Laboratorio de Estudios Cristalográficos, IACT-CSIC-UGR, Avda. Las Palmeras, no. 4, Armilla, Granada, E-18100, Spain.
Instituto de Investigación Biosanitaria ibs. Granada, University of Granada, Granada, E-18014, Spain.
Macromol Biosci. 2021 Mar;21(3):e2000319. doi: 10.1002/mabi.202000319. Epub 2020 Dec 28.
This work explores in depth the simultaneous self-assembly and mineralization of type I collagen by a base-acid neutralization technique to prepare biomimetic collagen-apatite fibrils with varying mineralization extent and doped with luminescent bactericidal Tb ions. Two variants of the method are tested: base-acid titration, a solution of Ca(OH) is added dropwise to a stirred solution containing type I collagen dispersed in H PO ; and direct mixing, the Ca(OH) solution is added by fast dripping onto the acidic solution. Only the direct mixing variant yielded an effective control of calcium phosphate polymorphism. Luminescence spectroscopy reveals the long luminescence lifetime and high relative luminescence intensity of the Tb -doped materials, while two-photon confocal fluorescence microscopy shows the characteristic green fluorescence light when using excitation wavelength of 458 nm, which is not harmful to bone tissue. Cytotoxicity/viability tests reveal that direct mixing samples show higher cell proliferation than titration samples. Additionally, osteogenic differentiation essays show that all mineralized fibrils promote the osteogenic differentiation, but the effect is more pronounced when using samples prepared by direct mixing, and more notably when using the Tb -doped mineralized fibrils. Based on these findings it is concluded that the new nanocomposite is an ideal candidate for bone regenerative therapy.
本工作深入探索了通过酸碱中和技术使 I 型胶原同时自组装和矿化,以制备具有不同矿化程度的仿生胶原-磷灰石原纤维,并掺杂发光杀菌 Tb 离子。测试了两种方法变体:酸碱滴定,将 Ca(OH)溶液逐滴加入到含有分散在 H PO 中的 I 型胶原的搅拌溶液中;和直接混合,将 Ca(OH)溶液快速滴加到酸性溶液中。只有直接混合变体才能有效控制磷酸钙多晶型性。发光光谱揭示了 Tb 掺杂材料的长荧光寿命和高相对荧光强度,而双光子共聚焦荧光显微镜在使用 458nm 激发波长时显示出特征的绿色荧光,对骨组织无害。细胞毒性/活力测试表明,直接混合样品的细胞增殖率高于滴定样品。此外,成骨分化试验表明所有矿化纤维都促进成骨分化,但直接混合制备的样品效果更为明显,特别是使用 Tb 掺杂的矿化纤维时更为明显。基于这些发现,可以得出结论,新型纳米复合材料是骨再生治疗的理想候选材料。