Biomineralization Precursor Carrier System Based on Carboxyl- Functionalized Large Pore Mesoporous Silica Nanoparticles

Bone and teeth are derived from intrafibrillarly mineralized collagen fibrils as the second level of hierarchy.According to polymer-induced liquid-precursor process,using amorphous calcium phosphate precursor(ACP)is able to achieve intrafibrillar mineralization in the case of bone biomineral in vitro.Therefore,ACP precursors might be blended with any osteoconductive scaffold as a promising bone formation supplement for in-situ remineralization of collagens in bone.In this study,mesoporous silica nanoparticles with carboxyl-functionalized groups and ultra large-pores have been synthesized and used for the delivery of liquid like biomimetic precursors(ACP).The precursor delivery capacity of the nanoparticles was verified by the precursor release profile and successful mineralization of 2D and 3D collagen models.The nanoparticles could be completely degraded in 60 days and exhibited good biocompatibility as well.The successful translational strategy for biomineralization precursors showed that biomineralization precursor laden ultra large pore mesoporous silica possessed the potential as a versatile supplement in demineralized bone formation through the induction of intrafibrillar collagen mineralization.

羧基化聚酰胺——胺/无定形磷酸钙镁诱导胶原纤维再矿化的研究

目的:制备并表征羧基化聚酰胺—胺稳定的无定形磷酸钙镁纳米复合体(PAMAM-COOH/ACMP),并初步验证其诱导人牙本质胶原纤维再矿化的能力。方法:在水溶液中制备PAMAM-COOH/ACMP并分别使用傅里叶变换红外光谱(FTIR)、透射电子显微镜(TEM),选区电子衍射(SAED),能谱面扫描(EDX-Mapping)进行表征,依次获得化学结构、形貌、物相及元素分布信息。在仿生条件下,利用PAMAM-COOH/ACMP诱导完全脱矿的人牙本质胶原纤维模型再矿化,对牙本质进行FTIR、X射线衍射(XRD)及扫描电子显微镜(SEM)检测以评价再矿化效果。结果:FTIR检测结果提示,PAMAM-COOH/ACMP中存在磷酸根基团,碳氮键和酰胺键。TEM、EDX-Mapping及SEAD结果显示,PAMAM-COOH/ACMP为直径60~90 nm的近似圆形纳米非晶相颗粒,钙磷镁元素集中分布于颗粒中。SEM结果显示,牙本质表面未见大块沉积矿物,但高倍镜下可见5 mg/mL和10 mg/mL PAMAM-COOH/ACMP处理组的胶原纤维被连续矿物包裹并使纤维间隙减小。根据XRD与FTIR的检测结果,发现这些新生成的矿物为磷酸钙沉积。结论:成功制备了新型纳米材料PAMAM-COOH/ACMP纳米复合体,该纳米复合体在室温条件下尺寸稳定性佳,具有精确诱导人牙本质胶原纤维再矿化的能力。

羧基化的聚酰胺—胺/无定形磷酸钙诱导Ⅰ型胶原纤维矿化的研究

目的:利用羧基化的聚酰胺—胺稳定矿化物前驱相无定形磷酸钙,合成并表征同时具有有机和无机材料特性的仿生矿化复合物(ACP/CPAMAM),并观察其诱导胶原纤维仿生矿化的效果。方法:制备ACP/CPAMAM纳米复合物,并通过透射电子显微镜、选区电子衍射、粒径分析、电位分析等对其表征和验证。最终体外实验应用牛跟腱胶原纤维,借助透射电镜—能谱分析观察胶原纤维内部及周围晶体形成情况。结果:ACP/CPAMAM纳米复合物成功合成并且为无定形相,平均粒径为25.13 nm。透射电子显微镜及选区电子衍射显示,ACP的表面出现10 nm厚的低衬度包裹层,证实了ACP/CPAMAM的成功合成且其结构为非晶相。透射电镜—能谱分析显示,应用ACP/CPAMAM矿化肌腱Ⅰ型胶原纤维后可见高密度晶体,胶原纤维周围可见致密、连续的晶体形成,证实该纳米复合物可连续诱导胶原纤维矿化。结论:ACP/CPAMAM作为一种新型的纳米复合生物材料具有良好的生物活性和仿生矿化特性,能够诱导胶原纤维形成矿化产物,提示ACP/CPAMAM可能成为一种新型诱导胶原纤维仿生再矿化的纳米材料。

羧基化聚酰胺—胺/无定形磷酸钙改善牙本质粘接的实验研究

目的:探讨粘接剂负载羧基化聚酰胺-胺/无定形磷酸钙(PAMAM—COOH/ACP)纳米复合体对树脂-牙本质粘接性能的影响。方法:收集新鲜拔除的无龋无白斑人前磨牙或第三磨牙80个并制成统一牙本质粘接试样,将80个试样随机分为4组(A组、B组、C组、D组)。A组采用自酸蚀粘接剂进行树脂粘接,B组、C组、D组分别采用含0.3wt%ACP、0.3wt%PAMAM—COOH和0.3wt%PAMAM—COOH/ACP的自酸蚀粘接剂进行树脂粘接。对各组粘接试样行剪切强度测试,并对测试结果行单因素方差分析。采用扫描电子显微镜(SEM)观察各组牙本质粘接界面断端,并在超景深三维显微系统(50倍)下统计断裂类型。结果:A组、B组、C组、D组剪切强度分别为(8.67±4.78)MPa、(10.11±3.53)MPa、(11.94±4.78)MPa、(12.01±2.91)MPa。C组和D组的剪切强度均高于A组(P<0.05),B组、C组、D组组间比较,差异无统计学意义(P>0.05)。SEM下观察断端,A组只可见树脂残留,B组可见少量疏松矿化产物生成,C组可见矿化产物深入牙本质内,D组形成致密的矿化产物且牙本质小管管径缩小。各组的断裂模式均以黏附破坏为主,除A组外,其余各组均发生少量内聚破坏或混合破坏。结论:PAMAM—COOH/ACP纳米复合体加入自酸蚀粘接剂中可提高其树脂-牙本质粘接强度。