Jia Mingyu, Chen Zhihong, Zhou Huajian, Zhang Yukang, Wu Min
Department of Orthopedics, the First Affiliated Hospital of Bengbu Medical University, Bengbu Anhui, 233000, P. R. China.
Department of Orthopedics, Sihong Branch Jinting Hospital, Sihong Jiangsu, 223900, P. R. China.
Zhongguo Xiu Fu Chong Jian Wai Ke Za Zhi. 2025 Sep 15;39(9):1203-1211. doi: 10.7507/1002-1892.202506018.
To investigate the antioxidant and osteogenic induction capabilities of calcium phosphate nanoflowers (hereinafter referred to as nanoflowers) at different concentrations.
Nanoflowers were prepared using gelatin, tripolyphosphate, and calcium chloride. Their morphology, microstructure, elemental composition and distribution, diameter, and molecular constitution were characterized using scanning electron microscopy, transmission electron microscopy, Fourier transform infrared spectroscopy, and energy-dispersive spectroscopy. Femurs and tibias were harvested from twelve 4-week-old Sprague Dawley rats, and bone marrow mesenchymal stem cells (BMSCs) were isolated and cultured using the whole bone marrow adherent method, followed by passaging. The third passage cells were identified as stem cells by flow cytometry and then co-cultured with nanoflowers at concentrations of 0, 0.4, 0.8, 1.2, 1.6, 2.0, 2.4, 2.8, 3.2, and 3.6 mg/mL. Cell counting kit 8 (CCK-8) assay was performed to screen for the optimal concentration that demonstrated the best cell viability, which was subsequently used as the experimental concentration for further studies. After co-culturing BMSCs with the screened concentration of nanoflowers, the biocompatibility of the nanoflowers was verified through live/dead cell staining, scratch assay, and cytoskeleton staining. The antioxidant capacity was assessed by using reactive oxygen species (ROS) fluorescence staining. The osteoinductive ability was evaluated via alkaline phosphatase (ALP) staining, alizarin red staining, and immunofluorescence staining of osteocalcin (OCN) and Runt-related transcription factor 2 (RUNX2). All the above indicators were compared with the control group of normally cultured BMSCs without the addition of nanoflowers.
Scanning electron microscopy revealed that the prepared nanoflowers exhibited a flower-like structure; transmission electron microscopy scans discovered that the nanoflowers possessed a multi-layered structure, and high-magnification images displayed continuous atomic arrangements, with the nanoflower diameter measuring (2.00±0.25) μm; energy-dispersive spectroscopy indicated that the nanoflowers contained elements such as C, N, O, P, and Ca, which were uniformly distributed across the flower region; Fourier transform infrared spectroscopy analyzed the absorption peaks of each component, demonstrating the successful preparation of the nanoflowers. Through CCK-8 screening, the concentrations of 0.8, 1.2, and 1.6 mg/mL were selected for subsequent experiments. The live/dead cell staining showed that nanoflowers at different concentrations exhibited good cell compatibility, with the 1.2 mg/mL concentration being the best (<0.05). The scratch assay results indicated that the cell migration ability in the 1.2 mg/mL group was superior to the other groups (<0.05). The cytoskeleton staining revealed that the cell morphology was well-extended in all concentration groups, with no significant difference compared to the control group. The ROS fluorescence staining demonstrated that the ROS fluorescence in all concentration groups decreased compared to the control group after lipopolysaccharide induction (<0.05), with the 1.2 mg/mL group showing the weakest fluorescence. The ALP staining showed blue-purple nodular deposits around the cells in all groups, with the 1.2 mg/mL group being significantly more prominent. The alizarin red staining displayed orange-red mineralized nodules around the cells in all groups, with the 1.2 mg/mL group having more and denser nodules. The immunofluorescence staining revealed that the expressions of RUNX2 and OCN proteins in all concentration groups increased compared to the control group, with the 1.2 mg/mL group showing the strongest protein expression (<0.05).
The study successfully prepares nanoflowers, among which the 1.2 mg/mL nanoflowers exhibits excellent cell compatibility, antioxidant properties, and osteogenic induction capability, demonstrating their potential as an artificial bone substitute material.
研究不同浓度磷酸钙纳米花(以下简称纳米花)的抗氧化及成骨诱导能力。
用明胶、三聚磷酸钠和氯化钙制备纳米花。采用扫描电子显微镜、透射电子显微镜、傅里叶变换红外光谱和能谱对其形态、微观结构、元素组成与分布、直径及分子结构进行表征。从12只4周龄的Sprague Dawley大鼠中获取股骨和胫骨,采用全骨髓贴壁法分离培养骨髓间充质干细胞(BMSCs),随后传代。通过流式细胞术将第3代细胞鉴定为干细胞,然后分别与浓度为0、0.4、0.8、1.2、1.6、2.0、2.4、2.8、3.2和3.6 mg/mL的纳米花共培养。采用细胞计数试剂盒8(CCK-8)检测筛选出细胞活力最佳的最佳浓度,随后将其作为进一步研究的实验浓度。将BMSCs与筛选出浓度的纳米花共培养后,通过活/死细胞染色、划痕实验和细胞骨架染色验证纳米花的生物相容性。采用活性氧(ROS)荧光染色评估抗氧化能力。通过碱性磷酸酶(ALP)染色、茜素红染色以及骨钙素(OCN)和Runt相关转录因子2(RUNX2)的免疫荧光染色评估成骨诱导能力。将上述所有指标与未添加纳米花的正常培养BMSCs对照组进行比较。
扫描电子显微镜显示制备的纳米花呈花状结构;透射电子显微镜扫描发现纳米花具有多层结构,高倍图像显示原子排列连续,纳米花直径为(2.00±0.25)μm;能谱表明纳米花含有C、N、O、P和Ca等元素,这些元素在花区域均匀分布;傅里叶变换红外光谱分析了各组分的吸收峰,表明纳米花制备成功。通过CCK-8筛选,选择0.8、1.2和1.6 mg/mL的浓度用于后续实验。活/死细胞染色显示不同浓度的纳米花均具有良好的细胞相容性,其中1.2 mg/mL浓度最佳(P<0.05)。划痕实验结果表明,1.2 mg/mL组的细胞迁移能力优于其他组(P<0.05)。细胞骨架染色显示,所有浓度组的细胞形态均伸展良好,与对照组相比无显著差异。ROS荧光染色表明,脂多糖诱导后,所有浓度组的ROS荧光均低于对照组(P<0.05),其中1.2 mg/mL组荧光最弱。ALP染色显示所有组细胞周围均有蓝紫色结节状沉积,1.2 mg/mL组尤为明显。茜素红染色显示所有组细胞周围均有橙红色矿化结节,1.2 mg/mL组的结节更多、更密集。免疫荧光染色显示,所有浓度组RUNX2和OCN蛋白的表达均高于对照组,1.2 mg/mL组蛋白表达最强(P<0.05)。
本研究成功制备了纳米花,其中1.2 mg/mL的纳米花具有优异的细胞相容性、抗氧化性能和成骨诱导能力,表明其有望成为一种人工骨替代材料。
