三维电沉积在多孔纳米纤维支架上的磷酸钙及其对钙的控制释放用于骨再生。
Three-Dimensional Electrodeposition of Calcium Phosphates on Porous Nanofibrous Scaffolds and Their Controlled Release of Calcium for Bone Regeneration.
机构信息
Department of Biologic and Materials Sciences, University of Michigan, Ann Arbor, Michigan 48109, United States.
Department of Biomedical Engineering, University of Michigan, Ann Arbor, Michigan 48109, United States.
出版信息
ACS Appl Mater Interfaces. 2020 Jul 22;12(29):32503-32513. doi: 10.1021/acsami.0c11003. Epub 2020 Jul 13.
Abstract
To mimic the bone matrix of mineralized collagen and to impart microporous structure to facilitate cell migration and bone regeneration, we developed a nanofibrous (NF) polymer scaffold with highly interconnected pores and three-dimensional calcium phosphate coating utilizing an electrodeposition technique. The mineral content, morphology, crystal structure, and chemical composition could be tailored by adjusting the deposition temperature, voltage, and duration. A higher voltage and a higher temperature led to a greater rate of mineralization. Furthermore, nearly linear calcium releasing kinetics was achieved from the mineralized 3D scaffolds. The releasing rate was controlled by varying the initial electrodeposition conditions. A higher deposition voltage and temperature led to slower calcium release, which was associated with the highly crystalline and stoichiometric hydroxyapatite content. This premineralized NF scaffold enhanced bone regeneration over the control scaffold in a subcutaneous implantation model, which was associated with released calcium ions in facilitating osteogenic cell proliferation.
摘要
为了模拟矿化胶原的骨基质并赋予其微孔结构以促进细胞迁移和骨再生,我们利用电沉积技术开发了一种具有高度互联孔和三维磷酸钙涂层的纳米纤维(NF)聚合物支架。通过调整沉积温度、电压和时间,可以调整矿化含量、形态、晶体结构和化学成分。更高的电压和更高的温度导致更高的矿化速率。此外,从矿化的 3D 支架中实现了近乎线性的钙释放动力学。通过改变初始电沉积条件可以控制释放速率。更高的沉积电压和温度导致较慢的钙释放,这与高结晶度和化学计量羟基磷灰石含量有关。这种预矿化 NF 支架在皮下植入模型中增强了骨再生,这与促进成骨细胞增殖的释放钙离子有关。
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