生物陶瓷

原位形成的针状缺钙型HA晶体提高了多孔生物陶瓷的抗压强度。

Needle-like calcium-deficient hydroxyapatite created in-situ reinforces compressive strength of the porous bioceramic .

HA生物陶瓷材料的增强工艺探讨

Discussion on Reinforcement Technology of HA Bioceramic Material

Fe3Al/HAP生物陶瓷的制备及力学性能

Preparation and Properties of Fe_3Al / HAP Composite Biomaterials

烧结条件对多孔HA生物陶瓷种植体性能的影响

Effects of sintering condition on property of porous HA bioceramic implant

晶须取向对HAP/SiCw复合生物陶瓷力学性能的影响

Effect of Whisker Orientation on Mechanical Properties of HAP - SiC_w Composite Bioceramics

研究结果表明：1、采用有机泡沫浸法可以制备三维贯通的网化HA生物陶瓷，孔径大小均匀，孔隙高达95%。

The porosity reached 95 % with homogeneous pore size .

激光合成HA生物陶瓷涂层的热力学动力学研究

Thermodynamic and Dynamics of Laser Synthesizing HA Bioceramic Coating

几种阳离子置换磷酸钙生物陶瓷的XRD分析

XRD analysis of several cation-substituted calcium phosphate bioceramics

Y2O3对激光涂覆生物陶瓷涂层的影响

Effect of Y_2O_3 on Bioceramic Coating by Laser Cladding

Ti基表面激光涂敷生物陶瓷初探

Laser Cladding Bioceramic Coating on Ti-substrate

用于大段骨缺损修复的TCP／HA基多孔生物陶瓷的研制

The Development Study of TCP / HA based Porous Bioceramics for Repair of Large Segment Bone Defects

磷酸钙生物陶瓷材料包括磷酸三钙（β-TCP）和羟基磷灰石（HA），具有较好的生物相容性和生物活性。

The calcium phosphate bioceramics , including tricalcium phosphate and hydroxyapatite , possess better biocompatibility and bioactivity .

本文采用原位合成技术制备了多孔CaOP2O5SiO2系生物陶瓷。

The porous CaO-P 2O 5-SiO 2 system bioceramics were prepared by in-situ synthesis technique .

主要对多孔βTCP生物陶瓷在体内降解过程进行研究。

This paper was devoted to the study of the biodegradation process in vivo of porous β - TCP bioceramics .

采用一种电化学沉积磷酸钙生物陶瓷涂层的新方法&阴极旋转电沉积工艺。通过测定涂层的XRD、界面结合强度、SEM观察表面与断面，研究了工艺的沉积特性及机理。

A kind of new method of electrochemical deposited calcium phosphate bioceramic coating-electrodeposition bioceramic coating by cathode revolving is introduced .

影响α-TCP和HA生物陶瓷表面形成类骨磷灰石的形貌、结构的因素研究

Critical factors on the morphology and structure of Bone-like apatite layers formed on α - TCP and HA surfaces

RPM技术在生物陶瓷人工骨制备过程中的应用

Application of Rapid Prototyping Manufacturing in the Preparation of Bioceramic Artificial Bone

PLD制备生物陶瓷薄膜的研究现状

Present research state of pulsed laser deposition of bioceramic coating

激光辐照对HAP生物陶瓷显微组织结构的影响

The Effect of Laser Irradiation on Microstructure of HAP Bioceramic

双相磷酸钙（biphasiccalciumphosphate，BCP）生物陶瓷材料在整型外科领域是一类重要的骨修复材料。

Biphasic calcium phosphate ( BCP ) ceramic is an important bone grafting material in orthopedic field .

结果表明，采用激光表面重熔预处理作过渡层制备的生物陶瓷涂层的界面结合良好，表层为HA和β－TCP组成的活性生物陶瓷复合涂层。

The results show that laser remelting pretreatment is favorable to improvement of the mechanical properties and biocompatibility of bioceramic coating .

对双壳类贝壳的扫描电镜（SEM）观察显示它是一种由细片状无机霰石和有机胶原蛋白组成的生物陶瓷复合材料。

The observation of scanning electron microscope shows that bivalve shell is a bio-ceramic composite consisting of thin sheets of aragonite and organic proteins .

电参数对钛合金微弧氧化法制备TiO2生物陶瓷涂层的影响

Effect of Electrical Parameters on Preparing TiO_2 Bioceramic Coatings on Titanium Alloy by Micro-arc Oxidation Technique

该研究从β磷酸三钙（βTCP）粉末制备开始，通过改变其组成和改进其制备工艺，制取了性能优良的βTCP多孔生物陶瓷。

The preparation of porous β - tricalcium phosphate bioceramic ( PTCP ) was improved with the adjustment of the constituents and the sintering-process .

脉冲激光沉积羟基磷灰石（HAP）生物陶瓷涂层的研究进展

Development of Research on Hydroxyapatite ( HAP ) Bioceramic Coating Fabricated by Pulsed Laser Deposition

目的采用廉价的CaCO3和CaHPO4·2H2O作为原料，在激光的作用下通过反应制备HA生物陶瓷涂层。

Objective Calcium phosphate bioceramic coatings were synthesized by laser using cheap raw materials CaCO_3 and CaHPO_4 · 2H_2O .

目的建立一种新的生物陶瓷（Bioceramics）体内血管化动物模型。

Objective To establish a new vascularized animal-model with bioceramics .

微弧氧化法直接合成CaTi4（PO4）6生物陶瓷膜

Direct synthesis of CaTi_4 ( PO_4 ) _6 bio-ceramic film by micro-arc oxidation

将羟基磷灰石（HAP）电泳沉积在钛基材上，得到了结构稳定的HAP生物陶瓷涂层。

Hydroxyapatite ( HAP ) bioceramic coatings with stable structure were prepared on titanium substrate by electrophoretic deposition .

目的为了解决骨组织工程中成骨细胞在可降解支架材料上三维生长这一问题，本文对无机聚合物聚磷酸钙（CPP）生物陶瓷进行了研究。

Objective To help in solving the problem of growth of osteoblasts on biodegradable scaffolds in bone tissue engineering .