Mechanical and fluid dynamic characteristics of S-type triply periodic minimal surface radial functionally graded bone scaffolds

doi:10.12307/2026.460

Abstract

Abstract: BACKGROUND: The biomimetic design and functional gradient regulation of bone scaffolds are key to improving the efficacy of bone defect repair. Currently, homogeneous scaffolds struggle to balance mechanical load-bearing and material transport, often leading to stress concentration or inadequate nutrient supply after implantation, thus limiting bone regeneration outcomes.
OBJECTIVE: To investigate the differences in mechanical performance, mass transport capacity, and cellular microenvironment construction among Primitive (P-type), Gyroid (G-type), and GP composite scaffold structures.
METHODS: Based on digital light processing and triply periodic minimal surface theory, a Sigmoid function-driven topological gradient algorithm was proposed to fabricate β-calcium silicate/bioglass radially graded scaffolds with single G-type structure, single P-type structure, and GP type composite structure. The performance of the three types of scaffolds was systematically compared through mechanical simulation, fluid dynamics simulation, and wall shear stress analysis.
RESULTS AND CONCLUSION: (1) Finite element analysis showed that the G-type structure scaffold had a uniform stress distribution and the highest maximum Mises stress, while the GP-type composite structure scaffold had the lowest maximum Mises stress and a more uniform stress distribution than the single-structure scaffolds. The P-type structure scaffold had the largest maximum displacement, while the GP-type composite structure scaffold had the smallest maximum displacement. Static compression test results showed that the elastic moduli of the G-type, P-type, and GP-type composite structure scaffolds were 2.90, 3.39, and 3.38 GPa, respectively. Fluid dynamics simulation and permeability tests showed that the permeability of the GP-type composite structure scaffold was 3.4 × 10⁻⁹ m², significantly higher than that of the single-structure scaffolds, and within the optimal range of cancellous bone permeability. The average wall shear stress of the G-type structure scaffold was 0.86 Pa, with a maximum of 1.13 Pa; the average wall shear stress of the P-type structure scaffold was 1.40 Pa, with a maximum of 2.65 Pa; and the average wall shear stress of the GP-type composite structure scaffold was 1.01 Pa, with a maximum of 1.68 Pa, which is within the optimal range for bone regeneration stimulation. (2) The results indicate that the GP-type composite structure scaffold, designed with a biomimetic Haversian system gradient, can effectively balance mechanical support and biological function.

Key words: β-calcium silicate, bioactive glass, bone scaffold, functionally graded scaffold, triply periodic minimal surface, wall shear stress

CLC Number:

Jia Xianghong, Xu Yan, Zhang Xujing. Mechanical and fluid dynamic characteristics of S-type triply periodic minimal surface radial functionally graded bone scaffolds[J]. Chinese Journal of Tissue Engineering Research, 2026, 30(32): 8327-8334.

Figures/Tables 10

.2 支架有限元压缩模拟和机械压缩实验结果静态压缩测试结果表明，3种三周期极小曲面结构支架表现出不同的力学特性(图7)。 G型结构支架的弹性模量为2.90 GPa，压缩强度较高，抗变形能力良好，适合骨组织支撑；P型结构支架的弹性模量为 3.39 GPa，刚度更高，适用于高负荷区域；GP型复合结构支架的弹性模量为3.38 GPa，兼具刚度和弹性恢复能力。应用有限元分析进一步验证了支架的力学性能，3种结构支架的Von Mises应力分布云图，见图8。G型结构支架的应力分布均匀，最大Mises应力为2.73 MPa，适合高负荷分散；P型结构支架的最大Mises应力为2.68 MPa，致密外层增强了力学稳定性；GP型复合结构支架的最大Mises应力最低(2.47 MPa)，显著低于单一结构支架，表明应力分布更均匀，可减少局部应力集中和材料损伤风险。在100 N轴向载荷条件下，3种支架的位移分布云图，见图9。GP型复合结构支架(外侧P型、内侧G型)的最大位移量为2.75×10-2 mm，位移分布呈现明显的轴向梯度特征，底部区域位移最小(< 0.005 mm)，顶部区域位移最大，等值线沿轴向均匀过渡，表明应力传递得到优化，无明显应力集中现象。相比之下，G型结构支架的最大位移量为3.22×10-2 mm，较GP型复合结构支架增大17%；P型结构支架的最大位移量为3.61×10-2 mm，较GP型复合结构支架增大31%。综合分析表明：GP型复合结构支架有效综合了单一结构支架的力学优势，最大位移量最小，该复合设计显著提升了支架的整体刚度和抗变形能力。尽管GP型复合结构支架的弹性模量(3.38 GPa)与P型结构支架(3.39 GPa)相近，但GP型复合结构支架的最大位移量更小且应力分布更为均匀，表明GP型复合结构支架在保持高刚度的同时，其内部的梯度过渡设计有效优化了载荷传递路径，避免了应力集中，从而赋予了结构更高的效能，使该支架在承受相同载荷时变形更小，即“兼具刚度和弹性恢复能力”。 "

2.3 支架渗透性分析结果流速分布(图10)显示，G型结构支架凭借三维贯通孔隙网络展现出均匀的流线分布，流道内未观测到明显涡流或滞流区；P型结构支架呈现明显的流速梯度，外缘致密区流速显著降低，而内层通道流速略有提升；GP型复合结构支架的综合表现最优，流线分布结果显示流体在支架内部保持了相对平稳的流动，特别是G型区域流体流速较为均匀，而P型外层流速略有减缓。压力分布(图11)表明，G型结构支架内部压力场最为均衡，最大压力梯度出现在边缘区域；P型结构支架外缘产生显著压力积聚，形成明显的压力边界层；GP型复合结构支架的压力分布相对最为理想。GP型复合结构支架通过梯度设计保持了较为均匀的压力分布，压力过渡区扩展避免了局部高压区域的形成，形成平缓的液压梯度。渗透性测试结果(图12)显示，3组结构支架渗透率比较差异有显著性意义(P < 0.01)。G型结构支架的渗透率为1.5×10-9 m2， P型结构支架的渗透率最低(1.2×10-9 m2)，而GP型复合结构支架表现出显著的协同增强效应，渗透率最高(3.4×10-9 m2)。GP型复合结构支架的渗透率显著高于G型、P型结构支架(P < 0.01，P < 0.001)，G型结构支架的渗透率高于P型结构支架(P < 0.05)。所有支架的渗透率均处于松质骨渗透率的典型参考范围(0.5× 10-9-5.0×10-9 m2)内，表明具备良好的生物传输潜力。 2.4 支架壁剪切应力分布通过计算流体力学模拟分析了3种三周期极小曲面结构(G型、P型及GP型复合结构)硅灰石支架的壁剪切应力分布特性(图13)，结果显示：G型结构支架因高孔隙率(> 50%)和互通孔道设计流体流动平稳，壁剪切应力平均值为0.86 Pa、最大值为1.13 Pa；P型结构支架因本身横纵相交的通道设计，即使和G型结构支架拥有同样的孔隙率，壁剪切应力平均值为1.40 Pa、最大值为2.65 Pa，分别为G型结构支架的1.63和2.35倍，虽然有相同的孔隙率，相比于P型结构支架，G型结构支架的壁剪切应力分布均匀，均处于有效生物力学刺激区间；GP型复合结构综合G型和P型几何特征，虽然外层P型结构致密设计导致流体路径受限，壁剪切应力最大值反而降低(相比P型结构支架)，为1.68 Pa，壁剪切应力平均值为1.01 Pa，表明GP型复合结构支架的壁剪切应力分布更均衡。 "

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