In Situ Photo-Crosslinkable Protein Bioadhesive for Bone Graft Fixation.

Journal of dental research Pub Date : 2024-04-01 Epub Date: 2024-02-05 DOI:10.1177/00220345231224709
J Yun, I H Nam, H Lee, Y K Jo, H Lee, S H Jun, H J Cha
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Abstract

Bone grafting is a fundamental dental surgery procedure widely used for implant placement and periodontal disease management treatments. Despite its broad applications, vertical bone augmentation presents unique challenges, including the risk of graft displacement due to gravitational and masticatory forces. Traditional physical stabilization methods introduce additional complexities and risks, underscoring the need for innovative fixation technologies. This study aimed to develop an in situ photo-crosslinkable bioadhesive hydrogel (iPBAH) as a multifunctional bone graft binder to enhance the process of bone reconstruction. The bioadhesive is composed of mussel-derived adhesive protein (MAP) fused with the cell-adhesive peptide RGD. The numerous tyrosine residues in MAP facilitate rapid photo-crosslinking, enabling efficient hydrogel formation using visible blue light. Subsequently, iPBAH underwent comprehensive characterization to evaluate its suitability as a multifunctional bone graft binder. iPBAH efficiently underwent in situ crosslinking through harmless exposure to visible light within minutes and displayed several exceptional properties, including a microporous structure, underwater adhesion, extended durability, high compressive strength, and biocompatibility. In vivo assessments, using male Sprague-Dawley rats, demonstrated that iPBAH binder significantly enhanced bone regeneration in a rat calvarial bone defect model. The in situ crosslinking of the iPBAH binder during bone graft transplantation can effectively fill irregular and complex defect shapes while simultaneously preventing graft material leakage. The improved physical attributes of the bound graft material can enhance its resistance to external forces, thereby ensuring sustained retention over time. Moreover, the interaction between iPBAH and surrounding tissues promotes adhesion and integration of the graft material with host tissues in the defect area. In addition, the included RGD peptide in iPBAH can augment inherent cell recruitment, adhesion, and growth, consequently expediting osteogenesis.

用于骨移植固定的原位光交联蛋白生物粘合剂
植骨是一种基本的牙科手术方法,广泛用于种植体植入和牙周病治疗。尽管应用广泛,但垂直骨增量术也面临着独特的挑战,包括因重力和咀嚼力而导致移植骨移位的风险。传统的物理稳定方法带来了额外的复杂性和风险,突出了对创新固定技术的需求。本研究旨在开发一种原位光交联生物粘合剂水凝胶(iPBAH),作为一种多功能骨移植物粘合剂,以改善骨重建过程。这种生物粘合剂由贻贝源粘合蛋白(MAP)与细胞粘合肽 RGD 融合而成。MAP 中的大量酪氨酸残基有助于快速光交联,从而在可见蓝光下高效形成水凝胶。iPBAH 可在数分钟内通过无害的可见光照射实现原位交联,并显示出多种优异特性,包括微孔结构、水下粘附性、持久性、高抗压强度和生物相容性。使用雄性 Sprague-Dawley 大鼠进行的体内评估表明,iPBAH 粘合剂可显著促进大鼠腓骨缺损模型中的骨再生。在骨移植过程中,iPBAH 粘合剂的原位交联可有效填充不规则和复杂的缺损形状,同时防止移植材料渗漏。粘合后的移植物材料物理属性得到改善,可增强其抵抗外力的能力,从而确保长期的持续保留。此外,iPBAH 与周围组织的相互作用还能促进移植材料与缺损区域宿主组织的粘附和整合。此外,iPBAH 中的 RGD 肽还能增强固有细胞的募集、粘附和生长,从而加快成骨过程。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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