Regeneration of periodontal bone defects has long posed a significant challenge to clinicians. Traditional guided bone regeneration (GBR) membranes have a single function, making it difficult to achieve immunoregulation and bone regeneration under the inflammatory and infection-prone conditions of diabetes. To address this, we developed a “one-step synergistic electro-assembly” technique and electrically controlled assembly techniques to engineer a Janus collagen membrane with a spatially programmable, biphasic structure. This novel manufacturing process utilizes electrical signals to simultaneously control collagen self-assembly into a gradient Janus structure and chemically reduce graphene oxide (GO) via Ferulic Acid (FA) in situ. This creates a seamlessly integrated “conductive-antioxidant” interface without the need for toxic reducing agents or physical lamination. It enhances the applicability of collagen membranes in scenarios, where they carry and sustainably release bioactive drugs and promote the regeneration of both soft and hard tissues. Here, this dual-function membrane integrates osteoinductive and barrier properties within a single construct, enabling ordered, site-specific release of ferulic acid (FA) and graphene oxide (GO). The FA side (barrier membrane layer) confers antioxidant and anti-inflammatory effects, while the FA/GO-enhanced osteogenic side (inductive membrane layer) increases electrical conductivity, promoting electrostimulated bone formation. Meanwhile, the controlled release of FA and GO exerts synergistic antibacterial, anti-inflammatory, and osteogenic effects, ultimately enhancing periodontal bone regeneration in diabetic rat models. The inductive membrane layer enhanced M2 macrophage polarization to modulate the immune microenvironment, and activated Ca 2+ signaling and the TGF-β/Smad pathway to promote osteogenic differentiation of mesenchymal stem cells. These findings demonstrate that the electrically assembled Janus membrane offers a promising platform for multifunctional tissue repair, advancing the clinical repair of complex bone defects under inflammatory conditions.
Li et al. (Sun,) studied this question.
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