With the increase of A-M2S proportion, the hydrophilicity and mineralization ability showed an enhanced trend, and the compressive strength and elastic modulus were increased from 15.29 MPa and 94.61 MPa to 44.30 MPa and 435.77 MPa, respectively. Furthermore, A-M2S/PLA scaffolds not only exhibited good cytocompatibility of bone marrow mesenchymal stem cells (BMSCs), human umbilical vein endothelial cells (HUVECs), and Schwann cells (SCs), but also effectively promoted osteogenesis, angiogenesis, and neurogenesis in vitro. After implanting 10% A-M2S/PLA scaffolds in vivo, the scaffolds showed the most effective repair of cranium defects compared to the blank and control group (PLA). Additionally, they promoted the secretion of proteins related to bone regeneration and neurovascular formation. These results provided the basis for expanding the application of A-M2S and PLA in bone tissue engineering and presented a novel concept for neurovascularized bone repair.