An ideal guided bone regeneration membrane (GBRM) is expected not only to perform barrier function, but also to enhance osteogenesis and resist bacteria infection. However, currently available membranes have limited bioactivities. To address this challenge, a Janus GBRM (JGM) is designed and fabricated by sequential fractional electrospinning here. The random gelatin fibers loaded with hydroxyapatite (HAP) are designed as the inner face to promote the osteoblasts’ adhesion, proliferation, and osteogenic differentiation, meanwhile the aligned poly(caprolactone) (PCL) nanofibers loaded with poly(methacryloxyethyltrimethyl ammonium chloride‐co‐2‐Aminoethyl 2‐methylacrylate hydrochloride) (P(DMC‐AMA)) are designed as the outer layer to resist epithelia invasion and bacterial infection. In vitro assays reveal that the inner face displays enhanced osteogenic effects, meanwhile the outer surface can regulate the epithelia to spread along the aligned direction and kill the contacted bacteria. Interestingly, the outer face can induce macrophages to polarize toward the M2 phenotype, thus manipulating a favorable osteoimmune environment. These results suggest that the JGM simultaneously meets the critical requirements of barrier, osteogenic, antibacterial, and osteoimmunomodulatory functions. Consequently, the JGM shows better in vivo bone tissue regeneration performance than the commercial Bio‐Gide membrane. This work provides a novel platform to design multi‐functional membranes/scaffolds, displaying great potential applications in tissue engineering.
Nonadherent wound dressings with moisture management and long-lasting antibacterial properties have great significance for wound healing clinically. Herein, a novel multicomponent zwitterionic gradational membrane is fabricated by a co-electrospinning method to realize low biofouling and favorable moisture control as well as longacting antibacterial properties during the chronic woundhealing process. The obtained membrane possesses excellent anti-biofouling performance that effectively resists protein, bacteria, and cell adhesion according to in vitro antifouling evaluation. Furthermore, the gradational co-electrospinning method grants the composite membrane with moisture retention capability which could effectively absorb wound exudate and maintain a moisture healing environment. Additionally, in vivo and in vitro antibacterial investigations reflect that the composite membrane has excellent long-acting antibacterial property. Moreover, in vivo wound healing assessment confirms that the prepared membrane significantly reduces the complete wound healing time than commercial wound dressing. These results highlight such a zwitterionic gradational membrane as an advanced wound dressing to meet the various requirements for chronic wound infection and skin tissue regeneration in clinical applications.
Rapid endothelialization and prevention of restenosis are two vital challenges for the preparation of a small-diameter vascular graft (SDVG), while postoperative infection after implantation is often neglected.
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