Tian Wenhan, He Guanping, Liu Yuzeng, Guan Juan
School of Materials Science and Engineering, Beihang University, Beijing, 100083, P. R. China.
Department of Orthopedics, Beijing Chaoyang Hospital, Capital Medical University, Beijing, 100020, P. R. China.
Zhongguo Xiu Fu Chong Jian Wai Ke Za Zhi. 2024 Sep 15;38(9):1123-1129. doi: 10.7507/1002-1892.202404120.
To develop a biodegradable implantable bone material with compatible mechanics with the bone tissue, providing a new biomaterial for clinical bone repair and regeneration.
Silk reinforced polycaprolactone composites (SPC) containing 20%, 40%, and 60% silk were prepared by layer-by-layer assembly and hot-pressing technology. Macroscopic morphology was observed and microstructure were observed by scanning electron microscopy, compressive mechanical properties were detected by compression test, surface wettability was detected by surface contact angle test, degradation of materials was observed after soaking in PBS for 180 days, and proliferation of MC3T3-E1 cells was detected by cell counting kit 8 assay. Six Sprague Dawley rats were subcutaneously implanted with polycaprolactone (PCL) and 20%-SPC, respectively. Masson staining was used to analyze the degradation behavior and vascularization effect within 180 days.
The pore defects of the three SPC sections were relatively few. In the range of 20% to 60%, as the silk content increased and the PCL content decreased, the interlayer spacing of silk fabric decreased, and the fibers almost covered the entire cross-section. The compressive modulus and compressive strength of SPC showed an increasing trend, and the compressive modulus of 60%-SPC was slightly lower than that of 40%-SPC. There were significant differences in compressive modulus and compressive strength between the materials ( <0.05). simulated fluid degradation experiments showed that the mass loss of the three types of SPC after 180 days of degradation was within 5%, with the highest mass loss observed in 60%-SPC. The differences in mass loss between the materials were significant ( <0.05). As the silk content increased, the static water contact angle of each material gradually decreased, and all could promote the proliferation of MC3T3-E1 cells. The subcutaneous degradation experiment in rats showed that 20%-SPC began to degrade at 30 days after implantation, and material degradation and vascularization were significant at 180 days, which was in sharp contrast to PCL.
SPC has the mechanical and hydrophilic properties that are compatible with bone tissue. It maintains its mechanical strength for a long time in a simulated body fluid environment , and achieves dynamic synchronization of material degradation, tissue regeneration, and vascularization through the body's immune regulation mechanism . It is expected to provide a new type of implant material for clinical bone repair.
研发一种与骨组织力学性能相匹配的可生物降解植入性骨材料,为临床骨修复与再生提供新型生物材料。
采用层层组装和热压技术制备含20%、40%和60%丝素的丝素增强聚己内酯复合材料(SPC)。观察宏观形态,通过扫描电子显微镜观察微观结构,通过压缩试验检测压缩力学性能,通过表面接触角试验检测表面润湿性,将材料浸泡于PBS中180天后观察材料降解情况,通过细胞计数试剂盒8检测MC3T3-E1细胞增殖情况。分别将聚己内酯(PCL)和20%-SPC皮下植入6只Sprague Dawley大鼠体内。采用Masson染色分析180天内的降解行为和血管化效果。
三个SPC切片的孔隙缺陷相对较少。在20%至60%范围内,随着丝素含量增加、PCL含量降低,丝织物的层间距减小,纤维几乎覆盖整个横截面。SPC的压缩模量和压缩强度呈上升趋势,60%-SPC的压缩模量略低于40%-SPC。材料间的压缩模量和压缩强度存在显著差异(<0.05)。模拟体液降解实验表明,三种类型的SPC在降解180天后质量损失均在5%以内,60%-SPC的质量损失最高。材料间的质量损失差异显著(<0.05)。随着丝素含量增加,各材料的静态水接触角逐渐减小,且均能促进MC3T3-E1细胞增殖。大鼠皮下降解实验表明,20%-SPC在植入后30天开始降解,180天时材料降解和血管化明显,这与PCL形成鲜明对比。
SPC具有与骨组织相匹配的力学性能和亲水性能。在模拟体液环境中能长时间保持其力学强度,并通过机体免疫调节机制实现材料降解、组织再生和血管化的动态同步。有望为临床骨修复提供新型植入材料。
