Blom E J, Klein-Nulend J, Wolke J G C, van Waas M A J, Driessens F C M, Burger E H
Department of Oral Cell Biology, Academic Centre for Dentistry Amsterdam, Amsterdam, The Netherlands.
J Biomed Mater Res. 2002 Feb;59(2):265-72. doi: 10.1002/jbm.1241.
The bone regenerative properties of calcium phosphate cements (CPCs) may be improved by the addition of growth factors, such as recombinant human transforming growth factor-beta1 (rhTGF-beta1). Previously, we showed that rhTGF-beta1 in CPC stimulated the differentiation of preosteoblastic cells from adult rat long bones. The intermixing of rhTGF-beta1 in CPC, which was subsequently applied to rat calvarial defects, enhanced bone growth around the cement and increased the degradation of the cement. However, it is unknown whether the addition of rhTGF-beta1 changes the material properties of CPC and what the characteristics of the release of rhTGF-beta1 from CPC are. Therefore, we determined in this study the release of rhTGF-beta1, in vitro, from the cement pellets as implanted in the rat calvariae. The possible intervening effects of rhTGF-beta1 intermixing on the clinical compliance of CPC were studied through an assessment of its compressive strength and setting time, as well as its crystallinity, calcium-to-phosphorus ratio, porosity, and microscopic structure. We prepared CPC by mixing calcium phosphate powder (58% alpha-tricalcium phosphate, 25% anhydrous dicalcium phosphate, 8.5% calcium carbonate, and 8.5% hydroxyapatite) with a liquid (3 g/mL). The liquid for standard CPC consisted of water with 4% disodium hydrogen phosphate, whereas the liquid for modified CPC was mixed with an equal amount of 4 mM hydrochloride with 0.2% bovine serum albumin. The hydrochloride liquid contained rhTGF-beta1 in different concentrations for the release experiments. Most of the rhTGF-beta1 incorporated in the cement pellets was released within the first 48 h. For all concentrations of intermixed rhTGF-beta1 (100 ng to 2.5 mg/g of CPC), approximately 0.5% was released in the first 4 h, increasing to 1.0% after 48 h. Further release was only about 0.1% from 2 days to 8 weeks. CPC modification slightly increased the initial setting time at 20 degrees C from 2.6 to 5 min but had no effect on the final setting time of CPC at 20 degrees C or the initial and final setting times at 37 degrees C. The compressive strength was increased from 18 MPa in the standard CPC to 28 MPa in the modified CPC only 4 h after mixing. The compressive strength diminished in the modified CPC between 24 h and 8 weeks from 55 to 25 MPa. No other significant change was found with the CPC modification for rhTGF-beta1. X-ray diffraction revealed that standard and modified CPCs changed similarly from the original components, alpha-tricalcium phosphate and anhydrous dicalcium phosphate, into an apatite cement. The calcium-to-phosphorus ratio, as determined with an electron microprobe, did not differ for standard CPC and modified CPC. Standard and modified CPCs became dense and homogeneous structures after 24 h, but the modified CPC contained more crystal plaques than the standard CPC, as observed with scanning electron microscopy (SEM). SEM and back- scattered electron images revealed that after 8 weeks the cements showed equally and uniformly dense structures with microscopic pores (<1 microm). Both CPCs showed fewer crystal plaques at 8 weeks than at 24 h. This study shows that CPC is not severely changed by its modification for rhTGF-beta1. The prolonged setting time of modified cement may affect the clinical handling but is still within acceptable limits. The compressive strength for both standard and modified cements was within the range of thin trabecular bone; therefore, both CPCs can withstand equal mechanical loading. The faster diminishing compressive strength of modified cement from 24 h to 8 weeks likely results in early breakdown and so might be favorable for bone regeneration. Together with the beneficial effects on bone regeneration from the addition of rhTGF-beta1 to CPC, as shown in our previous studies, we conclude that the envisaged applications for CPC in bone defects are upgraded by the intermixing of rhTGF-beta1. Therefore, the combination of CPC and rhTGF-beta1 forms a promising synthetic bone graft.
通过添加生长因子,如重组人转化生长因子β1(rhTGF-β1),磷酸钙骨水泥(CPC)的骨再生特性可能会得到改善。此前,我们发现CPC中的rhTGF-β1能刺激成年大鼠长骨前成骨细胞的分化。将rhTGF-β1混入CPC中,随后应用于大鼠颅骨缺损处,可促进骨水泥周围的骨生长并加速骨水泥的降解。然而,尚不清楚添加rhTGF-β1是否会改变CPC的材料特性,以及rhTGF-β1从CPC中释放的特点是什么。因此,在本研究中,我们测定了植入大鼠颅骨的骨水泥微丸中rhTGF-β1的体外释放情况。通过评估其抗压强度、凝固时间、结晶度、钙磷比、孔隙率和微观结构,研究了rhTGF-β1混入对CPC临床顺应性的可能干预作用。我们通过将磷酸钙粉末(58%α-磷酸三钙、25%无水磷酸二钙、8.5%碳酸钙和8.5%羟基磷灰石)与液体(3 g/mL)混合来制备CPC。标准CPC的液体由含4%磷酸氢二钠的水组成,而改性CPC的液体则与等量含0.2%牛血清白蛋白的4 mM盐酸混合。盐酸液体含有不同浓度的rhTGF-β1用于释放实验。混入骨水泥微丸中的大部分rhTGF-β1在最初48小时内释放。对于所有浓度的混入rhTGF-β1(100 ng至2.5 mg/g CPC),约0.5%在最初4小时内释放,48小时后增加到1.0%。从2天到8周的进一步释放仅约0.1%。CPC改性使20℃下的初始凝固时间从2.6分钟略有增加至5分钟,但对20℃下CPC的最终凝固时间或37℃下的初始和最终凝固时间没有影响。混合后仅4小时,抗压强度从标准CPC的18 MPa增加到改性CPC的28 MPa。改性CPC在24小时至8周之间的抗压强度从55 MPa降至25 MPa。rhTGF-β1对CPC的改性未发现其他显著变化。X射线衍射显示,标准和改性CPC从原始成分α-磷酸三钙和无水磷酸二钙转变为磷灰石骨水泥的方式相似。用电子微探针测定的钙磷比,标准CPC和改性CPC没有差异。24小时后,标准和改性CPC都变成致密均匀的结构,但如扫描电子显微镜(SEM)观察到的,改性CPC比标准CPC含有更多的晶体斑块。SEM和背散射电子图像显示,8周后骨水泥呈现出同样致密且均匀的结构,有微观孔隙(<1微米)。两种CPC在8周时的晶体斑块都比24小时时少。本研究表明,CPC因rhTGF-β1改性而未发生严重变化。改性骨水泥延长的凝固时间可能会影响临床操作,但仍在可接受范围内。标准和改性骨水泥的抗压强度都在薄小梁骨的范围内;因此,两种CPC都能承受同等的机械负荷。改性骨水泥从24小时到8周抗压强度更快地降低可能导致早期分解,因此可能有利于骨再生。结合我们之前研究中rhTGF-β1添加到CPC对骨再生的有益作用,我们得出结论,rhTGF-β1混入提升了CPC在骨缺损方面的预期应用。因此,CPC和rhTGF-β1的组合形成了一种有前景的合成骨移植材料。
