Silicon Enhances Functional Mitochondrial Transfer to Improve Neurovascularization in Diabetic Bone Regeneration

Silicon Enhances Functional Mitochondrial Transfer to Improve Neurovascularization in Diabetic Bone Regeneration

Abstract Diabetes mellitus is a metabolic disorder associated with an increased risk of fractures and delayed fracture healing, leading to a higher prevalence of bone defects. Recent advancements in strategies aim at regulating immune responses and enhancing neurovascularization have not met expecta...

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Main Authors: Yu‐Xuan Ma, Chen Lei, Tao Ye, Qian‐Qian Wan, Kai‐Yan Wang, Yi‐Na Zhu, Ling Li, Xu‐Fang Liu, Long‐Zhang Niu, Franklin R. Tay, Zhao Mu, Kai Jiao, Li‐Na Niu
Format: Article
Language:English
Published: Wiley 2025-05-01
Series:Advanced Science
Subjects:
bioactive silicon
diabetic bone defects
macrophages
mitochondrial transfer
neural
vascular
Online Access:https://doi.org/10.1002/advs.202415459
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Summary:Abstract Diabetes mellitus is a metabolic disorder associated with an increased risk of fractures and delayed fracture healing, leading to a higher prevalence of bone defects. Recent advancements in strategies aim at regulating immune responses and enhancing neurovascularization have not met expectations. This study demonstrates that a silicon‐based strategy significantly enhances vascularization and innervation, thereby optimizing the repair of diabetic bone defects. Silicon improves mitochondrial function and modulates mitochondrial fission dynamics in macrophages via the Drp1‐Mff signaling pathway. Subsequently, functional mitochondria are transferred from macrophages to endothelial and neuronal cells through microvesicles, providing a protective mechanism for blood vessels and peripheral nerves during early wound healing. On this basis, an optimized strategy combining a silicified collagen scaffold with a Drp1‐Fis1 interaction inhibitor is used to further regulate mitochondrial fission in macrophages and enhance the trafficking of functional mitochondria into stressed receptor cells. In diabetic mice with critical‐sized calvarial defects, the silicon‐based treatment significantly promotes vessel formation, nerve growth, and mineralized tissue development. These findings provide therapeutic insights into the role of silicon in promoting diabetic bone regeneration and highlight the importance of intercellular communication in diabetic conditions.
ISSN:2198-3844

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