材料科学
生物相容性
生物医学工程
骨愈合
固定(群体遗传学)
复合材料
无定形磷酸钙
骨折
生物力学
矿化(土壤科学)
人造骨
骨病理学
肿胀 的
骨形成
断裂(地质)
各向异性
牙科
钙
髁突
机械强度
生物材料
作者
Chenchen Lu,Yue Wang,Renxin Chen,Chenglong Wang,Hehe Wang,Lingyu Zeng,Haotian Chu,Jingfeng Li,Chunyu Chang
摘要
ABSTRACT The use of resorbable screws for fracture fixation offers significant advantages over traditional metal implants, including the elimination of secondary surgery and the reduction of stress shielding. However, current resorbable screws are clinically limited by inflammatory responses, inappropriate degradation rates, and insufficient osteogenic activity. Herein, inspired by natural bone tissue, high‐strength resorbable screws are developed through sequential pre‐stretching, solvent exchanging, air drying, and machining of mineralized chitin hydrogels. The amorphous calcium phosphate gradually transforms into a rod‐shaped hydroxyapatite in alkaline gel networks during the mineralization process. The anisotropic structure of the screws produced by pre‐stretching the chitin/HAP hydrogel significantly enhances their axial mechanical strength and radial swelling performance. This improvement enables the screws to function as “expansion screws”, facilitating fracture fixation in practical applications. The resulting chitin/HAP screws demonstrate excellent biocompatibility and enhanced osteogenic differentiation capability. The in vivo assessment in the rat femoral condyle indicates that the chitin/HAP screws are initially firmly fixed within the bone tunnel, then gradually degrade and are replaced by new bone without causing any inflammation. Our chitin/HAP screws exhibit appropriate biodegradability, excellent biocompatibility, and support normal bone remodeling, highlighting their potential applications in internal fracture fixation.
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