磷灰石晶体构型及其与生物分子相互作用的计算模拟研究

生物磷灰石是动物和人体骨骼及牙釉质的主要无机矿物成分,磷灰石矿物晶体的组成和结构影响了骨及牙釉质的机械强度和生理功能。羟基磷灰石空间群的确定一直存在争议,其中羟基存在两种不同排列方式,使得其具有六方和单斜两种晶相。另外,磷灰石晶体结构中的类质同象替换,影响了其结构、物理和化学特性。本文综述了计算机模拟方法在原子及分子水平上对磷灰石晶体的空间群确定、磷灰石替代机制、小分子及生物大分子相互作用的研究,对磷灰石晶体化学、界面化学及开发生物材料的深入研究具有一定的科学意义和较强的应用价值。     

制备条件影响碳酸羟基磷灰石晶格的计算分析

在碳酸羟基磷灰石(CHA)结构分析中,对A型取代(CO₃^2-取代OH^-)和B型取代(CO₃^2-取代PO₄^3-)2种取代的稳定性仍存有争议。为了研究碳酸取代的可能位置和2种取代稳定性,本文利用计算机辅助手段详细研究了不同反应顺序和不同反应试剂对碳酸羟基磷灰石晶体结构的影响。本实验分别采用含Na和不含Na 2种不同的反应试剂,分别在HA生成过程中和HA生成以后加入CO₃^2-,通过离子共沉淀法制备了4种碳酸羟基磷灰石。通过X射线衍射(XRD)、红外光谱(IR)对他们的结构和基团进行了表征,并用Jade 6.5, Materials Studio 4.0以及Origin 7.0进行了精修、计算和拟合。结果表明,无论工艺过程如何变化,均主要生成晶体能量较低、晶格结构稳定的B型取代碳酸羟基磷灰石;与普通磷灰石相比,由于存在晶格畸变,因此碳酸取代磷灰石的结晶度下降;碳酸根在反应溶液中的浓度影响CHA的晶格畸变程度,较高游离碳酸浓度引起的晶格畸变大;Na⁺的引入,可以降低碳酸羟基磷灰石中的晶格畸变,从而提高结晶度;含Na的B型取代主要是取代Ca(Ⅱ)位置的Ca离子。IR分析结果表明四种碳酸羟基磷灰石中的CO₃^2-均以B型取代为主,通过对870 cm^-1附近峰的拟合,计算出材料中A型取代和B型取代的比值。     

纳米磷灰石晶体的制备

在人体骨中,不同的年龄段,不同部位的生物磷灰石晶体的尺寸和形貌有差异[1-3],人们已经制备出纳米级类骨磷灰石晶体模拟天然骨磷灰石。合成方法、条件、反应的前驱物等不一样,得到晶体的形貌、尺寸也不一样[3,4]。本文用硝酸钙的二甲基甲酰胺溶液和磷酸钠水熔液反应制备纳米磷灰石晶体并研究其形貌和尺寸。1　材料和方法30克分析纯硝酸钙在搅拌下加入45克分析纯二甲基甲酰胺中(A)。18克分析纯磷酸纳溶解于1500ml去离子水中(B)。B加热到25℃,不断搅拌下,缓缓将溶液A滴入其中,滴定完后继续搅拌2h,温度控制在70℃。室温陈化24h、离心分离…     

羟基磷灰石/胶原矿化机理的研究进展

仿生合成的羟基磷灰石(HAp)/胶原复合材料的结构和成分与天然骨相似,具有很好的生物相容性、生物活性和生物可降解性,有望成为新一代的骨替代材料。羟基磷灰石/胶原矿化过程其实质是晶体在自组装的胶原纤维上形成的过程,但这一过程在体内是如何进行的至今仍然不清楚。对胶原矿化机理的研究能为制备具有更优越结构和功能的新型骨替代材料提供理论参考。本文概述了羟基磷灰石/胶原矿化机理的研究进展。     

纳米羟基磷灰石复合材料在硬组织工程领域中的应用研究

人体骨骼的晶体成分主要是纳米羟基磷灰石(n-HA),n-HA具有优良的生物相容性、骨传导性和骨结合能力,被广泛应用于硬组织修复材料中。本文综述了纳米羟基磷灰石在构建人体骨修复支架材料、骨替代材料和口腔医用材料方面的应用研究。     

鲁米诺-二甲亚砜-氢氧化钠体系化学发光机理的理论研究

用密度泛函理论(DFT) B3PW91/6-31G**方法研究了鲁米诺-二甲亚砜-氢氧化钠化学发光反应体系中反应物、中间体和产物的分子结构和振动频率, 用B3PW91/6-311＋G(3df,2p)方法获得反应能量以及用时间相关(Time Dependent, TD)的B3PW91/6-311＋G(3df, 2p)方法进行电子激发能态分析. 研究结果支持了下列化学发光反应通道: LH₂(¹A)＋OH^－ →LH₂•OH^－(¹A)→LH^－(¹A)→L^·－(²A)→TS₁(³A)→LO₂^2－(³A)→TS₂(³A)→AP^2－*(?³A)→AP^2－(X³A)＋hν, 最后即AP^2－*回到基态发光; 或AP^2－*(?³A)→AP^2－*(?¹A)→AP^2－(a¹A)＋hν, 即激发态势能面交叉后的单重态跃迁发光. 它们在可见光区域主要有400～460和500～530 nm的强吸收谱带, 与实验结果符合. 研究还表明, 质子化的鲁米诺能量将大幅度降低, 说明酸性溶液导致鲁米诺的反应活性降低, 从理论上解释了鲁米诺化学发光体系的溶液须呈碱性, pH值影响发光反应的实验事实.     

DNA-纳米多孔羟基磷灰石修饰电极用于研究DNA与亚甲基蓝的相互作用

利用溶胶-凝胶法将具有优良生物相容性和独特吸附性的羟基磷灰石(HAp)修饰在玻碳电极上形成纳米多孔薄膜. 电化学实验结果证明该纳米多孔羟基磷灰石薄膜能有效地将双链DNA吸附于其表面. 采用循环伏安法系统研究了固定在HAp薄膜上的DNA与亚甲基蓝(MB)之间的相互作用. 实验结果表明, 在20～200 mV•s^－1扫描速度范围内该电极反应过程系表面反应控制; 在pH 6.0～7.4范围内, MB在DNA修饰电极上的峰电位随pH的增加而向负方向移动; 当磷酸盐缓冲溶液中的离子强度小于59 mmol•L^－1时, MB与DNA之间为静电作用, 当离子强度大于59 mmol•L^－1时, 二者之间既有静电作用, 也有部分嵌入作用. 根据Langmuir吸附公式, 得出MB与DNA之间的结合常数为4.2×10⁴ mol^－1•L.     

光引发甲基丙烯酸聚合改性羟基磷灰石表面的研究

羟基磷灰石(HPA)具有良好的生物相容性和生物活性,被认为是最有前途的陶瓷人工齿和人工骨置换材料。然而,纯HAP的力学性能比较差,断裂韧性(KIC)不超过1.0MPa.m1/2(自然骨为2-12MPa.m1/2)[1],作为人工种植体其使用可靠性较差。这大大限制了它在承载部位骨替换中的应用。为了改善     

羟基磷灰石在磺化聚醚苯并咪唑薄膜表面的生长

以聚[2,2′-(对氧基联苯)-5,5′-苯并咪唑](OPBI)及其磺化产物磺化聚[2,2′-(对氧基联苯)-5,5′-苯并咪唑](SOPBI)薄膜作为基体, 采用交替沉积和模拟体液(SBF)浸泡相结合的方法快速在薄膜表面沉积羟基磷灰石层. 采用选区电子衍射(SAED)和衰减全反射傅里叶变换红外光谱(ATR-FTIR)对羟基磷灰石(HA)的晶体结构进行了分析. 用扫描电子显微镜(SEM)对整个沉积过程中羟基磷灰石的形态变化进行了跟踪. 实验结果表明, SOPBI薄膜诱导HA沉积的速率明显快于OPBI薄膜. SOPBI的磺酸基团不但提供了固定Ca²⁺的负电表面, 而且还有助于咪唑基团对Ca²⁺的固定. 而缺失磺酸基团的OPBI在不同pH值的交替沉积溶液中的电离形式阻碍了咪唑基团对Ca²⁺和HPO₄^2-的作用, 且未能在SBF浸泡过程中得到改善.     

羟基磷灰石对牛血清白蛋白的吸附特性研究

研究了羟基磷灰石表面电位随溶液PO₄^3-浓度、Ca²⁺浓度、离子强度和pH的变化规律;测定了不同操作条件下牛血清白蛋白在羟基磷灰石上的吸附容量;吸附等温线的测定结果表明该吸附属于Langmuir型;通过对该吸附过程的动力学研究,计算得到的表观活化能和吸附热数值较低,表明该吸附是物理吸附.     

聚丙烯酸钠对钛表面仿生生长磷灰石涂层的调制

1　前言羟基磷灰石 (Ｃａ10 (ＯＨ) 2 (ＰＯ4 ) 6,ｈｙｄｒｏｘｙａｐａｔｉｔｅ ,ＨＡ)作为人体硬组织的主要无机成分具有良好的生物活性。钛表面等离子喷涂ＨＡ综合了钛的力学性能和ＨＡ的生物活性 ,得到了广泛应用[1] 。但喷涂技术具有视线效应的缺点 ,同时涂层与基体界面的长期可靠性也是广泛关注的问题。为此发展的各种涂层方法中仿生化学法制备磷灰石涂层是极为活跃的前沿领域[2 ] 之一。仿生法基于异相成核原理[3 ] :将基体预先功能化后浸入磷酸钙过饱和溶液 ,在溶液过饱和度低于均相沉淀的条件下在基体表面发生磷灰石异相成核并自发…     

Interatomic potential models for natural apatite crystals: incorporating strontium and the lanthanides

A comprehensive set of interatomic potential parameters for modeling natural apatite crystals is presented. These potentials build on those previously used in research on apatites with new potentials fitted empirically to crystal structures and their properties using the GULP program. We demonstrate that the new potentials produce good models for the different compounds used for fitting, as well as for several natural apatites. Also presented are predicted enthalpies of mixing of strontium and calcium apatites and predicted cation site preferences in strontium calcium fluorapatite.     

可降解自固化类骨磷灰石支架的研究

0引言一直以来,钙磷生物材料如羟基磷灰石(hy-droxyapatite,HA)由于其成份与骨的无机成份相似,具有良好的生物相容性,作为骨修复材料引起了人们广泛的兴趣。磷酸钙骨水泥是一类可在生理条件下自固化的非陶瓷型类HA人工骨材料,这种由磷酸钙骨水泥(calcium phosphate cement,CPC)转变而成的HA,与天然骨磷灰石有类似的组成结构,植入人体后可参与新陈代谢,促进骨组织生长[1,2]。一些研究显示,CPC具有成骨活性和生物降解性,在体内被吸收的同时可引导新骨的生成,从而可克服自体骨、磷酸三钙陶瓷因吸收降解过快造成的局部缺陷以及陶瓷型HA长…     

Kinetics of 1H --> 31P NMR cross-polarization in bone apatite and its mineral standards

Kinetics of NMR cross-polarization (CP) from protons to phosphorus-31 nuclei was studied in the following samples: mineral of whole human bone, apatite prepared from bone, natural brushite, synthetic hydroxyapatite (hydrated and calcined), and synthetic carbonatoapatite of type B with 9 wt% of CO(3) (2-). In order to avoid an effect of magic angle spinning on CP and relaxation, the experiments were carried out on static samples. Parameters of the CP kinetics were discussed for trabecular and cortical bone tissue from adult subjects in comparison to the synthetic mineral standards. It was found that carbonatoapatite shows similar CP behavior to the bone mineral. Both materials undergo two-component CP kinetics. The fast-relaxing classical component is from the surface of apatite crystals and the slow-relaxing nonclassical component comes from the crystal interior. The components have been unambiguously assigned using inverse CP from phosphorus-31 to protons. The study provides information on a structured water layer, which covers crystal surface of carbonato- and bone apatite. The layer encompasses ca 40% of apatite phosphorus and its thickness is more than ca 2 nm.     

Thermal and structural properties of sodium,potassium and carbonate doped strontium hydroxyfluorapatite

Ion-doping in hydroxyapatite bioceramics has attracted a lot of interest particularly for biomedical applications in repairing and replacing failure parts of musculoskeletal systems. Thus the multiple doping aims to mimic and resemble the chemical composition of the bone mineral component. Herein strontium hydroxyapatites bioceramics containing sodium Na⁺ and potassium K⁺ as cationic substituent and carbonate CO₃^2? and fluoride as anionic substituent were synthesized and characterized by several analysis techniques. Therefore the chemical assays indicated that obtained compounds were less stoichiometric comparably to bone tissues. The X-ray diffraction diagrams and the infrared spectra revealed that pure phases of hydroxyfluorapatite containg the cited ions were obtained. The triple insertion of sodium, potassium and carbonate into the apatite structure leaded to the B-type carbonate apatite. The FE-SEM micrographs of the powders were formed by agglomerates. Moreover, the particles' morphology strongly depends on the ions nature and amount. The D-GTA curves indicated that the heating of the powders from the room temperature to 1000 °C didn't affect the structural and thermal stability of the materials apart from a partial decomposition of the apatite inducing the formation of the β-tristrontium phosphate phase and enhancing the biomaterial character of the materials.     

钛表面生物活性榍石/氧化钛复合涂层的结构和磷灰石形成机理

采用微弧氧化和热处理复合技术,在钛表面制备了具有双层结构的榍石/氧化钛复合涂层。榍石/氧化钛复合涂层的外层是由微弧氧化涂层经热处理后晶化生成;而内层是由钛基底的氧化生成,并且氧化钛表现出不同的Ti,O原子比。由于钛基底的氧化,孔径在50~500nm的微孔呈层状结构分布在涂层内层。与微弧氧化涂层相比,该复合涂层具有很好的磷灰石诱导能力,这是由于榍石沿着特定晶面和晶向与羟基磷灰石表现出良好的晶体学匹配关系,从而为磷灰石的成核和取向沉积过程提供良好的位点。     

钛表面生物活性榍石/氧化钛复合涂层的结构和磷灰石形成机理(英文)

采用微弧氧化和热处理复合技术,在钛表面制备了具有双层结构的榍石/氧化钛复合涂层。榍石/氧化钛复合涂层的外层是由微弧氧化涂层经热处理后晶化生成;而内层是由钛基底的氧化生成,并且氧化钛表现出不同的Ti,O原子比。由于钛基底的氧化,孔径在50~500 nm的微孔呈层状结构分布在涂层内层。与微弧氧化涂层相比,该复合涂层具有很好的磷灰石诱导能力,这是由于榍石沿着特定晶面和晶向与羟基磷灰石表现出良好的晶体学匹配关系,从而为磷灰石的成核和取向沉积过程提供良好的位点。     

Regulating the physicochemical and biological properties in vitro of octacalcium phosphate by substitution with strontium in a large doping range

Octacalcium phosphate (OCP) is a key precursor of biological apatite in bone and teeth with excellent osteoconductive and biodegradable properties for bone regeneration. In this work, strontium was employed for improving the poor bioactivity and osteogenesis of OCP by ionic substitution using a homogeneous precipitation method. Sr was successfully incorporated in the structure within a fairly large doping range, even up to 23.25 mol.%, leading to lattice expansion and preferred growth. Sr-OCP samples with better cellular affinity had significantly enhanced the viability, proliferation and osteogenic differentiation of bone mesenchymal stem cells, compared with control. Dynamically released biological ions were involved in the biological apatite deposition for biomineralization/cellular calcification, and remarkably promoted the osteogenic ability. Results indicated the effective enhancements of Sr substitution on the biocompatibility, bioactivity and osteogenesis of OCP biomaterials, providing a potential strategy for the accounts of ionic substitution in biomaterials and the following bone repair applications.     

Optimisation de la Synthèse des Apatites Phosphocalciques Vectrices D’antiseptiques Élaborées à Partir du Nitrate de Calcium et de L’Acide Phosphorique

Oxygenated phosphocalcic apatite is an apatite with an excellent biocompatibility, osteoconduction, and having antiseptic properties able to limit the proliferation of the micro-organisms in the site implementation, without using an antibiotic. However, the synthesis of this apatite encounters several difficulties. On one hand, it depends on many factors such as pH of the reaction, atomic ratio Ca/P of the reagents, temperature of the reaction (T), duration of reaction (D), and concentration in ions calcium ([Ca²⁺]). On the other hand, the product to be developed must have a chemical composition allowing it a dissolution speed in compliance with the bone neoformation and having antiseptic properties.

Aiming to control the synthesis of these apatites and to limit the number of experiments necessary to this study, we applied the methodology of the experimental designs. The mathematical models elaborated in this study allowed us to forecast the optimum conditions of the oxygenated phosphocalcic apatite synthesis.

Supplemental materials are available for this article. Go to the publisher's online edition of Phosphorus, Sulfur, and Silicon and the Related Elements to view the free supplemental file.